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android / platform / external / openfst / refs/heads/jb-mr1.1-release / . / src / include / fst / extensions / pdt / shortest-path.h
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// shortest-path.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
// Functions to find shortest paths in a PDT.
#ifndef FST_EXTENSIONS_PDT_SHORTEST_PATH_H__
#define FST_EXTENSIONS_PDT_SHORTEST_PATH_H__
#include <fst/shortest-path.h>
#include <fst/extensions/pdt/paren.h>
#include <fst/extensions/pdt/pdt.h>
#include <unordered_map>
using std::tr1::unordered_map;
using std::tr1::unordered_multimap;
#include <tr1/unordered_set>
using std::tr1::unordered_set;
using std::tr1::unordered_multiset;
#include <stack>
#include <vector>
using std::vector;
namespace fst {
template <class Arc, class Queue>
struct PdtShortestPathOptions {
bool keep_parentheses;
bool path_gc;
PdtShortestPathOptions(bool kp = false, bool gc = true)
: keep_parentheses(kp), path_gc(gc) {}
};
// Class to store PDT shortest path results. Stores shortest path
// tree info 'Distance()', Parent(), and ArcParent() information keyed
// on two types:
// (1) By SearchState: This is a usual node in a shortest path tree but:
// (a) is w.r.t a PDT search state - a pair of a PDT state and
// a 'start' state, which is either the PDT start state or
// the destination state of an open parenthesis.
// (b) the Distance() is from this 'start' state to the search state.
// (c) Parent().state is kNoLabel for the 'start' state.
//
// (2) By ParenSpec: This connects shortest path trees depending on the
// the parenthesis taken. Given the parenthesis spec:
// (a) the Distance() is from the Parent() 'start' state to the
// parenthesis destination state.
// (b) the ArcParent() is the parenthesis arc.
template <class Arc>
class PdtShortestPathData {
public:
static const uint8 kFinal;
typedef typename Arc::StateId StateId;
typedef typename Arc::Weight Weight;
typedef typename Arc::Label Label;
struct SearchState {
SearchState() : state(kNoStateId), start(kNoStateId) {}
SearchState(StateId s, StateId t) : state(s), start(t) {}
bool operator==(const SearchState &s) const {
if (&s == this)
return true;
return s.state == this->state && s.start == this->start;
}
StateId state; // PDT state
StateId start; // PDT paren 'source' state
};
// Specifies paren id, source and dest 'start' states of a paren.
// These are the 'start' states of the respective sub-graphs.
struct ParenSpec {
ParenSpec()
: paren_id(kNoLabel), src_start(kNoStateId), dest_start(kNoStateId) {}
ParenSpec(Label id, StateId s, StateId d)
: paren_id(id), src_start(s), dest_start(d) {}
Label paren_id; // Id of parenthesis
StateId src_start; // sub-graph 'start' state for paren source.
StateId dest_start; // sub-graph 'start' state for paren dest.
bool operator==(const ParenSpec &x) const {
if (&x == this)
return true;
return x.paren_id == this->paren_id &&
x.src_start == this->src_start &&
x.dest_start == this->dest_start;
}
};
struct SearchData {
SearchData() : distance(Weight::Zero()),
parent(kNoStateId, kNoStateId),
paren_id(kNoLabel),
flags(0) {}
Weight distance; // Distance to this state from PDT 'start' state
SearchState parent; // Parent state in shortest path tree
int16 paren_id; // If parent arc has paren, paren ID, o.w. kNoLabel
uint8 flags; // First byte reserved for PdtShortestPathData use
};
PdtShortestPathData(bool gc)
: state_(kNoStateId, kNoStateId),
paren_(kNoLabel, kNoStateId, kNoStateId),
gc_(gc),
nstates_(0),
ngc_(0),
finished_(false) {}
~PdtShortestPathData() {
VLOG(1) << "opm size: " << paren_map_.size();
VLOG(1) << "# of search states: " << nstates_;
if (gc_)
VLOG(1) << "# of GC'd search states: " << ngc_;
}
void Clear() {
search_map_.clear();
search_multimap_.clear();
paren_map_.clear();
state_ = SearchState(kNoStateId, kNoStateId);
nstates_ = 0;
ngc_ = 0;
}
Weight Distance(SearchState s) const {
SearchData *data = GetSearchData(s);
return data->distance;
}
Weight Distance(const ParenSpec &paren) const {
SearchData *data = GetSearchData(paren);
return data->distance;
}
SearchState Parent(SearchState s) const {
SearchData *data = GetSearchData(s);
return data->parent;
}
SearchState Parent(const ParenSpec &paren) const {
SearchData *data = GetSearchData(paren);
return data->parent;
}
Label ParenId(SearchState s) const {
SearchData *data = GetSearchData(s);
return data->paren_id;
}
uint8 Flags(SearchState s) const {
SearchData *data = GetSearchData(s);
return data->flags;
}
void SetDistance(SearchState s, Weight w) {
SearchData *data = GetSearchData(s);
data->distance = w;
}
void SetDistance(const ParenSpec &paren, Weight w) {
SearchData *data = GetSearchData(paren);
data->distance = w;
}
void SetParent(SearchState s, SearchState p) {
SearchData *data = GetSearchData(s);
data->parent = p;
}
void SetParent(const ParenSpec &paren, SearchState p) {
SearchData *data = GetSearchData(paren);
data->parent = p;
}
void SetParenId(SearchState s, Label p) {
if (p >= 32768)
FSTERROR() << "PdtShortestPathData: Paren ID does not fits in an int16";
SearchData *data = GetSearchData(s);
data->paren_id = p;
}
void SetFlags(SearchState s, uint8 f, uint8 mask) {
SearchData *data = GetSearchData(s);
data->flags &= ~mask;
data->flags |= f & mask;
}
void GC(StateId s);
void Finish() { finished_ = true; }
private:
static const Arc kNoArc;
static const size_t kPrime0;
static const size_t kPrime1;
static const uint8 kInited;
static const uint8 kMarked;
// Hash for search state
struct SearchStateHash {
size_t operator()(const SearchState &s) const {
return s.state + s.start * kPrime0;
}
};
// Hash for paren map
struct ParenHash {
size_t operator()(const ParenSpec &paren) const {
return paren.paren_id + paren.src_start * kPrime0 +
paren.dest_start * kPrime1;
}
};
typedef unordered_map<SearchState, SearchData, SearchStateHash> SearchMap;
typedef unordered_multimap<StateId, StateId> SearchMultimap;
// Hash map from paren spec to open paren data
typedef unordered_map<ParenSpec, SearchData, ParenHash> ParenMap;
SearchData *GetSearchData(SearchState s) const {
if (s == state_)
return state_data_;
if (finished_) {
typename SearchMap::iterator it = search_map_.find(s);
if (it == search_map_.end())
return &null_search_data_;
state_ = s;
return state_data_ = &(it->second);
} else {
state_ = s;
state_data_ = &search_map_[s];
if (!(state_data_->flags & kInited)) {
++nstates_;
if (gc_)
search_multimap_.insert(make_pair(s.start, s.state));
state_data_->flags = kInited;
}
return state_data_;
}
}
SearchData *GetSearchData(ParenSpec paren) const {
if (paren == paren_)
return paren_data_;
if (finished_) {
typename ParenMap::iterator it = paren_map_.find(paren);
if (it == paren_map_.end())
return &null_search_data_;
paren_ = paren;
return state_data_ = &(it->second);
} else {
paren_ = paren;
return paren_data_ = &paren_map_[paren];
}
}
mutable SearchMap search_map_; // Maps from search state to data
mutable SearchMultimap search_multimap_; // Maps from 'start' to subgraph
mutable ParenMap paren_map_; // Maps paren spec to search data
mutable SearchState state_; // Last state accessed
mutable SearchData *state_data_; // Last state data accessed
mutable ParenSpec paren_; // Last paren spec accessed
mutable SearchData *paren_data_; // Last paren data accessed
bool gc_; // Allow GC?
mutable size_t nstates_; // Total number of search states
size_t ngc_; // Number of GC'd search states
mutable SearchData null_search_data_; // Null search data
bool finished_; // Read-only access when true
DISALLOW_COPY_AND_ASSIGN(PdtShortestPathData);
};
// Deletes inaccessible search data from a given 'start' (open paren dest)
// state. Assumes 'final' (close paren source or PDT final) states have
// been flagged 'kFinal'.
template<class Arc>
void PdtShortestPathData<Arc>::GC(StateId start) {
if (!gc_)
return;
vector<StateId> final;
for (typename SearchMultimap::iterator mmit = search_multimap_.find(start);
mmit != search_multimap_.end() && mmit->first == start;
++mmit) {
SearchState s(mmit->second, start);
const SearchData &data = search_map_[s];
if (data.flags & kFinal)
final.push_back(s.state);
}
// Mark phase
for (size_t i = 0; i < final.size(); ++i) {
SearchState s(final[i], start);
while (s.state != kNoLabel) {
SearchData *sdata = &search_map_[s];
if (sdata->flags & kMarked)
break;
sdata->flags |= kMarked;
SearchState p = sdata->parent;
if (p.start != start && p.start != kNoLabel) { // entering sub-subgraph
ParenSpec paren(sdata->paren_id, s.start, p.start);
SearchData *pdata = &paren_map_[paren];
s = pdata->parent;
} else {
s = p;
}
}
}
// Sweep phase
typename SearchMultimap::iterator mmit = search_multimap_.find(start);
while (mmit != search_multimap_.end() && mmit->first == start) {
SearchState s(mmit->second, start);
typename SearchMap::iterator mit = search_map_.find(s);
const SearchData &data = mit->second;
if (!(data.flags & kMarked)) {
search_map_.erase(mit);
++ngc_;
}
search_multimap_.erase(mmit++);
}
}
template<class Arc> const Arc PdtShortestPathData<Arc>::kNoArc
= Arc(kNoLabel, kNoLabel, Weight::Zero(), kNoStateId);
template<class Arc> const size_t PdtShortestPathData<Arc>::kPrime0 = 7853;
template<class Arc> const size_t PdtShortestPathData<Arc>::kPrime1 = 7867;
template<class Arc> const uint8 PdtShortestPathData<Arc>::kInited = 0x01;
template<class Arc> const uint8 PdtShortestPathData<Arc>::kFinal = 0x02;
template<class Arc> const uint8 PdtShortestPathData<Arc>::kMarked = 0x04;
// This computes the single source shortest (balanced) path (SSSP)
// through a weighted PDT that has a bounded stack (i.e. is expandable
// as an FST). It is a generalization of the classic SSSP graph
// algorithm that removes a state s from a queue (defined by a
// user-provided queue type) and relaxes the destination states of
// transitions leaving s. In this PDT version, states that have
// entering open parentheses are treated as source states for a
// sub-graph SSSP problem with the shortest path up to the open
// parenthesis being first saved. When a close parenthesis is then
// encountered any balancing open parenthesis is examined for this
// saved information and multiplied back. In this way, each sub-graph
// is entered only once rather than repeatedly. If every state in the
// input PDT has the property that there is a unique 'start' state for
// it with entering open parentheses, then this algorithm is quite
// straight-forward. In general, this will not be the case, so the
// algorithm (implicitly) creates a new graph where each state is a
// pair of an original state and a possible parenthesis 'start' state
// for that state.
template<class Arc, class Queue>
class PdtShortestPath {
public:
typedef typename Arc::StateId StateId;
typedef typename Arc::Weight Weight;
typedef typename Arc::Label Label;
typedef PdtShortestPathData<Arc> SpData;
typedef typename SpData::SearchState SearchState;
typedef typename SpData::ParenSpec ParenSpec;
typedef typename PdtParenReachable<Arc>::SetIterator StateSetIterator;
typedef typename PdtBalanceData<Arc>::SetIterator CloseSourceIterator;
PdtShortestPath(const Fst<Arc> &ifst,
const vector<pair<Label, Label> > &parens,
const PdtShortestPathOptions<Arc, Queue> &opts)
: kFinal(SpData::kFinal),
ifst_(ifst.Copy()),
parens_(parens),
keep_parens_(opts.keep_parentheses),
start_(ifst.Start()),
sp_data_(opts.path_gc),
error_(false) {
if ((Weight::Properties() & (kPath | kRightSemiring))
!= (kPath | kRightSemiring)) {
FSTERROR() << "SingleShortestPath: Weight needs to have the path"
<< " property and be right distributive: " << Weight::Type();
error_ = true;
}
for (Label i = 0; i < parens.size(); ++i) {
const pair<Label, Label> &p = parens[i];
paren_id_map_[p.first] = i;
paren_id_map_[p.second] = i;
}
};
~PdtShortestPath() {
VLOG(1) << "# of input states: " << CountStates(*ifst_);
VLOG(1) << "# of enqueued: " << nenqueued_;
VLOG(1) << "cpmm size: " << close_paren_multimap_.size();
delete ifst_;
}
void ShortestPath(MutableFst<Arc> *ofst) {
Init(ofst);
GetDistance(start_);
GetPath();
sp_data_.Finish();
if (error_) ofst->SetProperties(kError, kError);
}
const PdtShortestPathData<Arc> &GetShortestPathData() const {
return sp_data_;
}
PdtBalanceData<Arc> *GetBalanceData() { return &balance_data_; }
private:
static const Arc kNoArc;
static const uint8 kEnqueued;
static const uint8 kExpanded;
const uint8 kFinal;
public:
// Hash multimap from close paren label to an paren arc.
typedef unordered_multimap<ParenState<Arc>, Arc,
typename ParenState<Arc>::Hash> CloseParenMultimap;
const CloseParenMultimap &GetCloseParenMultimap() const {
return close_paren_multimap_;
}
private:
void Init(MutableFst<Arc> *ofst);
void GetDistance(StateId start);
void ProcFinal(SearchState s);
void ProcArcs(SearchState s);
void ProcOpenParen(Label paren_id, SearchState s, Arc arc, Weight w);
void ProcCloseParen(Label paren_id, SearchState s, const Arc &arc, Weight w);
void ProcNonParen(SearchState s, const Arc &arc, Weight w);
void Relax(SearchState s, SearchState t, Arc arc, Weight w, Label paren_id);
void Enqueue(SearchState d);
void GetPath();
Arc GetPathArc(SearchState s, SearchState p, Label paren_id, bool open);
Fst<Arc> *ifst_;
MutableFst<Arc> *ofst_;
const vector<pair<Label, Label> > &parens_;
bool keep_parens_;
Queue *state_queue_; // current state queue
StateId start_;
Weight f_distance_;
SearchState f_parent_;
SpData sp_data_;
unordered_map<Label, Label> paren_id_map_;
CloseParenMultimap close_paren_multimap_;
PdtBalanceData<Arc> balance_data_;
ssize_t nenqueued_;
bool error_;
DISALLOW_COPY_AND_ASSIGN(PdtShortestPath);
};
template<class Arc, class Queue>
void PdtShortestPath<Arc, Queue>::Init(MutableFst<Arc> *ofst) {
ofst_ = ofst;
ofst->DeleteStates();
ofst->SetInputSymbols(ifst_->InputSymbols());
ofst->SetOutputSymbols(ifst_->OutputSymbols());
if (ifst_->Start() == kNoStateId)
return;
f_distance_ = Weight::Zero();
f_parent_ = SearchState(kNoStateId, kNoStateId);
sp_data_.Clear();
close_paren_multimap_.clear();
balance_data_.Clear();
nenqueued_ = 0;
// Find open parens per destination state and close parens per source state.
for (StateIterator<Fst<Arc> > siter(*ifst_); !siter.Done(); siter.Next()) {
StateId s = siter.Value();
for (ArcIterator<Fst<Arc> > aiter(*ifst_, s);
!aiter.Done(); aiter.Next()) {
const Arc &arc = aiter.Value();
typename unordered_map<Label, Label>::const_iterator pit
= paren_id_map_.find(arc.ilabel);
if (pit != paren_id_map_.end()) { // Is a paren?
Label paren_id = pit->second;
if (arc.ilabel == parens_[paren_id].first) { // Open paren
balance_data_.OpenInsert(paren_id, arc.nextstate);
} else { // Close paren
ParenState<Arc> paren_state(paren_id, s);
close_paren_multimap_.insert(make_pair(paren_state, arc));
}
}
}
}
}
// Computes the shortest distance stored in a recursive way. Each
// sub-graph (i.e. different paren 'start' state) begins with weight One().
template<class Arc, class Queue>
void PdtShortestPath<Arc, Queue>::GetDistance(StateId start) {
if (start == kNoStateId)
return;
Queue state_queue;
state_queue_ = &state_queue;
SearchState q(start, start);
Enqueue(q);
sp_data_.SetDistance(q, Weight::One());
while (!state_queue_->Empty()) {
StateId state = state_queue_->Head();
state_queue_->Dequeue();
SearchState s(state, start);
sp_data_.SetFlags(s, 0, kEnqueued);
ProcFinal(s);
ProcArcs(s);
sp_data_.SetFlags(s, kExpanded, kExpanded);
}
balance_data_.FinishInsert(start);
sp_data_.GC(start);
}
// Updates best complete path.
template<class Arc, class Queue>
void PdtShortestPath<Arc, Queue>::ProcFinal(SearchState s) {
if (ifst_->Final(s.state) != Weight::Zero() && s.start == start_) {
Weight w = Times(sp_data_.Distance(s),
ifst_->Final(s.state));
if (f_distance_ != Plus(f_distance_, w)) {
if (f_parent_.state != kNoStateId)
sp_data_.SetFlags(f_parent_, 0, kFinal);
sp_data_.SetFlags(s, kFinal, kFinal);
f_distance_ = Plus(f_distance_, w);
f_parent_ = s;
}
}
}
// Processes all arcs leaving the state s.
template<class Arc, class Queue>
void PdtShortestPath<Arc, Queue>::ProcArcs(SearchState s) {
for (ArcIterator< Fst<Arc> > aiter(*ifst_, s.state);
!aiter.Done();
aiter.Next()) {
Arc arc = aiter.Value();
Weight w = Times(sp_data_.Distance(s), arc.weight);
typename unordered_map<Label, Label>::const_iterator pit
= paren_id_map_.find(arc.ilabel);
if (pit != paren_id_map_.end()) { // Is a paren?
Label paren_id = pit->second;
if (arc.ilabel == parens_[paren_id].first)
ProcOpenParen(paren_id, s, arc, w);
else
ProcCloseParen(paren_id, s, arc, w);
} else {
ProcNonParen(s, arc, w);
}
}
}
// Saves the shortest path info for reaching this parenthesis
// and starts a new SSSP in the sub-graph pointed to by the parenthesis
// if previously unvisited. Otherwise it finds any previously encountered
// closing parentheses and relaxes them using the recursively stored
// shortest distance to them.
template<class Arc, class Queue> inline
void PdtShortestPath<Arc, Queue>::ProcOpenParen(
Label paren_id, SearchState s, Arc arc, Weight w) {
SearchState d(arc.nextstate, arc.nextstate);
ParenSpec paren(paren_id, s.start, d.start);
Weight pdist = sp_data_.Distance(paren);
if (pdist != Plus(pdist, w)) {
sp_data_.SetDistance(paren, w);
sp_data_.SetParent(paren, s);
Weight dist = sp_data_.Distance(d);
if (dist == Weight::Zero()) {
Queue *state_queue = state_queue_;
GetDistance(d.start);
state_queue_ = state_queue;
}
for (CloseSourceIterator set_iter =
balance_data_.Find(paren_id, arc.nextstate);
!set_iter.Done(); set_iter.Next()) {
SearchState cpstate(set_iter.Element(), d.start);
ParenState<Arc> paren_state(paren_id, cpstate.state);
for (typename CloseParenMultimap::const_iterator cpit =
close_paren_multimap_.find(paren_state);
cpit != close_paren_multimap_.end() && paren_state == cpit->first;
++cpit) {
const Arc &cparc = cpit->second;
Weight cpw = Times(w, Times(sp_data_.Distance(cpstate),
cparc.weight));
Relax(cpstate, s, cparc, cpw, paren_id);
}
}
}
}
// Saves the correspondence between each closing parenthesis and its
// balancing open parenthesis info. Relaxes any close parenthesis
// destination state that has a balancing previously encountered open
// parenthesis.
template<class Arc, class Queue> inline
void PdtShortestPath<Arc, Queue>::ProcCloseParen(
Label paren_id, SearchState s, const Arc &arc, Weight w) {
ParenState<Arc> paren_state(paren_id, s.start);
if (!(sp_data_.Flags(s) & kExpanded)) {
balance_data_.CloseInsert(paren_id, s.start, s.state);
sp_data_.SetFlags(s, kFinal, kFinal);
}
}
// For non-parentheses, classical relaxation.
template<class Arc, class Queue> inline
void PdtShortestPath<Arc, Queue>::ProcNonParen(
SearchState s, const Arc &arc, Weight w) {
Relax(s, s, arc, w, kNoLabel);
}
// Classical relaxation on the search graph for 'arc' from state 's'.
// State 't' is in the same sub-graph as the nextstate should be (i.e.
// has the same paren 'start'.
template<class Arc, class Queue> inline
void PdtShortestPath<Arc, Queue>::Relax(
SearchState s, SearchState t, Arc arc, Weight w, Label paren_id) {
SearchState d(arc.nextstate, t.start);
Weight dist = sp_data_.Distance(d);
if (dist != Plus(dist, w)) {
sp_data_.SetParent(d, s);
sp_data_.SetParenId(d, paren_id);
sp_data_.SetDistance(d, Plus(dist, w));
Enqueue(d);
}
}
template<class Arc, class Queue> inline
void PdtShortestPath<Arc, Queue>::Enqueue(SearchState s) {
if (!(sp_data_.Flags(s) & kEnqueued)) {
state_queue_->Enqueue(s.state);
sp_data_.SetFlags(s, kEnqueued, kEnqueued);
++nenqueued_;
} else {
state_queue_->Update(s.state);
}
}
// Follows parent pointers to find the shortest path. Uses a stack
// since the shortest distance is stored recursively.
template<class Arc, class Queue>
void PdtShortestPath<Arc, Queue>::GetPath() {
SearchState s = f_parent_, d = SearchState(kNoStateId, kNoStateId);
StateId s_p = kNoStateId, d_p = kNoStateId;
Arc arc(kNoArc);
Label paren_id = kNoLabel;
stack<ParenSpec> paren_stack;
while (s.state != kNoStateId) {
d_p = s_p;
s_p = ofst_->AddState();
if (d.state == kNoStateId) {
ofst_->SetFinal(s_p, ifst_->Final(f_parent_.state));
} else {
if (paren_id != kNoLabel) { // paren?
if (arc.ilabel == parens_[paren_id].first) { // open paren
paren_stack.pop();
} else { // close paren
ParenSpec paren(paren_id, d.start, s.start);
paren_stack.push(paren);
}
if (!keep_parens_)
arc.ilabel = arc.olabel = 0;
}
arc.nextstate = d_p;
ofst_->AddArc(s_p, arc);
}
d = s;
s = sp_data_.Parent(d);
paren_id = sp_data_.ParenId(d);
if (s.state != kNoStateId) {
arc = GetPathArc(s, d, paren_id, false);
} else if (!paren_stack.empty()) {
ParenSpec paren = paren_stack.top();
s = sp_data_.Parent(paren);
paren_id = paren.paren_id;
arc = GetPathArc(s, d, paren_id, true);
}
}
ofst_->SetStart(s_p);
ofst_->SetProperties(
ShortestPathProperties(ofst_->Properties(kFstProperties, false)),
kFstProperties);
}
// Finds transition with least weight between two states with label matching
// paren_id and open/close paren type or a non-paren if kNoLabel.
template<class Arc, class Queue>
Arc PdtShortestPath<Arc, Queue>::GetPathArc(
SearchState s, SearchState d, Label paren_id, bool open_paren) {
Arc path_arc = kNoArc;
for (ArcIterator< Fst<Arc> > aiter(*ifst_, s.state);
!aiter.Done();
aiter.Next()) {
const Arc &arc = aiter.Value();
if (arc.nextstate != d.state)
continue;
Label arc_paren_id = kNoLabel;
typename unordered_map<Label, Label>::const_iterator pit
= paren_id_map_.find(arc.ilabel);
if (pit != paren_id_map_.end()) {
arc_paren_id = pit->second;
bool arc_open_paren = arc.ilabel == parens_[arc_paren_id].first;
if (arc_open_paren != open_paren)
continue;
}
if (arc_paren_id != paren_id)
continue;
if (arc.weight == Plus(arc.weight, path_arc.weight))
path_arc = arc;
}
if (path_arc.nextstate == kNoStateId) {
FSTERROR() << "PdtShortestPath::GetPathArc failed to find arc";
error_ = true;
}
return path_arc;
}
template<class Arc, class Queue>
const Arc PdtShortestPath<Arc, Queue>::kNoArc
= Arc(kNoLabel, kNoLabel, Weight::Zero(), kNoStateId);
template<class Arc, class Queue>
const uint8 PdtShortestPath<Arc, Queue>::kEnqueued = 0x10;
template<class Arc, class Queue>
const uint8 PdtShortestPath<Arc, Queue>::kExpanded = 0x20;
template<class Arc, class Queue>
void ShortestPath(const Fst<Arc> &ifst,
const vector<pair<typename Arc::Label,
typename Arc::Label> > &parens,
MutableFst<Arc> *ofst,
const PdtShortestPathOptions<Arc, Queue> &opts) {
PdtShortestPath<Arc, Queue> psp(ifst, parens, opts);
psp.ShortestPath(ofst);
}
template<class Arc>
void ShortestPath(const Fst<Arc> &ifst,
const vector<pair<typename Arc::Label,
typename Arc::Label> > &parens,
MutableFst<Arc> *ofst) {
typedef FifoQueue<typename Arc::StateId> Queue;
PdtShortestPathOptions<Arc, Queue> opts;
PdtShortestPath<Arc, Queue> psp(ifst, parens, opts);
psp.ShortestPath(ofst);
}
} // namespace fst
#endif // FST_EXTENSIONS_PDT_SHORTEST_PATH_H__