ublas::vector<int> decodeBPSK(const ublas::vector<double> &rx) { ublas::vector<int> vHat(rx.size()); for (unsigned int i = 0; i < rx.size(); i++) { vHat(i) = 0.5 * (sign(rx(i)) + 1); } return vHat; }
const float NaoPose::getHomLength(const ublas::vector<float> &vec) { float sum = 0.0f; for (ublas::vector<float>::const_iterator i = vec.begin(); i != vec.end() - 1; ++i) { sum += *i * *i; } return sqrt(sum); }
/** * \f$U+=V \f$ where U and V are type * uvlas::vector<T> and you * want to specify WHERE to add * the DenseVector<T> V */ void addVector ( const ublas::vector<value_type>& V, const std::vector<size_type>& dof_indices ) { FEELPP_ASSERT ( V.size() == dof_indices.size() ).error( "invalid dof indices" ); for ( size_type i=0; i<V.size(); i++ ) this->add ( dof_indices[i], V( i ) ); }
double biterr(const ublas::vector<int> &u, const ublas::vector<int> &v) { int numErr = 0; for (unsigned int i = 0; i < u.size(); i++) { if (u(i) != v(i)) { numErr++; } } return static_cast<double>(numErr) / u.size(); }
ublas::vector<T> cross( const ublas::vector<T> &a, const ublas::vector<T> &b ) { BOOST_ASSERT(a.size() == 3); BOOST_ASSERT(b.size() == 3); ublas::vector<T> result(3); result(0) = a(1) * b(2) - a(2) * b(1); result(1) = a(2) * b(0) - a(0) * b(2); result(2) = a(0) * b(1) - a(1) * b(0); return result; }
void printVector(const ublas::vector<T> &u) { for (unsigned int i = 0; i < u.size(); i++) { std::cout << u(i); if (i + 1 < u.size()) { std::cout << ", "; } } std::cout << std::endl; }
ublas::vector<int> mod2(const ublas::vector<int> &u) { ublas::vector<int> v(u.size()); for (unsigned int i = 0; i < u.size(); i++) { v(i) = u(i) % 2; // modulus result can be negative if u(i) negative, depending on implementation if (v(i) < 0) { v(i) += 2; } } return v; }
void kronecker() { for (size_t i = 0; i < expectation_.size(); ++i) for (size_t j = 0; j <= i; ++j) covMatrix_(i, j) = expectation_(i) * expectation_(j); }
ScalarType diff(ublas::vector<ScalarType> & v1, viennacl::vector<ScalarType> & v2) { ublas::vector<ScalarType> v2_cpu(v2.size()); viennacl::backend::finish(); viennacl::copy(v2.begin(), v2.end(), v2_cpu.begin()); for (unsigned int i=0;i<v1.size(); ++i) { if ( std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ) > 0 ) { //if (std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ) < 1e-10 ) //absolute tolerance (avoid round-off issues) // v2_cpu[i] = 0; //else v2_cpu[i] = std::fabs(v2_cpu[i] - v1[i]) / std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ); } else v2_cpu[i] = 0.0; if (v2_cpu[i] > 0.0001) { //std::cout << "Neighbor: " << i-1 << ": " << v1[i-1] << " vs. " << v2_cpu[i-1] << std::endl; std::cout << "Error at entry " << i << ": " << v1[i] << " vs. " << v2_cpu[i] << std::endl; //std::cout << "Neighbor: " << i+1 << ": " << v1[i+1] << " vs. " << v2_cpu[i+1] << std::endl; exit(EXIT_FAILURE); } } return norm_inf(v2_cpu); }
ublas::vector<double> dirichlet_rnd(const ublas::vector<int>& nz) { //! Returns sample from a Dirichlet distribution with dimension k = len(nz). int k = nz.size(); ublas::vector<double> A(k); for (int i=0; i<k; ++i) { A(i) = Rmath::rgamma(1+nz(i), 1); } return A/sum(A); }
EmpCovar(const UpdateBlock& params, CovMatrix& covariance) : params_(params),p_(params.size()), rowCount_(0) { // Set up storage sum_.resize(params.size()); sumSq_.resize(params.size()); expectation_.resize(params.size()); for(size_t i = 0; i<params.size(); ++i) { sum_(i) = 0.0; expectation_(i) = 0.0; for(size_t j = 0; j < params.size(); ++j) sumSq_(i,j) = 0.0; } covMatrix_ = covariance; // Add a parameter row //setCovariance(covariance); //sample(); }
ScalarType diff ( ublas::vector<ScalarType> & v1, viennacl::vector<ScalarType,Alignment> & v2 ) { ublas::vector<ScalarType> v2_cpu ( v2.size() ); viennacl::copy( v2.begin(), v2.end(), v2_cpu.begin() ); for ( unsigned int i=0; i<v1.size(); ++i ) { if ( std::max ( fabs ( v2_cpu[i] ), fabs ( v1[i] ) ) > 0 ) v2_cpu[i] = fabs ( v2_cpu[i] - v1[i] ) / std::max ( fabs ( v2_cpu[i] ), fabs ( v1[i] ) ); else v2_cpu[i] = 0.0; } return norm_inf ( v2_cpu ); }
/** returns the first n elites * @param p_start start value of the elite values * @param p_end end value of the elite values ([start, end) elite elements must be created) * @param p_population const reference to the population * @param p_rankIndex rank index (first index has the position of the population element, that has the smalles fitness value) * @param p_elite vector with elite individual **/ template<typename T, typename L> inline void bestof<T,L>::getElite( const std::size_t& p_start, const std::size_t& p_end, const std::vector< boost::shared_ptr< individual::individual<L> > >& p_population, const ublas::vector<T>&, const ublas::vector<std::size_t>& p_rankIndex, const ublas::vector<std::size_t>&, std::vector< boost::shared_ptr< individual::individual<L> > >& p_elite ) { const std::size_t l_end = std::min(p_end, m_number); std::size_t n = p_start; for(std::size_t i=p_start; i < p_end; ++i) { p_elite.push_back( p_population[p_rankIndex[p_rankIndex.size()-1-n]] ); n++; if (n >= l_end) n = p_start; } }
ScalarType diff(ublas::vector<ScalarType> const & v1, VCLVectorType const & v2) { ublas::vector<ScalarType> v2_cpu(v2.size()); viennacl::backend::finish(); //workaround for a bug in APP SDK 2.7 on Trinity APUs (with Catalyst 12.8) viennacl::copy(v2.begin(), v2.end(), v2_cpu.begin()); for (unsigned int i=0;i<v1.size(); ++i) { if (v2_cpu[i] != v1[i]) return 1; } return 0; }
Serialization SDPSeriationGen::Impl::readout_plain(ublas::vector<double>& x,const AdjMat::AdjMatT& adj) { unsigned int n = x.size(); // tricky: make sure x > 0 at all times. x += ublas::scalar_vector<double>(n, 1 - (*min_element(x.begin(),x.end()))); Serialization::RankT ranks(n); std::vector<bool> done(n,false); // find highest component of x ublas::vector<double>::iterator it = BEST_ELEM(x); int idx = std::distance(x.begin(),it); L("Determine Actual Path through Graph.\n"); for(unsigned int i=0;i<n;i++){ ranks[i] = idx; done[idx] = true; *it = 0.0; it = BEST_ELEM(x); idx = std::distance(x.begin(),it); } return Serialization(ranks); }
ScalarType diff(ublas::vector<ScalarType> const & v1, ViennaCLVectorType const & vcl_vec) { ublas::vector<ScalarType> v2_cpu(vcl_vec.size()); viennacl::backend::finish(); viennacl::copy(vcl_vec, v2_cpu); for (unsigned int i=0;i<v1.size(); ++i) { if ( std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ) > 0 ) v2_cpu[i] = std::fabs(v2_cpu[i] - v1[i]) / std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ); else v2_cpu[i] = 0.0; } return ublas::norm_inf(v2_cpu); }
ScalarType diff(ublas::vector<ScalarType> & v1, viennacl::vector<ScalarType> & v2) { ublas::vector<ScalarType> v2_cpu(v2.size()); viennacl::backend::finish(); //workaround for a bug in APP SDK 2.7 on Trinity APUs (with Catalyst 12.8) viennacl::copy(v2.begin(), v2.end(), v2_cpu.begin()); for (std::size_t i=0;i<v1.size(); ++i) { if ( std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ) > 0 ) v2_cpu[i] = std::fabs(v2_cpu[i] - v1[i]) / std::max( std::fabs(v2_cpu[i]), std::fabs(v1[i]) ); else v2_cpu[i] = 0.0; } return norm_inf(v2_cpu); }
void image2vector_2d(const ublas::fixed_vector<size_t, 2> size, const float_accessor_t & image, ublas::vector<float_t> & vector) { if(image.size() != size) throw Exception("Exception: Dimensions of image and grid do not agree in Image2Grid::image2vector()."); size_t n_x_vertices = size(0); size_t n_y_vertices = size(1); vector.resize(n_x_vertices * n_y_vertices, false); for(size_t i = 0; i < n_x_vertices; i++) for(size_t j = 0; j < n_y_vertices; ++j) { size_t vertex_index = i + j * n_x_vertices; vector(vertex_index) = image[ublas::fixed_vector<size_t, 2>(i, j)]; } }
void vector2image_2d(const ublas::fixed_vector<size_t, 2> size, const ublas::vector< float_t > &vector, float_accessor_t & image) { size_t n_x_vertices = size(0); size_t n_y_vertices = size(1); if(vector.size() != n_x_vertices * n_y_vertices) throw Exception("Exception: vector of wrong length in vector2image()."); if(image.size() != size) throw Exception("Exception: image of wrong size in vector2image()."); for(size_t i = 0; i < n_x_vertices; i++) for(size_t j = 0; j < n_y_vertices; ++j) { size_t vertex_index = i + j * n_x_vertices; image[ublas::fixed_vector<size_t, 2>(i, j)] = vector(vertex_index); } }
void vector2vector_image_2d(const ublas::fixed_vector<size_t, 2> size, const ublas::vector< float_t > &vector, vector_image_accessor_t & vector_image) { const size_t n_x_vertices = size(0); const size_t n_y_vertices = size(1); const size_t dimension = vector_image_accessor_t::data_t::dimension; if(vector.size() != n_x_vertices * n_y_vertices * dimension) throw Exception("Exception: tla::vector of wrong length in vector2image()."); if(vector_image.size() != size) throw Exception("Exception: vector_image of wrong size in vector2vector_image()."); for(size_t i = 0; i < n_x_vertices; i++) for(size_t j = 0; j < n_y_vertices; ++j) for(size_t k = 0; k < dimension; ++k) { size_t vertex_index = dimension * ( i + j * n_x_vertices ) + k; vector_image[ublas::fixed_vector<size_t, 2>(i, j)](k) = vector(vertex_index); } }
Serialization SDPSeriationGen::Impl::readout_connected(ublas::vector<double>& x,const AdjMat::AdjMatT& adj) { unsigned int n = x.size(); // tricky: make sure x > 0 at all times. x += ublas::scalar_vector<double>(n, 1 - (*min_element(x.begin(),x.end()))); Serialization::RankT ranks(n); std::vector<bool> done(n,false); // find highest component of x ublas::vector<double>::iterator it = BEST_ELEM(x); int idx = std::distance(x.begin(),it); L("Determine Actual Path through Graph.\n"); for(unsigned int i=0;i<n;i++){ // mark as visited ranks[i] = idx; done[idx] = true; // make sure we do not visit again *it = 0.0; // [m,i] = max(x.*A(:,i)); ublas::vector<double> adjcol = ublas::column(adj,idx); for(unsigned int j=0;j<adjcol.size();j++) if(adjcol[j]>0.00001) adjcol[j]=1; ublas::vector<double> tmp = ublas::element_prod(x,adjcol); it = BEST_ELEM(tmp); if( *it < 0.000000001 && i<n-1) { // if *it small, then either x[it] visited or adj(old_idx,idx) not connected // --> we reached a dead end, find next best start point it = BEST_ELEM(x); idx = std::distance(x.begin(),it); }else{ idx = std::distance(tmp.begin(),it); // point it in x, not tmp: it = x.begin(); it += idx; } } return Serialization(ranks); }
void learn(const database<T, bool> &data, ublas::vector<double> vec_sample_weights) { ASSERT(data.patterns.size2() == data.targets.size(), ""); _weak_classifiers.clear(); _¦Á.clear(); for (size_t k = 0; k < classifier_size(); ++k){ auto classifier = _master_classifier.clone(); auto sum = ublas::sum(vec_sample_weights); for (auto &e:vec_sample_weights){ e /= sum; } classifier.learn(data, vec_sample_weights); double eps = 0.0; ublas::vector<bool> re(data.targets.size()); for (size_t i = 0; i < data.patterns.size2(); ++i){ re[i] = classifier(ublas::column(data.patterns, i)); if (re[i] != (data.targets)[i]){ eps += vec_sample_weights[i]; } } #ifdef _CONSOLE std::cout << k << "Adaboost Classifier error : " << eps << std::endl; #endif if (eps >= 0.5) continue; auto _¦Ák = 0.5*ln((1.0-eps) / (eps+1e-4)); for (size_t i = 0; i < vec_sample_weights.size(); ++i){ if ((data.targets)[i] != re[i]) vec_sample_weights[i] *= exp(_¦Ák); else vec_sample_weights[i] *= exp(-_¦Ák); } _weak_classifiers.push_back(classifier); _¦Á.push_back(_¦Ák); } }
int main() { boost::random::mt19937 gen; gen.seed(static_cast<unsigned int>(std::time(0))); const unsigned int M = M3; const unsigned int N = N3; const unsigned int iterations = 5; const unsigned int frames = 30; const double EbN0[EBN0_SIZE] = { -7.0, -6.5, -6.0, -5.5, -5.0, -4.5, -4.0, -3.5, -3.0, -2.5, -2.0, -1.5, -1.0, -0.5, 0, 0.5, 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, 5.0, 5.5, 6.0, 6.5, 7.0 }; double ber0[EBN0_SIZE]; double ber1[EBN0_SIZE]; double ber2[EBN0_SIZE]; ublas::vector<int> fer0(EBN0_SIZE); ublas::vector<int> fer1(EBN0_SIZE); ublas::vector<int> fer2(EBN0_SIZE); ublas::matrix<int> H(M, N); initMatrix<int>(H, hData3); // LU matrices ublas::matrix<int> L(ublas::zero_matrix<int>(M, N - M)); ublas::matrix<int> U(ublas::zero_matrix<int>(M, N - M)); reorderHMatrix(H, L, U); /* writeMatrix<int>(H, "H.csv"); writeMatrix<int>(L, "Lpre.csv"); writeMatrix<int>(U, "Upre.csv"); */ boost::random::uniform_int_distribution<> uniformDistribution(0, 1); boost::random::normal_distribution<> normalDistribution; //ublas::matrix<int> C(EBN0_SIZE * frames, M); /* ublas::matrix<int> dSource(M, frames); initMatrix<int>(dSource, dSourceData3); writeMatrix<int>(dSource, "dSource.csv"); */ for (unsigned int i = 0; i < EBN0_SIZE; i++) { //std::cout << "EbN0 : " << i << std::endl; ber0[i] = 0.0; ber1[i] = 0.0; ber2[i] = 0.0; fer0(i) = 0; fer1(i) = 0; fer2(i) = 0; // Make random data (0/1) ublas::matrix<int> dSource(M, frames); for (unsigned int j = 0; j < frames; j++) { for (unsigned int k = 0; k < M; k++) { dSource(k, j) = uniformDistribution(gen); } } //std::cout << "dSource=" << std::endl; //printMatrix<int>(dSource); for (unsigned int j = 0; j < frames; j++) { //std::cout << "Frame : " << j << std::endl; // Encoding message const ublas::vector<int> c = makeParityCheck(ublas::column(dSource, j), H, L, U); //ublas::row(C, i * (EBN0_SIZE + 1) + j) = c; //std::cout << "newH=" << std::endl; //printMatrix<int>(newH); //std::cout << "c=" << std::endl; //printVector<int>(c); ublas::vector<int> u(c.size() + M); ublas::subrange(u, 0, c.size()) = c; ublas::subrange(u, c.size(), c.size() + M) = ublas::column(dSource, j); //std::cout << "u=" << std::endl; //printVector<int>(u); // BPSK modulation ublas::vector<int> bpskMod(u.size()); for (unsigned int k = 0; k < u.size(); k++) { bpskMod(k) = 2 * u(k) - 1; } //std::cout << "bpskMod=" << std::endl; //printVector<int>(bpskMod); // Additional white gaussian noise double N0 = 1 / (std::exp(EbN0[i] * std::log(10) / 10)); //std::cout << "N0=" << N0 << std::endl; ublas::vector<double> tx(bpskMod); for (unsigned int k = 0; k < tx.size(); k++) { tx(k) += std::sqrt(N0) * normalDistribution(gen); } //std::cout << "tx=" << std::endl; //printVector<double>(tx); ublas::vector<int> vhat0 = decodeBPSK(tx); double rat0 = biterr(vhat0, u); ber0[i] += rat0; ublas::vector<int> vhat1 = decodeBitFlipping(tx, H, iterations); // newH //std::cout << "vhat1=" << std::endl; //printVector<int>(vhat1); double rat1 = biterr(vhat1, u); //std::cout << "rat1=" << rat1 << std::endl; ber1[i] += rat1; ublas::vector<int> vhat2 = decodeLogDomainSimple(tx, H, iterations); double rat2 = biterr(vhat2, u); ber2[i] += rat2; // Check messages if (checkMessage(vhat0, H) > 0) { if (rat0 <= 0.0) { //std::cout << "False negative: rat0=" << rat0 << std::endl; } fer0(i)++; } else if (rat0 > 0) { //std::cout << "False positive: rat0=" << rat0 << std::endl; } if (checkMessage(vhat1, H) > 0) { if (rat1 <= 0.0) { //std::cout << "False negative: rat1=" << rat1 << std::endl; } fer1(i)++; } else if (rat1 > 0) { //std::cout << "False positive: rat1=" << rat1 << std::endl; } if (checkMessage(vhat2, H) > 0) { if (rat2 <= 0.0) { //std::cout << "False negative: rat2=" << rat2 << std::endl; } fer2(i)++; } else if (rat2 > 0) { //std::cout << "False positive: rat2=" << rat2 << std::endl; } } ber0[i] /= frames; ber1[i] /= frames; ber2[i] /= frames; } std::cout << std::endl; /* std::cout << "H=[" << std::endl; printMatrix<int>(H); std::cout << "];" << std::endl; */ std::cout.precision(4); std::cout << "EbN0=["; for (unsigned int i = 0; i < EBN0_SIZE; i++) { std::cout << EbN0[i] << " "; } std::cout << "];" << std::endl; std::cout << "figure(1);" << std::endl; std::cout << "ber0=["; for (unsigned int i = 0; i < EBN0_SIZE; i++) { std::cout << ber0[i] << " "; } std::cout << "];" << std::endl; std::cout << "plot(EbN0, ber0, 'or--');" << std::endl; std::cout << "hold;" << std::endl; std::cout << "ber1=["; for (unsigned int i = 0; i < EBN0_SIZE; i++) { std::cout << ber1[i] << " "; } std::cout << "];" << std::endl; std::cout << "plot(EbN0, ber1, 'og-');" << std::endl; std::cout << "ber2=["; for (unsigned int i = 0; i < EBN0_SIZE; i++) { std::cout << ber2[i] << " "; } std::cout << "];" << std::endl; std::cout << "plot(EbN0, ber2, 'ob-');" << std::endl; std::cout << "grid on;" << std::endl; std::cout << "hold off;" << std::endl; std::cout << "title('Bit Error Rate');" << std::endl; std::cout << "legend('BPSK', 'BitFlip', 'LogDomainSimple');" << std::endl; std::cout << "xlabel('EbN0');" << std::endl; std::cout << "ylabel('BER');" << std::endl; std::cout << "figure(2);" << std::endl; std::cout << "fer0=[" << std::endl; printVector<int>(fer0); std::cout << "];" << std::endl; std::cout << "plot(EbN0, fer0, 'or:');" << std::endl; std::cout << "hold;" << std::endl; std::cout << "fer1=[" << std::endl; printVector<int>(fer1); std::cout << "];" << std::endl; std::cout << "plot(EbN0, fer1, 'og-');" << std::endl; std::cout << "fer2=[" << std::endl; printVector<int>(fer2); std::cout << "];" << std::endl; std::cout << "plot(EbN0, fer2, 'ob-');" << std::endl; std::cout << "grid on;" << std::endl; std::cout << "hold off;" << std::endl; std::cout << "title('Frame Errors');" << std::endl; std::cout << "legend('BPSK', 'BitFlip', 'LogDomainSimple');" << std::endl; std::cout << "xlabel('EbN0');" << std::endl; std::cout << "ylabel('FER');" << std::endl; /* writeMatrix<int>(L, "Lpost.csv"); writeMatrix<int>(U, "Upost.csv"); //writeMatrix<int>(dSource, "dSource.csv"); writeMatrix<int>(C, "C.csv"); */ return 0; }
ublas::vector<int> decodeBitFlipping(const ublas::vector<double> &rx, const ublas::matrix<int> &H, const unsigned int iterations) { // Get matrix dimensions const unsigned int M = H.size1(); const unsigned int N = H.size2(); // Prior hard-decision ublas::vector<int> ci(rx.size()); for (unsigned int i = 0; i < rx.size(); i++) { ci(i) = 0.5 * (sign(rx(i)) + 1); } //std::cout << "ci=" << std::endl; //printVector<int>(ci); // Initialization ublas::matrix<int> rji(ublas::zero_matrix<int>(M, N)); // Associate the ci matrix with non-zero elements of H ublas::matrix<int> qij(M, N); for (unsigned int i = 0; i < M; i++) { ublas::row(qij, i) = ublas::element_prod(ublas::row(H, i), ci); } //std::cout << "qij=" << std::endl; //printMatrix<int>(qij); ublas::vector<int> vHat(N); // Iteration for (unsigned int n = 0; n < iterations; n++) { //std::cout << "Iteration : " << n << std::endl; // Horizontal step for (unsigned int i = 0; i < M; i++) { int qijSum = 0; for (unsigned int j = 0; j < N; j++) { if (H(i, j) != 0) { qijSum += qij(i, j); } } for (unsigned int j = 0; j < N; j++) { if (H(i, j) != 0) { rji(i, j) = (qijSum + qij(i, j)) % 2; } } } // Vertical step for (unsigned int j = 0; j < N; j++) { int rjiNumberOfOnes = 0; for (unsigned int i = 0; i < M; i++) { if (rji(i, j) != 0) { rjiNumberOfOnes++; } } int hNumberOfOnes = 0; for (unsigned int i = 0; i < M; i++) { if (H(i, j) != 0) { hNumberOfOnes++; } } for (unsigned int i = 0; i < M; i++) { if (H(i, j) != 0) { // Update qij, set '1' for majority of 1s else '0', excluding i if (rjiNumberOfOnes + ci(j) >= hNumberOfOnes - rjiNumberOfOnes + rji(i, j)) { qij(i, j) = 1; } else { qij(i, j) = 0; } } } // Bit decoding if (rjiNumberOfOnes + ci(j) >= hNumberOfOnes - rjiNumberOfOnes) { vHat(j) = 1; } else { vHat(j) = 0; } } } return vHat; }
void fill_savitzky_golay( ublas::vector<double>& first, ublas::vector<double>& second ) { first.resize(41); second.resize(41); first[0] = 0.0323312535450935; first[1] = 0.00850822461712981; first[2] = -0.00829006501156256; first[3] = -0.0189798856843667; first[4] = -0.0244279796179967; first[5] = -0.0254515609024968; first[6] = -0.0228183155012423; first[7] = -0.0172464012509389; first[8] = -0.00940444786162312; first[9] = 8.84430833381321e-05; first[10] = 0.0106626981272472; first[11] = 0.0217982719400757; first[12] = 0.0330246473184647; first[13] = 0.0439208351857245; first[14] = 0.0541153745918351; first[15] = 0.0632863327134455; first[16] = 0.0711613048538743; first[17] = 0.0775174144431092; first[18] = 0.0821813130378076; first[19] = 0.0850291803212959; first[20] = 0.0859867241035703; first[21] = 0.0850291803212959; first[22] = 0.0821813130378076; first[23] = 0.0775174144431092; first[24] = 0.0711613048538743; first[25] = 0.0632863327134455; first[26] = 0.0541153745918351; first[27] = 0.0439208351857245; first[28] = 0.0330246473184647; first[29] = 0.0217982719400757; first[30] = 0.0106626981272472; first[31] = 8.84430833381564e-05; first[32] = -0.00940444786162310; first[33] = -0.0172464012509389; first[34] = -0.0228183155012423; first[35] = -0.0254515609024968; first[36] = -0.0244279796179966; first[37] = -0.0189798856843667; first[38] = -0.00829006501156248; first[39] = 0.00850822461712988; first[40] = 0.0323312535450935; second[0] = 0.00733573478893954; second[1] = 0.00426393421288486; second[2] = 0.00160828961169289; second[3] = -0.000653101960681753; second[4] = -0.00254214345028448; second[5] = -0.00408073780316071; second[6] = -0.00529078796535584; second[7] = -0.00619419688291528; second[8] = -0.00681286750188443; second[9] = -0.00716870276830871; second[10] = -0.00728360562823351; second[11] = -0.00717947902770424; second[12] = -0.00687822591276632; second[13] = -0.00640174922946515; second[14] = -0.00577195192384613; second[15] = -0.00501073694195466; second[16] = -0.00414000722983617; second[17] = -0.00318166573353605; second[18] = -0.00215761539909971; second[19] = -0.00108975917257256; second[20] = -4.35165292826184e-19; second[21] = 0.00108975917257256; second[22] = 0.00215761539909971; second[23] = 0.00318166573353605; second[24] = 0.00414000722983617; second[25] = 0.00501073694195467; second[26] = 0.00577195192384613; second[27] = 0.00640174922946515; second[28] = 0.00687822591276632; second[29] = 0.00717947902770425; second[30] = 0.00728360562823351; second[31] = 0.00716870276830871; second[32] = 0.00681286750188444; second[33] = 0.00619419688291529; second[34] = 0.00529078796535585; second[35] = 0.00408073780316072; second[36] = 0.00254214345028449; second[37] = 0.000653101960681753; second[38] = -0.00160828961169289; second[39] = -0.00426393421288486; second[40] = -0.00733573478893955; }
void initVector(ublas::vector<T> &u, const T data[]) { for (unsigned int i = 0; i < u.size(); i++) { u(i) = data[i]; } }
int pmols::HJPacker::exploringSearch(ublas::vector<float> &x_, bool change_step) { std::cout << "EXPLORING SEARCH (with " << (change_step ? "step change" : "no step change") << ")" << std::endl; std::cout << " —— objective func before iteration: " << totalDist << std::endl; float sum1, sum2; int mol_idx, op_num; float dist0, dist; bool changed = false; bool terminate = true; bool mol_moved; float max_step_rot = 0, max_step_trans = 0; float min_step_rot = params.step_alpha, min_step_trans = params.step_x; std:: cout << " prevTotalDist: " << prevTotalDist << std::endl; std:: cout << " totalDist: " << totalDist << std::endl; for (int i = 0; i < x_.size(); ++i) { // std::cout << "\t——— coord num: " << i << std::endl; if(i % 6 < 3) { if(step[i] > max_step_trans) max_step_trans = step[i]; else if(step[i] < min_step_trans) min_step_trans = step[i]; } else { if (step[i] > max_step_rot) max_step_rot = step[i]; else if(step[i] < min_step_rot) min_step_rot = step[i]; } if(step[i] < eps(i)) continue; if(terminate) terminate = false; mol_idx = i / 6; op_num = i % 6; dist0 = cellLinkedLists->MolDist(mol_idx); // std::cout << "\t\tdist0: " << dist0 << std::endl; mol_moved = cellLinkedLists->MoveMol(mol_idx, (MOVE_OP)op_num, step[i]); dist = cellLinkedLists->MolDist(mol_idx); sum1 = mol_moved ? ( totalDist - dist0 + dist ) : totalDist; if(mol_moved) { // std::cout << "\t\tsum1: " << sum1 << std::endl; // std::cout << "\t\tdist: " << dist << std::endl; cellLinkedLists->CancelMove(); } // if(sum1 < 0) { // std::cout << "\t——— Negative value of sum." << std::endl; // std::cout << "\t\tcoord number: " << i << std::endl; // std::cout << "\t\tsum1: " << sum2 << std::endl; // std::cout << "\t\tsum2: " << sum2 << std::endl; // std::cout << "\t\tprevTotalSum: " << prevTotalDist << std::endl; // std::cout << "\t\ttotalSum: " << totalDist << std::endl; // std::cout << "\t\tdist0: " << dist0 << std::endl; // std::cout << "\t\tdist: " << dist << std::endl; // std::cout << "\t\tmol_moved: " << mol_moved << std::endl; // } mol_moved = cellLinkedLists->MoveMol(mol_idx, (MOVE_OP)op_num, -step[i]); dist = cellLinkedLists->MolDist(mol_idx); sum2 = mol_moved ? ( totalDist - dist0 + dist ) : totalDist; if(mol_moved) { // std::cout << "\t\tsum2: " << sum2 << std::endl; // std::cout << "\t\tdist: " << dist << std::endl; cellLinkedLists->CancelMove(); } // if(sum2 < 0) { // std::cout << "\t——— Negative value of sum." << std::endl; // std::cout << "\t\tcoord number: " << i << std::endl; // std::cout << "\t\tsum1: " << sum1 << std::endl; // std::cout << "\t\tsum2: " << sum2 << std::endl; // std::cout << "\t\tprevTotalSum: " << prevTotalDist << std::endl; // std::cout << "\t\ttotalSum: " << totalDist << std::endl; // std::cout << "\t\tdist0: " << dist0 << std::endl; // std::cout << "\t\tdist: " << dist << std::endl; // std::cout << "\t\tmol_moved: " << mol_moved << std::endl; // } // if(sum1 < 0 || sum2 < 0) // std::cout << std::endl; if (prevTotalDist <= std::min(sum1, sum2) && change_step) step[i] *= params.step_coefficient; else { if(sum1 < std::min(prevTotalDist, sum2)) { x_[i] += step[i]; cellLinkedLists->MoveMol(mol_idx, (MOVE_OP)op_num, step[i]); totalDist = sum1; prevTotalDist = totalDist; changed = true; // std::cout << "\t\ttotal sum changed to sum1, current value: " << totalDist << std::endl; } else if(sum2 < std::min(prevTotalDist, sum1)) { x_[i] -= step[i]; cellLinkedLists->MoveMol(mol_idx, (MOVE_OP)op_num, -step[i]); totalDist = sum2; prevTotalDist = totalDist; // std::cout << "\t\ttotal sum changed to sum2, current value: " << totalDist << std::endl; changed = true; } } // std::cout << std::endl; } std::cout << "\tmax rotation step: " << max_step_rot << std::endl; std::cout << "\tmax translation step: " << max_step_trans << std::endl << std::endl; std::cout << "\tmin rotation step: " << min_step_rot << std::endl; std::cout << "\tmin translation step: " << min_step_trans << std::endl; std::cout << " —— objective func after iteration: " << totalDist << std::endl; if (terminate) return -1; return (int)changed; }
ublas::vector<int> decodeLogDomainSimple(const ublas::vector<double> &rx, const ublas::matrix<int> &H, const unsigned int iterations) { // Get matrix dimensions const unsigned int M = H.size1(); const unsigned int N = H.size2(); // Prior hard-decision ublas::vector<double> Lci(rx.size()); for (unsigned int i = 0; i < rx.size(); i++) { Lci(i) = -rx(i); } // Initialization ublas::matrix<double> Lrji(ublas::zero_matrix<double>(M, N)); ublas::matrix<double> Pibetaij(ublas::zero_matrix<double>(M, N)); // Associate the L(ci) matrix with non-zero elements of H ublas::matrix<double> Lqij(M, N); for (unsigned int i = 0; i < M; i++) { ublas::row(Lqij, i) = ublas::element_prod(ublas::row(H, i), Lci); } ublas::vector<int> vHat(N); // Iteration for (unsigned int n = 0; n < iterations; n++) { //std::cout << "Iteration : " << n << std::endl; // Get the sign and magnitude of L(qij) ublas::matrix<int> alphaij(M, N); ublas::matrix<double> betaij(M, N); for (unsigned int i = 0; i < M; i++) { for (unsigned int j = 0; j < N; j++) { alphaij(i, j) = sign(Lqij(i, j)); betaij(i, j) = std::abs(Lqij(i, j)); } } // Horizontal step for (unsigned int i = 0; i < M; i++) { int prodOfalphaij = 1; for (unsigned int j = 0; j < N; j++) { if (H(i, j) != 0) { prodOfalphaij *= alphaij(i, j); } } // Get the minimum of betaij for (unsigned int j = 0; j < N; j++) { if (H(i, j) != 0) { // Minimum of betaij double minOfBetaij = std::numeric_limits<double>::max(); for (unsigned int k = 0; k < N; k++) { if (j != k && H(i, k) != 0) { if (betaij(i, k) < minOfBetaij) { minOfBetaij = betaij(i, k); } } } // Multiplication alphaij // Update L(rji) Lrji(i, j) = prodOfalphaij * alphaij(i, j) * minOfBetaij; } } } // Vertical step for (unsigned int j = 0; j < N; j++) { double sumOfLrji = 0.0; for (unsigned int i = 0; i < M; i++) { if (H(i, j) != 0) { sumOfLrji += Lrji(i, j); } } for (unsigned int i = 0; i < M; i++) { if (H(i, j) != 0) { // Update L(qij) by summation of L(rij) Lqij(i, j) = Lci(j) + sumOfLrji - Lrji(i, j); } } // Get L(Qij) double LQi = Lci(j) + sumOfLrji; // Decode L(Qi) if (LQi < 0) { vHat(j) = 1; } else { vHat(j) = 0; } } } return vHat; }