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#include <iostream>
#include "config.h"
#ifndef HAVE_EIGEN
int main() { std::cerr << "Please rebuild with --with-eigen PATH\n"; return 1; }
#else
#include <cstdlib>
#include <algorithm>
#include <cmath>
#include <set>
#include <cstring> // memset
#include <ctime>
#include <boost/program_options.hpp>
#include <boost/program_options/variables_map.hpp>
#include <Eigen/Dense>
#include "array2d.h"
#include "m.h"
#include "lattice.h"
#include "stringlib.h"
#include "filelib.h"
#include "tdict.h"
namespace po = boost::program_options;
using namespace std;
#define kDIMENSIONS 25
typedef Eigen::Matrix<float, kDIMENSIONS, 1> RVector;
typedef Eigen::Matrix<float, 1, kDIMENSIONS> RTVector;
typedef Eigen::Matrix<float, kDIMENSIONS, kDIMENSIONS> TMatrix;
vector<RVector> r_src, r_trg;
bool InitCommandLine(int argc, char** argv, po::variables_map* conf) {
po::options_description opts("Configuration options");
opts.add_options()
("input,i",po::value<string>(),"Input file")
("iterations,I",po::value<unsigned>()->default_value(1000),"Number of iterations of training")
("eta,e", po::value<float>()->default_value(0.1f), "Eta for SGD")
("random_seed", po::value<unsigned>(), "Random seed")
("diagonal_tension,T", po::value<double>()->default_value(4.0), "How sharp or flat around the diagonal is the alignment distribution (0 = uniform, >0 sharpens)")
("testset,x", po::value<string>(), "After training completes, compute the log likelihood of this set of sentence pairs under the learned model");
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 (argc < 2 || conf->count("help")) {
cerr << "Usage " << argv[0] << " [OPTIONS] -i corpus.fr-en\n";
cerr << dcmdline_options << endl;
return false;
}
return true;
}
void Normalize(RVector* v) {
float norm = v->norm();
*v /= norm;
}
int main(int argc, char** argv) {
po::variables_map conf;
if (!InitCommandLine(argc, argv, &conf)) return 1;
const string fname = conf["input"].as<string>();
const int ITERATIONS = conf["iterations"].as<unsigned>();
const float eta = conf["eta"].as<float>();
const double diagonal_tension = conf["diagonal_tension"].as<double>();
bool SGD = true;
if (diagonal_tension < 0.0) {
cerr << "Invalid value for diagonal_tension: must be >= 0\n";
return 1;
}
string testset;
if (conf.count("testset")) testset = conf["testset"].as<string>();
unsigned lc = 0;
vector<double> unnormed_a_i;
string line;
string ssrc, strg;
bool flag = false;
Lattice src, trg;
vector<WordID> vocab_e;
{ // read through corpus, initialize int map, check lines are good
set<WordID> svocab_e;
cerr << "INITIAL READ OF " << fname << endl;
ReadFile rf(fname);
istream& in = *rf.stream();
while(getline(in, line)) {
++lc;
if (lc % 1000 == 0) { cerr << '.'; flag = true; }
if (lc %50000 == 0) { cerr << " [" << lc << "]\n" << flush; flag = false; }
ParseTranslatorInput(line, &ssrc, &strg);
LatticeTools::ConvertTextToLattice(ssrc, &src);
LatticeTools::ConvertTextToLattice(strg, &trg);
if (src.size() == 0 || trg.size() == 0) {
cerr << "Error: " << lc << "\n" << line << endl;
assert(src.size() > 0);
assert(trg.size() > 0);
}
if (src.size() > unnormed_a_i.size())
unnormed_a_i.resize(src.size());
for (unsigned i = 0; i < trg.size(); ++i) {
assert(trg[i].size() == 1);
svocab_e.insert(trg[i][0].label);
}
}
copy(svocab_e.begin(), svocab_e.end(), back_inserter(vocab_e));
}
if (flag) cerr << endl;
cerr << "Number of target word types: " << vocab_e.size() << endl;
const float num_examples = lc;
r_trg.resize(TD::NumWords() + 1);
r_src.resize(TD::NumWords() + 1);
if (conf.count("random_seed")) {
srand(conf["random_seed"].as<unsigned>());
} else {
unsigned seed = time(NULL);
cerr << "Random seed: " << seed << endl;
srand(seed);
}
TMatrix t = TMatrix::Random() / 100.0;
for (unsigned i = 1; i < r_trg.size(); ++i) {
r_trg[i] = RVector::Random();
r_src[i] = RVector::Random();
r_trg[i][i % kDIMENSIONS] = 0.5;
r_src[i][(i-1) % kDIMENSIONS] = 0.5;
Normalize(&r_trg[i]);
Normalize(&r_src[i]);
}
vector<set<unsigned> > trg_pos(TD::NumWords() + 1);
// do optimization
TMatrix g;
vector<TMatrix> exp_src;
vector<double> z_src;
for (int iter = 0; iter < ITERATIONS; ++iter) {
cerr << "ITERATION " << (iter + 1) << endl;
ReadFile rf(fname);
istream& in = *rf.stream();
double likelihood = 0;
double denom = 0.0;
lc = 0;
flag = false;
g *= 0;
while(getline(in, line)) {
++lc;
if (lc % 1000 == 0) { cerr << '.'; flag = true; }
if (lc %50000 == 0) { cerr << " [" << lc << "]\n" << flush; flag = false; }
ParseTranslatorInput(line, &ssrc, &strg);
LatticeTools::ConvertTextToLattice(ssrc, &src);
LatticeTools::ConvertTextToLattice(strg, &trg);
denom += trg.size();
exp_src.clear(); exp_src.resize(src.size(), TMatrix::Zero());
z_src.clear(); z_src.resize(src.size(), 0.0);
Array2D<TMatrix> exp_refs(src.size(), trg.size(), TMatrix::Zero());
Array2D<double> z_refs(src.size(), trg.size(), 0.0);
for (unsigned j = 0; j < trg.size(); ++j)
trg_pos[trg[j][0].label].insert(j);
for (unsigned i = 0; i < src.size(); ++i) {
const RVector& r_s = r_src[src[i][0].label];
const RTVector pred = r_s.transpose() * t;
TMatrix& exp_m = exp_src[i];
double& z = z_src[i];
for (unsigned k = 0; k < vocab_e.size(); ++k) {
const WordID v_k = vocab_e[k];
const RVector& r_t = r_trg[v_k];
const double dot_prod = pred * r_t;
const double u = exp(dot_prod);
z += u;
const TMatrix v = r_s * r_t.transpose() * u;
exp_m += v;
set<unsigned>& ref_locs = trg_pos[v_k];
if (!ref_locs.empty()) {
for (set<unsigned>::iterator it = ref_locs.begin(); it != ref_locs.end(); ++it) {
TMatrix& exp_ref_ij = exp_refs(i, *it);
double& z_ref_ij = z_refs(i, *it);
z_ref_ij += u;
exp_ref_ij += v;
}
}
}
}
for (unsigned j = 0; j < trg.size(); ++j)
trg_pos[trg[j][0].label].clear();
// model expectations for a single target generation with
// uniform alignment prior
double m_z = 0;
TMatrix m_exp = TMatrix::Zero();
for (unsigned i = 0; i < src.size(); ++i) {
m_exp += exp_src[i];
m_z += z_src[i];
}
m_exp /= m_z;
Array2D<bool> al(src.size(), trg.size(), false);
for (unsigned j = 0; j < trg.size(); ++j) {
double ref_z = 0;
TMatrix ref_exp = TMatrix::Zero();
int max_i = 0;
double max_s = -9999999;
for (unsigned i = 0; i < src.size(); ++i) {
ref_exp += exp_refs(i, j);
ref_z += z_refs(i, j);
if (log(z_refs(i, j)) > max_s) {
max_s = log(z_refs(i, j));
max_i = i;
}
// TODO handle alignment prob
}
if (ref_z <= 0) {
cerr << "TRG=" << TD::Convert(trg[j][0].label) << endl;
cerr << " LINE=" << line << endl;
cerr << " REF_EXP=\n" << ref_exp << endl;
cerr << " M_EXP=\n" << m_exp << endl;
abort();
}
al(max_i, j) = true;
ref_exp /= ref_z;
g += m_exp - ref_exp;
likelihood += log(ref_z) - log(m_z);
if (SGD) {
t -= g * eta / num_examples;
g *= 0;
} else {
assert(!"not implemented");
}
}
if (iter == (ITERATIONS - 1) || lc == 28) { cerr << al << endl; }
}
if (flag) { cerr << endl; }
const double base2_likelihood = likelihood / log(2);
cerr << " log_e likelihood: " << likelihood << endl;
cerr << " log_2 likelihood: " << base2_likelihood << endl;
cerr << " cross entropy: " << (-base2_likelihood / denom) << endl;
cerr << " perplexity: " << pow(2.0, -base2_likelihood / denom) << endl;
cerr << t << endl;
}
cerr << "TRANSLATION MATRIX:" << endl << t << endl;
return 0;
}
#endif
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