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#include <sstream>
#include <iostream>
#include <fstream>
#include <vector>
#include <cassert>
#include <cmath>
#include <ctime>
#include <boost/program_options.hpp>
#include <boost/program_options/variables_map.hpp>
#include <boost/shared_ptr.hpp>
#include "config.h"
#include "stringlib.h"
#include "verbose.h"
#include "cllh_observer.h"
#include "hg.h"
#include "prob.h"
#include "inside_outside.h"
#include "ff_register.h"
#include "decoder.h"
#include "filelib.h"
#include "online_optimizer.h"
#include "fdict.h"
#include "weights.h"
#include "sparse_vector.h"
#include "sampler.h"
#ifdef HAVE_MPI
#include <boost/mpi/timer.hpp>
#include <boost/mpi.hpp>
namespace mpi = boost::mpi;
#endif
using namespace std;
namespace po = boost::program_options;
bool InitCommandLine(int argc, char** argv, po::variables_map* conf) {
po::options_description opts("Configuration options");
opts.add_options()
("weights,w",po::value<string>(), "Initial feature weights")
("training_data,d",po::value<string>(), "Training data corpus")
("test_data,t",po::value<string>(), "(optional) Test data")
("decoder_config,c",po::value<string>(), "Decoder configuration file")
("minibatch_size_per_proc,s", po::value<unsigned>()->default_value(8),
"Number of training instances evaluated per processor in each minibatch")
("max_passes", po::value<double>()->default_value(20.0), "Maximum number of passes through the data")
("max_walltime", po::value<unsigned>(), "Walltime to run (in minutes)")
("write_every_n_minibatches", po::value<unsigned>()->default_value(100), "Write weights every N minibatches processed")
("random_seed,S", po::value<uint32_t>(), "Random seed")
("regularization,r", po::value<string>()->default_value("none"),
"Regularization 'none', 'l1', or 'l2'")
("regularization_strength,C", po::value<double>(), "Regularization strength")
("eta,e", po::value<double>()->default_value(1.0), "Initial learning rate (eta)");
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("training_data") || !conf->count("decoder_config")) {
cerr << dcmdline_options << endl;
return false;
}
return true;
}
void ReadTrainingCorpus(const string& fname, int rank, int size, vector<string>* c, vector<int>* order) {
ReadFile rf(fname);
istream& in = *rf.stream();
string line;
int id = 0;
while(getline(in, line)) {
if (id % size == rank) {
c->push_back(line);
order->push_back(id);
}
++id;
}
}
static const double kMINUS_EPSILON = -1e-6;
struct TrainingObserver : public DecoderObserver {
void Reset() {
acc_grad.clear();
acc_obj = 0;
total_complete = 0;
}
virtual void NotifyDecodingStart(const SentenceMetadata&) {
cur_model_exp.clear();
cur_obj = 0;
state = 1;
}
// compute model expectations, denominator of objective
virtual void NotifyTranslationForest(const SentenceMetadata&, Hypergraph* hg) {
assert(state == 1);
state = 2;
const prob_t z = InsideOutside<prob_t,
EdgeProb,
SparseVector<prob_t>,
EdgeFeaturesAndProbWeightFunction>(*hg, &cur_model_exp);
cur_obj = log(z);
cur_model_exp /= z;
}
// compute "empirical" expectations, numerator of objective
virtual void NotifyAlignmentForest(const SentenceMetadata&, Hypergraph* hg) {
assert(state == 2);
state = 3;
SparseVector<prob_t> ref_exp;
const prob_t ref_z = InsideOutside<prob_t,
EdgeProb,
SparseVector<prob_t>,
EdgeFeaturesAndProbWeightFunction>(*hg, &ref_exp);
ref_exp /= ref_z;
double log_ref_z;
#if 0
if (crf_uniform_empirical) {
log_ref_z = ref_exp.dot(feature_weights);
} else {
log_ref_z = log(ref_z);
}
#else
log_ref_z = log(ref_z);
#endif
// rounding errors means that <0 is too strict
if ((cur_obj - log_ref_z) < kMINUS_EPSILON) {
cerr << "DIFF. ERR! log_model_z < log_ref_z: " << cur_obj << " " << log_ref_z << endl;
exit(1);
}
assert(!std::isnan(log_ref_z));
ref_exp -= cur_model_exp;
acc_grad += ref_exp;
acc_obj += (cur_obj - log_ref_z);
}
virtual void NotifyDecodingComplete(const SentenceMetadata&) {
if (state == 3) {
++total_complete;
} else {
}
}
void GetGradient(SparseVector<double>* g) const {
g->clear();
#if HAVE_CXX11
for (auto& gi : acc_grad) {
#else
for (FastSparseVector<prob_t>::const_iterator it = acc_grad.begin(); it != acc_grad.end(); ++it) {
pair<unsigned, double>& gi = *it;
#endif
g->set_value(gi.first, -gi.second.as_float());
}
}
int total_complete;
SparseVector<prob_t> cur_model_exp;
SparseVector<prob_t> acc_grad;
double acc_obj;
double cur_obj;
int state;
};
#ifdef HAVE_MPI
namespace boost { namespace mpi {
template<>
struct is_commutative<std::plus<SparseVector<double> >, SparseVector<double> >
: mpl::true_ { };
} } // end namespace boost::mpi
#endif
class AdaGradOptimizer {
public:
explicit AdaGradOptimizer(double e) :
eta(e),
G() {}
void update(const SparseVector<double>& g, vector<double>* x) {
if (x->size() > G.size()) G.resize(x->size(), 0.0);
#if HAVE_CXX11
for (auto& gi : g) {
#else
for (SparseVector<double>::const_iterator it = g.begin(); it != g.end(); ++it) {
const pair<unsigned,double>& gi = *it;
#endif
if (gi.second) {
G[gi.first] += gi.second * gi.second;
(*x)[gi.first] -= eta / sqrt(G[gi.first]) * gi.second;
}
}
}
const double eta;
vector<double> G;
};
class AdaGradL1Optimizer {
public:
explicit AdaGradL1Optimizer(double e, double l) :
t(),
eta(e),
lambda(l),
G() {}
void update(const SparseVector<double>& g, vector<double>* x) {
t += 1.0;
if (x->size() > G.size()) {
G.resize(x->size(), 0.0);
u.resize(x->size(), 0.0);
}
#if HAVE_CXX11
for (auto& gi : g) {
#else
for (SparseVector<double>::const_iterator it = g.begin(); it != g.end(); ++it) {
const pair<unsigned,double>& gi = *it;
#endif
if (gi.second) {
u[gi.first] += gi.second;
G[gi.first] += gi.second * gi.second;
double z = fabs(u[gi.first] / t) - lambda;
double s = 1;
if (u[gi.first] > 0) s = -1;
if (z > 0 && G[gi.first])
(*x)[gi.first] = eta * s * z * t / sqrt(G[gi.first]);
else
(*x)[gi.first] = 0.0;
}
}
}
double t;
const double eta;
const double lambda;
vector<double> G, u;
};
unsigned non_zeros(const vector<double>& x) {
unsigned nz = 0;
for (unsigned i = 0; i < x.size(); ++i)
if (x[i]) ++nz;
return nz;
}
int main(int argc, char** argv) {
#ifdef HAVE_MPI
mpi::environment env(argc, argv);
mpi::communicator world;
const int size = world.size();
const int rank = world.rank();
#else
const int size = 1;
const int rank = 0;
#endif
if (size > 1) SetSilent(true); // turn off verbose decoder output
register_feature_functions();
po::variables_map conf;
if (!InitCommandLine(argc, argv, &conf))
return 1;
ReadFile ini_rf(conf["decoder_config"].as<string>());
Decoder decoder(ini_rf.stream());
// load initial weights
vector<weight_t> init_weights;
if (conf.count("input_weights"))
Weights::InitFromFile(conf["input_weights"].as<string>(), &init_weights);
vector<string> corpus, test_corpus;
vector<int> ids;
ReadTrainingCorpus(conf["training_data"].as<string>(), rank, size, &corpus, &ids);
assert(corpus.size() > 0);
if (conf.count("test_data"))
ReadTrainingCorpus(conf["test_data"].as<string>(), rank, size, &corpus, &ids);
const unsigned size_per_proc = conf["minibatch_size_per_proc"].as<unsigned>();
if (size_per_proc > corpus.size()) {
cerr << "Minibatch size must be smaller than corpus size!\n";
return 1;
}
const double minibatch_size = size_per_proc * size;
size_t total_corpus_size = 0;
#ifdef HAVE_MPI
reduce(world, corpus.size(), total_corpus_size, std::plus<size_t>(), 0);
#else
total_corpus_size = corpus.size();
#endif
if (rank == 0)
cerr << "Total corpus size: " << total_corpus_size << endl;
boost::shared_ptr<MT19937> rng;
if (conf.count("random_seed"))
rng.reset(new MT19937(conf["random_seed"].as<uint32_t>()));
else
rng.reset(new MT19937);
double passes_per_minibatch = static_cast<double>(size_per_proc) / total_corpus_size;
int write_weights_every_ith = conf["write_every_n_minibatches"].as<unsigned>();
unsigned max_iteration = conf["max_passes"].as<double>() / passes_per_minibatch;
++max_iteration;
if (rank == 0)
cerr << "Max passes through data = " << conf["max_passes"].as<double>() << endl
<< " --> max minibatches = " << max_iteration << endl;
unsigned timeout = 0;
if (conf.count("max_walltime"))
timeout = 60 * conf["max_walltime"].as<unsigned>();
vector<weight_t>& lambdas = decoder.CurrentWeightVector();
if (init_weights.size()) {
lambdas.swap(init_weights);
init_weights.clear();
}
//AdaGradOptimizer adagrad(conf["eta"].as<double>());
AdaGradL1Optimizer adagrad(conf["eta"].as<double>(), conf["regularization_strength"].as<double>());
int iter = -1;
bool converged = false;
TrainingObserver observer;
ConditionalLikelihoodObserver cllh_observer;
const time_t start_time = time(NULL);
while (!converged) {
#ifdef HAVE_MPI
mpi::timer timer;
#endif
++iter;
observer.Reset();
if (rank == 0) {
converged = (iter == max_iteration);
string fname = "weights.cur.gz";
if (iter % write_weights_every_ith == 0) {
ostringstream o; o << "weights." << iter << ".gz";
fname = o.str();
}
const time_t cur_time = time(NULL);
if (timeout && ((cur_time - start_time) > timeout)) {
converged = true;
fname = "weights.final.gz";
}
ostringstream vv;
double minutes = (cur_time - start_time) / 60.0;
vv << "total walltime=" << minutes << "min iter=" << iter << " minibatch=" << size_per_proc << " sentences/proc x " << size << " procs. num_feats=" << non_zeros(lambdas) << '/' << FD::NumFeats() << " passes_thru_data=" << (iter * size_per_proc / static_cast<double>(corpus.size()));
const string svv = vv.str();
cerr << svv << endl;
Weights::WriteToFile(fname, lambdas, true, &svv);
}
for (int i = 0; i < size_per_proc; ++i) {
int ei = corpus.size() * rng->next();
int id = ids[ei];
decoder.SetId(id);
decoder.Decode(corpus[ei], &observer);
}
SparseVector<double> local_grad, g;
observer.GetGradient(&local_grad);
#ifdef HAVE_MPI
reduce(world, local_grad, g, std::plus<SparseVector<double> >(), 0);
#else
g.swap(local_grad);
#endif
local_grad.clear();
if (rank == 0) {
g /= minibatch_size;
lambdas.resize(FD::NumFeats(), 0.0); // might have seen new features
adagrad.update(g, &lambdas);
Weights::SanityCheck(lambdas);
Weights::ShowLargestFeatures(lambdas);
}
#ifdef HAVE_MPI
broadcast(world, lambdas, 0);
broadcast(world, converged, 0);
world.barrier();
if (rank == 0) { cerr << " ELAPSED TIME THIS ITERATION=" << timer.elapsed() << endl; }
#endif
}
cerr << "CONVERGED = " << converged << endl;
cerr << "EXITING...\n";
return 0;
}
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