source: branches/HeuristicLab.Problems.GPDL/CodeGenerator/MonteCarloTreeSearchCodeGen.cs @ 10410

using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Text;
using HeuristicLab.Grammars;

namespace CodeGenerator {
  public class MonteCarloTreeSearchCodeGen {

    private string solverTemplate = @"
namespace ?PROBLEMNAME? {
  public class SearchTreeNode {
    public int tries;
    public double sumQuality = 0.0;
    public double bestQuality = double.NegativeInfinity;
    public bool ready;
    public SearchTreeNode[] children;

    public SearchTreeNode() {
    }
  }

  public sealed class ?IDENT?Solver {

    private readonly ?IDENT?Problem problem;
    private readonly Random random;
    private SearchTreeNode searchTree = new SearchTreeNode();
   
    private Tree SampleTree() {
      var extensionsStack = new Stack<Tuple<Tree, int, int>>(); // the unfinished tree, the state, and the index of the extension point
      var t = new Tree(-1, new Tree[1]);
      extensionsStack.Push(Tuple.Create(t, 0, 0));
      SampleTree(searchTree, extensionsStack);
      return t.subtrees[0];
    }

    private void SampleTree(SearchTreeNode searchTree, Stack<Tuple<Tree, int, int>> extensionPoints) {
      const int RANDOM_TRIES = 100;
      if(extensionPoints.Count == 0) return; // nothing to do
      var extensionPoint = extensionPoints.Pop();
      Tree parent = extensionPoint.Item1;
      int state = extensionPoint.Item2;
      int subtreeIdx = extensionPoint.Item3;
      Tree t = null;
      
      if(searchTree.tries < RANDOM_TRIES || Grammar.subtreeCount[state] == 0) {
        searchTree.tries++; // could be moved to UpdateTree
        t = SampleTreeRandom(state);
        if(Grammar.subtreeCount[state] == 0) {
          // when we produced a terminal continue filling up all other empty points
          Debug.Assert(searchTree.children == null || searchTree.children.Length == 1);
          if(searchTree.children == null)
            searchTree.children = new SearchTreeNode[] { new SearchTreeNode() } ;
          SampleTree(searchTree.children[0], extensionPoints);
        } else {
          // fill up all remaining slots randomly
          foreach(var p in extensionPoints) {
            var pParent = p.Item1;
            var pState = p.Item2;
            var pIdx = p.Item3;
            pParent.subtrees[pIdx] = SampleTreeRandom(pState);
          }
        }
      } else {
        if(Grammar.subtreeCount[state] == 1) {
          searchTree.tries++; // could be moved to updateTree
          if(searchTree.children == null) {
            int nChildren = Grammar.transition[state].Length;
            searchTree.children = new SearchTreeNode[nChildren];
          }
          Debug.Assert(searchTree.children.Length == Grammar.transition[state].Length);
          Debug.Assert(searchTree.tries - RANDOM_TRIES - 1 == searchTree.children.Where(c=>c!=null).Sum(c=>c.tries));
          var altIdx = SelectAlternative(searchTree);
          t = new Tree(altIdx, new Tree[1]);
          extensionPoints.Push(Tuple.Create(t, Grammar.transition[state][altIdx], 0));
          SampleTree(searchTree.children[altIdx], extensionPoints);
        } else {
          // multiple subtrees
          var subtrees = new Tree[Grammar.subtreeCount[state]];
          t = new Tree(-1, subtrees);
          for(int i = subtrees.Length - 1; i >= 0; i--) {
            extensionPoints.Push(Tuple.Create(t, Grammar.transition[state][i], i));
          }
          SampleTree(searchTree, extensionPoints);
        }
      }
      Debug.Assert(parent.subtrees[subtreeIdx] == null);
      parent.subtrees[subtreeIdx] = t;
    }

    private int SelectAlternative(SearchTreeNode searchTree) {
      // any alternative not yet explored?
      var altIdx = Array.FindIndex(searchTree.children, (e) => e == null);
      if(altIdx >= 0) {
        searchTree.children[altIdx] = new SearchTreeNode();
        return altIdx;
      } else {
        // select the least sampled alternative
        altIdx = 0;
        int minSamples = searchTree.children[altIdx].tries;
        for(int idx = 1; idx < searchTree.children.Length; idx++) {
          if(searchTree.children[idx].tries < minSamples) {
            minSamples = searchTree.children[idx].tries;
            altIdx = idx;
          }
        }
        // select the alternative with the largest average
        // altIdx = 0;
        // double bestAverage = UCB(searchTree, searchTree.children[altIdx]);
        // for(int idx = 1; idx < searchTree.children.Length; idx++) {
        //   if (UCB(searchTree, searchTree.children[idx]) > UCB(searchTree, searchTree.children[altIdx])) {
        //     altIdx = idx;
        //   }
        // }
        return altIdx;
      }
    }

    private double UCB(SearchTreeNode parent, SearchTreeNode n) {
      Debug.Assert(parent.tries >= n.tries);
      Debug.Assert(n.tries > 0);
      return n.sumQuality / n.tries + Math.Sqrt((2 * Math.Log(parent.tries)) / n.tries ); // constant is dependent fitness function values
    }

    private void UpdateSearchTree(Tree t, double quality) {
      var trees = new Stack<Tree>();
      trees.Push(t);
      UpdateSearchTree(searchTree, trees, quality);
    }

    private void UpdateSearchTree(SearchTreeNode searchTree, Stack<Tree> trees, double quality) {
      if(trees.Count == 0 || searchTree == null) return;
      var t = trees.Pop();
      searchTree.sumQuality += quality;
      if(quality > searchTree.bestQuality)
        searchTree.bestQuality = quality;
      if(searchTree.children == null) return;
      if(t.subtrees == null) { 
        Debug.Assert(searchTree.children.Length == 1);
        UpdateSearchTree(searchTree.children[0], trees, quality);
      } else if(t.altIdx==-1) {
        for(int idx = t.subtrees.Length - 1 ; idx >= 0; idx--) {
          trees.Push(t.subtrees[idx]);
        }
        UpdateSearchTree(searchTree, trees, quality);
      } else {
        Debug.Assert(t.subtrees.Length == 1);
        trees.Push(t.subtrees[0]);
        UpdateSearchTree(searchTree.children[t.altIdx], trees, quality);
      }
    }

    // same as in random search solver (could reuse random search)
    private Tree SampleTreeRandom(int state) {
      return SampleTreeRandom(state, 5);
    }
    private Tree SampleTreeRandom(int state, int maxDepth) {
      Tree t = null;

      // terminals
      if(Grammar.subtreeCount[state] == 0) {
        t = CreateTerminalNode(state, random, problem);
      } else {
        // if the symbol has alternatives then we must choose one randomly (only one sub-tree in this case)
        if(Grammar.subtreeCount[state] == 1) {
          var targetStates = Grammar.transition[state];
          var altIdx = SampleAlternative(random, state, maxDepth);
          var alternative = SampleTreeRandom(targetStates[altIdx], maxDepth - 1);
          t = new Tree(altIdx, new Tree[] { alternative });
        } else {
          // if the symbol contains only one sequence we must use create sub-trees for each symbol in the sequence
          Tree[] subtrees = new Tree[Grammar.subtreeCount[state]];
          for(int i = 0; i < Grammar.subtreeCount[state]; i++) {
            subtrees[i] = SampleTreeRandom(Grammar.transition[state][i], maxDepth - 1);
          }
          t = new Tree(-1, subtrees); // alternative index is ignored
        }
      }
      return t;
    }

    private static Tree CreateTerminalNode(int state, Random random, ?IDENT?Problem problem) {
      switch(state) {
        ?CREATETERMINALNODECODE?
        default: { throw new ArgumentException(""Unknown state index"" + state); }
      }
    }

    private int SampleAlternative(Random random, int state, int maxDepth) {
      switch(state) {

?SAMPLEALTERNATIVECODE?

        default: throw new InvalidOperationException();
      }
    }


    public static void Main(string[] args) {
      // if(args.Length >= 1) ParseArguments(args);

      var problem = new ?IDENT?Problem();
      var solver = new ?IDENT?Solver(problem);
      solver.Start();
    }

    public ?IDENT?Solver(?IDENT?Problem problem) {
      this.problem = problem;
      this.random = new Random();
    }

    private void Start() {
      Console.ReadLine();
      var bestF = ?MAXIMIZATION? ? double.NegativeInfinity : double.PositiveInfinity;
      int n = 0;
      long sumDepth = 0;
      long sumSize = 0;
      var sumF = 0.0;
      var sw = new System.Diagnostics.Stopwatch();
      sw.Start();
      while (true) {

        int steps, depth;
        var _t = SampleTree();
        //  _t.PrintTree(0); Console.WriteLine();

        // inefficient but don't care for now
        steps = _t.GetSize();
        depth = _t.GetDepth();
        var f = problem.Evaluate(_t);
        if(?MAXIMIZATION?)
          UpdateSearchTree(_t, f);
        else
          UpdateSearchTree(_t, -f);
        n++;    
        sumSize += steps;
        sumDepth += depth;
        sumF += f;
        if (problem.IsBetter(f, bestF)) {
          bestF = f;
          _t.PrintTree(0); Console.WriteLine();
          Console.WriteLine(""{0}\t{1}\t(size={2}, depth={3})"", n, bestF, steps, depth);
        }
        if (n % 1000 == 0) {
          sw.Stop();
          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);
          sumSize = 0;
          sumDepth = 0;
          sumF = 0.0;
          sw.Restart();
        }
      }
    }
  }
}";

    public void Generate(IGrammar grammar, IEnumerable<TerminalNode> terminals, bool maximization, SourceBuilder problemSourceCode) {
      var solverSourceCode = new SourceBuilder();
      solverSourceCode.Append(solverTemplate)
        .Replace("?MAXIMIZATION?", maximization.ToString().ToLowerInvariant())
        .Replace("?SAMPLEALTERNATIVECODE?", GenerateSampleAlternativeSource(grammar))
        .Replace("?CREATETERMINALNODECODE?", GenerateCreateTerminalCode(grammar, terminals))
      ;

      problemSourceCode.Append(solverSourceCode.ToString());
    }



    private string GenerateSampleAlternativeSource(IGrammar grammar) {
      Debug.Assert(grammar.Symbols.First().Equals(grammar.StartSymbol));
      var sb = new SourceBuilder();
      int stateCount = 0;
      foreach (var s in grammar.Symbols) {
        sb.AppendFormat("case {0}: ", stateCount++);
        if (grammar.IsTerminal(s)) {
          // ignore
        } else {
          var terminalAltIndexes = grammar.GetAlternatives(s)
            .Select((alt, idx) => new { alt, idx })
            .Where((p) => p.alt.All(symb => grammar.IsTerminal(symb)))
            .Select(p => p.idx);
          var nonTerminalAltIndexes = grammar.GetAlternatives(s)
            .Select((alt, idx) => new { alt, idx })
            .Where((p) => p.alt.Any(symb => grammar.IsNonTerminal(symb)))
            .Select(p => p.idx);
          var hasTerminalAlts = terminalAltIndexes.Any();
          var hasNonTerminalAlts = nonTerminalAltIndexes.Any();
          if (hasTerminalAlts && hasNonTerminalAlts) {
            sb.Append("if(maxDepth <= 1) {").BeginBlock();
            GenerateReturnStatement(terminalAltIndexes, sb);
            sb.Append("} else {");
            GenerateReturnStatement(nonTerminalAltIndexes, sb);
            sb.Append("}").EndBlock();
          } else {
            GenerateReturnStatement(grammar.NumberOfAlternatives(s), sb);
          }
        }
      }
      return sb.ToString();
    }
    private string GenerateCreateTerminalCode(IGrammar grammar, IEnumerable<TerminalNode> terminals) {
      Debug.Assert(grammar.Symbols.First().Equals(grammar.StartSymbol));
      var sb = new SourceBuilder();
      var allSymbols = grammar.Symbols.ToList();
      foreach (var s in grammar.Symbols) {
        if (grammar.IsTerminal(s)) {
          sb.AppendFormat("case {0}: {{", allSymbols.IndexOf(s)).BeginBlock();
          sb.AppendFormat("var t = new {0}Tree();", s.Name).AppendLine();
          var terminal = terminals.Single(t => t.Ident == s.Name);
          foreach (var constr in terminal.Constraints) {
            if (constr.Type == ConstraintNodeType.Set) {
              sb.Append("{").BeginBlock();
              sb.AppendFormat("var elements = problem.GetAllowed{0}_{1}().ToArray();", terminal.Ident, constr.Ident).AppendLine();
              sb.AppendFormat("t.{0} = elements[random.Next(elements.Length)]; ", constr.Ident).EndBlock();
              sb.AppendLine("}");
            } else {
              throw new NotSupportedException("The MTCS solver does not support RANGE constraints.");
            }
          }
          sb.AppendLine("return t;").EndBlock();
          sb.Append("}");
        }
      }
      return sb.ToString();
    }
    private void GenerateReturnStatement(IEnumerable<int> idxs, SourceBuilder sb) {
      if (idxs.Count() == 1) {
        sb.AppendFormat("return {0};", idxs.Single()).AppendLine();
      } else {
        var idxStr = idxs.Aggregate(string.Empty, (str, idx) => str + idx + ", ");
        sb.AppendFormat("return new int[] {{ {0} }}[random.Next({1})]; ", idxStr, idxs.Count()).AppendLine();
      }
    }

    private void GenerateReturnStatement(int nAlts, SourceBuilder sb) {
      if (nAlts > 1) {
        sb.AppendFormat("return random.Next({0});", nAlts).AppendLine();
      } else if (nAlts == 1) {
        sb.AppendLine("return 0; ");
      } else {
        sb.AppendLine("throw new InvalidProgramException();");
      }
    }
  }
}