/usr/include/hfst/implementations/HfstTransitionGraph.h is in libhfst45-dev 3.10.0~r2798-3.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 3 of the License, or (at your option) any later version.
// See the file COPYING included with this distribution for more
// information.
#ifndef _HFST_TRANSITION_GRAPH_H_
#define _HFST_TRANSITION_GRAPH_H_
/** @file HfstTransitionGraph.h
@brief Class HfstTransitionGraph */
#include <cstdio>
#include <string>
#include <set>
#include <cassert>
#include <iostream>
#include <algorithm>
#include <stack>
#include "../HfstSymbolDefs.h"
#include "../HfstExceptionDefs.h"
#include "../HfstDataTypes.h"
#include "../HarmonizeUnknownAndIdentitySymbols.h"
#include "../HfstFlagDiacritics.h"
#include "../HfstEpsilonHandler.h"
#include "ConvertTransducerFormat.h"
#include "HfstTransition.h"
#include "HfstTropicalTransducerTransitionData.h"
//#include "HfstFastTransitionData.h"
#include "../string-utils.h"
#include "../hfstdll.h"
namespace hfst {
/** @brief A namespace for all code that forms a bridge between
backend libraries and HFST.
Most code in this namespace is not intended to be accessed
by the user of the HFST interface. An exception is HFST's
own transducer class hfst::HfstTransitionGraph and classes that
are needed to use it.
*/
namespace implementations {
/** @brief The number of a state in an HfstTransitionGraph. */
typedef unsigned int HfstState;
typedef std::pair<HfstState, std::vector<std::pair<std::string, std::string> > > HfstReplacement;
typedef std::vector<HfstReplacement> HfstReplacements;
typedef std::map<HfstState, HfstReplacements > HfstReplacementsMap;
typedef std::vector<std::vector<hfst::implementations::HfstBasicTransition> > HfstBasicStates;
/** @brief A simple transition graph format that consists of
states and transitions between those states.
Probably the easiest way to use this template is to choose
the implementations #HfstBasicTransducer
(HfstTransitionGraph<HfstTropicalTransducerTransitionData>)
and #HfstBasicTransition
(HfstTransition<HfstTropicalTransducerTransitionData>).
The class HfstTropicalTransducerTransitionData contains an input string,
an output string and a float weight. HfstBasicTransducer is the
implementation that is used as an example in this documentation.
An example of creating a HfstBasicTransducer [foo:bar baz:baz]
with weight 0.4 from scratch:
\verbatim
// Create an empty transducer
// The transducer has initially one start state (number zero)
// that is not final
HfstBasicTransducer fsm;
// Add two states to the transducer
fsm.add_state(1);
fsm.add_state(2);
// Create a transition [foo:bar] leading to state 1 with weight 0.1 ...
HfstBasicTransition tr(1, "foo", "bar", 0.1);
// ... and add it to state zero
fsm.add_transition(0, tr);
// Add a transition [baz:baz] with weight 0 from state 1 to state 2
fsm.add_transition(1, HfstBasicTransition(2, "baz", "baz", 0.0));
// Set state 2 as final with weight 0.3
fsm.set_final_weight(2, 0.3);
\endverbatim
An example of iterating through a HfstBasicTransducer's states
and transitions when printing it in AT&T format to stderr:
\verbatim
// The first state is always number zero.
unsigned int source_state=0;
// Go through all states
for (HfstBasicTransducer::const_iterator it = fsm.begin();
it != fsm.end(); it++ )
{
// Go through all transitions
for (HfstBasicTransducer::HfstTransitions::const_iterator tr_it
= it->begin(); tr_it != it->end(); tr_it++)
{
std::cerr << source_state << "\t"
<< tr_it->get_target_state() << "\t"
<< tr_it->get_input_symbol() << "\t"
<< tr_it->get_output_symbol() << "\t"
<< tr_it->get_weight() << std::endl;
}
if (fsm.is_final_state(source_state))
{
std::cerr << source_state << "\t"
<< fsm.get_final_weight(source_state) << std::endl;
}
// the next state is numbered source_state + 1
source_state++;
}
\endverbatim
@see #HfstBasicTransducer HfstBasicTransition */
template <class C> class HfstTransitionGraph
{
// --- Datatypes and variables ---
public:
/** @brief Datatype for a symbol in a transition. */
typedef typename C::SymbolType HfstSymbol;
/** @brief Datatype for a symbol pair in a transition. */
typedef std::pair<HfstSymbol, HfstSymbol>
HfstSymbolPair;
/** @brief A set of symbol pairs. */
typedef std::set<HfstSymbolPair> HfstSymbolPairSet;
/** @brief A set of symbol pairs. */
typedef std::set<HfstSymbol> HfstSymbolSet;
/** @brief A vector of symbol pairs. */
typedef std::vector<HfstSymbolPair> HfstSymbolPairVector;
/** @brief Datatype for the alphabet of a graph. */
typedef std::set<HfstSymbol> HfstTransitionGraphAlphabet;
/** @brief Datatype for the states of a transition in a graph. */
typedef std::vector<HfstTransition<C> > HfstTransitions;
/* Datatype for the states of a graph and their transitions.
Each index of the vector is a state and the transitions
on that index are the transitions of that state. */
typedef std::vector<HfstTransitions> HfstStates;
/* States of the graph and their transitions. */
HfstStates state_vector;
protected:
/* The initial state number. */
static const HfstState INITIAL_STATE = 0;
/* Datatype for the final states and their weights in a graph. */
typedef std::map<HfstState,typename C::WeightType> FinalWeightMap;
/* The final states and their weights in the graph. */
FinalWeightMap final_weight_map;
/* The alphabet of the graph. */
HfstTransitionGraphAlphabet alphabet;
/* Used by substitute function. */
typedef unsigned int HfstNumber;
typedef std::vector<HfstNumber> HfstNumberVector;
typedef std::pair<HfstNumber, HfstNumber> HfstNumberPair;
typedef std::map<HfstNumberPair, HfstNumberPair> HfstNumberPairSubstitutions;
protected:
/* @brief An iterator type that points to a state in a graph.
The value pointed by the iterator is of type HfstTransitions. */
typedef typename HfstStates::iterator iterator;
public:
/** @brief A const iterator type that points a state in a graph.
The value pointed by the iterator is of type HfstTransitions. */
typedef typename HfstStates::const_iterator const_iterator;
/** @brief The name of the graph. */
std::string name;
/** @brief The states of the graph. */
std::vector<HfstState> states() const {
std::vector<HfstState> retval(this->get_max_state()+1, 0);
for (unsigned int i=0; i<(this->get_max_state()+1); i++)
retval[i] = i;
return retval;
}
/** @brief The states of the graph and their transitions. */
HfstBasicStates states_and_transitions() const {
return state_vector;
}
// --------------------------------------------------------
// --- Construction, assignment, copying and conversion ---
// --------------------------------------------------------
/** @brief Create a graph with one initial state that has state number
zero and is not a final state, i.e. create an empty graph. */
HFSTDLL HfstTransitionGraph(void) {
initialize_alphabet(alphabet);
HfstTransitions tr;
state_vector.push_back(tr);
}
HFSTDLL HfstTransitionGraph(FILE *file) {
initialize_alphabet(alphabet);
HfstTransitions tr;
state_vector.push_back(tr);
unsigned int linecount=0;
this->assign(read_in_att_format(file, "@0@", linecount));
}
/** @brief The assignment operator. */
HFSTDLL HfstTransitionGraph &operator=(const HfstTransitionGraph &graph)
{
if (this == &graph)
return *this;
state_vector = graph.state_vector;
final_weight_map = graph.final_weight_map;
alphabet = graph.alphabet;
assert(alphabet.count(HfstSymbol()) == 0);
return *this;
}
HFSTDLL HfstTransitionGraph &assign(const HfstTransitionGraph &graph)
{
return this->operator=(graph);
}
/** @brief Create a deep copy of HfstTransitionGraph \a graph. */
HFSTDLL HfstTransitionGraph(const HfstTransitionGraph &graph) {
state_vector = graph.state_vector;
final_weight_map = graph.final_weight_map;
alphabet = graph.alphabet;
assert(alphabet.count(HfstSymbol()) == 0);
}
/** @brief Create an HfstTransitionGraph equivalent to HfstTransducer
\a transducer. FIXME: move to a separate file */
HFSTDLL HfstTransitionGraph(const hfst::HfstTransducer &transducer) {
HfstTransitionGraph<HfstTropicalTransducerTransitionData>
*fsm = ConversionFunctions::
hfst_transducer_to_hfst_basic_transducer(transducer);
state_vector = fsm->state_vector;
final_weight_map = fsm->final_weight_map;
alphabet = fsm->alphabet;
delete fsm;
}
// --------------------------------------------------
// --- Initialization, optimization and debugging ---
// --------------------------------------------------
protected:
/* Add epsilon, unknown and identity symbols to the alphabet
\a alpha. */
void initialize_alphabet(HfstTransitionGraphAlphabet &alpha) {
alpha.insert(C::get_epsilon());
alpha.insert(C::get_unknown());
alpha.insert(C::get_identity());
}
/* Check that all symbols that occur in the transitions of the graph
are also in the alphabet. */
bool check_alphabet()
{
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
if(alphabet.find(data.get_input_symbol())
== alphabet.end()) {
return false;
}
if(alphabet.find(data.get_output_symbol())
== alphabet.end()) {
return false;
}
}
}
return true;
}
public:
/* Print the alphabet of the graph to standard error stream. */
HFSTDLL void print_alphabet() const
{
for (typename HfstTransitionGraphAlphabet::const_iterator it
= alphabet.begin(); it != alphabet.end(); it++)
{
if (it != alphabet.begin())
std::cerr << ", ";
std::cerr << *it;
}
std::cerr << std::endl;
}
protected:
/* Get the number of the \a symbol. */
unsigned int get_symbol_number
(const HfstSymbol &symbol) const {
return C::get_number(symbol);
}
/* For internal optimization: Reserve space for
\a number_of_states states. */
void initialize_state_vector
(unsigned int number_of_states)
{
state_vector.reserve(number_of_states);
}
/* For internal optimization: Reserve space for
\a number_of_transitions transitions for state number
\a state_number. */
void initialize_transition_vector
(unsigned int state_number, unsigned int number_of_transitions)
{
add_state(state_number);
state_vector[state_number].reserve(number_of_transitions);
}
// -----------------------------------
// ---------- The alphabet -----------
// -----------------------------------
public:
/** @brief Explicitly add \a symbol to the alphabet of the graph.
@note Usually the user does not have to take care of the alphabet
of a graph. This function can be useful in some special cases. */
HFSTDLL void add_symbol_to_alphabet(const HfstSymbol &symbol) {
alphabet.insert(symbol);
}
/** @brief Remove symbol \a symbol from the alphabet of the graph.
@note Use with care, removing symbols that occur in the transitions
of the graph can have unexpected results. */
HFSTDLL void remove_symbol_from_alphabet(const HfstSymbol &symbol) {
alphabet.erase(symbol);
}
HFSTDLL void remove_symbols_from_alphabet(const HfstSymbolSet &symbols) {
for (typename HfstSymbolSet::const_iterator it = symbols.begin();
it != symbols.end(); it++)
{
alphabet.erase(*it);
}
}
/** @brief Same as #add_symbol_to_alphabet for each symbol in
\a symbols. */
HFSTDLL void add_symbols_to_alphabet(const HfstSymbolSet &symbols)
{
for (typename HfstSymbolSet::const_iterator it = symbols.begin();
it != symbols.end(); it++)
{
alphabet.insert(*it);
}
}
HFSTDLL void add_symbols_to_alphabet(const HfstSymbolPairSet &symbols)
{
for (typename HfstSymbolPairSet::const_iterator it = symbols.begin();
it != symbols.end(); it++)
{
alphabet.insert(it->first);
alphabet.insert(it->second);
}
}
/* Remove all symbols that are given in \a symbols but do not occur
in transitions of the graph from its alphabet. */
HFSTDLL void prune_alphabet_after_substitution(const std::set<unsigned int> &symbols)
{
if (symbols.size() == 0)
return;
std::vector<bool> symbols_found;
symbols_found.resize
(C::get_max_number()+1, false);
// Go through all transitions
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
const C & data = tr_it->get_transition_data();
symbols_found.at(data.get_input_number()) = true;
symbols_found.at(data.get_output_number()) = true;
}
}
// Remove symbols in \a symbols from the alphabet if they did not
// occur in any transitions
for (std::set<unsigned int>::const_iterator it = symbols.begin();
it != symbols.end(); it++)
{
if (! symbols_found.at(*it))
alphabet.erase(C::get_symbol(*it));
}
}
HFSTDLL HfstTransitionGraphAlphabet symbols_used()
{
HfstTransitionGraphAlphabet retval;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
retval.insert(data.get_input_symbol());
retval.insert(data.get_output_symbol());
}
}
return retval;
}
/** @brief Remove all symbols that do not occur in transitions of
the graph from its alphabet.
@param force Whether unused symbols are removed even if
unknown or identity symbols occur in transitions.
Epsilon, unknown and identity \link hfst::String symbols\endlink
are always included in the alphabet. */
HFSTDLL void prune_alphabet(bool force=true) {
// Which symbols occur in the graph
HfstTransitionGraphAlphabet symbols_found = symbols_used();
// Whether unknown or identity symbols are used
bool unknowns_or_identities_used =
( (symbols_found.find("@_UNKNOWN_SYMBOL_@") != symbols_found.end()) ||
(symbols_found.find("@_IDENTITY_SYMBOL_@") != symbols_found.end()) );
// We cannot prune the transducer because unknowns or identities
// are used in its transitions.
if (!force && unknowns_or_identities_used)
return;
// Special symbols are always known
symbols_found.insert("@_EPSILON_SYMBOL_@");
symbols_found.insert("@_UNKNOWN_SYMBOL_@");
symbols_found.insert("@_IDENTITY_SYMBOL_@");
// Which symbols in the graph's alphabet did not occur in
// the graph
HfstTransitionGraphAlphabet symbols_not_found;
for (typename HfstTransitionGraphAlphabet::iterator it
= alphabet.begin();
it != alphabet.end(); it++)
{
if (symbols_found.find(*it) == symbols_found.end())
symbols_not_found.insert(*it);
}
// Remove the symbols that did not occur in the graph
// from its alphabet
for (typename HfstTransitionGraphAlphabet::iterator it
= symbols_not_found.begin();
it != symbols_not_found.end(); it++)
{
alphabet.erase(*it);
}
}
/** @brief Get the set of HfstSymbols in the alphabet
of the graph.
The HfstSymbols do not necessarily occur in any transitions
of the graph. Epsilon, unknown and identity \link
hfst::String symbols\endlink are always included in the alphabet. */
HFSTDLL const HfstTransitionGraphAlphabet &get_alphabet() const {
return alphabet;
}
HFSTDLL StringPairSet get_transition_pairs() const {
StringPairSet retval;
for (const_iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::const_iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
retval.insert(StringPair(data.get_input_symbol(),
data.get_output_symbol()));
}
}
return retval;
}
// ----------------------------------------------------------------
// --- Adding states and transitions and iterating through them ---
// ----------------------------------------------------------------
/** @brief Add a new state to this graph and return its number.
@return The next (smallest) free state number. */
HFSTDLL HfstState add_state(void) {
HfstTransitions tr;
state_vector.push_back(tr);
return state_vector.size()-1;
}
/** @brief Add a state \a s to this graph.
If the state already exists, it is not added again.
All states with state number smaller than \a s are also
added to the graph if they did not exist before.
@return \a s*/
HFSTDLL HfstState add_state(HfstState s) {
while(state_vector.size() <= s) {
HfstTransitions tr;
state_vector.push_back(tr);
}
return s;
}
/** @brief Get the biggest state number in use. */
HFSTDLL HfstState get_max_state() const {
return state_vector.size()-1;
}
/** @brief Add a transition \a transition to state \a s.
If state \a s does not exist, it is created. */
HFSTDLL void add_transition(HfstState s, const HfstTransition<C> & transition,
bool add_symbols_to_alphabet=true) {
C data = transition.get_transition_data();
add_state(s);
add_state(transition.get_target_state());
if (add_symbols_to_alphabet) {
alphabet.insert(data.get_input_symbol());
alphabet.insert(data.get_output_symbol());
}
state_vector[s].push_back(transition);
}
/** @brief Remove transition \a transition from state \a s.
\a remove_symbols_from_alphabet defines whether
symbols in \a transition are removed from the alphabet
if they are no longer used in the graph.
If \a state or \a transition does not exist, nothing is done. */
HFSTDLL void remove_transition(HfstState s, const HfstTransition<C> & transition,
bool remove_symbols_from_alphabet=false)
{
if (! (state_vector.size() > s))
{
return;
}
HfstTransitions & transitions = state_vector[s];
// iterators to transitions to be removed
// transitions must be removed in reverse order so that iterators
// are not invalidated
std::stack<typename HfstTransitions::iterator> elements_to_remove;
// find the transitions to be removed
for (typename HfstTransitions::iterator it = transitions.begin();
it != transitions.end(); it++)
{
// weight is ignored
if (it->get_input_symbol() == transition.get_input_symbol() &&
it->get_output_symbol() == transition.get_output_symbol() &&
it->get_target_state() == transition.get_target_state())
{
// schedule transition to be removed
elements_to_remove.push(it);
}
}
// remove the transitions in reverse order
while (!elements_to_remove.empty())
{
state_vector[s].erase(elements_to_remove.top());
elements_to_remove.pop();
}
if (remove_symbols_from_alphabet)
{
HfstTransitionGraphAlphabet alpha = this->symbols_used();
if (alpha.find(transition.get_input_symbol()) == alpha.end())
this->remove_symbol_from_alphabet(transition.get_input_symbol());
if (alpha.find(transition.get_output_symbol()) == alpha.end())
this->remove_symbol_from_alphabet(transition.get_output_symbol());
}
}
/** @brief Whether state \a s is final.
FIXME: return positive infinity instead if not final. */
HFSTDLL bool is_final_state(HfstState s) const {
return (final_weight_map.find(s) != final_weight_map.end());
}
/** Get the final weight of state \a s in this graph. */
HFSTDLL typename C::WeightType get_final_weight(HfstState s) const {
if (s > this->get_max_state())
HFST_THROW(StateIndexOutOfBoundsException);
if (final_weight_map.find(s) != final_weight_map.end())
return final_weight_map.find(s)->second;
HFST_THROW(StateIsNotFinalException);
}
/** @brief Set the final weight of state \a s in this graph
to \a weight.
If the state does not exist, it is created. */
HFSTDLL void set_final_weight(HfstState s,
const typename C::WeightType & weight) {
add_state(s);
final_weight_map[s] = weight;
}
/** @brief Sort the arcs of this transducer according to input and
output symbols. */
HFSTDLL HfstTransitionGraph &sort_arcs(void)
{
for (typename HfstStates::iterator it = state_vector.begin();
it != state_vector.end();
++it)
{
HfstTransitions &transitions = *it;
std::sort<typename HfstTransitions::iterator>
(transitions.begin(),transitions.end());
}
return *this;
}
/** @brief Get an iterator to the beginning of the states in
the graph.
For an example, see #HfstTransitionGraph */
HFSTDLL iterator begin() { return state_vector.begin(); }
/** @brief Get a const iterator to the beginning of
states in the graph. */
HFSTDLL const_iterator begin() const { return state_vector.begin(); }
/** @brief Get an iterator to the end of states (last state + 1)
in the graph. */
HFSTDLL iterator end() { return state_vector.end(); }
/** @brief Get a const iterator to the end of states (last state + 1)
in the graph. */
HFSTDLL const_iterator end() const { return state_vector.end(); }
/** @brief Get the set of transitions of state \a s in this graph.
If the state does not exist, a @a StateIndexOutOfBoundsException
is thrown.
*/
HFSTDLL const HfstTransitions & operator[](HfstState s) const
{
if (s >= state_vector.size()) {
HFST_THROW(StateIndexOutOfBoundsException); }
return state_vector[s];
}
/** @brief Alternative name for operator[].
Python interface uses this function as '[]' is not a legal name.
@see operator[]
*/
HFSTDLL const HfstTransitions & transitions(HfstState s) const
{
return this->operator[](s);
}
/** @brief Get mutable transitions.
*/
HFSTDLL HfstTransitions & transitions(HfstState s)
{
if (s >= state_vector.size()) {
HFST_THROW(StateIndexOutOfBoundsException); }
return state_vector[s];
}
// --------------------------------------------------
// ----- Reading and writing in AT&T format -----
// --------------------------------------------------
protected:
/* Change state numbers s1 to s2 and vice versa. */
void swap_state_numbers(HfstState s1, HfstState s2) {
HfstTransitions s1_copy = state_vector[s1];
state_vector[s1] = state_vector[s2];
state_vector[s2] = s1_copy;
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// Go through all transitions
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
HfstState new_target=tr_it.get_target_state();
if (tr_it.get_target_state() == s1)
new_target = s2;
if (tr_it.get_target_state() == s2)
new_target = s1;
if (new_target != tr_it.get_target_state())
{
HfstTransition<C> tr
(new_target,
tr_it.get_input_symbol(),
tr_it.get_output_symbol(),
tr_it.get_weight());
it->operator[](i) = tr;
}
} // all transitions gone through
} // ----- all states gone through -----
// Swap final states, if needed
typename FinalWeightMap::iterator s1_it = final_weight_map.find(s1);
typename FinalWeightMap::iterator s2_it = final_weight_map.find(s2);
typename FinalWeightMap::iterator end_it = final_weight_map.end();
if (s1_it != end_it && s2_it != end_it) {
typename C::WeightType s1_weight = s1_it->second;
final_weight_map[s1] = s2_it->second;
final_weight_map[s2] = s1_weight;
}
if (s1_it != end_it) {
typename C::WeightType w = s1_it->second;
final_weight_map.erase(s1);
final_weight_map[s2] = w;
}
if (s2_it != end_it) {
typename C::WeightType w = s2_it->second;
final_weight_map.erase(s2);
final_weight_map[s1] = w;
}
return;
}
static void write_weight(FILE * file, float weight)
{
//if (weight == 0) // avoid unnecessary 0.000000's
// fprintf(file, "%i", 0);
//else
fprintf(file, "%f", weight);
}
static void write_weight(std::ostream & os, float weight)
{
//if (weight == 0) // avoid unnecessary 0.000000's
// os << 0;
//else
os << weight;
}
static void xfstize(std::string & symbol)
{
std::string escaped_symbol;
for (size_t pos = 0; pos < symbol.size(); pos++)
{
if (symbol[pos] == '%')
escaped_symbol.append("\"%\"");
else if (symbol[pos] == '"')
escaped_symbol.append("%\"");
else if (symbol[pos] == '?')
escaped_symbol.append("\"?\"");
else
escaped_symbol.append(1, symbol[pos]);
}
symbol = escaped_symbol;
}
static void xfstize_symbol(std::string & symbol)
{
xfstize(symbol);
replace_all(symbol, "@_EPSILON_SYMBOL_@", "0");
replace_all(symbol, "@_UNKNOWN_SYMBOL_@", "?");
replace_all(symbol, "@_IDENTITY_SYMBOL_@", "?");
replace_all(symbol, "\t", "@_TAB_@");
}
void print_xfst_state(std::ostream & os, HfstState state)
{
if (state == INITIAL_STATE) { os << "S"; }
if (is_final_state(state)) { os << "f"; }
os << "s" << state;
}
void print_xfst_state(FILE * file, HfstState state)
{
if (state == INITIAL_STATE) { fprintf(file, "S"); }
if (is_final_state(state)) { fprintf(file, "f"); }
fprintf(file, "s%i", state);
}
void print_xfst_arc(std::ostream & os, C data)
{
// replace all spaces, epsilons and tabs
if (data.get_input_symbol() !=
data.get_output_symbol())
{
os << "<";
}
std::string s = data.get_input_symbol();
xfstize_symbol(s);
os << s;
if (data.get_input_symbol() !=
data.get_output_symbol() ||
data.get_output_symbol() == "@_UNKNOWN_SYMBOL_@")
{
s = data.get_output_symbol();
xfstize_symbol(s);
os << ":" << s;
}
if (data.get_input_symbol() !=
data.get_output_symbol())
{
os << ">";
}
}
void print_xfst_arc(FILE * file, C data)
{
if (data.get_input_symbol() !=
data.get_output_symbol())
{
fprintf(file, "<");
}
// replace all spaces, epsilons and tabs
std::string s = data.get_input_symbol();
xfstize_symbol(s);
fprintf(file, "%s", s.c_str());
if (data.get_input_symbol() !=
data.get_output_symbol() ||
data.get_output_symbol() == "@_UNKNOWN_SYMBOL_@")
{
s = data.get_output_symbol();
xfstize_symbol(s);
fprintf(file, ":%s", s.c_str());
}
if (data.get_input_symbol() !=
data.get_output_symbol())
{
fprintf(file, ">");
}
}
public:
/** @brief Write the graph in xfst text format to ostream \a os.
\a write_weights defines whether weights are printed (todo). */
HFSTDLL void write_in_xfst_format(std::ostream &os, bool write_weights=true)
{
(void)write_weights; // todo
unsigned int source_state=0;
for (iterator it = begin(); it != end(); it++)
{
print_xfst_state(os, source_state);
os << ":\t";
if (it->begin() == it->end())
{
os << "(no arcs)";
}
else
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
if (tr_it != it->begin())
{
os << ", ";
}
C data = tr_it->get_transition_data();
print_xfst_arc(os, data);
os << " -> ";
print_xfst_state(os, tr_it->get_target_state());
}
}
os << "." << std::endl;
source_state++;
}
}
// note: unknown and identity are both '?'
HFSTDLL static std::string prologize_symbol(const std::string & symbol)
{
if (symbol == "0")
return "%0";
if (symbol == "?")
return "%?";
if (symbol == "@_EPSILON_SYMBOL_@")
return "0";
if (symbol == "@_UNKNOWN_SYMBOL_@")
return "?";
if(symbol == "@_IDENTITY_SYMBOL_@")
return "?";
// prepend a backslash to a double quote and to a backslash
std::string retval(symbol);
replace_all(retval, "\\", "\\\\");
replace_all(retval, "\"", "\\\"");
return retval;
}
// caveat: '?' is always unknown
HFSTDLL static std::string deprologize_symbol(const std::string & symbol)
{
if (symbol == "%0")
return "0";
if (symbol == "%?")
return "?";
if (symbol == "0")
return "@_EPSILON_SYMBOL_@";
if (symbol == "?")
return "@_UNKNOWN_SYMBOL_@";
// remove the escaping backslash in front of a double quote and
// a double quote
std::string retval(symbol);
replace_all(retval, "\\\"", "\"");
replace_all(retval, "\\\\", "\\");
return retval;
}
HFSTDLL static void print_prolog_arc_symbols(FILE * file, C data)
{
std::string symbol = prologize_symbol(data.get_input_symbol());
fprintf(file, "\"%s\"", symbol.c_str());
if (data.get_input_symbol() !=
data.get_output_symbol() ||
data.get_input_symbol() == "@_UNKNOWN_SYMBOL_@")
{
symbol = prologize_symbol(data.get_output_symbol());
fprintf(file, ":\"%s\"", symbol.c_str());
}
}
HFSTDLL static void print_prolog_arc_symbols(std::ostream & os, C data)
{
std::string symbol = prologize_symbol(data.get_input_symbol());
os << "\"" << symbol << "\"";
if (data.get_input_symbol() !=
data.get_output_symbol() ||
data.get_input_symbol() == "@_UNKNOWN_SYMBOL_@")
{
symbol = prologize_symbol(data.get_output_symbol());
os << ":\"" << symbol << "\"";
}
}
/** @brief Write the graph in prolog format to FILE \a file.
\a write_weights defines whether weights are printed (todo). */
HFSTDLL void write_in_prolog_format(FILE * file, const std::string & name,
bool write_weights=true)
{
unsigned int source_state=0;
const char * identifier = name.c_str();
// Print the name.
if (name.find(",") != std::string::npos)
{
std::string msg("no commas allowed in the name of prolog networks");
HFST_THROW_MESSAGE(HfstException, msg);
}
fprintf(file, "network(%s).\n", identifier);
// Print symbols that are in the alphabet but not used in arcs.
HfstTransitionGraphAlphabet symbols_used_ = symbols_used();
initialize_alphabet(symbols_used_); // exclude special symbols
for (typename HfstTransitionGraphAlphabet::const_iterator it
= alphabet.begin(); it != alphabet.end(); it++)
{
if (symbols_used_.find(*it) == symbols_used_.end())
{
fprintf(file, "symbol(%s, \"%s\").\n", identifier, prologize_symbol(it->c_str()).c_str());
}
}
// Print arcs.
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
fprintf(file, "arc(%s, %i, %i, ",
identifier, source_state, tr_it->get_target_state());
C data = tr_it->get_transition_data();
print_prolog_arc_symbols(file, data);
if (write_weights) {
fprintf(file, ", ");
write_weight(file, data.get_weight());
}
fprintf(file, ").\n");
}
source_state++;
}
// Print final states.
for (typename FinalWeightMap::const_iterator it
= this->final_weight_map.begin();
it != this->final_weight_map.end(); it++)
{
fprintf(file, "final(%s, %i", identifier, it->first);
if (write_weights)
{
fprintf(file, ", ");
write_weight(file, it->second);
}
fprintf(file, ").\n");
}
}
/** @brief Write the graph in prolog format to ostream \a os.
\a write_weights defines whether weights are printed (todo). */
HFSTDLL void write_in_prolog_format(std::ostream & os, const std::string & name,
bool write_weights=true)
{
unsigned int source_state=0;
// Print the name.
if (name.find(",") != std::string::npos)
{
std::string msg("no commas allowed in the name of prolog networks");
HFST_THROW_MESSAGE(HfstException, msg);
}
os << "network(" << name << ")." << std::endl;
// Print symbols that are in the alphabet but not used in arcs.
HfstTransitionGraphAlphabet symbols_used_ = symbols_used();
initialize_alphabet(symbols_used_); // exclude special symbols
for (typename HfstTransitionGraphAlphabet::const_iterator it
= alphabet.begin(); it != alphabet.end(); it++)
{
if (symbols_used_.find(*it) == symbols_used_.end())
{
os << "symbol(" << name << ", \"" << prologize_symbol(*it) << "\")." << std::endl;
}
}
// Print arcs.
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
os << "arc(" << name << ", " << source_state << ", " << tr_it->get_target_state() << ", ";
C data = tr_it->get_transition_data();
print_prolog_arc_symbols(os, data);
if (write_weights) {
os << ", ";
write_weight(os, data.get_weight());
}
os << ")." << std::endl;
}
source_state++;
}
// Print final states.
for (typename FinalWeightMap::const_iterator it
= this->final_weight_map.begin();
it != this->final_weight_map.end(); it++)
{
os << "final(" << name << ", " << it->first;
if (write_weights) {
os << ", ";
write_weight(os, it->second);
}
os << ")." << std::endl;
}
}
// If \a str is of format ".+", change it to .+ and return true.
// Else, return false.
HFSTDLL static bool strip_quotes_from_both_sides(std::string & str)
{
if (str.size() < 3)
return false;
if (str[0] != '"' || str[str.length()-1] != '"')
return false;
str.erase(0, 1);
str.erase(str.length()-1, 1);
return true;
}
// If \a str is of format .+)\.", change it to .+ and return true.
// Else, return false.
HFSTDLL static bool strip_ending_parenthesis_and_comma(std::string & str)
{
if (str.size() < 3)
return false;
if (str[str.length()-2] != ')' || str[str.length()-1] != '.')
return false;
str.erase(str.length()-2);
return true;
}
HFSTDLL static bool parse_prolog_network_line(const std::string & line, std::string & name)
{
// 'network(NAME).'
char namearr[100];
int n = sscanf(line.c_str(), "network(%s", namearr);
if (n != 1)
return false;
std::string namestr(namearr);
// strip the ending ")." from namestr
if (!strip_ending_parenthesis_and_comma(namestr))
return false;
name = namestr;
return true;
}
// Get positions of \a c in \a str. If \a esc is precedes
// \a c, \a c is not included.
HFSTDLL static std::vector<unsigned int> get_positions_of_unescaped_char
(const std::string & str, char c, char esc)
{
std::vector<unsigned int> retval;
for (size_t i=0; i < str.length(); i++)
{
if (str[i] == c)
{
if (i == 0)
retval.push_back(i);
else if (str[i-1] == esc)
; // skip escaped chars
else
retval.push_back(i);
}
}
return retval;
}
// Extract input and output symbols, if possible, from prolog arc
// \a str and store them to \a isymbol and \a osymbol.
// Return whether symbols were successfully extracted.
// \a str must be of format "foo":"bar" or "foo"
HFSTDLL static bool get_prolog_arc_symbols
(const std::string & str, std::string & isymbol, std::string & osymbol)
{
// find positions of non-escaped double quotes (todo: double double-quote?)
std::vector<unsigned int> quote_positions
= get_positions_of_unescaped_char(str, '"', '\\');
// "foo"
if (quote_positions.size() == 2)
{
if (quote_positions[0] != 0 ||
quote_positions[1] != str.length()-1)
return false; // extra characters outside quotes
}
// "foo":"bar"
else if (quote_positions.size() == 4)
{
if (quote_positions[0] != 0 ||
quote_positions[3] != str.length()-1)
{
return false; // extra characters outside quotes
}
if (quote_positions[2] - quote_positions[1] != 2)
{
return false; // missing colon between inner quotes
}
if (str[quote_positions[1] + 1] != ':')
{
return false; // else than colon between inner quotes
}
}
// not valid prolog arc
else
{
return false;
}
// "foo"
if (quote_positions.size() == 2)
{
// "foo" -> foo
std::string symbol(str, quote_positions[0]+1, quote_positions[1]-quote_positions[0]-1);
isymbol = deprologize_symbol(symbol);
if (isymbol == "@_UNKNOWN_SYMBOL_@") // single unknown -> identity
isymbol = "@_IDENTITY_SYMBOL_@";
osymbol = isymbol;
}
// "foo":"bar"
else
{
// "foo" -> foo, "bar" -> bar
std::string insymbol(str, quote_positions[0]+1, quote_positions[1]-quote_positions[0]-1);
std::string outsymbol(str, quote_positions[2]+1, quote_positions[3]-quote_positions[2]-1);
isymbol = deprologize_symbol(insymbol);
osymbol = deprologize_symbol(outsymbol);
}
return true;
}
HFSTDLL static bool extract_weight(std::string & symbol, float & weight)
{
size_t last_double_quote = symbol.find_last_of('"');
size_t last_space = symbol.find_last_of(' ');
// at least two double quotes should be found
if (last_double_quote == std::string::npos)
{ return false; }
if (last_space == std::string::npos) {
; // no weight
}
else if (last_double_quote > last_space) {
; // no weight, last space is part of a symbol
}
else if (last_double_quote + 2 == last_space && last_space < symbol.size()-1) // + 2 because of the comma
{
std::istringstream buffer(symbol.substr(last_space+1));
buffer >> weight;
if (buffer.fail()) // a float could not be read
{ return false; }
symbol.resize(last_space-1); // get rid of the comma and weight
}
else {
return false; // not valid symbol and weight
}
return true;
}
HFSTDLL static bool parse_prolog_arc_line(const std::string & line, HfstTransitionGraph & graph)
{
// symbolstr can also contain the weight
char namestr[100]; char sourcestr[100];
char targetstr[100]; char symbolstr[100];
int n = sscanf(line.c_str(), "arc(%[^,], %[^,], %[^,], %[^\t\n]",
namestr, sourcestr, targetstr, symbolstr);
std::string symbol(symbolstr);
// strip the ending ")." from symbolstr
if (!strip_ending_parenthesis_and_comma(symbol))
{ return false; }
if (n != 4)
{ return false; }
if (std::string(namestr) != graph.name)
{ return false; }
unsigned int source = atoi(sourcestr);
unsigned int target = atoi(targetstr);
// handle the weight that might be included in symbol string
float weight = 0;
if (! extract_weight(symbol, weight))
{ return false; }
std::string isymbol = "";
std::string osymbol = "";
if (!get_prolog_arc_symbols(symbol, isymbol, osymbol))
return false;
graph.add_transition(source, HfstTransition<C>(target, isymbol, osymbol, weight));
return true;
}
HFSTDLL static bool parse_prolog_final_line(const std::string & line, HfstTransitionGraph & graph)
{
// 'final(NAME, number).' or 'final(NAME, number, weight).'
char namestr[100];
char finalstr[100];
char weightstr[100];
float weight = 0;
unsigned int number_of_commas = 0;
size_t pos = line.find(',');
while (pos != std::string::npos)
{
number_of_commas++;
pos = line.find(',', pos+1);
}
if (number_of_commas == 1)
{
int n = sscanf(line.c_str(), "final(%[^,], %[^)]).", namestr, finalstr);
if (n != 2)
{ return false; }
}
else if (number_of_commas == 2)
{
int n = sscanf(line.c_str(), "final(%[^,], %[^,], %[^)]).", namestr, finalstr, weightstr);
if (n != 3)
{ return false; }
std::istringstream buffer(weightstr);
buffer >> weight;
if (buffer.fail()) // a float could not be read
{ return false; }
}
else
{
return false;
}
if (std::string(namestr) != graph.name)
return false;
graph.set_final_weight(atoi(finalstr), weight);
return true;
}
HFSTDLL static bool parse_prolog_symbol_line(const std::string & line, HfstTransitionGraph & graph)
{
// 'symbol(NAME, "foo").'
char namearr[100];
char symbolarr[100];
int n = sscanf(line.c_str(), "symbol(%[^,], %s", namearr, symbolarr);
if (n != 2)
return false;
std::string namestr(namearr);
std::string symbolstr(symbolarr);
if (namestr != graph.name)
return false;
if (! strip_ending_parenthesis_and_comma(symbolstr))
return false;
if (! strip_quotes_from_both_sides(symbolstr))
return false;
graph.add_symbol_to_alphabet(deprologize_symbol(symbolstr));
return true;
}
// Erase newlines from the end of \a str and return \a str.
HFSTDLL static std::string strip_newlines(std::string & str)
{
for (signed int i=(signed int)str.length()-1; i >= 0; --i)
{
if (str[i] == '\n' || str[i] == '\r')
str.erase(i, 1);
else
break;
}
return str;
}
// Try to get a line from \a is (if \a file == NULL)
// or from \a file. If successfull, strip the line from newlines,
// increment \a linecount by one and return the line.
// Else, throw an EndOfStreamException.
HFSTDLL static std::string get_stripped_line
(std::istream & is, FILE * file, unsigned int & linecount)
{
char line [255];
if (file == NULL) { /* we use streams */
if (! is.getline(line,255).eof())
HFST_THROW(EndOfStreamException);
}
else { /* we use FILEs */
if (NULL == fgets(line, 255, file))
HFST_THROW(EndOfStreamException);
}
linecount++;
std::string linestr(line);
return strip_newlines(linestr);
}
/* Create an HfstTransitionGraph as defined in prolog format
in istream \a is or FILE \a file.
The functions is called by functions
read_in_prolog_format(istream&) and
read_in_prolog_format(FILE*).
If \a file is NULL, it is ignored and \a is is used.
If \a file is not NULL, it is used and \a is is ignored. */
HFSTDLL static HfstTransitionGraph read_in_prolog_format
(std::istream &is, FILE *file, unsigned int & linecount)
{
HfstTransitionGraph retval;
std::string linestr;
while(true)
{
try
{
linestr = get_stripped_line(is, file, linecount);
}
catch (const EndOfStreamException & e)
{
HFST_THROW(NotValidPrologFormatException);
}
if (linestr.length() != 0 && linestr[0] == '#')
{
continue; // comment line
}
else
{
break; // first non-comment line
}
}
if (! parse_prolog_network_line(linestr, retval.name))
{
std::string message("first line not valid prolog: ");
message.append(linestr);
HFST_THROW_MESSAGE(NotValidPrologFormatException, message);
}
while(true)
{
try
{
linestr = get_stripped_line(is, file, linecount);
if (linestr == "") // prolog separator
{
return retval;
}
}
catch (const EndOfStreamException & e)
{
return retval;
}
if (! (parse_prolog_arc_line(linestr, retval) ||
parse_prolog_final_line(linestr, retval) ||
parse_prolog_symbol_line(linestr, retval)) )
{
std::string message("line not valid prolog: ");
message.append(linestr);
HFST_THROW_MESSAGE(NotValidPrologFormatException, message);
}
}
HFST_THROW(NotValidPrologFormatException); // this should not happen
}
HFSTDLL static HfstTransitionGraph read_in_prolog_format
(std::istream &is,
unsigned int & linecount)
{
return read_in_prolog_format
(is, NULL /* a dummy variable */,
linecount);
}
HFSTDLL static HfstTransitionGraph read_in_prolog_format
(FILE *file,
unsigned int & linecount)
{
return read_in_prolog_format
(std::cin /* a dummy variable */,
file, linecount);
}
/** @brief Write the graph in xfst text format to FILE \a file.
\a write_weights defines whether weights are printed (todo). */
HFSTDLL void write_in_xfst_format(FILE * file, bool write_weights=true)
{
(void)write_weights;
unsigned int source_state=0;
for (iterator it = begin(); it != end(); it++)
{
print_xfst_state(file, source_state);
fprintf(file, ":\t");
if (it->begin() == it->end())
{
fprintf(file, "(no arcs)");
}
else
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
if (tr_it != it->begin())
{
fprintf(file, ", ");
}
C data = tr_it->get_transition_data();
print_xfst_arc(file, data);
fprintf(file, " -> ");
print_xfst_state(file, tr_it->get_target_state());
}
}
fprintf(file, ".\n");
source_state++;
}
}
/** @brief Write the graph in AT&T format to ostream \a os.
\a write_weights defines whether weights are printed. */
HFSTDLL void write_in_att_format(std::ostream &os, bool write_weights=true)
{
unsigned int source_state=0;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
std::string isymbol = data.get_input_symbol();
replace_all(isymbol, " ", "@_SPACE_@");
replace_all(isymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(isymbol, "\t", "@_TAB_@");
std::string osymbol = data.get_output_symbol();
replace_all(osymbol, " ", "@_SPACE_@");
replace_all(osymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(osymbol, "\t", "@_TAB_@");
os << source_state << "\t"
<< tr_it->get_target_state() << "\t"
<< isymbol << "\t"
<< osymbol;
if (write_weights) {
os << "\t";
write_weight(os, data.get_weight());
}
os << "\n";
}
if (is_final_state(source_state))
{
os << source_state;
if (write_weights) {
os << "\t";
write_weight(os, get_final_weight(source_state));
}
os << "\n";
}
source_state++;
}
}
/** @brief Write the graph in AT&T format to FILE \a file.
\a write_weights defines whether weights are printed. */
HFSTDLL void write_in_att_format(FILE *file, bool write_weights=true)
{
unsigned int source_state=0;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
std::string isymbol = data.get_input_symbol();
replace_all(isymbol, " ", "@_SPACE_@");
replace_all(isymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(isymbol, "\t", "@_TAB_@");
std::string osymbol = data.get_output_symbol();
replace_all(osymbol, " ", "@_SPACE_@");
replace_all(osymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(osymbol, "\t", "@_TAB_@");
fprintf(file, "%i\t%i\t%s\t%s",
source_state,
tr_it->get_target_state(),
isymbol.c_str(),
osymbol.c_str());
if (write_weights) {
fprintf(file, "\t");
write_weight(file, data.get_weight());
}
fprintf(file, "\n");
}
if (is_final_state(source_state))
{
fprintf(file, "%i", source_state);
if (write_weights) {
fprintf(file, "\t");
write_weight(file, get_final_weight(source_state));
}
fprintf(file, "\n");
}
source_state++;
}
}
HFSTDLL void write_in_att_format(char * ptr, bool write_weights=true)
{
unsigned int source_state=0;
size_t cwt = 0; // characters written in total
size_t cw = 0; // characters written in latest call to sprintf
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
std::string isymbol = data.get_input_symbol();
replace_all(isymbol, " ", "@_SPACE_@");
replace_all(isymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(isymbol, "\t", "@_TAB_@");
std::string osymbol = data.get_output_symbol();
replace_all(osymbol, " ", "@_SPACE_@");
replace_all(osymbol, "@_EPSILON_SYMBOL_@", "@0@");
replace_all(osymbol, "\t", "@_TAB_@");
cw = sprintf(ptr + cwt, "%i\t%i\t%s\t%s",
source_state,
tr_it->get_target_state(),
isymbol.c_str(),
osymbol.c_str());
cwt = cwt + cw;
if (write_weights)
cw = sprintf(ptr + cwt, "\t%f",
data.get_weight());
cwt = cwt + cw;
cw = sprintf(ptr + cwt, "\n");
cwt = cwt + cw;
}
if (is_final_state(source_state))
{
cw = sprintf(ptr + cwt, "%i", source_state);
cwt = cwt + cw;
if (write_weights)
cw = sprintf(ptr + cwt, "\t%f",
get_final_weight(source_state));
cwt = cwt + cw;
cw = sprintf(ptr + cwt, "\n");
cwt = cwt + cw;
}
source_state++;
}
}
/** @brief Write the graph in AT&T format to FILE \a file using numbers
instead of symbol names.
\a write_weights defines whether weights are printed. */
HFSTDLL void write_in_att_format_number(FILE *file, bool write_weights=true)
{
unsigned int source_state=0;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
fprintf(file, "%i\t%i\t%i\t%i",
source_state,
tr_it->get_target_state(),
tr_it->get_input_number(),
tr_it->get_output_number());
if (write_weights)
fprintf(file, "\t%f",
data.get_weight());
fprintf(file, "\n");
if (is_final_state(source_state))
{
fprintf(file, "%i", source_state);
if (write_weights)
fprintf(file, "\t%f",
get_final_weight(source_state));
fprintf(file, "\n");
}
}
source_state++;
}
}
/* Create an HfstTransitionGraph as defined in AT&T format
in istream \a is or FILE \a file. \a epsilon_symbol defines
how epsilon is represented.
The functions is called by functions
read_in_att_format(istream&, std::string) and
read_in_att_format(FILE*, std::string).
If \a file is NULL, it is ignored and \a is is used.
If \a file is not NULL, it is used and \a is is ignored. */
HFSTDLL static HfstTransitionGraph read_in_att_format
(std::istream &is,
FILE *file,
std::string epsilon_symbol,
unsigned int & linecount) {
if (file == NULL) {
if (is.eof()) {
HFST_THROW(EndOfStreamException);
}
}
else {
if (feof(file)) {
HFST_THROW(EndOfStreamException);
}
}
HfstTransitionGraph retval;
char line [255];
while(true) {
if (file == NULL) { /* we use streams */
if (! is.getline(line,255).eof())
break;
}
else { /* we use FILEs */
if (NULL == fgets(line, 255, file))
break;
}
linecount++;
// an empty line signifying an empty transducer,
// a special case that is accepted if it is the only
// transducer in the stream
if ( // empty line with or without a newline
(line[0] == '\0') ||
(line[0] == '\n' && line[1] == '\0') ||
// windows newline
(line[0] == '\r' && line[1] == '\n' && line[2] == '\0')
) {
// make sure that the end-of-file is reached
if (file == NULL)
is.get();
else
fgetc(file);
break;
}
if (*line == '-') // transducer separator line is "--"
return retval;
// scan one line that can have a maximum of five fields
char a1 [100]; char a2 [100]; char a3 [100];
char a4 [100]; char a5 [100];
// how many fields could be parsed
int n = sscanf(line, "%s%s%s%s%s", a1, a2, a3, a4, a5);
// set value of weight
float weight = 0;
if (n == 2) // a final state line with weight
weight = atof(a2);
if (n == 5) // a transition line with weight
weight = atof(a5);
if (n == 1 || n == 2) // a final state line
retval.set_final_weight( atoi(a1), weight );
else if (n == 4 || n == 5) { // a transition line
std::string input_symbol=std::string(a3);
std::string output_symbol=std::string(a4);
// replace "@_SPACE_@"s with " " and "@0@"s with
// "@_EPSILON_SYMBOL_@"
replace_all(input_symbol, "@_SPACE_@", " ");
replace_all(input_symbol, "@0@", "@_EPSILON_SYMBOL_@");
replace_all(input_symbol, "@_TAB_@", "\t");
replace_all(input_symbol, "@_COLON_@", ":");
replace_all(output_symbol, "@_SPACE_@", " ");
replace_all(output_symbol, "@0@", "@_EPSILON_SYMBOL_@");
replace_all(output_symbol, "@_TAB_@", "\t");
replace_all(output_symbol, "@_COLON_@", ":");
if (epsilon_symbol.compare(input_symbol) == 0)
input_symbol="@_EPSILON_SYMBOL_@";
if (epsilon_symbol.compare(output_symbol) == 0)
output_symbol="@_EPSILON_SYMBOL_@";
HfstTransition <C> tr( atoi(a2), input_symbol,
output_symbol, weight );
retval.add_transition( atoi(a1), tr );
}
else { // line could not be parsed
std::string message(line);
HFST_THROW_MESSAGE
(NotValidAttFormatException,
message);
}
}
return retval;
}
/** @brief Create an HfstTransitionGraph as defined in AT&T
transducer format in istream \a is. \a epsilon_symbol
defines how epsilon is represented.
@pre \a is not at end, otherwise an exception is thrown.
@note Multiple AT&T transducer definitions are separated with
the line "--". */
HFSTDLL static HfstTransitionGraph read_in_att_format
(std::istream &is,
std::string epsilon_symbol,
unsigned int & linecount)
{
return read_in_att_format
(is, NULL /* a dummy variable */,
epsilon_symbol, linecount);
}
/** @brief Create an HfstTransitionGraph as defined
in AT&T transducer format in FILE \a file.
\a epsilon_symbol defines how epsilon is represented.
@pre \a is not at end, otherwise an exception is thrown.
@note Multiple AT&T transducer definitions are separated with
the line "--". */
HFSTDLL static HfstTransitionGraph read_in_att_format
(FILE *file,
std::string epsilon_symbol,
unsigned int & linecount)
{
return read_in_att_format
(std::cin /* a dummy variable */,
file, epsilon_symbol, linecount);
}
// ----------------------------------------------
// ----- Substitution functions -----
// ----------------------------------------------
protected:
/* A function that performs in-place-substitution in the graph. */
void substitute_(HfstSymbol old_symbol,
HfstSymbol new_symbol,
bool input_side=true,
bool output_side=true)
{
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// Go through all transitions
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
// The substituting input and output symbols for the
// current transition.
HfstSymbol substituting_input_symbol
= tr_it.get_input_symbol();
HfstSymbol substituting_output_symbol
= tr_it.get_output_symbol();
// Whether a substitution will be performed.
bool substitution_made=false;
if (input_side &&
tr_it.get_input_symbol() == old_symbol) {
substituting_input_symbol = new_symbol;
substitution_made=true;
}
if (output_side &&
tr_it.get_output_symbol() == old_symbol) {
substituting_output_symbol = new_symbol;
substitution_made=true;
}
// If a substitution is to be performed,
if (substitution_made) {
add_symbol_to_alphabet(new_symbol);
// change the current transition accordingly.
HfstTransition<C> tr
(tr_it.get_target_state(),
substituting_input_symbol,
substituting_output_symbol,
tr_it.get_weight());
it->operator[](i) = tr;
}
} // all transitions gone through
} // ----- all states gone through -----
return;
}
/* A function that performs in-place substitutions in the graph
as defined in \a substitutions.
substitutions[from_number] = to_number,
if substitutions[from_number] = no_substitution, no substitution is made */
void substitute_(const HfstNumberVector &substitutions,
unsigned int no_substitution)
{
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// Go through all transitions
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
HfstNumber old_inumber = tr_it.get_input_number();
HfstNumber old_onumber = tr_it.get_output_number();
HfstNumber new_inumber = substitutions.at(old_inumber);
HfstNumber new_onumber = substitutions.at(old_onumber);
// If a substitution is to be performed,
if (new_inumber != no_substitution ||
new_onumber != no_substitution)
{
if (new_inumber != no_substitution)
add_symbol_to_alphabet(C::get_symbol(new_inumber));
else
new_inumber = old_inumber;
if (new_onumber != no_substitution)
add_symbol_to_alphabet(C::get_symbol(new_onumber));
else
new_onumber = old_onumber;
// change the current transition accordingly.
HfstTransition<C> tr
(tr_it.get_target_state(),
new_inumber,
new_onumber,
tr_it.get_weight(), false);
it->operator[](i) = tr;
}
} // all transitions gone through
} // ----- all states gone through -----
return;
}
/* A function that performs in-place substitutions in the graph
as defined in \a substitutions. */
void substitute_(const HfstNumberPairSubstitutions &substitutions)
{
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// Go through all transitions
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
HfstNumberPair old_number_pair
( tr_it.get_input_number(),
tr_it.get_output_number() );
HfstNumberPairSubstitutions::const_iterator subst_it
= substitutions.find(old_number_pair);
// If a substitution is to be performed,
if (subst_it != substitutions.end()) {
HfstNumber new_input_number = subst_it->second.first;
HfstNumber new_output_number = subst_it->second.second;
add_symbol_to_alphabet(HfstTropicalTransducerTransitionData::
get_symbol(new_input_number));
add_symbol_to_alphabet(HfstTropicalTransducerTransitionData::
get_symbol(new_output_number));
// change the current transition accordingly.
HfstTransition<C> tr
(tr_it.get_target_state(),
new_input_number,
new_output_number,
tr_it.get_weight(), false);
it->operator[](i) = tr;
}
} // all transitions gone through
} // ----- all states gone through -----
return;
}
public:
/* A function that performs in-place removal of all transitions
equivalent to \a sp in the graph. */
HFSTDLL void remove_transitions(const HfstSymbolPair &sp)
{
unsigned int in_match = C::get_number(sp.first);
unsigned int out_match = C::get_number(sp.second);
bool in_match_used = false;
bool out_match_used = false;
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// Go through all transitions of the current state
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
// If a match was found, remove the transition:
unsigned int in_tr = tr_it.get_input_number();
unsigned int out_tr = tr_it.get_output_number();
if (in_tr == in_match && out_tr == out_match) {
it->erase(it->begin()+i); }
else
{
if (in_tr == in_match || out_tr == in_match) {
in_match_used=true; }
if (in_tr == out_match || out_tr == out_match) {
out_match_used=true; }
}
}
}
// Handle the alphabet
if (!in_match_used) {
alphabet.erase(sp.first); }
if (!out_match_used) {
alphabet.erase(sp.second); }
}
protected:
/* A function that performs in-place-substitution in the graph. */
void substitute_(const HfstSymbolPair &old_sp,
const HfstSymbolPairSet &new_sps)
{
if (new_sps.empty())
{
return remove_transitions(old_sp);
}
unsigned int old_input_number = C::get_number(old_sp.first);
unsigned int old_output_number = C::get_number(old_sp.second);
// Whether any substitution was performed
bool substitution_performed=false;
// ----- Go through all states -----
for (iterator it = begin(); it != end(); it++)
{
// The transitions to be added to the current state
HfstTransitions new_transitions;
// Go through all transitions of the current state
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
// If a match was found, substitute:
if (tr_it.get_input_number() == old_input_number &&
tr_it.get_output_number() == old_output_number)
{
substitution_performed=true;
// change the current transition so that it is equivalent
// to the first substituting transition in new_sps
typename HfstSymbolPairSet::const_iterator IT
= new_sps.begin();
HfstTransition<C> tr
(tr_it.get_target_state(),
C::get_number(IT->first),
C::get_number(IT->second),
tr_it.get_weight(),
true);
it->operator[](i) = tr;
// and schedule the rest of the substituting transitions
// in new_sps to be added to the current state.
while (IT != new_sps.end())
{
HfstTransition<C> TR
(tr_it.get_target_state(),
C::get_number(IT->first),
C::get_number(IT->second),
tr_it.get_weight(),
true);
new_transitions.push_back(TR);
IT++;
}
} // (substitution and scheduling done)
} // (all transitions of a state gone through)
// Add the new transitions to the current state
for (typename HfstTransitions
::const_iterator NIT = new_transitions.begin();
NIT != new_transitions.end(); NIT++)
{
it->push_back(*NIT);
}
} // ( ----- all states in the graph gone through ----- )
// If at least one substitution was performed, add all the
// symbols in the substituting transitions to the alphabet of
// the graph.
if (substitution_performed) {
add_symbols_to_alphabet(new_sps);
}
// Remove symbols that were removed because of substitutions
// (or didn't occur in the graph in the first place)
std::set<unsigned int> syms;
/*for (typename HfstSymbolPairSet::const_iterator it = new_sps.begin();
it != new_sps.end(); it++) {
syms.insert(C::get_number(it->first));
syms.insert(C::get_number(it->second)); ?????????
}*/
syms.insert(old_input_number);
syms.insert(old_output_number);
prune_alphabet_after_substitution(syms);
return;
}
/* A function that performs in-place-substitution in the graph. */
void substitute_(bool (*func)
(const HfstSymbolPair &sp, HfstSymbolPairSet &sps))
{
// ----- Go through all states. -----
for (iterator it = begin(); it != end(); it++)
{
// The transitions to be added to the current state.
HfstTransitions new_transitions;
// Go through all transitions.
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
HfstSymbolPair transition_symbol_pair
(tr_it.get_input_symbol(),
tr_it.get_output_symbol());
HfstSymbolPairSet substituting_transitions;
// If a substitution is to be performed,
bool perform_substitution=false;
try {
perform_substitution =
(*func)(transition_symbol_pair, substituting_transitions);
}
catch (const HfstException & e)
{
throw e;
}
if (perform_substitution)
{
// change the transition to the first element
// in new_sps
typename HfstSymbolPairSet::const_iterator IT
= substituting_transitions.begin();
if (! C::is_valid_symbol(IT->first) ||
! C::is_valid_symbol(IT->second) )
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute");
HfstTransition<C> tr
(tr_it.get_target_state(),
IT->first,
IT->second,
tr_it.get_weight());
it->operator[](i) = tr;
add_symbol_to_alphabet(IT->first);
add_symbol_to_alphabet(IT->second);
// and schedule the rest of the elements in new_sps
// to be added to this state.
while (IT != substituting_transitions.end())
{
if (! C::is_valid_symbol(IT->first) ||
! C::is_valid_symbol(IT->second) )
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute");
HfstTransition<C> TR
(tr_it.get_target_state(),
IT->first,
IT->second,
tr_it.get_weight());
new_transitions.push_back(TR);
add_symbol_to_alphabet(IT->first);
add_symbol_to_alphabet(IT->second);
IT++;
}
} // Substitution and scheduling performed.
} // All transitions gone through.
// Add the new transitions.
for (typename HfstTransitions
::const_iterator NIT = new_transitions.begin();
NIT != new_transitions.end(); NIT++)
{
it->push_back(*NIT);
}
} // ----- All states gone through. -----
return;
}
public:
/* ----------------------------------------
The public substitution functions.
---------------------------------------- */
/** @brief Substitute \a old_symbol with \a new_symbol in
all transitions. \a input_side and \a output_side define
whether the substitution is made on input and output sides. */
HFSTDLL HfstTransitionGraph &
substitute(const HfstSymbol &old_symbol,
const HfstSymbol &new_symbol,
bool input_side=true,
bool output_side=true) {
if (! C::is_valid_symbol(old_symbol) ||
! C::is_valid_symbol(new_symbol) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute"); }
// If a symbol is substituted with itself, do nothing.
if (old_symbol == new_symbol)
return *this;
// If the old symbol is not known to the graph, do nothing.
if (alphabet.find(old_symbol) == alphabet.end())
return *this;
// Remove the symbol to be substituted from the alphabet
// if the substitution is made on both sides.
if (input_side && output_side) {
/* Special symbols are always included in the alphabet */
if (! is_epsilon(old_symbol) &&
! is_unknown(old_symbol) &&
! is_identity(old_symbol)) {
alphabet.erase(old_symbol); }
}
// Insert the substituting symbol to the alphabet.
alphabet.insert(new_symbol);
substitute_(old_symbol, new_symbol, input_side, output_side);
return *this;
}
HFSTDLL HfstTransitionGraph &substitute_symbols
(const HfstSymbolSubstitutions &substitutions)
{ return this->substitute(substitutions); }
/** @brief Substitute all transitions as defined in \a substitutions */
HfstTransitionGraph &substitute
(const HfstSymbolSubstitutions &substitutions)
{
// add symbols to the global HfstTransition alphabet
for (HfstSymbolSubstitutions::const_iterator it
= substitutions.begin();
it != substitutions.end(); it++)
{
(void)get_symbol_number(it->first);
(void)get_symbol_number(it->second);
}
// how symbol numbers are substituted:
// substitutions_[from_symbol] = to_symbol
std::vector<unsigned int> substitutions_;
// marker that means that no substitution is made
unsigned int no_substitution = C::get_max_number()+substitutions.size()+1;
substitutions_.resize
(C::get_max_number()+1, no_substitution);
for (HfstSymbolSubstitutions::const_iterator it
= substitutions.begin();
it != substitutions.end(); it++)
{
HfstNumber from_symbol = get_symbol_number(it->first);
HfstNumber to_symbol = get_symbol_number(it->second);
substitutions_.at(from_symbol) = to_symbol;
}
substitute_(substitutions_, no_substitution);
return *this;
}
HFSTDLL HfstTransitionGraph &substitute_symbol_pairs
(const HfstSymbolPairSubstitutions &substitutions)
{ return this->substitute(substitutions); }
/** @brief Substitute all transitions as defined in \a substitutions.
For each transition x:y, \a substitutions is searched and if
a mapping x:y -> X:Y is found, the transition x:y is replaced
with X:Y. If no mapping is found, the transition remains the same.
*/
HFSTDLL HfstTransitionGraph &substitute
(const HfstSymbolPairSubstitutions &substitutions)
{
// Convert from symbols to numbers
HfstNumberPairSubstitutions substitutions_;
for (HfstSymbolPairSubstitutions::const_iterator it
= substitutions.begin();
it != substitutions.end(); it++)
{
HfstNumberPair from_transition
(get_symbol_number(it->first.first),
get_symbol_number(it->first.second));
HfstNumberPair to_transition
(get_symbol_number(it->second.first),
get_symbol_number(it->second.second));
substitutions_[from_transition] = to_transition;
}
substitute_(substitutions_);
return *this;
}
/** @brief Substitute all transitions \a sp with a set of transitions
\a sps. */
HFSTDLL HfstTransitionGraph &substitute
(const HfstSymbolPair &sp, const HfstSymbolPairSet &sps)
{
if (! C::is_valid_symbol(sp.first) ||
! C::is_valid_symbol(sp.second) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute"); }
for (typename HfstSymbolPairSet::const_iterator it = sps.begin();
it != sps.end(); it++)
{
if (! C::is_valid_symbol(it->first) ||
! C::is_valid_symbol(it->second) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute"); }
}
substitute_(sp, sps);
return *this;
}
/** @brief Substitute all transitions \a old_pair with
\a new_pair. */
HFSTDLL HfstTransitionGraph &substitute
(const HfstSymbolPair &old_pair,
const HfstSymbolPair &new_pair)
{
if (! C::is_valid_symbol(old_pair.first) ||
! C::is_valid_symbol(new_pair.first) ||
! C::is_valid_symbol(old_pair.second) ||
! C::is_valid_symbol(new_pair.second) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute"); }
StringPairSet new_pair_set;
new_pair_set.insert(new_pair);
substitute_(old_pair, new_pair_set);
return *this;
}
/** @brief Substitute all transitions with a set of transitions as
defined by function \a func.
\a func takes as its argument a transition \a sp and inserts
into the set of transitions \a sps the transitions with which
the original transition \a sp must be replaced. \a func returns
a value indicating whether any substitution must be made, i.e.
whether any transition was inserted into \a sps. */
HFSTDLL HfstTransitionGraph &
substitute(bool (*func)
(const HfstSymbolPair &sp, HfstSymbolPairSet &sps) )
{
substitute_(func);
return *this;
}
/* ----------------------------------------------------
Substitute string pair with a transition graph
---------------------------------------------------- */
protected:
/* Used in function
substitute(const StringPair&, HfstTransitionGraph&) */
struct substitution_data
{
HfstState origin_state;
HfstState target_state;
typename C::WeightType weight;
HfstTransitionGraph * substituting_graph;
substitution_data(HfstState origin,
HfstState target,
typename C::WeightType weight,
HfstTransitionGraph * substituting)
{
origin_state=origin;
target_state=target;
this->weight=weight;
substituting_graph=substituting;
}
};
/* Used in function substitute(const StringPair&,
HfstTransitionGraph&)
Add a copy of substituting graph with epsilon transitions between
states and with weight as defined in \a sub. */
void add_substitution(const substitution_data &sub) {
// Epsilon transition to initial state of \a graph
HfstState s = add_state();
HfstTransition <C> epsilon_transition
(s, C::get_epsilon(), C::get_epsilon(),
sub.weight);
add_transition(sub.origin_state, epsilon_transition);
/* Offset between state numbers */
unsigned int offset = s;
// Copy \a graph
const HfstTransitionGraph * graph = sub.substituting_graph;
HfstState source_state=0;
for (const_iterator it = graph->begin();
it != graph->end(); it++)
{
for (typename HfstTransitions::const_iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
HfstTransition <C> transition
(tr_it->get_target_state() + offset,
data.get_input_symbol(),
data.get_output_symbol(),
data.get_weight());
add_transition(source_state + offset, transition);
}
source_state++;
}
// Epsilon transitions from final states of \a graph
for (typename FinalWeightMap::const_iterator it
= graph->final_weight_map.begin();
it != graph->final_weight_map.end(); it++)
{
HfstTransition <C> epsilon_transition
(sub.target_state, C::get_epsilon(), C::get_epsilon(),
it->second);
add_transition(it->first + offset, epsilon_transition);
}
}
public:
/** @brief Substitute all transitions \a old_symbol : \a new_symbol
with a copy of \a graph.
Copies of \a graph are attached to this graph with
epsilon transitions.
The weights of the transitions to be substituted are copied
to epsilon transitions leaving from the source state of
the transitions to be substituted to the initial state
of a copy of \a graph.
The final weights in \a
graph are copied to epsilon transitions leading from
the final states (after substitution non-final states)
of \a graph to target states of transitions
\a old_symbol : \a new_symbol (that are substituted)
in this graph.
*/
HFSTDLL HfstTransitionGraph &
substitute(const HfstSymbolPair &sp,
const HfstTransitionGraph &graph) {
if ( ! ( C::is_valid_symbol(sp.first) &&
C::is_valid_symbol(sp.second) ) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::substitute(const HfstSymbolPair&, "
"const HfstTransitionGraph&)");
}
// If neither symbol to be substituted is known to the graph,
// do nothing.
if (alphabet.find(sp.first) == alphabet.end() &&
alphabet.find(sp.second) == alphabet.end())
return *this;
// Where the substituting copies of substituting graphs
// are inserted (source state, target state, weight)
std::vector<substitution_data> substitutions;
// Go through all states
HfstState source_state=0;
for (iterator it = begin(); it != end(); it++)
{
// The transitions that are substituted, i.e. removed
std::vector<typename HfstTransitions::iterator>
old_transitions;
// Go through all transitions
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
// Whether there is anything to substitute
// in this transition
if (data.get_input_symbol() == sp.first &&
data.get_output_symbol() == sp.second)
{
// schedule a substitution
substitutions.push_back(substitution_data
(source_state,
tr_it->get_target_state(),
data.get_weight(),
const_cast<HfstTransitionGraph *>(&graph)));
// schedule the old transition to be deleted
old_transitions.push_back(tr_it);
}
// (one transition gone through)
}
// (all transitions in a state gone through)
// Remove the substituted transitions
for (typename std::vector<typename
HfstTransitions::iterator>::iterator IT =
old_transitions.begin();
IT != old_transitions.end(); IT++) {
it->erase(*IT);
}
source_state++;
}
// (all states gone trough)
// Add the substitutions
for (typename std::vector<substitution_data>::iterator IT
= substitutions.begin();
IT != substitutions.end(); IT++)
{
add_substitution(*IT);
}
return *this;
}
HFSTDLL std::string weight2marker(float weight)
{
std::ostringstream o;
o << weight;
return std::string("@") + o.str() + std::string("@");
}
HFSTDLL HfstTransitionGraph & substitute_weights_with_markers() {
// Go through all current states (we are going to add them)
HfstState limit = state_vector.size();
for (HfstState state = 0; state < limit; state++)
{
// The transitions that are substituted
std::stack<typename HfstTransitions::iterator>
old_transitions;
// The transitions that will substitute
std::vector<HfstTransition <C> > new_transitions;
// Go through all transitions
for (typename HfstTransitions::iterator tr_it
= state_vector[state].begin();
tr_it != state_vector[state].end(); tr_it++)
{
C data = tr_it->get_transition_data();
// Whether there is anything to substitute
// in this transition
if (data.get_weight() != 0 )
{
// schedule a substitution
new_transitions.push_back
(HfstTransition <C> (tr_it->get_target_state(),
data.get_input_symbol(),
data.get_output_symbol(),
data.get_weight()));
// schedule the old transition to be deleted
old_transitions.push(tr_it);
}
// (one transition gone through)
}
// (all transitions in a state gone through)
// Remove the substituted transitions
while (! old_transitions.empty()) {
state_vector[state].erase(old_transitions.top());
old_transitions.pop();
}
// Add the substituting transitions
for (typename std::vector<HfstTransition <C> >::iterator IT
= new_transitions.begin();
IT != new_transitions.end(); IT++)
{
HfstState new_state = add_state();
std::string marker = weight2marker(IT->get_weight());
//std::cerr << "got marker '" << marker << "'" << std::endl;
HfstTransition <C> marker_transition(IT->get_target_state(),
marker,
marker,
0);
HfstTransition <C> new_transition(new_state,
IT->get_input_symbol(),
IT->get_output_symbol(),
0);
add_transition(state, new_transition);
add_transition(new_state, marker_transition);
}
}
// (all states gone trough)
// Go through the final states
std::set<HfstState> final_states_to_remove;
for (typename FinalWeightMap::iterator fin_it = final_weight_map.begin();
fin_it != final_weight_map.end(); fin_it++)
{
if (fin_it->second != 0)
{
HfstState new_state = add_state();
set_final_weight(new_state, 0);
std::string marker = weight2marker(fin_it->second);
HfstTransition <C> epsilon_transition(new_state,
marker,
marker,
0);
add_transition(fin_it->first, epsilon_transition);
final_states_to_remove.insert(fin_it->first);
}
}
for (std::set<HfstState>::iterator it = final_states_to_remove.begin();
it != final_states_to_remove.end(); it++)
{
final_weight_map.erase(*it);
}
return *this;
}
// ####
// another version of substitute for internal use..
// ####
typedef std::map<HfstSymbol, HfstTransitionGraph> SubstMap;
HFSTDLL HfstTransitionGraph &
substitute(SubstMap & substitution_map,
bool harmonize) {
bool symbol_found = false;
for (typename SubstMap::const_iterator it = substitution_map.begin();
it != substitution_map.end(); it++)
{
if ( ! ( C::is_valid_symbol(it->first) ))
{
HFST_THROW_MESSAGE(EmptyStringException,
"HfstTransitionGraph::substitute "
"(const std::map<HfstSymbol, HfstTransitionGraph> &)");
}
if (!symbol_found && alphabet.find(it->first) != alphabet.end())
{
symbol_found = true;
}
}
// If none of the symbols to be substituted is known to the graph,
// do nothing.
if (!symbol_found)
{
return *this;
}
std::set<String> substitutions_performed_for_symbols;
// Where the substituting copies of graphs
// are inserted (source state, target state, weight)
std::vector<substitution_data> substitutions;
// Go through all states
HfstState source_state=0;
for (iterator it = begin(); it != end(); it++)
{
// The transitions that are substituted, i.e. removed
std::stack<typename HfstTransitions::iterator>
old_transitions;
// Go through all transitions
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
// Whether there is anything to substitute
// in this transition
String istr = data.get_input_symbol();
String ostr = data.get_output_symbol();
typename SubstMap::iterator map_it_input = substitution_map.find(istr);
typename SubstMap::iterator map_it_output = substitution_map.find(ostr);
if (map_it_input == substitution_map.end() &&
map_it_output == substitution_map.end())
{
;
}
else if (istr != ostr)
{
std::string msg("symbol to be substituted must not occur only on one side of transition");
HFST_THROW_MESSAGE(HfstException, msg);
}
else
{
// schedule a substitution
substitution_data sd
(source_state,
tr_it->get_target_state(),
data.get_weight(),
&(map_it_input->second));
substitutions.push_back(sd);
// schedule the old transition to be deleted
old_transitions.push(tr_it);
// ...
substitutions_performed_for_symbols.insert(istr);
}
// (one transition gone through)
}
// (all transitions in a state gone through)
// Remove the substituted transitions
while (!old_transitions.empty())
{
it->erase(old_transitions.top());
old_transitions.pop();
}
source_state++;
}
// (all states gone trough)
// Remove all symbols that were substituted
for (StringSet::const_iterator sym_it = substitutions_performed_for_symbols.begin();
sym_it != substitutions_performed_for_symbols.end(); sym_it++)
{
if (*sym_it != "@_EPSILON_SYMBOL_@" && *sym_it != "@_UNKNOWN_SYMBOL_@" && *sym_it != "@_IDENTITY_SYMBOL_@")
this->remove_symbol_from_alphabet(*sym_it);
}
// Harmonize the resulting and the substituting graphs, if needed
if (harmonize)
{
for (StringSet::iterator sym_it = substitutions_performed_for_symbols.begin();
sym_it != substitutions_performed_for_symbols.end(); sym_it++)
{
this->harmonize(substitution_map.at(*sym_it));
}
}
// Add the substitutions
for (typename std::vector<substitution_data>::iterator IT
= substitutions.begin();
IT != substitutions.end(); IT++)
{
add_substitution(*IT);
}
return *this;
}
HFSTDLL bool marker2weight(const std::string & str, float & weight)
{
if (str.size() < 3)
return false;
if (str.at(0) != '@' || str.at(str.size()-1) != '@')
return false;
std::string weight_string = str.substr(1, str.size()-2);
std::stringstream sstream(weight_string);
sstream >> weight;
if (sstream.fail()) {
return false;
}
return true;
}
HFSTDLL HfstTransitionGraph & substitute_markers_with_weights() {
// Go through all states
HfstState limit = state_vector.size();
for (HfstState state = 0; state < limit; state++)
{
// The transitions that are substituted
std::stack<typename HfstTransitions::iterator>
old_transitions;
// The transitions that will substitute
std::vector<HfstTransition <C> > new_transitions;
// Go through all transitions
for (typename HfstTransitions::iterator tr_it
= state_vector[state].begin();
tr_it != state_vector[state].end(); tr_it++)
{
C data = tr_it->get_transition_data();
float weight = 0;
// Whether there is anything to substitute
// in this transition
if ( (!marker2weight(data.get_input_symbol(), weight)) &&
marker2weight(data.get_output_symbol(), weight) )
{
//std::cerr << "got weight '" << weight << "'" << std::endl;
// schedule a substitution
new_transitions.push_back
(HfstTransition <C> (tr_it->get_target_state(),
data.get_input_symbol(),
hfst::internal_epsilon,
weight));
// schedule the old transition to be deleted
old_transitions.push(tr_it);
}
// or the transition must be deleted
else if (marker2weight(data.get_input_symbol(), weight) &&
marker2weight(data.get_output_symbol(), weight) )
{
//std::cerr << "got weight '" << weight << "'" << std::endl;
// schedule the old transition to be deleted
old_transitions.push(tr_it);
}
else {}
// (one transition gone through)
}
// (all transitions in a state gone through)
// Remove the substituted transitions
while (! old_transitions.empty()) {
state_vector[state].erase(old_transitions.top());
old_transitions.pop();
}
// Add the substituting transitions
for (typename std::vector<HfstTransition <C> >::iterator IT
= new_transitions.begin();
IT != new_transitions.end(); IT++)
{
state_vector[state].push_back(*IT);
}
}
// (all states gone trough)
std::stack<StringSet::iterator> weight_markers;
for (StringSet::iterator it = alphabet.begin();
it != alphabet.end(); it++)
{
float foo;
if (marker2weight(*it, foo))
{
weight_markers.push(it);
}
}
while (! weight_markers.empty())
{
alphabet.erase(weight_markers.top());
weight_markers.pop();
}
return *this;
}
// aliases
HFSTDLL HfstTransitionGraph & substitute_symbol(const std::string &old_symbol, const std::string &new_symbol, bool input_side=true, bool output_side=true)
{ return this->substitute(old_symbol, new_symbol, input_side, output_side); }
HFSTDLL HfstTransitionGraph & substitute_symbol_pair(const StringPair &old_symbol_pair, const StringPair &new_symbol_pair)
{ return this->substitute(old_symbol_pair, new_symbol_pair); }
HFSTDLL HfstTransitionGraph & substitute_symbol_pair_with_set(const StringPair &old_symbol_pair, const hfst::StringPairSet &new_symbol_pair_set)
{ return this->substitute(old_symbol_pair, new_symbol_pair_set); }
HFSTDLL HfstTransitionGraph & substitute_symbol_pair_with_transducer(const StringPair &symbol_pair, HfstTransitionGraph &transducer)
{ return this->substitute(symbol_pair, transducer); }
/* ----------------------------
Insert freely functions
---------------------------- */
/** @brief Insert freely any number of \a symbol_pair in
the graph with weight \a weight. */
HFSTDLL HfstTransitionGraph &insert_freely
(const HfstSymbolPair &symbol_pair, typename C::WeightType weight)
{
if ( ! ( C::is_valid_symbol(symbol_pair.first) &&
C::is_valid_symbol(symbol_pair.second) ) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::insert_freely"
"(const HfstSymbolPair&, W)");
}
alphabet.insert(symbol_pair.first);
alphabet.insert(symbol_pair.second);
HfstState source_state=0;
for (iterator it = begin(); it != end(); it++) {
HfstTransition <C> tr( source_state, symbol_pair.first,
symbol_pair.second, weight );
it->push_back(tr);
source_state++;
}
return *this;
}
/** @brief Insert freely any number of any symbol in \a symbol_pairs in
the graph with weight \a weight. */
HFSTDLL HfstTransitionGraph &insert_freely
(const HfstSymbolPairSet &symbol_pairs,
typename C::WeightType weight)
{
for (typename HfstSymbolPairSet::const_iterator symbols_it
= symbol_pairs.begin();
symbols_it != symbol_pairs.end(); symbols_it++)
{
if ( ! ( C::is_valid_symbol(symbols_it->first) &&
C::is_valid_symbol(symbols_it->second) ) ) {
HFST_THROW_MESSAGE
(EmptyStringException,
"HfstTransitionGraph::insert_freely"
"(const HfstSymbolPairSet&, W)");
}
alphabet.insert(symbols_it->first);
alphabet.insert(symbols_it->second);
}
HfstState source_state=0;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstSymbolPairSet::const_iterator symbols_it
= symbol_pairs.begin();
symbols_it != symbol_pairs.end(); symbols_it++)
{
HfstTransition <C> tr( source_state, symbols_it->first,
symbols_it->second, weight );
it->push_back(tr);
}
source_state++;
}
return *this;
}
/** @brief Insert freely any number of \a graph in this
graph. */
HFSTDLL HfstTransitionGraph &insert_freely
(const HfstTransitionGraph &graph)
{
HfstSymbol marker_this = C::get_marker(alphabet);
HfstSymbol marker_graph = C::get_marker(alphabet);
HfstSymbol marker = marker_this;
if (marker_graph > marker)
marker = marker_graph;
HfstSymbolPair marker_pair(marker, marker);
insert_freely(marker_pair, 0);
substitute(marker_pair, graph);
alphabet.erase(marker); // TODO: fix
return *this;
}
/* -------------------------------
Harmonization function
------------------------------- */
/** @brief Harmonize this HfstTransitionGraph and \a another.
In harmonization the unknown and identity symbols in
transitions of both graphs are expanded according to
the symbols that are previously unknown to the graph.
For example the graphs
\verbatim
[a:b ?:?]
[c:d ? ?:c]
\endverbatim
are expanded to
\verbatim
[ a:b [?:? | ?:c | ?:d | c:d | d:c | c:? | d:?] ]
[ c:d [? | a | b] [?:c| a:c | b:?] ]
\endverbatim
when harmonized.
The symbol "?" means \@_UNKNOWN_SYMBOL_\@ in either or
both sides of a transition
(transitions of type [?:x], [x:?] and [?:?]).
The transition [?] means [\@_IDENTITY_SYMBOL_\@].
@note This function is always called for arguments of functions
that take two or more graphs as their arguments, unless otherwise
said.
*/
HFSTDLL HfstTransitionGraph &harmonize(HfstTransitionGraph &another)
{
HarmonizeUnknownAndIdentitySymbols foo(*this, another);
return *this;
}
/* -------------------------------
Disjunction functions
------------------------------- */
protected:
/* Disjunct the transition of path \a spv pointed by \a it
to state \a s. If the transition does not exist in the graph,
it is created as well as its target state.
@return The final state of path \a spv, when \a it is at end. */
HfstState disjunct(const StringPairVector &spv,
StringPairVector::const_iterator &it,
HfstState s)
{
// Path inserted, return the final state on this path
if (it == spv.end()) {
return s;
}
HfstTransitions tr = state_vector[s];
bool transition_found=false;
/* The target state of the transition followed or added */
HfstState next_state;
// Find the transition
// (Searching is slow?)
for (typename HfstTransitions::iterator tr_it = tr.begin();
tr_it != tr.end(); tr_it++)
{
C data = tr_it->get_transition_data();
if (data.get_input_symbol().compare(it->first) == 0 &&
data.get_output_symbol().compare(it->second) == 0)
{
transition_found=true;
next_state = tr_it->get_target_state();
break;
}
}
// If not found, create the transition
if (! transition_found)
{
next_state = add_state();
HfstTransition <C> transition(next_state, it->first,
it->second, 0);
add_transition(s, transition);
}
// Advance to the next transition on path
it++;
return disjunct(spv, it, next_state);
}
public:
/** @brief Disjunct this graph with a one-path graph
defined by string pair vector \a spv with weight \a weight.
@pre This graph must be a trie where all weights are in
final states, i.e. all transitions have a zero weight.
There is no way to test whether a graph is a trie, so the use
of this function is probably limited to fast construction
of a lexicon. Here is an example:
\verbatim
HfstBasicTransducer lexicon;
HfstTokenizer TOK;
lexicon.disjunct(TOK.tokenize("dog"), 0.3);
lexicon.disjunct(TOK.tokenize("cat"), 0.5);
lexicon.disjunct(TOK.tokenize("elephant"), 1.6);
\endverbatim
*/
HFSTDLL HfstTransitionGraph &disjunct
(const StringPairVector &spv, typename C::WeightType weight)
{
StringPairVector::const_iterator it = spv.begin();
HfstState final_state = disjunct(spv, it, INITIAL_STATE);
// Set the weight of final state
if (is_final_state(final_state))
{
float old_weight = get_final_weight(final_state);
if (old_weight < weight)
return *this; /* The same path with smaller weight remains */
}
set_final_weight(final_state, weight);
return *this;
}
HFSTDLL bool is_special_symbol(const std::string & symbol)
{
if (symbol.size() < 2)
return false;
if (symbol[0] == '@' && symbol[1] == '_')
return true;
return false;
}
HFSTDLL HfstTransitionGraph &complete()
{
HfstState failure_state = add_state();
HfstState current_state = 0;
for (iterator it = begin(); it != end(); it++)
{
std::set<HfstSymbol> symbols_present;
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
if (data.get_input_symbol() != data.get_output_symbol())
{
HFST_THROW(TransducersAreNotAutomataException);
}
symbols_present.insert(data.get_input_symbol());
}
for (std::set<std::string>::const_iterator alpha_it = alphabet.begin();
alpha_it != alphabet.end(); alpha_it++)
{
if (symbols_present.find(*alpha_it) ==
symbols_present.end() &&
! is_special_symbol(*alpha_it))
{
add_transition
(current_state,
HfstBasicTransition(failure_state, *alpha_it, *alpha_it, 0));
}
}
current_state++;
}
return *this;
}
HFSTDLL StringSet get_flags() const
{
StringSet flags;
for (StringSet::const_iterator it = alphabet.begin();
it != alphabet.end(); it++)
{
if (FdOperation::is_diacritic(*it)) {
flags.insert(*it);
}
}
return flags;
}
// Whether symbol \a symbol must be purged from transitions and alphabet
// of a transducer after \a flag has been eliminated from the transducer.
// If \a flag is the empty string, all flags have been eliminated.
HFSTDLL bool purge_symbol(const std::string & symbol, const std::string & flag)
{
if (! FdOperation::is_diacritic(symbol))
return false;
if (flag == "")
return true;
else if (FdOperation::get_feature(symbol) == flag)
return true;
return false;
}
// Replace arcs in \a transducer that use flag \a flag with epsilon arcs
// and remove \a flag from alphabet of \a transducer. If \a flag is the empty
// string, replace/remove all flags.
HFSTDLL void flag_purge(const std::string & flag)
{
// (1) Go through all states and transitions
for (iterator it = begin(); it != end(); it++)
{
for (unsigned int i=0; i < it->size(); i++)
{
HfstTransition<C> &tr_it = it->operator[](i);
if ( purge_symbol(tr_it.get_input_symbol(), flag) ||
purge_symbol(tr_it.get_output_symbol(), flag) )
{
// change the current transition
HfstTransition<C> tr
(tr_it.get_target_state(), "@_EPSILON_SYMBOL_@",
"@_EPSILON_SYMBOL_@", tr_it.get_weight());
it->operator[](i) = tr;
}
}
}
// (2) Go through the alphabet
StringSet extra_symbols;
for (StringSet::const_iterator it = alphabet.begin();
it != alphabet.end(); it++)
{
if (purge_symbol(*it, flag))
extra_symbols.insert(*it);
}
// remove symbols
remove_symbols_from_alphabet(extra_symbols);
}
/* A topological sort. */
struct TopologicalSort
{
std::vector<int> distance_of_state;
std::vector<std::set<HfstState> > states_at_distance;
/* Initialize the TopologicalSort by reserving space for a transducer
with biggest state number \a biggest_state_number, */
HFSTDLL void set_biggest_state_number(unsigned int biggest_state_number)
{
distance_of_state = std::vector<int>(biggest_state_number+1, -1);
}
/* Set the maximum distance of \a state to \a distance, */
HFSTDLL void set_state_at_distance(HfstState state, unsigned int distance,
bool overwrite)
{
// see that 'state' does not exceed the maximum state number given in initialization
if (state > (distance_of_state.size() - 1))
{
std::cerr << "ERROR in TopologicalSort::set_state_at_distance: first argument ("
<< state << ") is out of range (should be < " << distance_of_state.size()
<< ")" << std::endl;
}
// if there is nothing on index 'state',
// push back empty sets of states up to index 'state', including
while (distance + 1 > (unsigned int)states_at_distance.size())
{
std::set<HfstState> empty_set;
states_at_distance.push_back(empty_set);
}
// if there was previous distance defined for 'state', erase it, if needed
int previous_distance = distance_of_state.at(state);
if (previous_distance != -1 && previous_distance != (int)distance && overwrite)
{
states_at_distance.at(previous_distance).erase(state);
}
// set state and distance
states_at_distance.at(distance).insert(state);
distance_of_state.at(state) = distance;
}
/* The states that have a maximum distance of \a distance. */
HFSTDLL const std::set<HfstState> & get_states_at_distance(unsigned int distance)
{
// if there is nothing on index 'state',
// push back empty sets of states up to index 'state', including
while (distance > (states_at_distance.size() - 1))
{
std::set<HfstState> empty_set;
states_at_distance.push_back(empty_set);
}
return states_at_distance.at(distance);
}
};
enum SortDistance { MaximumDistance, MinimumDistance };
/*
Get a topological (maximum distance) sort of this graph.
@return A vector of sets of states. At each vector index ind, the
result contains the set of all states whose (maximum) distance from
the start state is ind.
*/
HFSTDLL std::vector<std::set<HfstState> > topsort(SortDistance dist) const
{
typedef std::set<HfstState>::const_iterator StateIt;
unsigned int current_distance = 0; // topological distance
TopologicalSort TopSort;
TopSort.set_biggest_state_number(state_vector.size()-1);
TopSort.set_state_at_distance(0,current_distance,(dist == MaximumDistance));
bool new_states_found = false; // end condition for do-while loop
do
{
new_states_found = false;
// states that are accessible from the current set of states
std::set<HfstState> new_states;
// go through all states at current distance
const std::set<HfstState> & states =
TopSort.get_states_at_distance(current_distance);
for (StateIt state_it = states.begin();
state_it != states.end(); state_it++)
{
// go through all transitions of each state
const HfstTransitions & transitions
= this->state_vector.at(*state_it);
for (typename HfstTransitions::const_iterator transition_it
= transitions.begin();
transition_it != transitions.end(); transition_it++)
{
new_states_found = true;
new_states.insert(transition_it->get_target_state());
}
// all transitions gone through
}
// all states gone through
// set each accessible state at distance one higher than the
// current distance
for (StateIt it = new_states.begin();
it != new_states.end(); it++)
{
TopSort.set_state_at_distance(*it, current_distance + 1, (dist == MaximumDistance));
}
current_distance++;
}
while (new_states_found);
return TopSort.states_at_distance;
}
/** The length of longest string accepted by this graph.
If no string is accepted, return -1. */
HFSTDLL int longest_path_size()
{
// get topological maximum distance sort
std::vector<std::set<HfstState> > states_sorted = this->topsort(MaximumDistance);
// go through all sets of states in descending order
for (int distance = states_sorted.size() - 1; distance >= 0; distance--)
{
const std::set<HfstState> & states
= states_sorted.at((unsigned int)distance);
// go through all states in a set
for (std::set<HfstState>::const_iterator it = states.begin();
it != states.end(); it++)
{
// if a final state is encountered, return the distance
// of that state
if (is_final_state(*it))
{
return distance;
}
}
}
// if no final states were encountered, return a negative value
return -1;
}
/** The lengths of strings accepted by this graph, in descending order.
If not string is accepted, return an empty vector. */
HFSTDLL std::vector<unsigned int> path_sizes()
{
std::vector<unsigned int> result;
// get topological maximum distance sort
std::vector<std::set<HfstState> > states_sorted = this->topsort(MinimumDistance);
// go through all sets of states in descending order
for (int distance = states_sorted.size() - 1; distance >= 0; distance--)
{
const std::set<HfstState> & states
= states_sorted.at((unsigned int)distance);
// go through all states in a set
for (std::set<HfstState>::const_iterator it = states.begin();
it != states.end(); it++)
{
// if a final state is encountered, add its distance
// to result
if (is_final_state(*it))
{
result.push_back((unsigned int)distance);
break; // go to next set of states
}
}
}
return result;
}
bool has_negative_epsilon_cycles
(HfstState state,
float total_weight,
std::map<HfstState, float> & state_weights)
{
std::map<HfstState, float>::const_iterator it = state_weights.find(state);
if (it != state_weights.end()) // cycle detected
{
if (total_weight - it->second < 0)
{
return true; // cycle with negative weight detected
}
return false; // cycle with positive weight
}
state_weights[state] = total_weight;
// Go through all transitions in this state
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](state);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
if (is_epsilon(it->get_input_symbol()) && is_epsilon(it->get_output_symbol()))
{
if (has_negative_epsilon_cycles
(it->get_target_state(), total_weight + it->get_weight(), state_weights))
return true;
}
}
state_weights.erase(state);
return false;
}
bool has_negative_epsilon_cycles()
{
bool has_negative_epsilon_transitions = false;
for (iterator it = begin(); it != end(); it++)
{
for (typename HfstTransitions::iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
if (is_epsilon(tr_it->get_input_symbol()) && is_epsilon(tr_it->get_output_symbol()) && tr_it->get_weight() < 0)
{
has_negative_epsilon_transitions = true;
break;
}
}
}
if (! has_negative_epsilon_transitions)
{
return false;
}
std::map<HfstState, float> state_weights;
for (unsigned int state = INITIAL_STATE; state < (this->get_max_state()+1); state++)
{
if (has_negative_epsilon_cycles(state, 0, state_weights))
return true;
}
return false;
}
HFSTDLL bool is_infinitely_ambiguous
(HfstState state,
std::set<HfstState> &epsilon_path_states,
std::vector<unsigned int> &states_handled)
{
if (states_handled[state] != 0)
return false;
// Go through all transitions in this state
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](state);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
// (Diacritics are also treated as epsilons, although it might cause false
// positive results, because loops with diacritics can be invalidated by
// other diacritics.)
if ( is_epsilon(it->get_input_symbol()) ||
FdOperation::is_diacritic(it->get_input_symbol()) )
{
epsilon_path_states.insert(state);
if (epsilon_path_states.find(it->get_target_state())
!= epsilon_path_states.end())
{
return true;
}
if (is_infinitely_ambiguous
(it->get_target_state(), epsilon_path_states, states_handled))
{
return true;
}
epsilon_path_states.erase(state);
}
}
// mark state as handled
states_handled[state] = 1;
return false;
}
HFSTDLL bool is_infinitely_ambiguous()
{
std::set<HfstState> epsilon_path_states;
HfstState max_state = this->get_max_state();
std::vector<unsigned int> states_handled(max_state+1, 0);
for (unsigned int state = INITIAL_STATE; state < (max_state+1); state++)
{
if (is_infinitely_ambiguous(state, epsilon_path_states, states_handled))
return true;
}
return false;
}
HFSTDLL bool is_lookup_infinitely_ambiguous
(const HfstOneLevelPath& s,
unsigned int& index, HfstState state,
std::set<HfstState> &epsilon_path_states
)
{
// Whether the end of the lookup path s has been reached
bool only_epsilons=false;
if ((unsigned int)s.second.size() == index)
{
only_epsilons=true;
}
// Go through all transitions in this state
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](state);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
// CASE 1: Input epsilons do not consume a symbol in the lookup path s,
// so they can be added freely.
// (Diacritics are also treated as epsilons, although it might cause false
// positive results, because loops with diacritics can be invalidated by
// other diacritics.)
if ( is_epsilon(it->get_input_symbol()) ||
FdOperation::is_diacritic(it->get_input_symbol()) )
{
epsilon_path_states.insert(state);
if (epsilon_path_states.find(it->get_target_state())
!= epsilon_path_states.end())
{
return true;
}
if (is_lookup_infinitely_ambiguous
(s, index, it->get_target_state(), epsilon_path_states))
{
return true;
}
epsilon_path_states.erase(state);
}
/* CASE 2: Other input symbols consume a symbol in the lookup path s,
so they can be added only if the end of the lookup path s has not
been reached. */
else if (! only_epsilons)
{
bool continu = false;
if (it->get_input_symbol().compare(s.second.at(index)) == 0)
continu = true;
else if ((it->get_input_symbol().compare("@_UNKNOWN_SYMBOL_@") ||
it->get_input_symbol().compare("@_IDENTITY_SYMBOL_@"))
&&
(alphabet.find(s.second.at(index)) == alphabet.end()))
{
continu = true;
}
if (continu)
{
index++; // consume an input symbol in the lookup path s
std::set<HfstState> empty_set;
if (is_lookup_infinitely_ambiguous
(s, index, it->get_target_state(), empty_set))
{
return true;
}
index--; // add the input symbol back to the lookup path s.
}
}
}
return false;
}
HFSTDLL bool is_lookup_infinitely_ambiguous(const HfstOneLevelPath & s)
{
std::set<HfstState> epsilon_path_states;
epsilon_path_states.insert(0);
unsigned int index=0;
return is_lookup_infinitely_ambiguous(s, index, INITIAL_STATE,
epsilon_path_states);
}
HFSTDLL bool is_lookup_infinitely_ambiguous(const StringVector & s)
{
std::set<HfstState> epsilon_path_states;
epsilon_path_states.insert(0);
unsigned int index=0;
HfstOneLevelPath path((float)0, s);
return is_lookup_infinitely_ambiguous(path, index, INITIAL_STATE,
epsilon_path_states);
}
HFSTDLL static void push_back_to_two_level_path
(HfstTwoLevelPath &path,
const StringPair &sp,
const float &weight)
{
path.second.push_back(sp);
path.first = path.first + weight;
}
HFSTDLL static void pop_back_from_two_level_path
(HfstTwoLevelPath &path,
const float &weight)
{
path.second.pop_back();
path.first = path.first - weight;
}
HFSTDLL static void add_to_results
(HfstTwoLevelPaths &results,
HfstTwoLevelPath &path_so_far,
const float &final_weight,
float * max_weight)
{
path_so_far.first = path_so_far.first + final_weight;
if (max_weight == NULL) // no weight limitation given
{
results.insert(path_so_far);
}
else if (!(path_so_far.first > *max_weight)) // weight limitation not exceeded
{
results.insert(path_so_far);
}
else // weight limitation exceeded
{
;
}
path_so_far.first = path_so_far.first - final_weight;
}
HFSTDLL static bool is_possible_transition
(const HfstBasicTransition &transition,
const StringVector &lookup_path,
const unsigned int &lookup_index,
const StringSet &alphabet,
bool &input_symbol_consumed)
{
std::string isymbol = transition.get_input_symbol();
// If we are not at the end of lookup_path,
if (! (lookup_index == (unsigned int)lookup_path.size()))
{
// we can go further if the current symbol in lookup_path
// matches to the input symbol of the transition, i.e
// either the input symbol is the same as the current symbol
if ( isymbol.compare(lookup_path.at(lookup_index)) == 0 ||
// or the input symbol is the identity or unknown symbol and
// the current symbol is not found in the alphabet
// of the transducer.
( (is_identity(isymbol) || is_unknown(isymbol)) &&
(alphabet.find(lookup_path.at(lookup_index))
== alphabet.end()) )
)
{
input_symbol_consumed=true;
return true;
}
}
// Whether there are more symbols in lookup_path or not,
// we can always go further if the input symbol of the transition
// is an epsilon or a flag diacritic.
if ( is_epsilon(isymbol) ||
FdOperation::is_diacritic(isymbol) )
{
input_symbol_consumed=false;
return true;
}
// No matches.
return false;
}
HFSTDLL void lookup_fd
(const StringVector &lookup_path,
HfstTwoLevelPaths &results,
HfstState state,
unsigned int lookup_index, // an iterator instead?
HfstTwoLevelPath &path_so_far,
StringSet &alphabet,
HfstEpsilonHandler Eh,
size_t infinite_cutoff,
float * max_weight = NULL)
{
// Check whether the number of input epsilon cycles is exceeded
if (! Eh.can_continue(state)) {
return;
}
// Check whether the maximum weight is exceeded
if (max_weight != NULL && path_so_far.first > *max_weight) {
return;
}
// If we are at the end of lookup_path,
if (lookup_index == lookup_path.size())
{
// and if the current state is final,
if (this->is_final_state(state))
{
// path_so_far is a valid result if max_weight is not exceeded
add_to_results
(results, path_so_far, this->get_final_weight(state), max_weight);
}
}
// Whether there are more symbols in lookup_path or not,
// go through all transitions in the current state.
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](state);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
bool input_symbol_consumed=false;
if ( is_possible_transition
(*it, lookup_path, lookup_index, alphabet,
input_symbol_consumed) )
{
// update path_so_far and lookup_index
std::string istr;
std::string ostr;
// identity symbol is replaced with the lookup symbol
if (is_identity(it->get_input_symbol()))
{
istr = lookup_path.at(lookup_index);
ostr = istr;
}
else
{
if (is_unknown(it->get_input_symbol()))
istr = lookup_path.at(lookup_index);
else
istr = it->get_input_symbol();
/*if (is_unknown(it->get_output_symbol()))
ostr = std::string("?");
else*/
ostr = it->get_output_symbol();
}
push_back_to_two_level_path
(path_so_far,
StringPair(istr, ostr),
it->get_weight());
HfstEpsilonHandler * Ehp = NULL;
if (input_symbol_consumed) {
lookup_index++;
Ehp = new HfstEpsilonHandler(infinite_cutoff);
}
else {
Eh.push_back(state);
Ehp = &Eh;
}
// call lookup for the target state of the transition
lookup_fd(lookup_path, results, it->get_target_state(),
lookup_index, path_so_far, alphabet, *Ehp, infinite_cutoff, max_weight);
// return to the original values of path_so_far
// and lookup_index
if (input_symbol_consumed) {
lookup_index--;
delete Ehp;
}
else {
// Eh.pop_back(); not needed because the destructor
// of Eh is automatically called next
}
pop_back_from_two_level_path(path_so_far, it->get_weight());
}
}
}
HFSTDLL void lookup_fd
(const StringVector &lookup_path,
HfstTwoLevelPaths &results,
size_t * infinite_cutoff = NULL,
float * max_weight = NULL)
{
HfstState state = 0;
unsigned int lookup_index = 0;
HfstTwoLevelPath path_so_far;
StringSet alphabet = this->get_alphabet();
if (infinite_cutoff != NULL)
{
HfstEpsilonHandler Eh(*infinite_cutoff);
lookup_fd(lookup_path, results, state, lookup_index, path_so_far,
alphabet, Eh, *infinite_cutoff, max_weight);
}
else
{
HfstEpsilonHandler Eh(100000);
lookup_fd(lookup_path, results, state, lookup_index, path_so_far,
alphabet, Eh, 100000, max_weight);
}
}
HFSTDLL void check_regexp_state_for_cycle(HfstState s, const std::set<HfstState> & states_visited)
{
if (states_visited.find(s) != states_visited.end())
{
throw "error: loop detected inside compile-replace regular expression";
}
}
// Returns whether tr is "^]":"^]". If tr is not allowed, throws an error message.
HFSTDLL bool check_regexp_transition_end(const HfstBasicTransition & tr, bool input_side)
{
std::string istr = tr.get_input_symbol();
std::string ostr = tr.get_output_symbol();
if (input_side && is_epsilon(istr))
{}
else if (!input_side && is_epsilon(ostr))
{}
else if ((input_side && is_special_symbol(istr)) || (!input_side && is_special_symbol(ostr)))
{
throw "error: special symbol detected in compile-replace regular expression";
}
else
{}
if ((input_side && ("^[" == istr)) || (!input_side && ("^[" == ostr)))
{
throw "error: ^[ detected inside compile-replace regular expression";
}
if ((input_side && ("^]" == istr)) || (!input_side && ("^]" == ostr)))
{
/*if (istr != ostr)
{
throw "error: ^] detected on only one side of transition inside compile-replace regular expression";
}*/
return true;
}
return false;
// weights?
// flag diacritics?
}
// If there is a "^[":"^[" transition leading to state \a s from some state
// S and state S is included in \a states_visited and \a path and \a full_paths
// are empty, this function can be used to find all (sub-)paths of form
// [x:y]* "^]" (x and y cannot be "^]" or "^[") starting from state \a s. The resulting
// paths are stored in \a full_paths. \a path is used to keep track of each path so
// far. Weights are currently ignored.
HFSTDLL void find_regexp_paths
(HfstState s,
std::set<HfstState> & states_visited,
std::vector<std::pair<std::string, std::string> > & path,
HfstReplacements & full_paths, bool input_side)
{
// no cycles allowed inside "^[" and "^]"
check_regexp_state_for_cycle(s, states_visited);
states_visited.insert(s);
// go through all transitions
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](s);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
// closing bracket..
if (check_regexp_transition_end(*it, input_side)) // throws error message if *it is not a valid transition
{
// ..cannot lead to a state already visited..
check_regexp_state_for_cycle(it->get_target_state(), states_visited);
// ..but else we can add the expression that it ends to the results
path.push_back(std::pair<std::string, std::string>(it->get_input_symbol(), it->get_output_symbol()));
full_paths.push_back
(HfstReplacement(it->get_target_state(), path));
path.pop_back(); // remove closing bracket as we are not going to proceed to next state
}
// add transition to path and call function again for its target state
else
{
path.push_back(StringPair(it->get_input_symbol(), it->get_output_symbol()));
find_regexp_paths
(it->get_target_state(),
states_visited,
path,
full_paths, input_side);
path.pop_back();
}
}
// all transitions gone through
states_visited.erase(s);
}
// For each "^[":"^[" transition in state \a s, find continuing paths of form [x:y]* "^]":"^]"
// (where x and y can freely be any symbols except "^]" or "^[") and store those paths in \a full_paths
// vector where the first member of each element is the state where the ending "^]":"^]" transition
// leads to and the second element is a vector of transitions (i.e. string pairs) without the ending
// "^]":"^]" transition.
// An error is thrown if mismatched "^[" or "^]" symbols, special symbols (epsilon, unknown, identity),
// or loops are encountered on a regexp path. Final states are allowed on regexp paths as they are also
// allowed by Xerox tools.
// Weights are currently ignored.
HFSTDLL void find_regexp_paths
(HfstState s,
std::vector<std::pair<HfstState, std::vector<std::pair<std::string, std::string> > > > & full_paths,
bool input_side)
{
// go through all transitions
const HfstBasicTransducer::HfstTransitions &transitions
= this->operator[](s);
for (HfstBasicTransducer::HfstTransitions::const_iterator it
= transitions.begin();
it != transitions.end(); it++)
{
std::string istr = it->get_input_symbol();
std::string ostr = it->get_output_symbol();
if ((input_side && ("^[" == istr)) || (!input_side && ("^[" == ostr)))
{
/*if (istr != ostr)
{
throw "error: ^[ detected on only one side of transition";
}*/
std::set<HfstState> states_visited;
states_visited.insert(s);
std::vector<std::pair<std::string, std::string> > path;
path.push_back(std::pair<std::string, std::string>(istr, ostr));
find_regexp_paths(it->get_target_state(), states_visited, path, full_paths, input_side);
//fprintf(stderr, "%u regexp paths found for state %u\n", (unsigned int)full_paths.size(), s); // debug
}
}
}
// Find all subpaths of form "^[" [x:y]* "^]" (x and y cannot be "^[" or "^]") and return them.
// retval[start_state] == vector(pair(end_state, vector(pair(isymbol,osymbol) ) ) )
// Weights are currently ignored.
HFSTDLL HfstReplacementsMap find_replacements(bool input_side)
{
HfstReplacementsMap replacements;
unsigned int state = 0;
for (iterator it = begin(); it != end(); it++)
{
//fprintf(stderr, "state %u......\n", state); // debug
HfstReplacements full_paths;
find_regexp_paths(state, full_paths, input_side);
if (full_paths.size() > 0)
{
replacements[state] = full_paths;
}
state++;
}
return replacements;
}
// Attach a copy of \a graph between states \a state1 and \a state2 with epsilon transitions.
// There will be an epsilon transition with weight zero from state \a state1 to the
// initial state of \a graph and one epsilon transition from each final state of
// \a graph to state \a state2 with a weight of that state's final weight. Final states of
// \a graph as well as its initial state are made normal non-final states when copying \a graph.
// Todo: copy alphabet? harmonize graphs?
HFSTDLL void insert_transducer(HfstState state1, HfstState state2, const HfstTransitionGraph & graph)
{
HfstState offset = add_state();
HfstState source_state=0;
for (const_iterator it = graph.begin();
it != graph.end(); it++)
{
for (typename HfstTransitions::const_iterator tr_it
= it->begin();
tr_it != it->end(); tr_it++)
{
C data = tr_it->get_transition_data();
HfstTransition <C> transition
(tr_it->get_target_state() + offset,
data.get_input_symbol(),
data.get_output_symbol(),
data.get_weight());
add_transition(source_state + offset, transition);
}
source_state++;
}
// Epsilon transitions
for (typename FinalWeightMap::const_iterator it
= graph.final_weight_map.begin();
it != graph.final_weight_map.end(); it++)
{
HfstTransition <C> epsilon_transition
(state2, C::get_epsilon(), C::get_epsilon(),
it->second);
add_transition(it->first + offset, epsilon_transition);
}
// Initial transition
HfstTransition <C> epsilon_transition
(offset, C::get_epsilon(), C::get_epsilon(), 0);
add_transition(state1, epsilon_transition);
}
typedef std::pair<HfstState, HfstState> StatePair;
typedef std::map<StatePair, HfstState> StateMap;
// Find target state corresponding to state pair \a target1, \a target2 in \a state_map and return that state.
// If not found, add a new state to \a intersection, add it to \a state_map and return it.
// \a was_new_state specifies whether a new state was added.
static HfstState find_target_state
(HfstState target1, HfstState target2, StateMap & state_map,
HfstTransitionGraph & intersection, bool & was_new_state)
{
StatePair state_pair(target1, target2);
StateMap::const_iterator it = state_map.find(state_pair);
if (it != state_map.end())
{
was_new_state=false;
return it->second;
}
HfstState retval = intersection.add_state();
state_map[state_pair] = retval;
was_new_state=true;
return retval;
}
// A function used by find_matches.
// Copy matching transition tr1/tr2 to state \a state in \a intersection and return
// the target state of that transition. Also make that state final, if needed.
HFSTDLL static HfstState handle_match(const HfstTransitionGraph & graph1, const HfstTransition <C> & tr1,
const HfstTransitionGraph & graph2, const HfstTransition <C> & tr2,
HfstTransitionGraph & intersection, HfstState state, StateMap & state_map)
{
HfstState target1 = tr1.get_target_state();
HfstState target2 = tr2.get_target_state();
bool was_new_state = false;
HfstState retval = find_target_state
(target1, target2, state_map, intersection, was_new_state);
// The sum of weight is copied to the resulting intersection.
float transition_weight = tr1.get_weight() + tr2.get_weight();
intersection.add_transition
(state, HfstTransition <C>
(retval, tr1.get_input_symbol(), tr1.get_output_symbol(), transition_weight));
// For each new state added, check if the corresponding states in \a graph1 and \a graph2
// are final. If they are, make the new state final with the sum of final weights.
if (was_new_state && (graph1.is_final_state(target1) && graph2.is_final_state(target2)))
{
float final_weight = graph1.get_final_weight(target1) + graph2.get_final_weight(target2);
intersection.set_final_weight(retval, final_weight);
}
return retval;
}
// A recursive function used by function intersect.
//
// @param graph1 The first transducer argument of intersection.
// @param state1 The current state of \a graph1.
// @param graph2 The second transducer argument of intersection.
// @param state2 The current state of \a graph2.
// @param intersection The intersection of \a graph1 and \a graph2.
// @param state The current state of \a intersection.
// @param state_map State pairs from \a graph1 and \a graph2 mapped to states in \a intersection.
// @param agenda States in \a intersection already handled or scheduled to be handled.
//
// @pre \a graph1 and \a graph2 must be arc-sorted (via sort_arcs()) to make transition matching faster.
// @pre \a graph1 and \a graph2 must be deterministic. (todo: handle equivalent transitions, maybe even epsilons?)
HFSTDLL static void find_matches
(HfstTransitionGraph & graph1, HfstState state1, HfstTransitionGraph & graph2, HfstState state2,
HfstTransitionGraph & intersection, HfstState state, StateMap & state_map, std::set<HfstState> & agenda)
{
agenda.insert(state); // do not handle \a state twice
HfstTransitions & tr1 = graph1.state_vector[state1]; // transitions of graph1
HfstTransitions & tr2 = graph2.state_vector[state2]; // transitions of graph2
if (tr1.size() == 0 || tr2.size() == 0)
{
return; // we cannot proceed as no matches are possible
}
unsigned int start_search_from=0; // where to start search in tr2
// *** Go through all transitions of state \a state1 in \a graph1 and try to find a match in
// transitions of state \a state2 in \a graph2. As transitions are sorted, we know that
// if a match is found for tr1[i] in tr2[j], a match for tr1[i+1] can be searched starting from
// tr2[j+1]. If no match is found for tr1[i] in tr2 but tr2[j] is the first element that is bigger
// than tr1[i], a match for tr1[i+1] can be searched starting from tr2[j]. ***
for (unsigned int i=0; i < tr1.size(); i++)
{
HfstTransition <C> & transition1 = tr1[i];
// Transition data (input and output symbols) to be compared.
const C & transition_data1 = transition1.get_transition_data();
// --- Go through tr2 starting from start_search_from. ---
for(unsigned int j=start_search_from; j < tr2.size(); j++)
{
HfstTransition <C> & transition2 = tr2[j];
// Transition data (input and output symbols) to be compared.
const C & transition_data2 = transition2.get_transition_data();
// todo: input:output duplicates with different weights? (lower weight is chosen always?)
if (transition_data2.less_than_ignore_weight(transition_data1))
{
// no match found, continue searching
}
else if (transition_data1.less_than_ignore_weight(transition_data2))
{
// No match can be found, start searching for next item in tr1
// starting from current item of tr2.
start_search_from=j;
break;
}
else
{
// Match found, copy transitions and define target state in intersection
HfstState target = handle_match(graph1, transition1, graph2, transition2, intersection, state, state_map);
// Recursive call for target state, if it is not already on the agenda.
if (agenda.find(target) == agenda.end())
{
find_matches(graph1, transition1.get_target_state(), graph2, transition2.get_target_state(), intersection, target, state_map, agenda);
}
// Start searching for next item in tr1 starting from next item of tr2.
start_search_from=j+1;
break;
}
}
// --- A transition in tr1 compared for all possible transitions in tr2, compare next transition. ---
}
// *** All transitions in tr1 gone through. ***
return;
}
HFSTDLL static HfstTransitionGraph intersect
(HfstTransitionGraph & graph1, HfstTransitionGraph & graph2)
{
HfstTransitionGraph retval;
StateMap state_map;
std::set<HfstState> agenda;
graph1.sort_arcs();
graph2.sort_arcs();
state_map[StatePair(0, 0)] = 0; // initial states
if (graph1.is_final_state(0) && graph2.is_final_state(0))
{
float final_weight = std::min(graph1.get_final_weight(0), graph2.get_final_weight(0));
retval.set_final_weight(0, final_weight);
}
find_matches(graph1, 0, graph2, 0, retval, 0, state_map, agenda);
return retval;
}
// A function used by find_matches_for_merge
// Copy matching transition graph_tr/merger_tr to state \a result_state in \a result and return
// the target state of that transition. Also make that state final, if needed.
HFSTDLL static HfstState handle_non_list_match(const HfstTransitionGraph & graph, const HfstTransition <C> & graph_transition,
const HfstTransitionGraph & merger, HfstState merger_target,
HfstTransitionGraph & result, HfstState result_state, StateMap & state_map)
{
HfstState graph_target = graph_transition.get_target_state();
bool was_new_state = false;
HfstState retval = find_target_state
(graph_target, merger_target, state_map, result, was_new_state);
result.add_transition
(result_state, HfstTransition <C>
(retval, graph_transition.get_input_symbol(), graph_transition.get_output_symbol(), graph_transition.get_weight()));
// For each new state added, check if the corresponding states in \a graph and \a merger
// are final. If they are, make the new state final with the sum of final weights.
if (was_new_state && (graph.is_final_state(graph_target) && merger.is_final_state(merger_target)))
{
float final_weight = graph.get_final_weight(graph_target) + merger.get_final_weight(merger_target);
result.set_final_weight(retval, final_weight);
}
return retval;
}
// A function used by find_matches_for_merge
// Copy matching transition graph_tr/merger_tr to state \a result_state in \a result and return
// the target state of that transition. Also make that state final, if needed.
HFSTDLL static HfstState handle_list_match(const HfstTransitionGraph & graph, const HfstTransition <C> & graph_transition,
const HfstTransitionGraph & merger, const HfstTransition <C> & merger_transition,
HfstTransitionGraph & result, HfstState result_state, StateMap & state_map, std::set<std::string> & markers_added)
{
HfstState graph_target = graph_transition.get_target_state();
HfstState merger_target = merger_transition.get_target_state();
bool was_new_state = false;
HfstState retval = find_target_state
(graph_target, merger_target, state_map, result, was_new_state);
// The sum of weight is copied to the resulting intersection.
float transition_weight = graph_transition.get_weight() + merger_transition.get_weight();
// testing: add a marker
HfstState extra_state = result.add_state();
result.add_transition
(result_state, HfstTransition <C>
(extra_state, "@" + graph_transition.get_input_symbol() + "@", "@" + graph_transition.get_output_symbol() + "@", 0));
markers_added.insert("@" + graph_transition.get_input_symbol() + "@");
result.add_transition
(extra_state /*result_state*/, HfstTransition <C>
(retval, merger_transition.get_input_symbol(), merger_transition.get_output_symbol(), transition_weight));
// For each new state added, check if the corresponding states in \a graph1 and \a graph2
// are final. If they are, make the new state final with the sum of final weights.
if (was_new_state && (graph.is_final_state(graph_target) && merger.is_final_state(merger_target)))
{
float final_weight = graph.get_final_weight(graph_target) + merger.get_final_weight(merger_target);
result.set_final_weight(retval, final_weight);
}
return retval;
}
HFSTDLL static bool is_list_symbol(const C & transition_data, const std::map<std::string, std::set<std::string> > & list_symbols)
{
std::string isymbol = transition_data.get_input_symbol();
std::string osymbol = transition_data.get_output_symbol();
if (isymbol != osymbol)
{
throw "is_list_symbol: input and output symbols must be the same";
}
return (list_symbols.find(isymbol) != list_symbols.end());
}
/*
// @pre \a transition_data is a list symbol
// @pre list symbols cannot contain '_' or '@'
static std::set<std::string> get_list_symbols(const std::string & list_symbol)
{
std::set<std::string> result;
unsigned int i = 6;
// skip list name
while(list_symbol[i] != '_')
{
i++;
}
i++;
// extract symbols
std::string symbol("");
while (list_symbol[i] != '@')
{
if (list_symbol[i] == '_')
{
result.insert(symbol);
symbol = std::string("");
}
else
{
symbol.append(1, list_symbol[i]);
}
i++;
}
result.insert(symbol);
return result;
}*/
// A recursive function used by function intersect.
//
// @param graph The first transducer argument of intersection.
// @param graph_state The current state of \a graph1.
// @param merger The second transducer argument of intersection.
// @param merger_state The current state of \a graph2.
// @param result The intersection of \a graph1 and \a graph2.
// @param result_state The current state of \a intersection.
// @param state_map State pairs from \a graph and \a merger mapped to states in \a result.
// @param agenda States in \a result already handled or scheduled to be handled.
//
// @pre \a graph and \a merger must be arc-sorted (via sort_arcs()) to make transition matching faster.
// @pre \a graph and \a merger must be deterministic. (todo: handle equivalent transitions, maybe even epsilons?)
HFSTDLL static void find_matches_for_merge
(HfstTransitionGraph & graph, HfstState graph_state, HfstTransitionGraph & merger, HfstState merger_state,
HfstTransitionGraph & result, HfstState result_state, StateMap & state_map, std::set<HfstState> & agenda,
const std::map<std::string, std::set<std::string> > & list_symbols, std::set<std::string> & markers_added)
{
agenda.insert(result_state); // do not handle \a result_state twice
HfstTransitions & graph_transitions = graph.state_vector[graph_state]; // transitions of graph
HfstTransitions & merger_transitions = merger.state_vector[merger_state]; // transitions of merger
if (graph_transitions.size() == 0)
{
return; // we cannot proceed as no matches are possible
}
// Go through all transitions in state \a graph_state of \a graph.
for (unsigned int i=0; i < graph_transitions.size(); i++)
{
HfstTransition <C> & graph_transition = graph_transitions[i];
const C & graph_transition_data = graph_transition.get_transition_data();
// List symbols must be checked separately
if (is_list_symbol(graph_transition_data, list_symbols))
{
const std::set<std::string> & symbol_list = list_symbols.find(graph_transition_data.get_input_symbol())->second;
bool list_match_found=false;
// Find all matches
for(unsigned int j=0; j < merger_transitions.size(); j++)
{
HfstTransition <C> & merger_transition = merger_transitions[j];
const C & merger_transition_data = merger_transition.get_transition_data();
const std::string & isymbol = merger_transition_data.get_input_symbol();
const std::string & osymbol = merger_transition_data.get_output_symbol();
if (isymbol != osymbol)
{
throw "find_matches_for_merge: input and output symbols must be the same";
}
if (symbol_list.find(isymbol) != symbol_list.end())
{
list_match_found=true;
HfstState target = handle_list_match(graph, graph_transition, merger, merger_transition, result, result_state, state_map, markers_added);
if (agenda.find(target) == agenda.end())
{
find_matches_for_merge(graph, graph_transition.get_target_state(), merger, merger_transition.get_target_state(), result, target, state_map, agenda, list_symbols, markers_added);
}
}
}
if (list_match_found)
{
continue;
}
}
// If symbol is not a list symbol or no match was found for it, copy symbol as such
// We use merger_state as merger transition target state
HfstState target = handle_non_list_match(graph, graph_transition, merger, merger_state, result, result_state, state_map);
if (agenda.find(target) == agenda.end())
{
find_matches_for_merge(graph, graph_transition.get_target_state(), merger, /*merger_transition.get_target_state()*/ merger_state, result, target, state_map, agenda, list_symbols, markers_added);
}
// --- A transition in graph compared for all corresponding transitions in merger, compare next transition. ---
}
// *** All transitions in state gone through. ***
return;
}
HFSTDLL static HfstTransitionGraph merge
(HfstTransitionGraph & graph, HfstTransitionGraph & merger, const std::map<std::string, std::set<std::string> > & list_symbols, std::set<std::string> & markers_added)
{
HfstTransitionGraph result;
StateMap state_map;
std::set<HfstState> agenda;
graph.sort_arcs();
merger.sort_arcs();
state_map[StatePair(0, 0)] = 0; // initial states
if (graph.is_final_state(0) && merger.is_final_state(0))
{
float final_weight = graph.get_final_weight(0) + merger.get_final_weight(0);
result.set_final_weight(0, final_weight);
}
try
{
find_matches_for_merge(graph, 0, merger, 0, result, 0, state_map, agenda, list_symbols, markers_added);
}
catch (const char * msg)
{
HFST_THROW_MESSAGE(TransducersAreNotAutomataException, std::string(msg));
}
return result;
}
/* /\** @brief Determine whether this graph has input-epsilon cycles. */
/* *\/ */
/* bool has_input_epsilon_cycles(void) */
/* { */
/* typedef std::map<HfstState, */
/* std::set<HfstTransition<C> > > */
/* HfstStates; */
/* HfstStates state_map; */
/* std::set<HfstState> total_seen; */
/* for (state_vector::iterator it = state_vector.begin(); */
/* it != state_vector.end(); ++it) { */
/* if (total_seen.count(*it) != 0) { */
/* continue; */
/* } */
/* } */
/* } */
// --- Friends ---
friend class ConversionFunctions;
friend class hfst::HarmonizeUnknownAndIdentitySymbols;
};
/** @brief An HfstTransitionGraph with transitions of type
HfstTropicalTransducerTransitionData and weight type float.
This is probably the most useful kind of HfstTransitionGraph. */
typedef HfstTransitionGraph <HfstTropicalTransducerTransitionData>
HfstBasicTransducer;
/** @brief A specialization for faster conversion. */
//typedef HfstTransitionGraph <HfstFastTransitionData>
// HfstFastTransducer;
}
}
#endif // #ifndef _HFST_TRANSITION_GRAPH_H_
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