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tagger.h
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tagger.h
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//
// CRF++ -- Yet Another CRF toolkit
//
// $Id: tagger.h 1588 2007-02-12 09:03:39Z taku $;
//
// Copyright(C) 2005-2007 Taku Kudo <[email protected]>
//
#ifndef CRFPP_TAGGER_H_
#define CRFPP_TAGGER_H_
#include <iostream>
#include <vector>
#include <queue>
#include "param.h"
#include "crfpp.h"
#include "scoped_ptr.h"
#include "feature_index.h"
namespace CRFPP {
static inline double toprob(Node *n, double Z) {
return std::exp(n->alpha + n->beta - n->cost - Z);
}
class Allocator;
class ModelImpl : public Model {
public:
ModelImpl() : nbest_(0), vlevel_(0) {}
virtual ~ModelImpl() {}
bool open(int argc, char** argv);
bool open(const char* arg);
bool openFromArray(int argc, char** argv,
const char *buf, size_t size);
bool openFromArray(const char* arg,
const char *buf, size_t size);
Tagger *createTagger() const;
const char* what() { return what_.str(); }
unsigned int nbest() const { return nbest_; }
unsigned int vlevel() const { return vlevel_; }
FeatureIndex *feature_index() const { return feature_index_.get(); }
const char *getTemplate() const;
private:
bool open(const Param ¶m);
bool openFromArray(const Param ¶m,
const char *buf, size_t size);
whatlog what_;
unsigned int nbest_;
unsigned int vlevel_;
scoped_ptr<DecoderFeatureIndex> feature_index_;
};
class TaggerImpl : public Tagger {
public:
explicit TaggerImpl() : mode_(TEST), vlevel_(0), nbest_(0),
ysize_(0), Z_(0), feature_id_(0),
thread_id_(0), feature_index_(0),
allocator_(0) {}
virtual ~TaggerImpl() { close(); }
Allocator *allocator() const {
return allocator_;
}
void set_feature_id(size_t id) { feature_id_ = id; }
size_t feature_id() const { return feature_id_; }
void set_thread_id(unsigned short id) { thread_id_ = id; }
unsigned short thread_id() const { return thread_id_; }
Node *node(size_t i, size_t j) const { return node_[i][j]; }
void set_node(Node *n, size_t i, size_t j) { node_[i][j] = n; }
// for LEARN mode
bool open(FeatureIndex *feature_index, Allocator *allocator);
// for TEST mode, but feature_index is shared.
bool open(FeatureIndex *feature_index,
unsigned int nvest, unsigned velvel);
// for TEST mode
bool open(const Param ¶m);
bool open(const char *argv);
bool open(int argc, char **argv);
bool set_model(const Model &model);
int eval();
double gradient(double *);
double collins(double *);
bool shrink();
bool parse_stream(std::istream *is, std::ostream *os);
bool read(std::istream *is);
void close();
bool add(size_t size, const char **line);
bool add(const char*);
size_t size() const { return x_.size(); }
size_t xsize() const { return feature_index_->xsize(); }
size_t dsize() const { return feature_index_->size(); }
const float *weight_vector() const { return feature_index_->alpha_float(); }
bool empty() const { return x_.empty(); }
size_t ysize() const { return ysize_; }
double cost() const { return cost_; }
double Z() const { return Z_; }
double prob() const { return std::exp(- cost_ - Z_); }
double prob(size_t i, size_t j) const {
return toprob(node_[i][j], Z_);
}
double prob(size_t i) const {
return toprob(node_[i][result_[i]], Z_);
}
void set_penalty(size_t i, size_t j, double penalty);
double penalty(size_t i, size_t j) const;
double alpha(size_t i, size_t j) const { return node_[i][j]->alpha; }
double beta(size_t i, size_t j) const { return node_[i][j]->beta; }
double emission_cost(size_t i, size_t j) const { return node_[i][j]->cost; }
double next_transition_cost(size_t i, size_t j, size_t k) const {
return node_[i][j]->rpath[k]->cost;
}
double prev_transition_cost(size_t i, size_t j, size_t k) const {
return node_[i][j]->lpath[k]->cost;
}
double best_cost(size_t i, size_t j) const {
return node_[i][j]->bestCost;
}
const int *emission_vector(size_t i, size_t j) const {
return const_cast<int *>(node_[i][j]->fvector);
}
const int* next_transition_vector(size_t i, size_t j, size_t k) const {
return node_[i][j]->rpath[k]->fvector;
}
const int* prev_transition_vector(size_t i, size_t j, size_t k) const {
return node_[i][j]->lpath[k]->fvector;
}
size_t answer(size_t i) const { return answer_[i]; }
size_t result(size_t i) const { return result_[i]; }
size_t y(size_t i) const { return result_[i]; }
const char* yname(size_t i) const { return feature_index_->y(i); }
const char* y2(size_t i) const { return yname(result_[i]); }
const char* x(size_t i, size_t j) const { return x_[i][j]; }
const char** x(size_t i) const {
return const_cast<const char **>(&x_[i][0]);
}
const char* toString();
const char* toString(char *, size_t);
const char* parse(const char*);
const char* parse(const char*, size_t);
const char* parse(const char*, size_t, char*, size_t);
bool parse();
bool clear();
bool next();
unsigned int vlevel() const { return vlevel_; }
float cost_factor() const {
return feature_index_ ? feature_index_->cost_factor() : 0.0;
}
size_t nbest() const { return nbest_; }
void set_vlevel(unsigned int vlevel) {
vlevel_ = vlevel;
}
void set_cost_factor(float cost_factor) {
if (cost_factor > 0 && feature_index_) {
feature_index_->set_cost_factor(cost_factor);
}
}
void set_nbest(size_t nbest) {
nbest_ = nbest;
}
const char* what() { return what_.str(); }
private:
void forwardbackward();
void viterbi();
void buildLattice();
bool initNbest();
bool add2(size_t, const char **, bool);
struct QueueElement {
Node *node;
QueueElement *next;
double fx;
double gx;
};
class QueueElementComp {
public:
const bool operator()(QueueElement *q1,
QueueElement *q2)
{ return(q1->fx > q2->fx); }
};
enum { TEST, TEST_SHARED, LEARN };
unsigned int mode_ ;
unsigned int vlevel_;
unsigned int nbest_;
size_t ysize_;
double cost_;
double Z_;
size_t feature_id_;
unsigned short thread_id_;
FeatureIndex *feature_index_;
Allocator *allocator_;
std::vector<std::vector <const char *> > x_;
std::vector<std::vector <Node *> > node_;
std::vector<std::vector<double> > penalty_;
std::vector<unsigned short int> answer_;
std::vector<unsigned short int> result_;
whatlog what_;
string_buffer os_;
scoped_ptr<std::priority_queue <QueueElement*, std::vector <QueueElement *>,
QueueElementComp> > agenda_;
scoped_ptr<FreeList <QueueElement> > nbest_freelist_;
};
}
#endif