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source: branches/2994-AutoDiffForIntervals/HeuristicLab.Problems.DataAnalysis.Symbolic/3.4/Interpreter/Interpreter.cs @ 17131

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Last change on this file since 17131 was 17131, checked in by gkronber, 5 years ago
#2994: added support for tanh symbol in new interpreters
File size: 51.5 KB

Rev	Line
[16674]	1	using System;
	2	using System.Collections.Generic;
[16695]	3	using System.Diagnostics;
[16674]	4	using System.Linq;
	5	using HeuristicLab.Common;
	6	using HeuristicLab.Encodings.SymbolicExpressionTreeEncoding;
	7
	8	namespace HeuristicLab.Problems.DataAnalysis.Symbolic {
	9	public abstract class Interpreter<T> where T : IAlgebraicType<T> {
	10	public struct Instruction {
	11	public byte opcode;
	12	public ushort narg;
	13	public int childIndex;
	14	public double dblVal;
	15	public object data; // any kind of data you want to store in instructions
	16	public T value;
	17	}
	18
	19	public T Evaluate(Instruction[] code) {
	20	for (int i = code.Length - 1; i >= 0; --i) {
	21	var instr = code[i];
	22	var c = instr.childIndex;
	23	var n = instr.narg;
	24
	25	switch (instr.opcode) {
	26	case OpCodes.Variable: {
	27	LoadVariable(instr);
	28	break;
	29	}
[16694]	30	case OpCodes.Constant: { break; } // we initialize constants in Compile. The value never changes afterwards
[16674]	31	case OpCodes.Add: {
	32	instr.value.Assign(code[c].value);
	33	for (int j = 1; j < n; ++j) {
	34	instr.value.Add(code[c + j].value);
	35	}
	36	break;
	37	}
	38
	39	case OpCodes.Sub: {
	40	if (n == 1) {
	41	instr.value.AssignNeg(code[c].value);
	42	} else {
	43	instr.value.Assign(code[c].value);
	44	for (int j = 1; j < n; ++j) {
	45	instr.value.Sub(code[c + j].value);
	46	}
	47	}
	48	break;
	49	}
	50
	51	case OpCodes.Mul: {
	52	instr.value.Assign(code[c].value);
	53	for (int j = 1; j < n; ++j) {
	54	instr.value.Mul(code[c + j].value);
	55	}
	56	break;
	57	}
	58
	59	case OpCodes.Div: {
	60	if (n == 1) {
	61	instr.value.AssignInv(code[c].value);
	62	} else {
	63	instr.value.Assign(code[c].value);
	64	for (int j = 1; j < n; ++j) {
	65	instr.value.Div(code[c + j].value);
	66	}
	67	}
	68	break;
	69	}
[16694]	70	case OpCodes.Square: {
	71	instr.value.AssignIntPower(code[c].value, 2);
	72	break;
	73	}
[16727]	74	case OpCodes.SquareRoot: {
	75	instr.value.AssignIntRoot(code[c].value, 2);
	76	break;
	77	}
	78	case OpCodes.Cube: {
	79	instr.value.AssignIntPower(code[c].value, 3);
	80	break;
	81	}
	82	case OpCodes.CubeRoot: {
	83	instr.value.AssignIntRoot(code[c].value, 3);
	84	break;
	85	}
[16674]	86	case OpCodes.Exp: {
	87	instr.value.AssignExp(code[c].value);
	88	break;
	89	}
	90	case OpCodes.Log: {
	91	instr.value.AssignLog(code[c].value);
	92	break;
	93	}
[16727]	94	case OpCodes.Sin: {
	95	instr.value.AssignSin(code[c].value);
	96	break;
	97	}
	98	case OpCodes.Cos: {
	99	instr.value.AssignCos(code[c].value);
	100	break;
	101	}
	102	case OpCodes.Absolute: {
	103	instr.value.AssignAbs(code[c].value);
	104	break;
	105	}
	106	case OpCodes.AnalyticQuotient: {
	107	instr.value.Assign(code[c].value);
	108	for (int j = 1; j < n; ++j) {
	109	var t = instr.value.One;
	110	t.Add(code[c + j].value.Clone().IntPower(2));
	111	instr.value.Div(t.IntRoot(2));
	112	}
	113	break;
	114	}
[17131]	115	case OpCodes.Tanh: {
	116	instr.value.AssignTanh(code[c].value);
	117	break;
	118	}
	119
	120	default: throw new ArgumentException($"Unknown opcode {instr.opcode}");
[16674]	121	}
	122	}
	123	return code[0].value;
	124	}
	125
	126	protected Instruction[] Compile(ISymbolicExpressionTree tree) {
	127	var root = tree.Root.GetSubtree(0).GetSubtree(0);
	128	var code = new Instruction[root.GetLength()];
	129	if (root.SubtreeCount > ushort.MaxValue) throw new ArgumentException("Number of subtrees is too big (>65.535)");
	130	int c = 1, i = 0;
	131	foreach (var node in root.IterateNodesBreadth()) {
	132	if (node.SubtreeCount > ushort.MaxValue) throw new ArgumentException("Number of subtrees is too big (>65.535)");
	133	code[i] = new Instruction {
	134	opcode = OpCodes.MapSymbolToOpCode(node),
	135	narg = (ushort)node.SubtreeCount,
	136	childIndex = c
	137	};
	138	if (node is VariableTreeNode variable) {
	139	InitializeTerminalInstruction(ref code[i], variable);
	140	} else if (node is ConstantTreeNode constant) {
	141	InitializeTerminalInstruction(ref code[i], constant);
	142	} else {
	143	InitializeInternalInstruction(ref code[i], node);
	144	}
	145	c += node.SubtreeCount;
	146	++i;
	147	}
	148	return code;
	149	}
	150
	151	protected abstract void InitializeTerminalInstruction(ref Instruction instruction, ConstantTreeNode constant);
	152	protected abstract void InitializeTerminalInstruction(ref Instruction instruction, VariableTreeNode variable);
	153	protected abstract void InitializeInternalInstruction(ref Instruction instruction, ISymbolicExpressionTreeNode node);
	154
	155	protected abstract void LoadVariable(Instruction a);
	156
	157	}
	158
	159
[16695]	160	public sealed class VectorEvaluator : Interpreter<AlgebraicDoubleVector> {
[16674]	161	private const int BATCHSIZE = 128;
	162	[ThreadStatic]
	163	private Dictionary<string, double[]> cachedData;
	164
	165	[ThreadStatic]
	166	private IDataset dataset;
	167
	168	[ThreadStatic]
	169	private int rowIndex;
	170
	171	[ThreadStatic]
	172	private int[] rows;
	173
	174	private void InitCache(IDataset dataset) {
	175	this.dataset = dataset;
	176	cachedData = new Dictionary<string, double[]>();
	177	foreach (var v in dataset.DoubleVariables) {
	178	cachedData[v] = dataset.GetReadOnlyDoubleValues(v).ToArray();
	179	}
	180	}
	181
	182	public double[] Evaluate(ISymbolicExpressionTree tree, IDataset dataset, int[] rows) {
	183	if (cachedData == null \|\| this.dataset != dataset) {
	184	InitCache(dataset);
	185	}
	186
	187	this.rows = rows;
	188	var code = Compile(tree);
	189	var remainingRows = rows.Length % BATCHSIZE;
	190	var roundedTotal = rows.Length - remainingRows;
	191
	192	var result = new double[rows.Length];
	193
	194	for (rowIndex = 0; rowIndex < roundedTotal; rowIndex += BATCHSIZE) {
	195	Evaluate(code);
	196	code[0].value.CopyTo(result, rowIndex, BATCHSIZE);
	197	}
	198
	199	if (remainingRows > 0) {
	200	Evaluate(code);
	201	code[0].value.CopyTo(result, roundedTotal, remainingRows);
	202	}
	203
	204	return result;
	205	}
	206
	207	protected override void InitializeTerminalInstruction(ref Instruction instruction, ConstantTreeNode constant) {
	208	instruction.dblVal = constant.Value;
[16695]	209	instruction.value = new AlgebraicDoubleVector(BATCHSIZE);
[16674]	210	instruction.value.AssignConstant(instruction.dblVal);
	211	}
	212
	213	protected override void InitializeTerminalInstruction(ref Instruction instruction, VariableTreeNode variable) {
	214	instruction.dblVal = variable.Weight;
[16695]	215	instruction.value = new AlgebraicDoubleVector(BATCHSIZE);
[16674]	216	if (cachedData.ContainsKey(variable.VariableName)) {
	217	instruction.data = cachedData[variable.VariableName];
	218	} else {
	219	instruction.data = dataset.GetDoubleValues(variable.VariableName).ToArray();
	220	cachedData[variable.VariableName] = (double[])instruction.data;
	221	}
	222	}
	223
	224	protected override void InitializeInternalInstruction(ref Instruction instruction, ISymbolicExpressionTreeNode node) {
[16695]	225	instruction.value = new AlgebraicDoubleVector(BATCHSIZE);
[16674]	226	}
	227
	228	protected override void LoadVariable(Instruction a) {
	229	var data = (double[])a.data;
	230	for (int i = rowIndex; i < rows.Length && i - rowIndex < BATCHSIZE; i++) a.value[i - rowIndex] = data[rows[i]];
	231	a.value.Scale(a.dblVal);
	232	}
	233	}
	234
[16695]	235	public sealed class VectorAutoDiffEvaluator : Interpreter<MultivariateDual<AlgebraicDoubleVector>> {
[16674]	236	private const int BATCHSIZE = 128;
	237	[ThreadStatic]
	238	private Dictionary<string, double[]> cachedData;
	239
	240	[ThreadStatic]
	241	private IDataset dataset;
	242
	243	[ThreadStatic]
	244	private int rowIndex;
	245
	246	[ThreadStatic]
	247	private int[] rows;
	248
	249	[ThreadStatic]
	250	private Dictionary<ISymbolicExpressionTreeNode, int> node2paramIdx;
	251
	252	private void InitCache(IDataset dataset) {
	253	this.dataset = dataset;
	254	cachedData = new Dictionary<string, double[]>();
	255	foreach (var v in dataset.DoubleVariables) {
	256	cachedData[v] = dataset.GetDoubleValues(v).ToArray();
	257	}
	258	}
	259
[16727]	260	/// <summary>
	261	///
	262	/// </summary>
	263	/// <param name="tree"></param>
	264	/// <param name="dataset"></param>
	265	/// <param name="rows"></param>
	266	/// <param name="parameterNodes"></param>
	267	/// <param name="fi">Function output. Must be allocated by the caller.</param>
	268	/// <param name="jac">Jacobian matrix. Must be allocated by the caller.</param>
	269	public void Evaluate(ISymbolicExpressionTree tree, IDataset dataset, int[] rows, ISymbolicExpressionTreeNode[] parameterNodes, double[] fi, double[,] jac) {
[16674]	270	if (cachedData == null \|\| this.dataset != dataset) {
	271	InitCache(dataset);
	272	}
	273
	274	int nParams = parameterNodes.Length;
	275	node2paramIdx = new Dictionary<ISymbolicExpressionTreeNode, int>();
	276	for (int i = 0; i < parameterNodes.Length; i++) node2paramIdx.Add(parameterNodes[i], i);
	277
	278	var code = Compile(tree);
	279
	280	var remainingRows = rows.Length % BATCHSIZE;
	281	var roundedTotal = rows.Length - remainingRows;
	282
	283	this.rows = rows;
	284
	285	for (rowIndex = 0; rowIndex < roundedTotal; rowIndex += BATCHSIZE) {
	286	Evaluate(code);
	287	code[0].value.Value.CopyTo(fi, rowIndex, BATCHSIZE);
	288
	289	// TRANSPOSE into JAC
[16682]	290	var g = code[0].value.Gradient;
	291	for (int j = 0; j < nParams; ++j) {
[16744]	292	if (g.Elements.TryGetValue(j, out AlgebraicDoubleVector v)) {
[16727]	293	v.CopyColumnTo(jac, j, rowIndex, BATCHSIZE);
	294	} else {
	295	for (int r = 0; r < BATCHSIZE; r++) jac[rowIndex + r, j] = 0.0;
	296	}
[16682]	297	}
[16674]	298	}
	299
	300	if (remainingRows > 0) {
	301	Evaluate(code);
	302	code[0].value.Value.CopyTo(fi, roundedTotal, remainingRows);
[16682]	303
	304	var g = code[0].value.Gradient;
[16674]	305	for (int j = 0; j < nParams; ++j)
[16727]	306	if (g.Elements.TryGetValue(j, out AlgebraicDoubleVector v)) {
	307	v.CopyColumnTo(jac, j, roundedTotal, remainingRows);
	308	} else {
	309	for (int r = 0; r < remainingRows; r++) jac[roundedTotal + r, j] = 0.0;
	310	}
[16674]	311	}
	312	}
	313
	314	protected override void InitializeInternalInstruction(ref Instruction instruction, ISymbolicExpressionTreeNode node) {
[16695]	315	var zero = new AlgebraicDoubleVector(BATCHSIZE);
	316	instruction.value = new MultivariateDual<AlgebraicDoubleVector>(zero);
[16674]	317	}
	318
	319	protected override void InitializeTerminalInstruction(ref Instruction instruction, ConstantTreeNode constant) {
	320	var g_arr = new double[BATCHSIZE];
[16682]	321	if (node2paramIdx.TryGetValue(constant, out var paramIdx)) {
[16674]	322	for (int i = 0; i < BATCHSIZE; i++) g_arr[i] = 1.0;
[16695]	323	var g = new AlgebraicDoubleVector(g_arr);
	324	instruction.value = new MultivariateDual<AlgebraicDoubleVector>(new AlgebraicDoubleVector(BATCHSIZE), paramIdx, g); // only a single column for the gradient
[16682]	325	} else {
[16695]	326	instruction.value = new MultivariateDual<AlgebraicDoubleVector>(new AlgebraicDoubleVector(BATCHSIZE));
[16674]	327	}
	328
[16682]	329	instruction.dblVal = constant.Value;
[16674]	330	instruction.value.Value.AssignConstant(instruction.dblVal);
	331	}
	332
	333	protected override void InitializeTerminalInstruction(ref Instruction instruction, VariableTreeNode variable) {
	334	double[] data;
	335	if (cachedData.ContainsKey(variable.VariableName)) {
	336	data = cachedData[variable.VariableName];
	337	} else {
	338	data = dataset.GetReadOnlyDoubleValues(variable.VariableName).ToArray();
	339	cachedData[variable.VariableName] = (double[])instruction.data;
	340	}
	341
	342	var paramIdx = -1;
	343	if (node2paramIdx.ContainsKey(variable)) {
	344	paramIdx = node2paramIdx[variable];
[16695]	345	var f = new AlgebraicDoubleVector(BATCHSIZE);
	346	var g = new AlgebraicDoubleVector(BATCHSIZE);
	347	instruction.value = new MultivariateDual<AlgebraicDoubleVector>(f, paramIdx, g);
[16682]	348	} else {
[16695]	349	var f = new AlgebraicDoubleVector(BATCHSIZE);
	350	instruction.value = new MultivariateDual<AlgebraicDoubleVector>(f);
[16674]	351	}
	352
	353	instruction.dblVal = variable.Weight;
	354	instruction.data = new object[] { data, paramIdx };
	355	}
	356
	357	protected override void LoadVariable(Instruction a) {
	358	var paramIdx = (int)((object[])a.data)[1];
	359	var data = (double[])((object[])a.data)[0];
	360
	361	for (int i = rowIndex; i < rows.Length && i - rowIndex < BATCHSIZE; i++) a.value.Value[i - rowIndex] = data[rows[i]];
	362	a.value.Scale(a.dblVal);
	363
	364	if (paramIdx >= 0) {
	365	// update gradient with variable values
[16682]	366	var g = a.value.Gradient.Elements[paramIdx];
[16674]	367	for (int i = rowIndex; i < rows.Length && i - rowIndex < BATCHSIZE; i++) {
[16727]	368	g[i - rowIndex] = data[rows[i]];
[16674]	369	}
	370	}
	371	}
	372	}
	373
	374
[16693]	375	public sealed class IntervalEvaluator : Interpreter<AlgebraicInterval> {
[16674]	376	[ThreadStatic]
[16831]	377	private IDictionary<string, Interval> intervals;
[16674]	378
[16831]	379	public Interval Evaluate(ISymbolicExpressionTree tree, IDictionary<string, Interval> intervals) {
[16674]	380	this.intervals = intervals;
	381	var code = Compile(tree);
	382	Evaluate(code);
[16682]	383	return new Interval(code[0].value.LowerBound.Value.Value, code[0].value.UpperBound.Value.Value);
[16674]	384	}
	385
[16831]	386	public Interval Evaluate(ISymbolicExpressionTree tree, IDictionary<string, Interval> intervals, ISymbolicExpressionTreeNode[] paramNodes, out double[] lowerGradient, out double[] upperGradient) {
[16682]	387	this.intervals = intervals;
	388	var code = Compile(tree);
	389	Evaluate(code);
	390	lowerGradient = new double[paramNodes.Length];
	391	upperGradient = new double[paramNodes.Length];
	392	var l = code[0].value.LowerBound;
	393	var u = code[0].value.UpperBound;
	394	for (int i = 0; i < paramNodes.Length; ++i) {
[16694]	395	if (paramNodes[i] == null) continue;
[16738]	396	if (l.Gradient.Elements.TryGetValue(paramNodes[i], out AlgebraicDouble value)) lowerGradient[i] = value;
	397	if (u.Gradient.Elements.TryGetValue(paramNodes[i], out value)) upperGradient[i] = value;
[16682]	398	}
	399	return new Interval(code[0].value.LowerBound.Value.Value, code[0].value.UpperBound.Value.Value);
	400	}
[16674]	401
	402	protected override void InitializeInternalInstruction(ref Instruction instruction, ISymbolicExpressionTreeNode node) {
	403	instruction.value = new AlgebraicInterval(0, 0);
	404	}
	405
	406
	407	protected override void InitializeTerminalInstruction(ref Instruction instruction, ConstantTreeNode constant) {
	408	instruction.dblVal = constant.Value;
[16682]	409	instruction.value = new AlgebraicInterval(
[16693]	410	new MultivariateDual<AlgebraicDouble>(constant.Value, constant, 1.0),
	411	new MultivariateDual<AlgebraicDouble>(constant.Value, constant, 1.0) // use node as key
[16682]	412	);
[16674]	413	}
	414
	415	protected override void InitializeTerminalInstruction(ref Instruction instruction, VariableTreeNode variable) {
	416	instruction.dblVal = variable.Weight;
[16682]	417	instruction.value = new AlgebraicInterval(
[16693]	418	low: new MultivariateDual<AlgebraicDouble>(intervals[variable.VariableName].LowerBound, variable, intervals[variable.VariableName].LowerBound), // bounds change by variable value d/dc (c I(var)) = I(var)
	419	high: new MultivariateDual<AlgebraicDouble>(intervals[variable.VariableName].UpperBound, variable, intervals[variable.VariableName].UpperBound)
[16682]	420	);
[16674]	421	}
	422
	423	protected override void LoadVariable(Instruction a) {
	424	// nothing to do
	425	}
	426	}
	427
	428	public interface IAlgebraicType<T> {
[16693]	429	T Zero { get; }
[16727]	430	T One { get; }
[16693]	431
[16682]	432	T AssignAbs(T a); // set this to assign abs(a)
[16674]	433	T Assign(T a); // assign this to same value as a (copy!)
	434	T AssignNeg(T a); // set this to negative(a)
	435	T AssignInv(T a); // set this to inv(a);
	436	T Scale(double s); // scale this with s
	437	T Add(T a); // add a to this
	438	T Sub(T a); // subtract a from this
	439	T Mul(T a); // multiply this with a
	440	T Div(T a); // divide this by a
	441	T AssignLog(T a); // set this to log a
	442	T AssignExp(T a); // set this to exp(a)
	443	T AssignSin(T a); // set this to sin(a)
	444	T AssignCos(T a); // set this to cos(a)
[17131]	445	T AssignTanh(T a); // set this to tanh(a)
[16674]	446	T AssignIntPower(T a, int p);
	447	T AssignIntRoot(T a, int r);
[16682]	448	T AssignSgn(T a); // set this to sign(a)
[16674]	449	T Clone();
	450	}
	451
[16682]	452	public static class Algebraic {
[16695]	453	public static T Abs<T>(this T a) where T : IAlgebraicType<T> { a.AssignAbs(a.Clone()); return a; }
	454	public static T Neg<T>(this T a) where T : IAlgebraicType<T> { a.AssignNeg(a.Clone()); return a; }
	455	public static T Inv<T>(this T a) where T : IAlgebraicType<T> { a.AssignInv(a.Clone()); return a; }
	456	public static T Log<T>(this T a) where T : IAlgebraicType<T> { a.AssignLog(a.Clone()); return a; }
	457	public static T Exp<T>(this T a) where T : IAlgebraicType<T> { a.AssignExp(a.Clone()); return a; }
	458	public static T Sin<T>(this T a) where T : IAlgebraicType<T> { a.AssignSin(a.Clone()); return a; }
	459	public static T Cos<T>(this T a) where T : IAlgebraicType<T> { a.AssignCos(a.Clone()); return a; }
	460	public static T Sgn<T>(this T a) where T : IAlgebraicType<T> { a.AssignSgn(a.Clone()); return a; }
	461	public static T IntPower<T>(this T a, int p) where T : IAlgebraicType<T> { a.AssignIntPower(a.Clone(), p); return a; }
	462	public static T IntRoot<T>(this T a, int r) where T : IAlgebraicType<T> { a.AssignIntRoot(a.Clone(), r); return a; }
[16674]	463
[16682]	464	public static T Max<T>(T a, T b) where T : IAlgebraicType<T> {
	465	// ((a + b) + abs(b - a)) / 2
	466	return a.Clone().Add(b).Add(b.Clone().Sub(a).Abs()).Scale(1.0 / 2.0);
	467	}
	468	public static T Min<T>(T a, T b) where T : IAlgebraicType<T> {
	469	// ((a + b) - abs(a - b)) / 2
	470	return a.Clone().Add(b).Sub(a.Clone().Sub(b).Abs()).Scale(1.0 / 2.0);
	471	}
	472	}
	473
	474
	475	// algebraic type wrapper for a double value
[16695]	476	[DebuggerDisplay("{Value}")]
[16693]	477	public sealed class AlgebraicDouble : IAlgebraicType<AlgebraicDouble> {
	478	public static implicit operator AlgebraicDouble(double value) { return new AlgebraicDouble(value); }
	479	public static implicit operator double(AlgebraicDouble value) { return value.Value; }
[16682]	480	public double Value;
	481
[16695]	482	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16693]	483	public AlgebraicDouble Zero => new AlgebraicDouble(0.0);
[16727]	484	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	485	public AlgebraicDouble One => new AlgebraicDouble(1.0);
[16693]	486	public AlgebraicDouble() { }
	487	public AlgebraicDouble(double value) { this.Value = value; }
	488	public AlgebraicDouble Assign(AlgebraicDouble a) { Value = a.Value; return this; }
	489	public AlgebraicDouble Add(AlgebraicDouble a) { Value += a.Value; return this; }
	490	public AlgebraicDouble Sub(AlgebraicDouble a) { Value -= a.Value; return this; }
	491	public AlgebraicDouble Mul(AlgebraicDouble a) { Value *= a.Value; return this; }
	492	public AlgebraicDouble Div(AlgebraicDouble a) { Value /= a.Value; return this; }
	493	public AlgebraicDouble Scale(double s) { Value *= s; return this; }
	494	public AlgebraicDouble AssignInv(AlgebraicDouble a) { Value = 1.0 / a.Value; return this; }
	495	public AlgebraicDouble AssignNeg(AlgebraicDouble a) { Value = -a.Value; return this; }
	496	public AlgebraicDouble AssignSin(AlgebraicDouble a) { Value = Math.Sin(a.Value); return this; }
	497	public AlgebraicDouble AssignCos(AlgebraicDouble a) { Value = Math.Cos(a.Value); return this; }
[17131]	498	public AlgebraicDouble AssignTanh(AlgebraicDouble a) { Value = Math.Tanh(a.Value); return this; }
[16744]	499	public AlgebraicDouble AssignLog(AlgebraicDouble a) { Value = a.Value <= 0 ? double.NegativeInfinity : Math.Log(a.Value); return this; } // alternative definiton of log to prevent NaN
[16693]	500	public AlgebraicDouble AssignExp(AlgebraicDouble a) { Value = Math.Exp(a.Value); return this; }
	501	public AlgebraicDouble AssignIntPower(AlgebraicDouble a, int p) { Value = Math.Pow(a.Value, p); return this; }
	502	public AlgebraicDouble AssignIntRoot(AlgebraicDouble a, int r) { Value = Math.Pow(a.Value, 1.0 / r); return this; }
	503	public AlgebraicDouble AssignAbs(AlgebraicDouble a) { Value = Math.Abs(a.Value); return this; }
[16744]	504	public AlgebraicDouble AssignSgn(AlgebraicDouble a) { Value = double.IsNaN(a.Value) ? double.NaN : Math.Sign(a.Value); return this; }
[16693]	505	public AlgebraicDouble Clone() { return new AlgebraicDouble(Value); }
[16695]	506
	507	public override string ToString() {
	508	return Value.ToString();
	509	}
[16682]	510	}
	511
[16674]	512	// a simple vector as an algebraic type
[16695]	513	[DebuggerDisplay("DoubleVector(len={Length}): {string.}")]
	514	public class AlgebraicDoubleVector : IAlgebraicType<AlgebraicDoubleVector> {
[16674]	515	private double[] arr;
	516	public double this[int idx] { get { return arr[idx]; } set { arr[idx] = value; } }
[16693]	517	public int Length => arr.Length;
	518
[16695]	519	public AlgebraicDoubleVector(int length) { arr = new double[length]; }
[16674]	520
[16695]	521	public AlgebraicDoubleVector() { }
[16682]	522
[16674]	523	/// <summary>
	524	///
	525	/// </summary>
	526	/// <param name="arr">array is not copied</param>
[16695]	527	public AlgebraicDoubleVector(double[] arr) { this.arr = arr; }
[16674]	528
[16695]	529	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	530	public AlgebraicDoubleVector Zero => new AlgebraicDoubleVector(new double[this.Length]); // must return vector of same length as this (therefore Zero is not static)
[16727]	531	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	532	public AlgebraicDoubleVector One => new AlgebraicDoubleVector(new double[this.Length]).AssignConstant(1.0); // must return vector of same length as this (therefore Zero is not static)
[16695]	533	public AlgebraicDoubleVector Assign(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = a.arr[i]; } return this; }
	534	public AlgebraicDoubleVector Add(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] += a.arr[i]; } return this; }
	535	public AlgebraicDoubleVector Sub(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] -= a.arr[i]; } return this; }
	536	public AlgebraicDoubleVector Mul(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] *= a.arr[i]; } return this; }
	537	public AlgebraicDoubleVector Div(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] /= a.arr[i]; } return this; }
	538	public AlgebraicDoubleVector AssignNeg(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = -a.arr[i]; } return this; }
	539	public AlgebraicDoubleVector AssignInv(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = 1.0 / a.arr[i]; } return this; }
	540	public AlgebraicDoubleVector Scale(double s) { for (int i = 0; i < arr.Length; ++i) { arr[i] *= s; } return this; }
	541	public AlgebraicDoubleVector AssignLog(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Log(a.arr[i]); } return this; }
	542	public AlgebraicDoubleVector AssignSin(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Sin(a.arr[i]); } return this; }
	543	public AlgebraicDoubleVector AssignExp(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Exp(a.arr[i]); } return this; }
	544	public AlgebraicDoubleVector AssignCos(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Cos(a.arr[i]); } return this; }
[17131]	545	public AlgebraicDoubleVector AssignTanh(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Tanh(a.arr[i]); } return this; }
[16695]	546	public AlgebraicDoubleVector AssignIntPower(AlgebraicDoubleVector a, int p) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Pow(a.arr[i], p); } return this; }
	547	public AlgebraicDoubleVector AssignIntRoot(AlgebraicDoubleVector a, int r) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Pow(a.arr[i], 1.0 / r); } return this; }
	548	public AlgebraicDoubleVector AssignAbs(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Abs(a.arr[i]); } return this; }
	549	public AlgebraicDoubleVector AssignSgn(AlgebraicDoubleVector a) { for (int i = 0; i < arr.Length; ++i) { arr[i] = Math.Sign(a.arr[i]); } return this; }
[16674]	550
[16695]	551	public AlgebraicDoubleVector Clone() {
	552	var v = new AlgebraicDoubleVector(this.arr.Length);
[16693]	553	Array.Copy(arr, v.arr, v.arr.Length);
	554	return v;
[16674]	555	}
	556
[16727]	557	public AlgebraicDoubleVector AssignConstant(double constantValue) {
[16674]	558	for (int i = 0; i < arr.Length; ++i) {
	559	arr[i] = constantValue;
	560	}
[16727]	561	return this;
[16674]	562	}
	563
[16693]	564	public void CopyTo(double[] dest, int idx, int length) {
	565	Array.Copy(arr, 0, dest, idx, length);
[16674]	566	}
	567
	568	public void CopyFrom(double[] data, int rowIndex) {
	569	Array.Copy(data, rowIndex, arr, 0, Math.Min(arr.Length, data.Length - rowIndex));
	570	}
[16693]	571	public void CopyRowTo(double[,] dest, int row) {
	572	for (int j = 0; j < arr.Length; ++j) dest[row, j] = arr[j];
	573	}
	574
	575	internal void CopyColumnTo(double[,] dest, int column, int row, int len) {
	576	for (int j = 0; j < len; ++j) dest[row + j, column] = arr[j];
	577	}
[16695]	578
	579	public override string ToString() {
	580	return "{" + string.Join(", ", arr.Take(Math.Max(5, arr.Length))) + (arr.Length > 5 ? "..." : string.Empty) + "}";
	581	}
[16674]	582	}
	583
[16727]	584
	585	/*
[16674]	586	// vectors of algebraic types
[16727]	587	public sealed class AlgebraicVector<T> : IAlgebraicType<AlgebraicVector<T>> where T : IAlgebraicType<T>, new() {
[16674]	588	private T[] elems;
	589
	590	public T this[int idx] { get { return elems[idx]; } set { elems[idx] = value; } }
	591
	592	public int Length => elems.Length;
	593
[16695]	594	private AlgebraicVector() { }
[16693]	595
[16695]	596	public AlgebraicVector(int len) { elems = new T[len]; }
[16674]	597
	598	/// <summary>
	599	///
	600	/// </summary>
[16693]	601	/// <param name="elems">The array is copied (element-wise clone)</param>
[16695]	602	public AlgebraicVector(T[] elems) {
[16674]	603	this.elems = new T[elems.Length];
	604	for (int i = 0; i < elems.Length; ++i) { this.elems[i] = elems[i].Clone(); }
	605	}
	606
	607	/// <summary>
	608	///
	609	/// </summary>
	610	/// <param name="elems">Array is not copied!</param>
	611	/// <returns></returns>
[16695]	612	public AlgebraicVector<T> FromArray(T[] elems) {
	613	var v = new AlgebraicVector<T>();
[16674]	614	v.elems = elems;
	615	return v;
	616	}
	617
	618	public void CopyTo(T[] dest) {
	619	if (dest.Length != elems.Length) throw new InvalidOperationException("arr lengths do not match in Vector<T>.Copy");
	620	Array.Copy(elems, dest, dest.Length);
	621	}
	622
[16695]	623	public AlgebraicVector<T> Clone() { return new AlgebraicVector<T>(elems); }
[16674]	624
	625
[16695]	626	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	627	public AlgebraicVector<T> Zero => new AlgebraicVector<T>(Length);
[16727]	628	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	629	public AlgebraicVector<T> One { get { var v = new AlgebraicVector<T>(Length); for (int i = 0; i < elems.Length; ++i) elems[i] = new T().One; return v; } }
[16695]	630	public AlgebraicVector<T> Assign(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].Assign(a.elems[i]); } return this; }
	631	public AlgebraicVector<T> Add(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].Add(a.elems[i]); } return this; }
	632	public AlgebraicVector<T> Sub(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].Sub(a.elems[i]); } return this; }
	633	public AlgebraicVector<T> Mul(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].Mul(a.elems[i]); } return this; }
	634	public AlgebraicVector<T> Div(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].Div(a.elems[i]); } return this; }
	635	public AlgebraicVector<T> AssignNeg(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignNeg(a.elems[i]); } return this; }
	636	public AlgebraicVector<T> Scale(double s) { for (int i = 0; i < elems.Length; ++i) { elems[i].Scale(s); } return this; }
	637	public AlgebraicVector<T> Scale(T s) { for (int i = 0; i < elems.Length; ++i) { elems[i].Mul(s); } return this; }
	638	public AlgebraicVector<T> AssignInv(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignInv(a.elems[i]); } return this; }
	639	public AlgebraicVector<T> AssignLog(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignLog(a.elems[i]); } return this; }
	640	public AlgebraicVector<T> AssignExp(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignExp(a.elems[i]); } return this; }
	641	public AlgebraicVector<T> AssignSin(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignSin(a.elems[i]); } return this; }
	642	public AlgebraicVector<T> AssignCos(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignCos(a.elems[i]); } return this; }
	643	public AlgebraicVector<T> AssignIntPower(AlgebraicVector<T> a, int p) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignIntPower(a.elems[i], p); } return this; }
	644	public AlgebraicVector<T> AssignIntRoot(AlgebraicVector<T> a, int r) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignIntRoot(a.elems[i], r); } return this; }
	645	public AlgebraicVector<T> AssignAbs(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignAbs(a.elems[i]); } return this; }
	646	public AlgebraicVector<T> AssignSgn(AlgebraicVector<T> a) { for (int i = 0; i < elems.Length; ++i) { elems[i].AssignSgn(a.elems[i]); } return this; }
[16674]	647	}
	648
[16727]	649	*/
[16674]	650
[16727]	651
[16682]	652	/// <summary>
	653	/// A sparse vector of algebraic types. Elements are accessed via a key of type K
	654	/// </summary>
	655	/// <typeparam name="K">Key type</typeparam>
	656	/// <typeparam name="T">Element type</typeparam>
[16695]	657	[DebuggerDisplay("SparseVector: {ToString()}")]
	658	public sealed class AlgebraicSparseVector<K, T> : IAlgebraicType<AlgebraicSparseVector<K, T>> where T : IAlgebraicType<T> {
	659	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16682]	660	private Dictionary<K, T> elems;
	661	public IReadOnlyDictionary<K, T> Elements => elems;
	662
[16693]	663
[16695]	664	public AlgebraicSparseVector(AlgebraicSparseVector<K, T> original) {
[16682]	665	elems = original.elems.ToDictionary(kvp => kvp.Key, kvp => kvp.Value.Clone());
	666	}
	667
[16693]	668	/// <summary>
	669	///
	670	/// </summary>
	671	/// <param name="keys"></param>
	672	/// <param name="values">values are cloned</param>
[16695]	673	public AlgebraicSparseVector(K[] keys, T[] values) {
[16682]	674	if (keys.Length != values.Length) throw new ArgumentException("lengths of keys and values doesn't match in SparseVector");
	675	elems = new Dictionary<K, T>(keys.Length);
	676	for (int i = 0; i < keys.Length; ++i) {
[16693]	677	elems.Add(keys[i], values[i].Clone());
[16682]	678	}
	679	}
	680
[16695]	681	public AlgebraicSparseVector() {
[16682]	682	this.elems = new Dictionary<K, T>();
	683	}
	684
[16695]	685	// keep only elements from a
	686	private void AssignFromSource(AlgebraicSparseVector<K, T> a, Func<T, T, T> mapAssign) {
	687	// remove elems from this which don't occur in a
	688	List<K> keysToRemove = new List<K>();
	689	foreach (var kvp in elems) {
	690	if (!a.elems.ContainsKey(kvp.Key)) keysToRemove.Add(kvp.Key);
	691	}
	692	foreach (var o in keysToRemove) elems.Remove(o); // -> zero
[16682]	693
[16695]	694	foreach (var kvp in a.elems) {
	695	if (elems.TryGetValue(kvp.Key, out T value))
	696	mapAssign(kvp.Value, value);
	697	else
	698	elems.Add(kvp.Key, mapAssign(kvp.Value, kvp.Value.Zero));
	699	}
	700	}
[16682]	701
[16695]	702	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	703	public AlgebraicSparseVector<K, T> Zero => new AlgebraicSparseVector<K, T>();
[16727]	704	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	705	public AlgebraicSparseVector<K, T> One => throw new NotSupportedException();
[16695]	706
	707	public AlgebraicSparseVector<K, T> Scale(T s) { foreach (var kvp in elems) { kvp.Value.Mul(s); } return this; }
	708	public AlgebraicSparseVector<K, T> Scale(double s) { foreach (var kvp in elems) { kvp.Value.Scale(s); } return this; }
	709
	710	public AlgebraicSparseVector<K, T> Assign(AlgebraicSparseVector<K, T> a) { elems.Clear(); AssignFromSource(a, (src, dest) => dest.Assign(src)); return this; }
	711	public AlgebraicSparseVector<K, T> AssignInv(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignInv(src)); return this; }
	712	public AlgebraicSparseVector<K, T> AssignNeg(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignNeg(src)); return this; }
	713	public AlgebraicSparseVector<K, T> AssignLog(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignLog(src)); return this; }
	714	public AlgebraicSparseVector<K, T> AssignExp(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignExp(src)); return this; }
	715	public AlgebraicSparseVector<K, T> AssignIntPower(AlgebraicSparseVector<K, T> a, int p) { AssignFromSource(a, (src, dest) => dest.AssignIntPower(src, p)); return this; }
	716	public AlgebraicSparseVector<K, T> AssignIntRoot(AlgebraicSparseVector<K, T> a, int r) { AssignFromSource(a, (src, dest) => dest.AssignIntRoot(src, r)); return this; }
	717	public AlgebraicSparseVector<K, T> AssignSin(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignSin(src)); return this; }
	718	public AlgebraicSparseVector<K, T> AssignCos(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignCos(src)); return this; }
[17131]	719	public AlgebraicSparseVector<K, T> AssignTanh(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignTanh(src)); return this; }
[16695]	720	public AlgebraicSparseVector<K, T> AssignAbs(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignAbs(src)); return this; }
	721	public AlgebraicSparseVector<K, T> AssignSgn(AlgebraicSparseVector<K, T> a) { AssignFromSource(a, (src, dest) => dest.AssignSgn(src)); return this; }
[16727]	722	public AlgebraicSparseVector<K, T> Add(AlgebraicSparseVector<K, T> a) {
	723	foreach (var kvp in a.elems) {
	724	if (elems.TryGetValue(kvp.Key, out T value))
	725	value.Add(kvp.Value);
	726	else
	727	elems.Add(kvp.Key, kvp.Value.Clone()); // 0 + a
	728	}
	729	return this;
	730	}
[16695]	731
[16727]	732	public AlgebraicSparseVector<K, T> Sub(AlgebraicSparseVector<K, T> a) {
	733	foreach (var kvp in a.elems) {
	734	if (elems.TryGetValue(kvp.Key, out T value))
	735	value.Sub(kvp.Value);
	736	else
	737	elems.Add(kvp.Key, kvp.Value.Zero.Sub(kvp.Value)); // 0 - a
	738	}
	739	return this;
	740	}
	741
	742	public AlgebraicSparseVector<K, T> Mul(AlgebraicSparseVector<K, T> a) {
	743	var keys = elems.Keys.ToArray();
	744	foreach (var k in keys) if (!a.elems.ContainsKey(k)) elems.Remove(k); // 0 * a => 0
	745	foreach (var kvp in a.elems) {
	746	if (elems.TryGetValue(kvp.Key, out T value))
	747	value.Mul(kvp.Value); // this * a
	748	}
	749	return this;
	750	}
	751
	752	public AlgebraicSparseVector<K, T> Div(AlgebraicSparseVector<K, T> a) {
	753	return Mul(a.Clone().Inv());
	754	}
	755
[16695]	756	public AlgebraicSparseVector<K, T> Clone() {
	757	return new AlgebraicSparseVector<K, T>(this);
[16682]	758	}
[16695]	759
	760	public override string ToString() {
	761	return "[" + string.Join(" ", elems.Select(kvp => kvp.Key + ": " + kvp.Value)) + "]";
	762	}
[16682]	763	}
	764
[16695]	765	[DebuggerDisplay("[{low.Value}..{high.Value}]")]
[16674]	766	public class AlgebraicInterval : IAlgebraicType<AlgebraicInterval> {
[16695]	767	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16693]	768	private MultivariateDual<AlgebraicDouble> low;
[16695]	769	public MultivariateDual<AlgebraicDouble> LowerBound => low.Clone();
	770
	771	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16693]	772	private MultivariateDual<AlgebraicDouble> high;
	773	public MultivariateDual<AlgebraicDouble> UpperBound => high.Clone();
[16674]	774
[16693]	775
[16674]	776	public AlgebraicInterval() : this(double.NegativeInfinity, double.PositiveInfinity) { }
	777
[16693]	778	public AlgebraicInterval(MultivariateDual<AlgebraicDouble> low, MultivariateDual<AlgebraicDouble> high) {
[16682]	779	this.low = low.Clone();
	780	this.high = high.Clone();
	781	}
	782
[16674]	783	public AlgebraicInterval(double low, double high) {
[16693]	784	this.low = new MultivariateDual<AlgebraicDouble>(new AlgebraicDouble(low));
	785	this.high = new MultivariateDual<AlgebraicDouble>(new AlgebraicDouble(high));
[16674]	786	}
	787
[16695]	788	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16693]	789	public AlgebraicInterval Zero => new AlgebraicInterval(0.0, 0.0);
[16727]	790	public AlgebraicInterval One => new AlgebraicInterval(1.0, 1.0);
[16674]	791	public AlgebraicInterval Add(AlgebraicInterval a) {
[16682]	792	low.Add(a.low);
	793	high.Add(a.high);
[16674]	794	return this;
	795	}
	796
[16693]	797	public AlgebraicInterval Mul(AlgebraicInterval a) {
	798	var v1 = low.Clone().Mul(a.low);
	799	var v2 = low.Clone().Mul(a.high);
	800	var v3 = high.Clone().Mul(a.low);
	801	var v4 = high.Clone().Mul(a.high);
	802
	803	low = Algebraic.Min(Algebraic.Min(v1, v2), Algebraic.Min(v3, v4));
	804	high = Algebraic.Max(Algebraic.Max(v1, v2), Algebraic.Max(v3, v4));
	805	return this;
	806	}
	807
[16674]	808	public AlgebraicInterval Assign(AlgebraicInterval a) {
	809	low = a.low;
	810	high = a.high;
	811	return this;
	812	}
	813
	814	public AlgebraicInterval AssignCos(AlgebraicInterval a) {
[16693]	815	return AssignSin(a.Clone().Sub(new AlgebraicInterval(Math.PI / 2, Math.PI / 2)));
[16674]	816	}
	817
	818	public AlgebraicInterval Div(AlgebraicInterval a) {
[16682]	819	if (a.Contains(0.0)) {
	820	if (a.low.Value.Value.IsAlmost(0.0) && a.high.Value.Value.IsAlmost(0.0)) {
[16693]	821	low = new MultivariateDual<AlgebraicDouble>(double.NegativeInfinity);
	822	high = new MultivariateDual<AlgebraicDouble>(double.PositiveInfinity);
[16682]	823	} else if (a.low.Value.Value.IsAlmost(0.0))
[16693]	824	Mul(new AlgebraicInterval(a.Clone().high.Inv(), new MultivariateDual<AlgebraicDouble>(double.PositiveInfinity)));
[16682]	825	else
[16693]	826	Mul(new AlgebraicInterval(new MultivariateDual<AlgebraicDouble>(double.NegativeInfinity), a.low.Clone().Inv()));
[16674]	827	} else {
[16682]	828	Mul(new AlgebraicInterval(a.high.Clone().Inv(), a.low.Clone().Inv())); // inverting leads to inverse roles of high and low
[16674]	829	}
	830	return this;
	831	}
	832
	833	public AlgebraicInterval AssignExp(AlgebraicInterval a) {
[16682]	834	low.AssignExp(a.low);
	835	high.AssignExp(a.high);
[16674]	836	return this;
	837	}
	838
[17131]	839	// tanh is a bijective function
	840	public AlgebraicInterval AssignTanh(AlgebraicInterval a) {
	841	low.AssignTanh(a.low);
	842	high.AssignTanh(a.high);
	843	return this;
	844	}
	845
[16674]	846	public AlgebraicInterval AssignIntPower(AlgebraicInterval a, int p) {
[16693]	847	if (p < 0) { // x^-3 == 1/(x^3)
	848	AssignIntPower(a, -p);
	849	return AssignInv(this);
[16744]	850	} else if (p == 0) {
	851	if (a.Contains(0.0)) {
	852	// => 0^0 = 0 ; might not be relevant
	853	low = new MultivariateDual<AlgebraicDouble>(0.0);
	854	high = new MultivariateDual<AlgebraicDouble>(1.0);
	855	return this;
	856	} else {
	857	// => 1
	858	low = new MultivariateDual<AlgebraicDouble>(1.0);
	859	high = new MultivariateDual<AlgebraicDouble>(1.0);
	860	return this;
	861	}
	862	} else if (p == 1) return this;
	863	else if (p % 2 == 0) {
[16693]	864	// p is even => interval must be positive
[16744]	865	if (a.Contains(0.0)) {
	866	low = new MultivariateDual<AlgebraicDouble>(0.0);
	867	high = Algebraic.Max(a.low.IntPower(p), a.high.IntPower(p));
[16693]	868	} else {
[16727]	869	var lowPower = a.low.IntPower(p);
	870	var highPower = a.high.IntPower(p);
[16693]	871	low = Algebraic.Min(lowPower, highPower);
	872	high = Algebraic.Max(lowPower, highPower);
	873	}
[16744]	874	} else {
	875	// p is uneven
	876	if (a.Contains(0.0)) {
	877	low.AssignIntPower(a.low, p);
	878	high.AssignIntPower(a.high, p);
	879	} else {
	880	var lowPower = a.low.IntPower(p);
	881	var highPower = a.high.IntPower(p);
	882	low = Algebraic.Min(lowPower, highPower);
	883	high = Algebraic.Max(lowPower, highPower);
	884	}
[16693]	885	}
[16744]	886	return this;
[16674]	887	}
	888
	889	public AlgebraicInterval AssignIntRoot(AlgebraicInterval a, int r) {
[16693]	890	if (r == 0) { low = new MultivariateDual<AlgebraicDouble>(double.NaN); high = new MultivariateDual<AlgebraicDouble>(double.NaN); return this; }
	891	if (r == 1) return this;
	892	if (r < 0) {
	893	// x^ (-1/2) = 1 / (x^(1/2))
	894	AssignIntRoot(a, -r);
	895	return AssignInv(this);
	896	} else {
	897	// root only defined for positive arguments
	898	if (a.LowerBound.Value.Value < 0) {
	899	low = new MultivariateDual<AlgebraicDouble>(double.NaN);
	900	high = new MultivariateDual<AlgebraicDouble>(double.NaN);
	901	return this;
	902	} else {
	903	low.AssignIntRoot(a.low, r);
	904	high.AssignIntRoot(a.high, r);
	905	return this;
	906	}
	907	}
[16674]	908	}
	909
	910	public AlgebraicInterval AssignInv(AlgebraicInterval a) {
[16693]	911	low = new MultivariateDual<AlgebraicDouble>(1.0);
	912	high = new MultivariateDual<AlgebraicDouble>(1.0);
[16674]	913	return Div(a);
	914	}
	915
	916	public AlgebraicInterval AssignLog(AlgebraicInterval a) {
[16682]	917	low.AssignLog(a.low);
	918	high.AssignLog(a.high);
[16674]	919	return this;
	920	}
	921
[16693]	922	public AlgebraicInterval AssignNeg(AlgebraicInterval a) {
	923	low.AssignNeg(a.high);
	924	high.AssignNeg(a.low);
[16674]	925	return this;
	926	}
	927
	928	public AlgebraicInterval Scale(double s) {
[16682]	929	low.Scale(s);
	930	high.Scale(s);
[16674]	931	if (s < 0) {
[16682]	932	var t = low;
	933	low = high;
	934	high = t;
[16674]	935	}
	936	return this;
	937	}
	938
	939	public AlgebraicInterval AssignSin(AlgebraicInterval a) {
[16693]	940	if (Math.Abs(a.UpperBound.Value.Value - a.LowerBound.Value.Value) >= Math.PI * 2) {
	941	low = new MultivariateDual<AlgebraicDouble>(-1.0);
	942	high = new MultivariateDual<AlgebraicDouble>(1.0);
	943	}
	944
	945	//divide the interval by PI/2 so that the optima lie at x element of N (0,1,2,3,4,...)
	946	double Pihalf = Math.PI / 2;
	947	var scaled = this.Clone().Scale(1.0 / Pihalf);
	948	//move to positive scale
	949	if (scaled.LowerBound.Value.Value < 0) {
	950	int periodsToMove = Math.Abs((int)scaled.LowerBound.Value.Value / 4) + 1;
	951	scaled.Add(new AlgebraicInterval(periodsToMove * 4, periodsToMove * 4));
	952	}
	953
	954	double scaledLowerBound = scaled.LowerBound.Value.Value % 4.0;
	955	double scaledUpperBound = scaled.UpperBound.Value.Value % 4.0;
	956	if (scaledUpperBound < scaledLowerBound) scaledUpperBound += 4.0;
	957	List<double> sinValues = new List<double>();
	958	sinValues.Add(Math.Sin(scaledLowerBound * Pihalf));
	959	sinValues.Add(Math.Sin(scaledUpperBound * Pihalf));
	960
	961	int startValue = (int)Math.Ceiling(scaledLowerBound);
	962	while (startValue < scaledUpperBound) {
	963	sinValues.Add(Math.Sin(startValue * Pihalf));
	964	startValue += 1;
	965	}
	966
	967	low = new MultivariateDual<AlgebraicDouble>(sinValues.Min());
	968	high = new MultivariateDual<AlgebraicDouble>(sinValues.Max());
	969	return this;
[16674]	970	}
	971
	972	public AlgebraicInterval Sub(AlgebraicInterval a) {
[16682]	973	// [x1,x2] − [y1,y2] = [x1 − y2,x2 − y1]
	974	low.Sub(a.high);
	975	high.Sub(a.low);
[16674]	976	return this;
	977	}
	978
	979	public AlgebraicInterval Clone() {
	980	return new AlgebraicInterval(low, high);
	981	}
	982
	983	public bool Contains(double val) {
[16682]	984	return LowerBound.Value.Value <= val && val <= UpperBound.Value.Value;
[16674]	985	}
[16682]	986
	987	public AlgebraicInterval AssignAbs(AlgebraicInterval a) {
	988	if (a.Contains(0.0)) {
	989	var abslow = a.low.Clone().Abs();
	990	var abshigh = a.high.Clone().Abs();
	991	a.high.Assign(Algebraic.Max(abslow, abshigh));
[16693]	992	a.low.Assign(new MultivariateDual<AlgebraicDouble>(0.0)); // lost gradient for lower bound
[16682]	993	} else {
	994	var abslow = a.low.Clone().Abs();
	995	var abshigh = a.high.Clone().Abs();
	996	a.low.Assign(Algebraic.Min(abslow, abshigh));
	997	a.high.Assign(Algebraic.Max(abslow, abshigh));
	998	}
	999	return this;
	1000	}
	1001
	1002	public AlgebraicInterval AssignSgn(AlgebraicInterval a) {
[16693]	1003	low.AssignSgn(a.low);
	1004	high.AssignSgn(a.high);
	1005	return this;
[16682]	1006	}
[16674]	1007	}
	1008
	1009	public class Dual<V> : IAlgebraicType<Dual<V>>
	1010	where V : IAlgebraicType<V> {
[16695]	1011	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16674]	1012	private V v;
[16694]	1013	public V Value => v;
	1014
[16695]	1015	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16674]	1016	private V dv;
[16682]	1017	public V Derivative => dv;
	1018
[16694]	1019	public Dual(V v, V dv) { this.v = v; this.dv = dv; }
[16693]	1020
[16695]	1021	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16693]	1022	public Dual<V> Zero => new Dual<V>(Value.Zero, Derivative.Zero);
[16727]	1023	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	1024	public Dual<V> One => new Dual<V>(Value.One, Derivative.Zero);
[16693]	1025
[16694]	1026	public Dual<V> Assign(Dual<V> a) { v.Assign(a.v); dv.Assign(a.dv); return this; }
	1027	public Dual<V> Scale(double s) { v.Scale(s); dv.Scale(s); return this; }
	1028	public Dual<V> Add(Dual<V> a) { v.Add(a.v); dv.Add(a.dv); return this; }
	1029	public Dual<V> Sub(Dual<V> a) { v.Sub(a.v); dv.Sub(a.dv); return this; }
	1030	public Dual<V> AssignNeg(Dual<V> a) { v.AssignNeg(a.v); dv.AssignNeg(a.dv); return this; }
	1031	public Dual<V> AssignInv(Dual<V> a) { v.AssignInv(a.v); dv.AssignNeg(a.dv).Mul(v).Mul(v); return this; } // (1/f(x))' = - f(x)' / f(x)^2
[16674]	1032
[16694]	1033	// (a(x) * b(x))' = b(x)a(x)' + b(x)'a(x);
[16674]	1034	public Dual<V> Mul(Dual<V> a) {
[16694]	1035	var t1 = a.dv.Clone().Mul(v);
	1036	var t2 = dv.Clone().Mul(a.v);
[16674]	1037	dv.Assign(t1).Add(t2);
	1038
	1039	v.Mul(a.v);
	1040	return this;
	1041	}
[16694]	1042	public Dual<V> Div(Dual<V> a) { Mul(a.Inv()); return this; }
[16674]	1043
[16694]	1044	public Dual<V> AssignExp(Dual<V> a) { v.AssignExp(a.v); dv.Assign(a.dv).Mul(v); return this; } // exp(f(x)) = exp(f(x))*f(x)'
	1045	public Dual<V> AssignLog(Dual<V> a) { v.AssignLog(a.v); dv.Assign(a.dv).Div(a.v); return this; } // log(x)' = 1/f(x) * f(x)'
[16674]	1046
[16694]	1047	public Dual<V> AssignIntPower(Dual<V> a, int p) { v.AssignIntPower(a.v, p); dv.Assign(a.dv).Scale(p).Mul(a.v.Clone().IntPower(p - 1)); return this; }
	1048	public Dual<V> AssignIntRoot(Dual<V> a, int r) { v.AssignIntRoot(a.v, r); dv.Assign(a.dv).Scale(1.0 / r).Mul(a.v.IntRoot(r - 1)); return this; }
[16674]	1049
[16694]	1050	public Dual<V> AssignSin(Dual<V> a) { v.AssignSin(a.v); dv.Assign(a.dv).Mul(a.v.Clone().Cos()); return this; }
	1051	public Dual<V> AssignCos(Dual<V> a) { v.AssignCos(a.v); dv.AssignNeg(a.dv).Mul(a.v.Clone().Sin()); return this; }
[17131]	1052	public Dual<V> AssignTanh(Dual<V> a) { v.AssignTanh(a.v); dv.Assign(a.dv.Mul(v.Clone().IntPower(2).Neg().Add(Value.One))); return this; }
[16674]	1053
[16694]	1054	public Dual<V> AssignAbs(Dual<V> a) { v.AssignAbs(a.v); dv.Assign(a.dv).Mul(a.v.Clone().Sgn()); return this; } // abs(f(x))' = f(x)*f'(x) / \|f(x)\|
	1055	public Dual<V> AssignSgn(Dual<V> a) { v.AssignSgn(a.v); dv.Assign(a.dv.Zero); return this; }
[16682]	1056
[16694]	1057	public Dual<V> Clone() { return new Dual<V>(v.Clone(), dv.Clone()); }
[16682]	1058
[16674]	1059	}
	1060
[16682]	1061	/// <summary>
	1062	/// An algebraic type which has a value as well as the partial derivatives of the value over multiple variables.
	1063	/// </summary>
	1064	/// <typeparam name="V"></typeparam>
[16695]	1065	[DebuggerDisplay("v={Value}; dv={dv}")]
[16682]	1066	public class MultivariateDual<V> : IAlgebraicType<MultivariateDual<V>> where V : IAlgebraicType<V>, new() {
[16695]	1067	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
[16674]	1068	private V v;
	1069	public V Value => v;
	1070
[16695]	1071	[DebuggerBrowsable(DebuggerBrowsableState.Never)]
	1072	private AlgebraicSparseVector<object, V> dv;
	1073	public AlgebraicSparseVector<object, V> Gradient => dv; // <key,value> partial derivative identified via the key
[16674]	1074
[16694]	1075	private MultivariateDual(MultivariateDual<V> orig) { this.v = orig.v.Clone(); this.dv = orig.dv.Clone(); }
[16674]	1076
[16682]	1077	/// <summary>
	1078	/// Constructor without partial derivative
	1079	/// </summary>
	1080	/// <param name="v"></param>
[16695]	1081	public MultivariateDual(V v) { this.v = v.Clone(); this.dv = new AlgebraicSparseVector<object, V>(); }
[16674]	1082
[16682]	1083	/// <summary>
	1084	/// Constructor for multiple partial derivatives
	1085	/// </summary>
	1086	/// <param name="v"></param>
	1087	/// <param name="keys"></param>
	1088	/// <param name="dv"></param>
[16695]	1089	public MultivariateDual(V v, object[] keys, V[] dv) { this.v = v.Clone(); this.dv = new AlgebraicSparseVector<object, V>(keys, dv); }
[16674]	1090
[16682]	1091	/// <summary>
	1092	/// Constructor for a single partial derivative
	1093	/// </summary>
	1094	/// <param name="v"></param>
	1095	/// <param name="key"></param>
	1096	/// <param name="dv"></param>
[16695]	1097	public MultivariateDual(V v, object key, V dv) { this.v = v.Clone(); this.dv = new AlgebraicSparseVector<object, V>(new[] { key }, new[] { dv }); }
[16682]	1098
[16693]	1099	/// <summary>
[16694]	1100	/// Constructor with a given value and gradient. For internal use.
[16693]	1101	/// </summary>
[16694]	1102	/// <param name="v">The value (not cloned).</param>
	1103	/// <param name="gradient">The gradient (not cloned).</param>
[16695]	1104	internal MultivariateDual(V v, AlgebraicSparseVector<object, V> gradient) { this.v = v; this.dv = gradient; }
[16693]	1105
[16694]	1106	public MultivariateDual<V> Clone() { return new MultivariateDual<V>(this); }
[16682]	1107
[16693]	1108	public MultivariateDual<V> Zero => new MultivariateDual<V>(Value.Zero, Gradient.Zero);
[16727]	1109	public MultivariateDual<V> One => new MultivariateDual<V>(Value.One, Gradient.Zero);
[16693]	1110
[16694]	1111	public MultivariateDual<V> Scale(double s) { v.Scale(s); dv.Scale(s); return this; }
[16693]	1112
[16694]	1113	public MultivariateDual<V> Add(MultivariateDual<V> a) { v.Add(a.v); dv.Add(a.dv); return this; }
	1114	public MultivariateDual<V> Sub(MultivariateDual<V> a) { v.Sub(a.v); dv.Sub(a.dv); return this; }
	1115	public MultivariateDual<V> Assign(MultivariateDual<V> a) { v.Assign(a.v); dv.Assign(a.dv); return this; }
[16682]	1116	public MultivariateDual<V> Mul(MultivariateDual<V> a) {
[16674]	1117	// (a(x) * b(x))' = b(x)a(x)' + b(x)'a(x);
	1118	var t1 = a.dv.Clone().Scale(v);
	1119	var t2 = dv.Clone().Scale(a.v);
[16682]	1120	dv.Assign(t1).Add(t2);
[16674]	1121
	1122	v.Mul(a.v);
	1123	return this;
	1124	}
[16694]	1125	public MultivariateDual<V> Div(MultivariateDual<V> a) { v.Div(a.v); dv.Mul(a.dv.Inv()); return this; }
	1126	public MultivariateDual<V> AssignNeg(MultivariateDual<V> a) { v.AssignNeg(a.v); dv.AssignNeg(a.dv); return this; }
	1127	public MultivariateDual<V> AssignInv(MultivariateDual<V> a) { v.AssignInv(a.v); dv.AssignNeg(a.dv).Scale(v).Scale(v); return this; } // (1/f(x))' = - f(x)' / f(x)^2
[16674]	1128
[16694]	1129	public MultivariateDual<V> AssignSin(MultivariateDual<V> a) { v.AssignSin(a.v); dv.Assign(a.dv).Scale(a.v.Clone().Cos()); return this; }
	1130	public MultivariateDual<V> AssignCos(MultivariateDual<V> a) { v.AssignCos(a.v); dv.AssignNeg(a.dv).Scale(a.v.Clone().Sin()); return this; }
[17131]	1131	public MultivariateDual<V> AssignTanh(MultivariateDual<V> a) { v.AssignTanh(a.v); dv.Assign(a.dv.Scale(v.Clone().IntPower(2).Neg().Add(Value.One))); return this; } // tanh(f(x))' = f(x)'sech²(f(x)) = f(x)'(1 - tanh²(f(x)))
[16674]	1132
[16694]	1133	public MultivariateDual<V> AssignIntPower(MultivariateDual<V> a, int p) { v.AssignIntPower(a.v, p); dv.Assign(a.dv).Scale(p).Scale(a.v.Clone().IntPower(p - 1)); return this; }
	1134	public MultivariateDual<V> AssignIntRoot(MultivariateDual<V> a, int r) { v.AssignIntRoot(a.v, r); dv.Assign(a.dv).Scale(1.0 / r).Scale(a.v.IntRoot(r - 1)); return this; }
[16682]	1135
[16694]	1136	public MultivariateDual<V> AssignExp(MultivariateDual<V> a) { v.AssignExp(a.v); dv.Assign(a.dv).Scale(v); return this; } // exp(f(x)) = exp(f(x))*f(x)'
	1137	public MultivariateDual<V> AssignLog(MultivariateDual<V> a) { v.AssignLog(a.v); dv.Assign(a.dv).Scale(a.v.Clone().Inv()); return this; } // log(x)' = 1/f(x) * f(x)'
[16682]	1138
[16694]	1139	public MultivariateDual<V> AssignAbs(MultivariateDual<V> a) { v.AssignAbs(a.v); dv.Assign(a.dv).Scale(a.v.Clone().Sgn()); return this; } // abs(f(x))' = f(x)*f'(x) / \|f(x)\| doesn't work for intervals
	1140	public MultivariateDual<V> AssignSgn(MultivariateDual<V> a) { v.AssignSgn(a.v); dv = a.dv.Zero; return this; } // sign(f(x))' = 0;
[16674]	1141	}
[16682]	1142	}

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