Ejemplo n.º 1
0
        /// <summary>
        /// Minimizes the given automaton using Hopcroft's algorithm.
        /// </summary>
        public static void MinimizeHopcroft(Automaton a)
        {
            a.Determinize();
            if (a.initial.numTransitions == 1)
            {
                Transition t = a.initial.TransitionsArray[0];
                if (t.to == a.initial && t.min == Character.MIN_CODE_POINT && t.max == Character.MAX_CODE_POINT)
                {
                    return;
                }
            }
            a.Totalize();

            // initialize data structures
            int[]   sigma = a.GetStartPoints();
            State[] states = a.GetNumberedStates();
            int     sigmaLen = sigma.Length, statesLen = states.Length;

            List <State>[,] reverse = new List <State> [statesLen, sigmaLen];
            ISet <State>[] partition  = new EquatableSet <State> [statesLen];
            List <State>[] splitblock = new List <State> [statesLen];
            int[]          block      = new int[statesLen];
            StateList[,] active      = new StateList[statesLen, sigmaLen];
            StateListNode[,] active2 = new StateListNode[statesLen, sigmaLen];
            LinkedList <Int32Pair> pending = new LinkedList <Int32Pair>();
            OpenBitSet             pending2 = new OpenBitSet(sigmaLen * statesLen);
            OpenBitSet             split = new OpenBitSet(statesLen),
                                   refine = new OpenBitSet(statesLen), refine2 = new OpenBitSet(statesLen);

            for (int q = 0; q < statesLen; q++)
            {
                splitblock[q] = new List <State>();
                partition[q]  = new EquatableSet <State>();
                for (int x = 0; x < sigmaLen; x++)
                {
                    active[q, x] = new StateList();
                }
            }
            // find initial partition and reverse edges
            for (int q = 0; q < statesLen; q++)
            {
                State qq = states[q];
                int   j  = qq.accept ? 0 : 1;
                partition[j].Add(qq);
                block[q] = j;
                for (int x = 0; x < sigmaLen; x++)
                {
                    //List<State>[] r = reverse[qq.Step(sigma[x]).number];
                    var r = qq.Step(sigma[x]).number;
                    if (reverse[r, x] == null)
                    {
                        reverse[r, x] = new List <State>();
                    }
                    reverse[r, x].Add(qq);
                }
            }
            // initialize active sets
            for (int j = 0; j <= 1; j++)
            {
                for (int x = 0; x < sigmaLen; x++)
                {
                    foreach (State qq in partition[j])
                    {
                        if (reverse[qq.number, x] != null)
                        {
                            active2[qq.number, x] = active[j, x].Add(qq);
                        }
                    }
                }
            }
            // initialize pending
            for (int x = 0; x < sigmaLen; x++)
            {
                int j = (active[0, x].Count <= active[1, x].Count) ? 0 : 1;
                pending.AddLast(new Int32Pair(j, x));
                pending2.Set(x * statesLen + j);
            }
            // process pending until fixed point
            int k = 2;

            while (pending.Count > 0)
            {
                Int32Pair ip = pending.First.Value;
                pending.Remove(ip);
                int p = ip.N1;
                int x = ip.N2;
                pending2.Clear(x * statesLen + p);
                // find states that need to be split off their blocks
                for (StateListNode m = active[p, x].First; m != null; m = m.Next)
                {
                    List <State> r = reverse[m.Q.number, x];
                    if (r != null)
                    {
                        foreach (State s in r)
                        {
                            int i = s.number;
                            if (!split.Get(i))
                            {
                                split.Set(i);
                                int j = block[i];
                                splitblock[j].Add(s);
                                if (!refine2.Get(j))
                                {
                                    refine2.Set(j);
                                    refine.Set(j);
                                }
                            }
                        }
                    }
                }
                // refine blocks
                for (int j = refine.NextSetBit(0); j >= 0; j = refine.NextSetBit(j + 1))
                {
                    List <State> sb = splitblock[j];
                    if (sb.Count < partition[j].Count)
                    {
                        ISet <State> b1 = partition[j];
                        ISet <State> b2 = partition[k];
                        foreach (State s in sb)
                        {
                            b1.Remove(s);
                            b2.Add(s);
                            block[s.number] = k;
                            for (int c = 0; c < sigmaLen; c++)
                            {
                                StateListNode sn = active2[s.number, c];
                                if (sn != null && sn.Sl == active[j, c])
                                {
                                    sn.Remove();
                                    active2[s.number, c] = active[k, c].Add(s);
                                }
                            }
                        }
                        // update pending
                        for (int c = 0; c < sigmaLen; c++)
                        {
                            int aj = active[j, c].Count, ak = active[k, c].Count, ofs = c * statesLen;
                            if (!pending2.Get(ofs + j) && 0 < aj && aj <= ak)
                            {
                                pending2.Set(ofs + j);
                                pending.AddLast(new Int32Pair(j, c));
                            }
                            else
                            {
                                pending2.Set(ofs + k);
                                pending.AddLast(new Int32Pair(k, c));
                            }
                        }
                        k++;
                    }
                    refine2.Clear(j);
                    foreach (State s in sb)
                    {
                        split.Clear(s.number);
                    }
                    sb.Clear();
                }
                refine.Clear(0, refine.Length - 1);
            }
            // make a new state for each equivalence class, set initial state
            State[] newstates = new State[k];
            for (int n = 0; n < newstates.Length; n++)
            {
                State s = new State();
                newstates[n] = s;
                foreach (State q in partition[n])
                {
                    if (q == a.initial)
                    {
                        a.initial = s;
                    }
                    s.accept = q.accept;
                    s.number = q.number; // select representative
                    q.number = n;
                }
            }
            // build transitions and set acceptance
            for (int n = 0; n < newstates.Length; n++)
            {
                State s = newstates[n];
                s.accept = states[s.number].accept;
                foreach (Transition t in states[s.number].GetTransitions())
                {
                    s.AddTransition(new Transition(t.min, t.max, newstates[t.to.number]));
                }
            }
            a.ClearNumberedStates();
            a.RemoveDeadTransitions();
        }
Ejemplo n.º 2
0
 /// <summary>
 /// Returns <c>true</c> if the given string is accepted by the automaton.
 /// <para/>
 /// Complexity: linear in the length of the string.
 /// <para/>
 /// <b>Note:</b> for full performance, use the <see cref="RunAutomaton"/> class.
 /// </summary>
 public static bool Run(Automaton a, string s)
 {
     if (a.IsSingleton)
     {
         return(s.Equals(a.singleton, StringComparison.Ordinal));
     }
     if (a.deterministic)
     {
         State p = a.initial;
         for (int i = 0, cp = 0; i < s.Length; i += Character.CharCount(cp))
         {
             State q = p.Step(cp = Character.CodePointAt(s, i));
             if (q == null)
             {
                 return(false);
             }
             p = q;
         }
         return(p.accept);
     }
     else
     {
         State[]            states   = a.GetNumberedStates();
         LinkedList <State> pp       = new LinkedList <State>();
         LinkedList <State> pp_other = new LinkedList <State>();
         OpenBitSet         bb       = new OpenBitSet(states.Length);
         OpenBitSet         bb_other = new OpenBitSet(states.Length);
         pp.AddLast(a.initial);
         List <State> dest   = new List <State>();
         bool         accept = a.initial.accept;
         for (int i = 0, c = 0; i < s.Length; i += Character.CharCount(c))
         {
             c      = Character.CodePointAt(s, i);
             accept = false;
             pp_other.Clear();
             bb_other.Clear(0, bb_other.Length - 1);
             foreach (State p in pp)
             {
                 dest.Clear();
                 p.Step(c, dest);
                 foreach (State q in dest)
                 {
                     if (q.accept)
                     {
                         accept = true;
                     }
                     if (!bb_other.Get(q.number))
                     {
                         bb_other.Set(q.number);
                         pp_other.AddLast(q);
                     }
                 }
             }
             LinkedList <State> tp = pp;
             pp       = pp_other;
             pp_other = tp;
             OpenBitSet tb = bb;
             bb       = bb_other;
             bb_other = tb;
         }
         return(accept);
     }
 }