src/include/fst/dfs-visit.h - platform/external/openfst - Git at Google

 // dfs-visit.h

 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 // Copyright 2005-2010 Google, Inc.
 // Author: riley@google.com (Michael Riley)
 //
 // \file
 // Depth-first search visitation. See visit.h for more general
 // search queue disciplines.

 #ifndef FST_LIB_DFS_VISIT_H__
 #define FST_LIB_DFS_VISIT_H__

 #include <stack>
 #include <vector>
 using std::vector;

 #include <fst/arcfilter.h>
 #include <fst/fst.h>


 namespace fst {

 // Visitor Interface - class determines actions taken during a Dfs.
 // If any of the boolean member functions return false, the DFS is
 // aborted by first calling FinishState() on all currently grey states
 // and then calling FinishVisit().
 //
 // Note this is similar to the more general visitor interface in visit.h
 // except that FinishState returns additional information appropriate only for
 // a DFS and some methods names here are better suited to a DFS.
 //
 // template <class Arc>
 // class Visitor {
 //  public:
 //   typedef typename Arc::StateId StateId;
 //
 //   Visitor(T *return_data);
 //   // Invoked before DFS visit
 //   void InitVisit(const Fst<Arc> &fst);
 //   // Invoked when state discovered (2nd arg is DFS tree root)
 //   bool InitState(StateId s, StateId root);
 //   // Invoked when tree arc examined (to white/undiscovered state)
 //   bool TreeArc(StateId s, const Arc &a);
 //   // Invoked when back arc examined (to grey/unfinished state)
 //   bool BackArc(StateId s, const Arc &a);
 //   // Invoked when forward or cross arc examined (to black/finished state)
 //   bool ForwardOrCrossArc(StateId s, const Arc &a);
 //   // Invoked when state finished (PARENT is kNoStateID and ARC == NULL
 //   // when S is tree root)
 //   void FinishState(StateId s, StateId parent, const Arc *parent_arc);
 //   // Invoked after DFS visit
 //   void FinishVisit();
 // };

 // An Fst state's DFS status
 const int kDfsWhite = 0;   // Undiscovered
 const int kDfsGrey =  1;   // Discovered & unfinished
 const int kDfsBlack = 2;   // Finished

 // An Fst state's DFS stack state
 template <class Arc>
 struct DfsState {
   typedef typename Arc::StateId StateId;

   DfsState(const Fst<Arc> &fst, StateId s): state_id(s), arc_iter(fst, s) {}

   StateId state_id;       // Fst state ...
   ArcIterator< Fst<Arc> > arc_iter;  // and its corresponding arcs
 };


 // Performs depth-first visitation. Visitor class argument determines
 // actions and contains any return data. ArcFilter determines arcs
 // that are considered.
 //
 // Note this is similar to Visit() in visit.h called with a LIFO
 // queue except this version has a Visitor class specialized and
 // augmented for a DFS.
 template <class Arc, class V, class ArcFilter>
 void DfsVisit(const Fst<Arc> &fst, V *visitor, ArcFilter filter) {
   typedef typename Arc::StateId StateId;

   visitor->InitVisit(fst);

   StateId start = fst.Start();
   if (start == kNoStateId) {
     visitor->FinishVisit();
     return;
   }

   vector<char> state_color;                // Fst state DFS status
   stack<DfsState<Arc> *> state_stack;      // DFS execution stack

   StateId nstates = start + 1;             // # of known states in general case
   bool expanded = false;
   if (fst.Properties(kExpanded, false)) {  // tests if expanded case, then
     nstates = CountStates(fst);            // uses ExpandedFst::NumStates().
     expanded = true;
   }

   state_color.resize(nstates, kDfsWhite);
   StateIterator< Fst<Arc> > siter(fst);

   // Continue DFS while true
   bool dfs = true;

   // Iterate over trees in DFS forest.
   for (StateId root = start; dfs && root < nstates;) {
     state_color[root] = kDfsGrey;
     state_stack.push(new DfsState<Arc>(fst, root));
     dfs = visitor->InitState(root, root);
     while (!state_stack.empty()) {
       DfsState<Arc> *dfs_state = state_stack.top();
       StateId s = dfs_state->state_id;
       if (s >= state_color.size()) {
         nstates = s + 1;
         state_color.resize(nstates, kDfsWhite);
       }
       ArcIterator< Fst<Arc> > &aiter = dfs_state->arc_iter;
       if (!dfs || aiter.Done()) {
         state_color[s] = kDfsBlack;
         delete dfs_state;
         state_stack.pop();
         if (!state_stack.empty()) {
           DfsState<Arc> *parent_state = state_stack.top();
           StateId p = parent_state->state_id;
           ArcIterator< Fst<Arc> > &piter = parent_state->arc_iter;
           visitor->FinishState(s, p, &piter.Value());
           piter.Next();
         } else {
           visitor->FinishState(s, kNoStateId, 0);
         }
         continue;
       }
       const Arc &arc = aiter.Value();
       if (arc.nextstate >= state_color.size()) {
         nstates = arc.nextstate + 1;
         state_color.resize(nstates, kDfsWhite);
       }
       if (!filter(arc)) {
         aiter.Next();
         continue;
       }
       int next_color = state_color[arc.nextstate];
       switch (next_color) {
         default:
         case kDfsWhite:
           dfs = visitor->TreeArc(s, arc);
           if (!dfs) break;
           state_color[arc.nextstate] = kDfsGrey;
           state_stack.push(new DfsState<Arc>(fst, arc.nextstate));
           dfs = visitor->InitState(arc.nextstate, root);
           break;
         case kDfsGrey:
           dfs = visitor->BackArc(s, arc);
           aiter.Next();
           break;
         case kDfsBlack:
           dfs = visitor->ForwardOrCrossArc(s, arc);
           aiter.Next();
           break;
       }
     }

     // Find next tree root
     for (root = root == start ? 0 : root + 1;
          root < nstates && state_color[root] != kDfsWhite;
          ++root);

     // Check for a state beyond the largest known state
     if (!expanded && root == nstates) {
       for (; !siter.Done(); siter.Next()) {
         if (siter.Value() == nstates) {
           ++nstates;
           state_color.push_back(kDfsWhite);
           break;
         }
       }
     }
   }
   visitor->FinishVisit();
 }


 template <class Arc, class V>
 void DfsVisit(const Fst<Arc> &fst, V *visitor) {
   DfsVisit(fst, visitor, AnyArcFilter<Arc>());
 }

 }  // namespace fst

 #endif  // FST_LIB_DFS_VISIT_H__
	// dfs-visit.h

	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	//
	// Copyright 2005-2010 Google, Inc.
	// Author: riley@google.com (Michael Riley)
	//
	// \file
	// Depth-first search visitation. See visit.h for more general
	// search queue disciplines.

	#ifndef FST_LIB_DFS_VISIT_H__
	#define FST_LIB_DFS_VISIT_H__

	#include <stack>
	#include <vector>
	using std::vector;

	#include <fst/arcfilter.h>
	#include <fst/fst.h>


	namespace fst {

	// Visitor Interface - class determines actions taken during a Dfs.
	// If any of the boolean member functions return false, the DFS is
	// aborted by first calling FinishState() on all currently grey states
	// and then calling FinishVisit().
	//
	// Note this is similar to the more general visitor interface in visit.h
	// except that FinishState returns additional information appropriate only for
	// a DFS and some methods names here are better suited to a DFS.
	//
	// template <class Arc>
	// class Visitor {
	// public:
	// typedef typename Arc::StateId StateId;
	//
	// Visitor(T *return_data);
	// // Invoked before DFS visit
	// void InitVisit(const Fst<Arc> &fst);
	// // Invoked when state discovered (2nd arg is DFS tree root)
	// bool InitState(StateId s, StateId root);
	// // Invoked when tree arc examined (to white/undiscovered state)
	// bool TreeArc(StateId s, const Arc &a);
	// // Invoked when back arc examined (to grey/unfinished state)
	// bool BackArc(StateId s, const Arc &a);
	// // Invoked when forward or cross arc examined (to black/finished state)
	// bool ForwardOrCrossArc(StateId s, const Arc &a);
	// // Invoked when state finished (PARENT is kNoStateID and ARC == NULL
	// // when S is tree root)
	// void FinishState(StateId s, StateId parent, const Arc *parent_arc);
	// // Invoked after DFS visit
	// void FinishVisit();
	// };

	// An Fst state's DFS status
	const int kDfsWhite = 0; // Undiscovered
	const int kDfsGrey = 1; // Discovered & unfinished
	const int kDfsBlack = 2; // Finished

	// An Fst state's DFS stack state
	template <class Arc>
	struct DfsState {
	typedef typename Arc::StateId StateId;

	DfsState(const Fst<Arc> &fst, StateId s): state_id(s), arc_iter(fst, s) {}

	StateId state_id; // Fst state ...
	ArcIterator< Fst<Arc> > arc_iter; // and its corresponding arcs
	};


	// Performs depth-first visitation. Visitor class argument determines
	// actions and contains any return data. ArcFilter determines arcs
	// that are considered.
	//
	// Note this is similar to Visit() in visit.h called with a LIFO
	// queue except this version has a Visitor class specialized and
	// augmented for a DFS.
	template <class Arc, class V, class ArcFilter>
	void DfsVisit(const Fst<Arc> &fst, V *visitor, ArcFilter filter) {
	typedef typename Arc::StateId StateId;

	visitor->InitVisit(fst);

	StateId start = fst.Start();
	if (start == kNoStateId) {
	visitor->FinishVisit();
	return;
	}

	vector<char> state_color; // Fst state DFS status
	stack<DfsState<Arc> *> state_stack; // DFS execution stack

	StateId nstates = start + 1; // # of known states in general case
	bool expanded = false;
	if (fst.Properties(kExpanded, false)) { // tests if expanded case, then
	nstates = CountStates(fst); // uses ExpandedFst::NumStates().
	expanded = true;
	}

	state_color.resize(nstates, kDfsWhite);
	StateIterator< Fst<Arc> > siter(fst);

	// Continue DFS while true
	bool dfs = true;

	// Iterate over trees in DFS forest.
	for (StateId root = start; dfs && root < nstates;) {
	state_color[root] = kDfsGrey;
	state_stack.push(new DfsState<Arc>(fst, root));
	dfs = visitor->InitState(root, root);
	while (!state_stack.empty()) {
	DfsState<Arc> *dfs_state = state_stack.top();
	StateId s = dfs_state->state_id;
	if (s >= state_color.size()) {
	nstates = s + 1;
	state_color.resize(nstates, kDfsWhite);
	}
	ArcIterator< Fst<Arc> > &aiter = dfs_state->arc_iter;
	if (!dfs \|\| aiter.Done()) {
	state_color[s] = kDfsBlack;
	delete dfs_state;
	state_stack.pop();
	if (!state_stack.empty()) {
	DfsState<Arc> *parent_state = state_stack.top();
	StateId p = parent_state->state_id;
	ArcIterator< Fst<Arc> > &piter = parent_state->arc_iter;
	visitor->FinishState(s, p, &piter.Value());
	piter.Next();
	} else {
	visitor->FinishState(s, kNoStateId, 0);
	}
	continue;
	}
	const Arc &arc = aiter.Value();
	if (arc.nextstate >= state_color.size()) {
	nstates = arc.nextstate + 1;
	state_color.resize(nstates, kDfsWhite);
	}
	if (!filter(arc)) {
	aiter.Next();
	continue;
	}
	int next_color = state_color[arc.nextstate];
	switch (next_color) {
	default:
	case kDfsWhite:
	dfs = visitor->TreeArc(s, arc);
	if (!dfs) break;
	state_color[arc.nextstate] = kDfsGrey;
	state_stack.push(new DfsState<Arc>(fst, arc.nextstate));
	dfs = visitor->InitState(arc.nextstate, root);
	break;
	case kDfsGrey:
	dfs = visitor->BackArc(s, arc);
	aiter.Next();
	break;
	case kDfsBlack:
	dfs = visitor->ForwardOrCrossArc(s, arc);
	aiter.Next();
	break;
	}
	}

	// Find next tree root
	for (root = root == start ? 0 : root + 1;
	root < nstates && state_color[root] != kDfsWhite;
	++root);

	// Check for a state beyond the largest known state
	if (!expanded && root == nstates) {
	for (; !siter.Done(); siter.Next()) {
	if (siter.Value() == nstates) {
	++nstates;
	state_color.push_back(kDfsWhite);
	break;
	}
	}
	}
	}
	visitor->FinishVisit();
	}


	template <class Arc, class V>
	void DfsVisit(const Fst<Arc> &fst, V *visitor) {
	DfsVisit(fst, visitor, AnyArcFilter<Arc>());
	}

	} // namespace fst

	#endif // FST_LIB_DFS_VISIT_H__