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#include <iostream>
#include <tr1/memory>
#include <queue>
#include <boost/multi_array.hpp>
#include <boost/program_options.hpp>
#include <boost/program_options/variables_map.hpp>
#include "base_measures.h"
#include "monotonic_pseg.h"
#include "trule.h"
#include "tdict.h"
#include "filelib.h"
#include "dict.h"
#include "sampler.h"
#include "ccrp_nt.h"
#include "corpus.h"
using namespace std;
using namespace std::tr1;
namespace po = boost::program_options;
static unsigned kMAX_SRC_PHRASE;
static unsigned kMAX_TRG_PHRASE;
void InitCommandLine(int argc, char** argv, po::variables_map* conf) {
po::options_description opts("Configuration options");
opts.add_options()
("samples,s",po::value<unsigned>()->default_value(1000),"Number of samples")
("input,i",po::value<string>(),"Read parallel data from")
("max_src_phrase",po::value<unsigned>()->default_value(4),"Maximum length of source language phrases")
("max_trg_phrase",po::value<unsigned>()->default_value(4),"Maximum length of target language phrases")
("model1,m",po::value<string>(),"Model 1 parameters (used in base distribution)")
("model1_interpolation_weight",po::value<double>()->default_value(0.95),"Mixing proportion of model 1 with uniform target distribution")
("random_seed,S",po::value<uint32_t>(), "Random seed");
po::options_description clo("Command line options");
clo.add_options()
("config", po::value<string>(), "Configuration file")
("help,h", "Print this help message and exit");
po::options_description dconfig_options, dcmdline_options;
dconfig_options.add(opts);
dcmdline_options.add(opts).add(clo);
po::store(parse_command_line(argc, argv, dcmdline_options), *conf);
if (conf->count("config")) {
ifstream config((*conf)["config"].as<string>().c_str());
po::store(po::parse_config_file(config, dconfig_options), *conf);
}
po::notify(*conf);
if (conf->count("help") || (conf->count("input") == 0)) {
cerr << dcmdline_options << endl;
exit(1);
}
}
shared_ptr<MT19937> prng;
template <typename Base>
struct ModelAndData {
explicit ModelAndData(MonotonicParallelSegementationModel& m, const Base& b, const vector<vector<int> >& ce, const vector<vector<int> >& cf, const set<int>& ve, const set<int>& vf) :
model(m),
rng(&*prng),
p0(b),
baseprob(prob_t::One()),
corpuse(ce),
corpusf(cf),
vocabe(ve),
vocabf(vf),
mh_samples(),
mh_rejects(),
kX(-TD::Convert("X")),
derivations(corpuse.size()) {}
void ResampleHyperparameters() {
}
void InstantiateRule(const pair<short,short>& from,
const pair<short,short>& to,
const vector<int>& sentf,
const vector<int>& sente,
TRule* rule) const {
rule->f_.clear();
rule->e_.clear();
rule->lhs_ = kX;
for (short i = from.first; i < to.first; ++i)
rule->f_.push_back(sentf[i]);
for (short i = from.second; i < to.second; ++i)
rule->e_.push_back(sente[i]);
}
void DecrementDerivation(const vector<pair<short,short> >& d, const vector<int>& sentf, const vector<int>& sente) {
if (d.size() < 2) return;
TRule x;
for (int i = 1; i < d.size(); ++i) {
InstantiateRule(d[i], d[i-1], sentf, sente, &x);
model.DecrementRule(x);
model.DecrementContinue();
}
model.DecrementStop();
}
void PrintDerivation(const vector<pair<short,short> >& d, const vector<int>& sentf, const vector<int>& sente) {
if (d.size() < 2) return;
TRule x;
for (int i = 1; i < d.size(); ++i) {
InstantiateRule(d[i], d[i-1], sentf, sente, &x);
cerr << i << '/' << (d.size() - 1) << ": " << x << endl;
}
}
void IncrementDerivation(const vector<pair<short,short> >& d, const vector<int>& sentf, const vector<int>& sente) {
if (d.size() < 2) return;
TRule x;
for (int i = 1; i < d.size(); ++i) {
InstantiateRule(d[i], d[i-1], sentf, sente, &x);
model.IncrementRule(x);
model.IncrementContinue();
}
model.IncrementStop();
}
prob_t Likelihood() const {
return model.Likelihood();
}
prob_t DerivationProposalProbability(const vector<pair<short,short> >& d, const vector<int>& sentf, const vector<int>& sente) const {
prob_t p = model.StopProbability();
if (d.size() < 2) return p;
TRule x;
const prob_t p_cont = model.ContinueProbability();
for (int i = 1; i < d.size(); ++i) {
InstantiateRule(d[i], d[i-1], sentf, sente, &x);
p *= p_cont;
p *= model.RuleProbability(x);
}
return p;
}
void Sample();
MonotonicParallelSegementationModel& model;
MT19937* rng;
const Base& p0;
prob_t baseprob; // cached value of generating the table table labels from p0
// this can't be used if we go to a hierarchical prior!
const vector<vector<int> >& corpuse, corpusf;
const set<int>& vocabe, vocabf;
unsigned mh_samples, mh_rejects;
const int kX;
vector<vector<pair<short, short> > > derivations;
};
template <typename Base>
void ModelAndData<Base>::Sample() {
unsigned MAXK = kMAX_SRC_PHRASE;
unsigned MAXL = kMAX_TRG_PHRASE;
TRule x;
x.lhs_ = -TD::Convert("X");
for (int samples = 0; samples < 1000; ++samples) {
if (samples % 1 == 0 && samples > 0) {
//ResampleHyperparameters();
cerr << " [" << samples << " LLH=" << log(Likelihood()) << " MH=" << ((double)mh_rejects / mh_samples) << "]\n";
for (int i = 0; i < 10; ++i) {
cerr << "SENTENCE: " << TD::GetString(corpusf[i]) << " ||| " << TD::GetString(corpuse[i]) << endl;
PrintDerivation(derivations[i], corpusf[i], corpuse[i]);
}
}
cerr << '.' << flush;
for (int s = 0; s < corpuse.size(); ++s) {
const vector<int>& sentf = corpusf[s];
const vector<int>& sente = corpuse[s];
// cerr << " CUSTOMERS: " << rules.num_customers() << endl;
// cerr << "SENTENCE: " << TD::GetString(sentf) << " ||| " << TD::GetString(sente) << endl;
vector<pair<short, short> >& deriv = derivations[s];
const prob_t p_cur = Likelihood();
DecrementDerivation(deriv, sentf, sente);
boost::multi_array<prob_t, 2> a(boost::extents[sentf.size() + 1][sente.size() + 1]);
boost::multi_array<prob_t, 4> trans(boost::extents[sentf.size() + 1][sente.size() + 1][MAXK][MAXL]);
a[0][0] = prob_t::One();
const prob_t q_stop = model.StopProbability();
const prob_t q_cont = model.ContinueProbability();
for (int i = 0; i < sentf.size(); ++i) {
for (int j = 0; j < sente.size(); ++j) {
const prob_t src_a = a[i][j];
x.f_.clear();
for (int k = 1; k <= MAXK; ++k) {
if (i + k > sentf.size()) break;
x.f_.push_back(sentf[i + k - 1]);
x.e_.clear();
for (int l = 1; l <= MAXL; ++l) {
if (j + l > sente.size()) break;
x.e_.push_back(sente[j + l - 1]);
const bool stop_now = ((j + l) == sente.size()) && ((i + k) == sentf.size());
const prob_t& cp = stop_now ? q_stop : q_cont;
trans[i][j][k - 1][l - 1] = model.RuleProbability(x) * cp;
a[i + k][j + l] += src_a * trans[i][j][k - 1][l - 1];
}
}
}
}
// cerr << "Inside: " << log(a[sentf.size()][sente.size()]) << endl;
const prob_t q_cur = DerivationProposalProbability(deriv, sentf, sente);
vector<pair<short,short> > newderiv;
int cur_i = sentf.size();
int cur_j = sente.size();
while(cur_i > 0 && cur_j > 0) {
newderiv.push_back(pair<short,short>(cur_i, cur_j));
// cerr << "NODE: (" << cur_i << "," << cur_j << ")\n";
SampleSet<prob_t> ss;
vector<pair<short,short> > nexts;
for (int k = 1; k <= MAXK; ++k) {
const int hyp_i = cur_i - k;
if (hyp_i < 0) break;
for (int l = 1; l <= MAXL; ++l) {
const int hyp_j = cur_j - l;
if (hyp_j < 0) break;
const prob_t& inside = a[hyp_i][hyp_j];
if (inside == prob_t::Zero()) continue;
const prob_t& transp = trans[hyp_i][hyp_j][k - 1][l - 1];
if (transp == prob_t::Zero()) continue;
const prob_t p = inside * transp;
ss.add(p);
nexts.push_back(pair<short,short>(hyp_i, hyp_j));
// cerr << " (" << hyp_i << "," << hyp_j << ") <--- " << log(p) << endl;
}
}
// cerr << " sample set has " << nexts.size() << " elements.\n";
const int selected = rng->SelectSample(ss);
cur_i = nexts[selected].first;
cur_j = nexts[selected].second;
}
newderiv.push_back(pair<short,short>(0,0));
const prob_t q_new = DerivationProposalProbability(newderiv, sentf, sente);
IncrementDerivation(newderiv, sentf, sente);
// cerr << "SANITY: " << q_new << " " <<log(DerivationProposalProbability(newderiv, sentf, sente)) << endl;
if (deriv.empty()) { deriv = newderiv; continue; }
++mh_samples;
if (deriv != newderiv) {
const prob_t p_new = Likelihood();
// cerr << "p_cur=" << log(p_cur) << "\t p_new=" << log(p_new) << endl;
// cerr << "q_cur=" << log(q_cur) << "\t q_new=" << log(q_new) << endl;
if (!rng->AcceptMetropolisHastings(p_new, p_cur, q_new, q_cur)) {
++mh_rejects;
DecrementDerivation(newderiv, sentf, sente);
IncrementDerivation(deriv, sentf, sente);
} else {
// cerr << " ACCEPT\n";
deriv = newderiv;
}
}
}
}
}
int main(int argc, char** argv) {
po::variables_map conf;
InitCommandLine(argc, argv, &conf);
kMAX_TRG_PHRASE = conf["max_trg_phrase"].as<unsigned>();
kMAX_SRC_PHRASE = conf["max_src_phrase"].as<unsigned>();
if (!conf.count("model1")) {
cerr << argv[0] << "Please use --model1 to specify model 1 parameters\n";
return 1;
}
if (conf.count("random_seed"))
prng.reset(new MT19937(conf["random_seed"].as<uint32_t>()));
else
prng.reset(new MT19937);
// MT19937& rng = *prng;
vector<vector<int> > corpuse, corpusf;
set<int> vocabe, vocabf;
corpus::ReadParallelCorpus(conf["input"].as<string>(), &corpusf, &corpuse, &vocabf, &vocabe);
cerr << "f-Corpus size: " << corpusf.size() << " sentences\n";
cerr << "f-Vocabulary size: " << vocabf.size() << " types\n";
cerr << "f-Corpus size: " << corpuse.size() << " sentences\n";
cerr << "f-Vocabulary size: " << vocabe.size() << " types\n";
assert(corpusf.size() == corpuse.size());
Model1 m1(conf["model1"].as<string>());
PhraseJointBase lp0(m1, conf["model1_interpolation_weight"].as<double>(), vocabe.size(), vocabf.size());
MonotonicParallelSegementationModel m(lp0);
ModelAndData<PhraseJointBase> posterior(m, lp0, corpuse, corpusf, vocabe, vocabf);
posterior.Sample();
return 0;
}
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