Context Navigation

MonteCarloTreeSearchCodeGen.cs @ 15767

Visit:

Last change on this file since 15767 was 10437, checked in by gkronber, 11 years ago
#2026 implemented epsilon-greedy search policy
File size: 17.3 KB

Rev	Line
[10408]	1	using System;
	2	using System.Collections.Generic;
	3	using System.Diagnostics;
	4	using System.Linq;
	5	using System.Text;
	6	using HeuristicLab.Grammars;
	7
	8	namespace CodeGenerator {
	9	public class MonteCarloTreeSearchCodeGen {
	10
	11	private string solverTemplate = @"
	12	namespace ?PROBLEMNAME? {
	13	public class SearchTreeNode {
	14	public int tries;
	15	public double sumQuality = 0.0;
	16	public double bestQuality = double.NegativeInfinity;
[10415]	17	public bool done;
[10408]	18	public SearchTreeNode[] children;
[10426]	19	// only for debugging
[10415]	20	public double[] Ucb {
	21	get {
	22	return (from c in children
[10426]	23	select ?IDENT?MonteCarloTreeSearchSolver.UCB(this, c)
[10415]	24	).ToArray();
	25	}
	26	}
[10408]	27	public SearchTreeNode() {
	28	}
	29	}
	30
[10426]	31	public sealed class ?IDENT?MonteCarloTreeSearchSolver {
	32	private int maxDepth = 20;
[10408]	33
	34	private readonly ?IDENT?Problem problem;
	35	private readonly Random random;
[10427]	36	private readonly ?IDENT?RandomSearchSolver randomSearch;
	37
[10408]	38	private SearchTreeNode searchTree = new SearchTreeNode();
	39
[10426]	40	private Tree SampleTree(int maxDepth) {
	41	var extensionsStack = new Stack<Tuple<Tree, int, int, int>>(); // the unfinished tree, the state, the index of the extension point and the maximal depth of a tree inserted at that point
[10408]	42	var t = new Tree(-1, new Tree[1]);
[10426]	43	extensionsStack.Push(Tuple.Create(t, 0, 0, maxDepth));
[10408]	44	SampleTree(searchTree, extensionsStack);
	45	return t.subtrees[0];
	46	}
	47
[10430]	48	private const int RANDOM_TRIES = 100;
[10427]	49
[10426]	50	private void SampleTree(SearchTreeNode searchTree, Stack<Tuple<Tree, int, int, int>> extensionPoints) {
[10408]	51	var extensionPoint = extensionPoints.Pop();
	52	Tree parent = extensionPoint.Item1;
	53	int state = extensionPoint.Item2;
	54	int subtreeIdx = extensionPoint.Item3;
[10426]	55	int maxDepth = extensionPoint.Item4;
	56	Debug.Assert(maxDepth >= 1);
[10427]	57	Debug.Assert(Grammar.minDepth[state] <= maxDepth);
[10408]	58	Tree t = null;
	59	if(searchTree.tries < RANDOM_TRIES \|\| Grammar.subtreeCount[state] == 0) {
[10427]	60	int steps = 0; int curDepth = this.maxDepth - maxDepth; int depth = this.maxDepth - maxDepth;
	61	t = randomSearch.SampleTree(state, maxDepth, ref steps, ref curDepth, ref depth);
[10408]	62	if(Grammar.subtreeCount[state] == 0) {
	63	// when we produced a terminal continue filling up all other empty points
	64	Debug.Assert(searchTree.children == null \|\| searchTree.children.Length == 1);
[10427]	65	if(extensionPoints.Count == 0) {
	66	searchTree.done = true;
	67	} else {
	68	if(searchTree.children == null)
	69	searchTree.children = new SearchTreeNode[] { new SearchTreeNode() } ;
	70	SampleTree(searchTree.children[0], extensionPoints);
	71	if(searchTree.children[0].done) searchTree.done = true;
	72	}
[10408]	73	} else {
	74	// fill up all remaining slots randomly
	75	foreach(var p in extensionPoints) {
	76	var pParent = p.Item1;
	77	var pState = p.Item2;
	78	var pIdx = p.Item3;
[10427]	79	var pMaxDepth = p.Item4;
	80	curDepth = this.maxDepth - pMaxDepth;
	81	depth = curDepth;
	82	pParent.subtrees[pIdx] = randomSearch.SampleTree(pState, pMaxDepth, ref steps, ref curDepth, ref depth);
[10408]	83	}
	84	}
[10427]	85	} else if(Grammar.subtreeCount[state] == 1) {
	86	if(searchTree.children == null) {
	87	int nChildren = Grammar.transition[state].Length;
	88	searchTree.children = new SearchTreeNode[nChildren];
	89	}
	90	Debug.Assert(searchTree.children.Length == Grammar.transition[state].Length);
	91	Debug.Assert(searchTree.tries - RANDOM_TRIES == searchTree.children.Where(c=>c!=null).Sum(c=>c.tries));
	92	var altIdx = SelectAlternative(searchTree, state, maxDepth);
	93	t = new Tree(altIdx, new Tree[1]);
	94	extensionPoints.Push(Tuple.Create(t, Grammar.transition[state][altIdx], 0, maxDepth - 1));
	95	SampleTree(searchTree.children[altIdx], extensionPoints);
	96	searchTree.done = (from idx in Enumerable.Range(0, searchTree.children.Length)
	97	where Grammar.minDepth[Grammar.transition[state][idx]] <= maxDepth - 1
	98	select searchTree.children[idx]).All(c=>c != null && c.done);
[10408]	99	} else {
[10427]	100	// multiple subtrees
	101	var subtrees = new Tree[Grammar.subtreeCount[state]];
	102	t = new Tree(-1, subtrees);
	103	for(int i = subtrees.Length - 1; i >= 0; i--) {
	104	extensionPoints.Push(Tuple.Create(t, Grammar.transition[state][i], i, maxDepth - 1));
[10408]	105	}
[10427]	106	SampleTree(searchTree, extensionPoints);
[10415]	107	}
[10408]	108	Debug.Assert(parent.subtrees[subtreeIdx] == null);
	109	parent.subtrees[subtreeIdx] = t;
	110	}
	111
[10427]	112	private int SelectAlternative(SearchTreeNode searchTree, int state, int maxDepth) {
[10409]	113	// any alternative not yet explored?
[10427]	114	var altIndexes = searchTree.children
	115	.Select((e,i) => new {Elem = e, Idx = i})
	116	.Where(p => p.Elem == null && Grammar.minDepth[Grammar.transition[state][p.Idx]] <= maxDepth)
	117	.Select(p => p.Idx);
	118	int altIdx = altIndexes.Any()?altIndexes.First() : -1;
[10409]	119	if(altIdx >= 0) {
	120	searchTree.children[altIdx] = new SearchTreeNode();
	121	return altIdx;
	122	} else {
[10427]	123	altIndexes = searchTree.children
	124	.Select((e,i) => new {Elem = e, Idx = i})
	125	.Where(p => p.Elem != null && !p.Elem.done && p.Elem.tries < RANDOM_TRIES && Grammar.minDepth[Grammar.transition[state][p.Idx]] <= maxDepth)
	126	.Select(p => p.Idx);
	127	altIdx = altIndexes.Any()?altIndexes.First() : -1;
[10415]	128	if(altIdx >= 0) return altIdx;
[10409]	129	// select the least sampled alternative
[10427]	130	//altIdx = -1;
	131	//int minSamples = int.MaxValue;
	132	//for(int idx = 0; idx < searchTree.children.Length; idx++) {
	133	// if(searchTree.children[idx] == null) continue;
	134	// if(!searchTree.children[idx].done && Grammar.minDepth[Grammar.transition[state][idx]] <= maxDepth && searchTree.children[idx].tries < minSamples) {
[10415]	135	// minSamples = searchTree.children[idx].tries;
	136	// altIdx = idx;
	137	// }
	138	//}
	139	// select the alternative with the largest average
[10436]	140	// altIdx = -1;
	141	// double best = double.NegativeInfinity;
	142	// for(int idx = 0; idx < searchTree.children.Length; idx++) {
	143	// if(searchTree.children[idx] == null) continue;
	144	// if (!searchTree.children[idx].done && Grammar.minDepth[Grammar.transition[state][idx]] <= maxDepth && UCB(searchTree, searchTree.children[idx]) > best) {
	145	// altIdx = idx;
	146	// best = UCB(searchTree, searchTree.children[idx]);
	147	// }
	148	// }
	149	// Softmax selection
[10437]	150	// double temperature = 1;
	151	// var ms = searchTree.children.Select((c,i) => c == null \|\| c.done \|\| Grammar.minDepth[Grammar.transition[state][i]] > maxDepth ? 0.0 : Math.Exp((c.sumQuality / c.tries) / temperature)).ToArray();
	152	// var msSum = ms.Sum();
	153	// if(msSum == 0.0) {
	154	// // uniform distribution
	155	// ms = searchTree.children.Select((c,i) => c == null \|\| c.done \|\| Grammar.minDepth[Grammar.transition[state][i]] > maxDepth ? 0.0 : 1.0).ToArray();
	156	// msSum = ms.Sum();
	157	// }
	158	// Debug.Assert(msSum > 0.0);
	159	// var r = random.NextDouble() * msSum;
	160	//
	161	// altIdx = 0;
	162	// var aggSum = 0.0;
	163	// while(altIdx < searchTree.children.Length && aggSum <= r) {
	164	// var c = searchTree.children[altIdx];
	165	// aggSum += ms[altIdx++];
	166	// }
	167	// altIdx--;
	168
	169	// epsilon-greedy selection
	170	double eps = 0.1;
	171	if(random.NextDouble() >= eps) {
	172	// select best
	173	altIdx = 0; while(searchTree.children[altIdx]==null) altIdx++;
	174	for(int idx=0;idx<searchTree.children.Length;idx++) {
	175	var c = searchTree.children[idx];
	176	if(c==null \|\| c.done \|\| Grammar.minDepth[Grammar.transition[state][idx]] > maxDepth) continue;
	177	if(searchTree.children[idx].bestQuality > searchTree.children[altIdx].bestQuality) {
	178	altIdx = idx;
	179	}
	180	}
	181	} else {
	182	// select random
	183	var allowedIndexes = (searchTree.children
	184	.Select((e,i) => new {Elem = e, Idx = i})
	185	.Where(p => p.Elem != null && !p.Elem.done && Grammar.minDepth[Grammar.transition[state][p.Idx]] <= maxDepth)
	186	.Select(p => p.Idx)).ToArray();
	187	altIdx = allowedIndexes[random.Next(allowedIndexes.Length)];
[10409]	188	}
[10427]	189	Debug.Assert(altIdx > -1);
[10409]	190	return altIdx;
	191	}
	192	}
[10436]	193
[10415]	194	public static double UCB(SearchTreeNode parent, SearchTreeNode n) {
[10408]	195	Debug.Assert(parent.tries >= n.tries);
	196	Debug.Assert(n.tries > 0);
[10430]	197	return n.sumQuality / n.tries + Math.Sqrt((400 * Math.Log(parent.tries)) / n.tries ); // constant is dependent fitness function values
[10408]	198	}
	199
	200	private void UpdateSearchTree(Tree t, double quality) {
	201	var trees = new Stack<Tree>();
	202	trees.Push(t);
	203	UpdateSearchTree(searchTree, trees, quality);
	204	}
	205
	206	private void UpdateSearchTree(SearchTreeNode searchTree, Stack<Tree> trees, double quality) {
	207	if(trees.Count == 0 \|\| searchTree == null) return;
	208	var t = trees.Pop();
[10411]	209	if(t.altIdx == -1) {
	210	// for trees with multiple sub-trees
[10408]	211	for(int idx = t.subtrees.Length - 1 ; idx >= 0; idx--) {
	212	trees.Push(t.subtrees[idx]);
	213	}
	214	UpdateSearchTree(searchTree, trees, quality);
	215	} else {
[10411]	216	searchTree.sumQuality += quality;
	217	searchTree.tries++;
	218	if(quality > searchTree.bestQuality)
	219	searchTree.bestQuality = quality;
	220	if(t.subtrees != null) {
	221	Debug.Assert(t.subtrees.Length == 1);
[10415]	222	if(searchTree.children != null) {
[10411]	223	trees.Push(t.subtrees[0]);
	224	UpdateSearchTree(searchTree.children[t.altIdx], trees, quality);
	225	}
	226	} else {
[10415]	227	if(searchTree.children != null) {
[10411]	228	Debug.Assert(searchTree.children.Length == 1);
	229	UpdateSearchTree(searchTree.children[0], trees, quality);
	230	}
	231	}
[10408]	232	}
	233	}
	234
[10427]	235	public ?IDENT?MonteCarloTreeSearchSolver(?IDENT?Problem problem, string[] args) {
	236	this.randomSearch = new ?IDENT?RandomSearchSolver(problem, args);
	237	if(args.Length > 0 ) ParseArguments(args);
	238	this.problem = problem;
	239	this.random = new Random();
[10408]	240	}
[10427]	241	private void ParseArguments(string[] args) {
	242	var maxDepthRegex = new Regex(@""--maxDepth=(?<d>.+)"");
[10408]	243
[10427]	244	var helpRegex = new Regex(@""--help\|/\?"");
	245
	246	foreach(var arg in args) {
	247	var maxDepthMatch = maxDepthRegex.Match(arg);
	248	var helpMatch = helpRegex.Match(arg);
	249	if(helpMatch.Success) {
	250	PrintUsage(); Environment.Exit(0);
	251	} else if(maxDepthMatch.Success) {
	252	maxDepth = int.Parse(maxDepthMatch.Groups[""d""].Captures[0].Value, System.Globalization.CultureInfo.InvariantCulture);
	253	if(maxDepth < 1 \|\| maxDepth > 100) throw new ArgumentException(""max depth must lie in range [1 ... 100]"");
[10408]	254	} else {
[10427]	255	Console.WriteLine(""Unknown switch {0}"", arg); PrintUsage(); Environment.Exit(0);
[10408]	256	}
	257	}
	258	}
[10427]	259	private void PrintUsage() {
	260	Console.WriteLine(""Find a solution using Monte-Carlo tree search."");
	261	Console.WriteLine();
	262	Console.WriteLine(""Parameters:"");
	263	Console.WriteLine(""\t--maxDepth=<depth>\tSets the maximal depth of sampled trees [Default: 20]"");
[10408]	264	}
	265
	266
	267
[10426]	268	public void Start() {
[10408]	269	Console.ReadLine();
	270	var bestF = ?MAXIMIZATION? ? double.NegativeInfinity : double.PositiveInfinity;
	271	int n = 0;
	272	long sumDepth = 0;
	273	long sumSize = 0;
	274	var sumF = 0.0;
	275	var sw = new System.Diagnostics.Stopwatch();
	276	sw.Start();
[10415]	277	while (!searchTree.done) {
[10408]	278
	279	int steps, depth;
[10426]	280	var _t = SampleTree(maxDepth);
[10408]	281	// _t.PrintTree(0); Console.WriteLine();
	282
	283	// inefficient but don't care for now
	284	steps = _t.GetSize();
	285	depth = _t.GetDepth();
[10426]	286	Debug.Assert(depth <= maxDepth);
[10408]	287	var f = problem.Evaluate(_t);
	288	if(?MAXIMIZATION?)
	289	UpdateSearchTree(_t, f);
	290	else
	291	UpdateSearchTree(_t, -f);
	292	n++;
	293	sumSize += steps;
	294	sumDepth += depth;
	295	sumF += f;
	296	if (problem.IsBetter(f, bestF)) {
	297	bestF = f;
	298	_t.PrintTree(0); Console.WriteLine();
	299	Console.WriteLine(""{0}\t{1}\t(size={2}, depth={3})"", n, bestF, steps, depth);
	300	}
	301	if (n % 1000 == 0) {
	302	sw.Stop();
	303	Console.WriteLine(""{0}\tbest: {1:0.000}\t(avg: {2:0.000})\t(avg size: {3:0.0})\t(avg. depth: {4:0.0})\t({5:0.00} sols/ms)"", n, bestF, sumF/1000.0, sumSize/1000.0, sumDepth/1000.0, 1000.0 / sw.ElapsedMilliseconds);
	304	sumSize = 0;
	305	sumDepth = 0;
	306	sumF = 0.0;
	307	sw.Restart();
	308	}
	309	}
	310	}
	311	}
	312	}";
	313
	314	public void Generate(IGrammar grammar, IEnumerable<TerminalNode> terminals, bool maximization, SourceBuilder problemSourceCode) {
	315	var solverSourceCode = new SourceBuilder();
	316	solverSourceCode.Append(solverTemplate)
	317	.Replace("?MAXIMIZATION?", maximization.ToString().ToLowerInvariant())
	318	.Replace("?SAMPLEALTERNATIVECODE?", GenerateSampleAlternativeSource(grammar))
	319	.Replace("?CREATETERMINALNODECODE?", GenerateCreateTerminalCode(grammar, terminals))
	320	;
	321
	322	problemSourceCode.Append(solverSourceCode.ToString());
	323	}
	324
	325
	326
	327	private string GenerateSampleAlternativeSource(IGrammar grammar) {
	328	Debug.Assert(grammar.Symbols.First().Equals(grammar.StartSymbol));
	329	var sb = new SourceBuilder();
	330	int stateCount = 0;
	331	foreach (var s in grammar.Symbols) {
	332	sb.AppendFormat("case {0}: ", stateCount++);
	333	if (grammar.IsTerminal(s)) {
	334	// ignore
	335	} else {
	336	var terminalAltIndexes = grammar.GetAlternatives(s)
	337	.Select((alt, idx) => new { alt, idx })
	338	.Where((p) => p.alt.All(symb => grammar.IsTerminal(symb)))
	339	.Select(p => p.idx);
	340	var nonTerminalAltIndexes = grammar.GetAlternatives(s)
	341	.Select((alt, idx) => new { alt, idx })
	342	.Where((p) => p.alt.Any(symb => grammar.IsNonTerminal(symb)))
	343	.Select(p => p.idx);
	344	var hasTerminalAlts = terminalAltIndexes.Any();
	345	var hasNonTerminalAlts = nonTerminalAltIndexes.Any();
	346	if (hasTerminalAlts && hasNonTerminalAlts) {
	347	sb.Append("if(maxDepth <= 1) {").BeginBlock();
	348	GenerateReturnStatement(terminalAltIndexes, sb);
	349	sb.Append("} else {");
[10415]	350	GenerateReturnStatement(nonTerminalAltIndexes.Concat(terminalAltIndexes), sb);
[10408]	351	sb.Append("}").EndBlock();
	352	} else {
	353	GenerateReturnStatement(grammar.NumberOfAlternatives(s), sb);
	354	}
	355	}
	356	}
	357	return sb.ToString();
	358	}
	359	private string GenerateCreateTerminalCode(IGrammar grammar, IEnumerable<TerminalNode> terminals) {
	360	Debug.Assert(grammar.Symbols.First().Equals(grammar.StartSymbol));
	361	var sb = new SourceBuilder();
	362	var allSymbols = grammar.Symbols.ToList();
	363	foreach (var s in grammar.Symbols) {
	364	if (grammar.IsTerminal(s)) {
	365	sb.AppendFormat("case {0}: {{", allSymbols.IndexOf(s)).BeginBlock();
	366	sb.AppendFormat("var t = new {0}Tree();", s.Name).AppendLine();
	367	var terminal = terminals.Single(t => t.Ident == s.Name);
	368	foreach (var constr in terminal.Constraints) {
	369	if (constr.Type == ConstraintNodeType.Set) {
[10415]	370	throw new NotImplementedException("Support for terminal symbols with attributes is not yet implemented.");
	371	// sb.Append("{").BeginBlock();
	372	// sb.AppendFormat("var elements = problem.GetAllowed{0}_{1}().ToArray();", terminal.Ident, constr.Ident).AppendLine();
	373	// sb.AppendFormat("t.{0} = elements[random.Next(elements.Length)]; ", constr.Ident).EndBlock();
	374	// sb.AppendLine("}");
[10408]	375	} else {
[10409]	376	throw new NotSupportedException("The MTCS solver does not support RANGE constraints.");
[10408]	377	}
	378	}
	379	sb.AppendLine("return t;").EndBlock();
	380	sb.Append("}");
	381	}
	382	}
	383	return sb.ToString();
	384	}
	385	private void GenerateReturnStatement(IEnumerable<int> idxs, SourceBuilder sb) {
	386	if (idxs.Count() == 1) {
	387	sb.AppendFormat("return {0};", idxs.Single()).AppendLine();
	388	} else {
	389	var idxStr = idxs.Aggregate(string.Empty, (str, idx) => str + idx + ", ");
	390	sb.AppendFormat("return new int[] {{ {0} }}[random.Next({1})]; ", idxStr, idxs.Count()).AppendLine();
	391	}
	392	}
	393
	394	private void GenerateReturnStatement(int nAlts, SourceBuilder sb) {
	395	if (nAlts > 1) {
	396	sb.AppendFormat("return random.Next({0});", nAlts).AppendLine();
	397	} else if (nAlts == 1) {
	398	sb.AppendLine("return 0; ");
	399	} else {
	400	sb.AppendLine("throw new InvalidProgramException();");
	401	}
	402	}
	403	}
	404	}

Note: See TracBrowser for help on using the repository browser.

Context Navigation

source: branches/HeuristicLab.Problems.GPDL/CodeGenerator/MonteCarloTreeSearchCodeGen.cs @ 15767

Download in other formats: