681 lines
17 KiB
C++
681 lines
17 KiB
C++
/*
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* Copyright © 2004-2011 Ondra Kamenik
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* Copyright © 2019 Dynare Team
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*
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* This file is part of Dynare.
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*
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* Dynare is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* Dynare is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with Dynare. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "QuasiTriangular.hh"
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#include "SylvException.hh"
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#include "SchurDecomp.hh"
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#include "int_power.hh"
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#include <dynblas.h>
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#include <cmath>
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#include <iostream>
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#include <sstream>
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double
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DiagonalBlock::getDeterminant() const
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{
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return (*alpha)*(*alpha) + getSBeta();
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}
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double
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DiagonalBlock::getSBeta() const
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{
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return -(*beta1)*(*beta2);
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}
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double
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DiagonalBlock::getSize() const
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{
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if (real)
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return std::abs(*alpha);
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else
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return std::sqrt(getDeterminant());
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}
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/* This function makes Diagonal inconsistent, it should only be used
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on temorary matrices, which will not be used any more, e.g. in
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QuasiTriangular::solve() (we need fast performance) */
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void
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DiagonalBlock::setReal()
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{
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*beta1 = 0;
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*beta2 = 0;
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real = true;
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}
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void
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DiagonalBlock::checkBlock(const double *d, int d_size)
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{
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const double *a1 = d + jbar*d_size+jbar;
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const double *b1 = a1 + d_size;
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const double *b2 = a1 + 1;
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const double *a2 = b1 + 1;
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if (a1 != alpha.a1)
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throw SYLV_MES_EXCEPTION("Bad alpha1.");
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if (!real && b1 != beta1)
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throw SYLV_MES_EXCEPTION("Bad beta1.");
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if (!real && b2 != beta2)
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throw SYLV_MES_EXCEPTION("Bad beta2.");
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if (!real && a2 != alpha.a2)
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throw SYLV_MES_EXCEPTION("Bad alpha2.");
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}
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Diagonal::Diagonal(double *data, int d_size)
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{
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int nc = getNumComplex(data, d_size); // return nc ≤ d_size/2
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num_all = d_size - nc;
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num_real = d_size - 2*nc;
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int jbar = 0;
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int j = 0;
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while (j < num_all)
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{
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int id = jbar*d_size + jbar; // index of diagonal block in data
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int ill = id + 1; // index of element below the diagonal
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int iur = id + d_size; // index of element right to diagonal
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int idd = id + d_size + 1; // index of element next on diagonal
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if ((jbar < d_size-1) && !isZero(data[ill]))
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{
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// it is not last column and we have nonzero below diagonal
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blocks.emplace_back(jbar, false, &data[id], &data[idd],
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&data[iur], &data[ill]);
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jbar++;
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}
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else
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// it is last column or we have zero below diagonal
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blocks.emplace_back(jbar, true, &data[id], &data[id], nullptr, nullptr);
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jbar++;
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j++;
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}
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}
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Diagonal::Diagonal(double *data, const Diagonal &d)
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{
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num_all = d.num_all;
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num_real = d.num_real;
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int d_size = d.getSize();
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for (const auto &block : d)
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{
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double *beta1 = nullptr;
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double *beta2 = nullptr;
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int id = block.getIndex()*(d_size+1);
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int idd = id;
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if (!block.isReal())
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{
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beta1 = &data[id+d_size];
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beta2 = &data[id+1];
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idd = id + d_size + 1;
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}
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blocks.emplace_back(block.getIndex(), block.isReal(),
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&data[id], &data[idd], beta1, beta2);
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}
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}
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int
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Diagonal::getNumComplex(const double *data, int d_size)
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{
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int num_complex = 0;
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int in = 1;
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for (int i = 0; i < d_size-1; i++, in = in + d_size + 1)
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if (!isZero(data[in]))
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{
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num_complex++;
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if (in < d_size - 2 && !isZero(data[in + d_size +1]))
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throw SYLV_MES_EXCEPTION("Matrix is not quasi-triangular");
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}
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return num_complex;
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}
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void
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Diagonal::changeBase(double *p)
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{
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int d_size = getSize();
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for (auto &it : *this)
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{
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const DiagonalBlock &b = it;
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int jbar = b.getIndex();
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int base = d_size*jbar + jbar;
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if (b.isReal())
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{
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DiagonalBlock bnew(jbar, true, &p[base], &p[base],
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nullptr, nullptr);
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it = bnew;
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}
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else
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{
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DiagonalBlock bnew(jbar, false, &p[base], &p[base+d_size+1],
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&p[base+d_size], &p[base+1]);
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it = bnew;
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}
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}
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}
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void
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Diagonal::getEigenValues(Vector &eig) const
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{
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int d_size = getSize();
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if (eig.length() != 2*d_size)
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{
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std::ostringstream mes;
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mes << "Wrong length of vector for eigenvalues len=" << eig.length()
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<< ", should be=" << 2*d_size << '.' << std::endl;
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throw SYLV_MES_EXCEPTION(mes.str());
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}
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for (const auto &b : *this)
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{
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int ind = b.getIndex();
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eig[2*ind] = *(b.getAlpha());
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if (b.isReal())
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eig[2*ind+1] = 0.0;
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else
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{
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double beta = std::sqrt(b.getSBeta());
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eig[2*ind+1] = beta;
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eig[2*ind+2] = eig[2*ind];
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eig[2*ind+3] = -beta;
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}
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}
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}
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/* Swaps logically blocks ‘it’, and ‘++it’. remember to move also
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addresses, alpha, beta1, beta2. This is a dirty (but most
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effective) way how to do it. */
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void
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Diagonal::swapLogically(diag_iter it)
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{
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diag_iter itp = it;
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++itp;
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if (it->isReal() && !itp->isReal())
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{
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// first is real, second is complex
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double *d1 = it->alpha.a1;
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double *d2 = itp->alpha.a1;
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double *d3 = itp->alpha.a2;
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// swap
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DiagonalBlock new_it(it->jbar, d1, d2);
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*it = new_it;
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DiagonalBlock new_itp(itp->jbar+1, d3);
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*itp = new_itp;
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}
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else if (!it->isReal() && itp->isReal())
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{
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// first is complex, second is real
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double *d1 = it->alpha.a1;
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double *d2 = it->alpha.a2;
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double *d3 = itp->alpha.a1;
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// swap
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DiagonalBlock new_it(it->jbar, d1);
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*it = new_it;
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DiagonalBlock new_itp(itp->jbar-1, d2, d3);
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*itp = new_itp;
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}
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}
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void
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Diagonal::checkConsistency(diag_iter it)
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{
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if (!it->isReal() && isZero(it->getBeta2()))
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{
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it->getBeta2() = 0.0; // put exact zero
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int jbar = it->getIndex();
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double *d2 = it->alpha.a2;
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it->alpha.a2 = it->alpha.a1;
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it->real = true;
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it->beta1 = nullptr;
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it->beta2 = nullptr;
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blocks.emplace(++it, jbar+1, d2);
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num_real += 2;
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num_all++;
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}
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}
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double
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Diagonal::getAverageSize(diag_iter start, diag_iter end)
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{
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double res = 0;
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int num = 0;
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for (diag_iter run = start; run != end; ++run)
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{
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num++;
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res += run->getSize();
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}
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if (num > 0)
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res = res/num;
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return res;
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}
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Diagonal::diag_iter
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Diagonal::findClosestBlock(diag_iter start, diag_iter end, double a)
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{
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diag_iter closest = start;
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double minim = 1.0e100;
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for (diag_iter run = start; run != end; ++run)
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{
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double dist = std::abs(a - run->getSize());
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if (dist < minim)
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{
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minim = dist;
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closest = run;
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}
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}
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return closest;
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}
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Diagonal::diag_iter
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Diagonal::findNextLargerBlock(diag_iter start, diag_iter end, double a)
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{
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diag_iter closest = start;
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double minim = 1.0e100;
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for (diag_iter run = start; run != end; ++run)
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{
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double dist = run->getSize() - a;
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if ((0 <= dist) && (dist < minim))
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{
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minim = dist;
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closest = run;
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}
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}
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return closest;
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}
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void
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Diagonal::print() const
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{
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auto ff = std::cout.flags();
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std::cout << "Num real: " << getNumReal() << ", num complex: " << getNumComplex() << std::endl
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<< std::fixed;
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for (const auto &it : *this)
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if (it.isReal())
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std::cout << "real: jbar=" << it.getIndex() << ", alpha=" << *(it.getAlpha()) << std::endl;
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else
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std::cout << "complex: jbar=" << it.getIndex()
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<< ", alpha=" << *(it.getAlpha())
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<< ", beta1=" << it.getBeta1()
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<< ", beta2=" << it.getBeta2() << std::endl;
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std::cout.flags(ff);
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}
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bool
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Diagonal::isZero(double p)
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{
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return (std::abs(p) < EPS);
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}
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QuasiTriangular::const_col_iter
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QuasiTriangular::col_begin(const DiagonalBlock &b) const
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return const_col_iter(&getData()[jbar*d_size], d_size, b.isReal(), 0);
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}
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QuasiTriangular::col_iter
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QuasiTriangular::col_begin(const DiagonalBlock &b)
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return col_iter(&getData()[jbar*d_size], d_size, b.isReal(), 0);
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}
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QuasiTriangular::const_row_iter
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QuasiTriangular::row_begin(const DiagonalBlock &b) const
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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int off = jbar*d_size+jbar+d_size;
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int col = jbar+1;
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if (!b.isReal())
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{
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off = off + d_size;
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col++;
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}
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return const_row_iter(&getData()[off], d_size, b.isReal(), col);
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}
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QuasiTriangular::row_iter
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QuasiTriangular::row_begin(const DiagonalBlock &b)
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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int off = jbar*d_size+jbar+d_size;
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int col = jbar+1;
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if (!b.isReal())
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{
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off = off + d_size;
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col++;
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}
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return row_iter(&getData()[off], d_size, b.isReal(), col);
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}
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QuasiTriangular::const_col_iter
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QuasiTriangular::col_end(const DiagonalBlock &b) const
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return const_col_iter(getData().base()+jbar*d_size+jbar, d_size, b.isReal(),
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jbar);
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}
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QuasiTriangular::col_iter
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QuasiTriangular::col_end(const DiagonalBlock &b)
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return col_iter(&getData()[jbar*d_size+jbar], d_size, b.isReal(), jbar);
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}
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QuasiTriangular::const_row_iter
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QuasiTriangular::row_end(const DiagonalBlock &b) const
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return const_row_iter(&getData()[d_size*d_size+jbar], d_size, b.isReal(),
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d_size);
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}
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QuasiTriangular::row_iter
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QuasiTriangular::row_end(const DiagonalBlock &b)
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{
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int jbar = b.getIndex();
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int d_size = diagonal.getSize();
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return row_iter(&getData()[d_size*d_size+jbar], d_size, b.isReal(), d_size);
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}
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QuasiTriangular::QuasiTriangular(double r, const QuasiTriangular &t)
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: SqSylvMatrix(t.nrows()), diagonal(getData().base(), t.diagonal)
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{
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setMatrix(r, t);
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}
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QuasiTriangular::QuasiTriangular(double r, const QuasiTriangular &t,
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double r2, const QuasiTriangular &t2)
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: SqSylvMatrix(t.nrows()), diagonal(getData().base(), t.diagonal)
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{
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setMatrix(r, t);
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addMatrix(r2, t2);
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}
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QuasiTriangular::QuasiTriangular(const QuasiTriangular &t)
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: SqSylvMatrix(t), diagonal(getData().base(), t.diagonal)
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{
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}
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QuasiTriangular::QuasiTriangular(const ConstVector &d, int d_size)
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: SqSylvMatrix(Vector{d}, d_size), diagonal(getData().base(), d_size)
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{
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}
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QuasiTriangular::QuasiTriangular(const std::string &dummy, const QuasiTriangular &t)
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: SqSylvMatrix(t.nrows()), diagonal(getData().base(), t.diagonal)
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{
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Vector aux(t.getData());
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blas_int d_size = diagonal.getSize();
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double alpha = 1.0;
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double beta = 0.0;
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blas_int lda = t.getLD(), ldb = t.getLD(), ldc = ld;
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dgemm("N", "N", &d_size, &d_size, &d_size, &alpha, aux.base(),
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&lda, t.getData().base(), &ldb, &beta, getData().base(), &ldc);
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}
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QuasiTriangular::QuasiTriangular(const SchurDecomp &decomp)
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: SqSylvMatrix(decomp.getT()),
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diagonal(getData().base(), decomp.getDim())
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{
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}
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// This pads matrix with intial columns with zeros
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QuasiTriangular::QuasiTriangular(const SchurDecompZero &decomp)
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: SqSylvMatrix(decomp.getDim())
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{
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// nullify first decomp.getZeroCols() columns
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int zeros = decomp.getZeroCols()*decomp.getDim();
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Vector zv(getData(), 0, zeros);
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zv.zeros();
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// fill right upper part with decomp.getRU()
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for (int i = 0; i < decomp.getRU().nrows(); i++)
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for (int j = 0; j < decomp.getRU().ncols(); j++)
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getData()[(j+decomp.getZeroCols())*decomp.getDim()+i] = decomp.getRU().get(i, j);
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// fill right lower part with decomp.getT()
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for (int i = 0; i < decomp.getT().nrows(); i++)
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for (int j = 0; j < decomp.getT().ncols(); j++)
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getData()[(j+decomp.getZeroCols())*decomp.getDim()+decomp.getZeroCols()+i]
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= decomp.getT().get(i, j);
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// construct diagonal
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diagonal = Diagonal{getData().base(), decomp.getDim()};
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}
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void
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QuasiTriangular::setMatrix(double r, const QuasiTriangular &t)
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{
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getData().zeros();
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getData().add(r, t.getData());
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}
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void
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QuasiTriangular::addMatrix(double r, const QuasiTriangular &t)
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{
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getData().add(r, t.getData());
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}
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void
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QuasiTriangular::addUnit()
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{
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for (diag_iter di = diag_begin(); di != diag_end(); ++di)
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di->getAlpha() = *(di->getAlpha()) + 1.0;
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}
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void
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QuasiTriangular::solve(Vector &x, const ConstVector &b, double &eig_min)
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{
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x = b;
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solvePre(x, eig_min);
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}
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void
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QuasiTriangular::solveTrans(Vector &x, const ConstVector &b, double &eig_min)
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{
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x = b;
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solvePreTrans(x, eig_min);
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}
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void
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QuasiTriangular::solvePre(Vector &x, double &eig_min)
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{
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addUnit();
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for (diag_iter di = diag_begin(); di != diag_end(); ++di)
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{
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double eig_size;
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if (!di->isReal())
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{
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eig_size = di->getDeterminant();
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eliminateLeft(di->getIndex()+1, di->getIndex(), x);
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}
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else
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eig_size = *di->getAlpha()*(*di->getAlpha());
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eig_min = std::min(eig_min, eig_size);
|
||
}
|
||
|
||
blas_int nn = diagonal.getSize();
|
||
blas_int lda = ld;
|
||
blas_int incx = x.skip();
|
||
dtrsv("U", "N", "N", &nn, getData().base(), &lda, x.base(), &incx);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::solvePreTrans(Vector &x, double &eig_min)
|
||
{
|
||
addUnit();
|
||
for (diag_iter di = diag_begin(); di != diag_end(); ++di)
|
||
{
|
||
double eig_size;
|
||
if (!di->isReal())
|
||
{
|
||
eig_size = di->getDeterminant();
|
||
eliminateRight(di->getIndex()+1, di->getIndex(), x);
|
||
}
|
||
else
|
||
eig_size = *di->getAlpha()*(*di->getAlpha());
|
||
if (eig_size < eig_min)
|
||
eig_min = eig_size;
|
||
}
|
||
|
||
blas_int nn = diagonal.getSize();
|
||
blas_int lda = ld;
|
||
blas_int incx = x.skip();
|
||
dtrsv("U", "T", "N", &nn, getData().base(), &lda, x.base(), &incx);
|
||
}
|
||
|
||
// Calculates x = T·b
|
||
void
|
||
QuasiTriangular::multVec(Vector &x, const ConstVector &b) const
|
||
{
|
||
x = b;
|
||
blas_int nn = diagonal.getSize();
|
||
blas_int lda = ld;
|
||
blas_int incx = x.skip();
|
||
dtrmv("U", "N", "N", &nn, getData().base(), &lda, x.base(), &incx);
|
||
for (const_diag_iter di = diag_begin(); di != diag_end(); ++di)
|
||
if (!di->isReal())
|
||
{
|
||
int jbar = di->getIndex();
|
||
x[jbar+1] += di->getBeta2()*(b[jbar]);
|
||
}
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multVecTrans(Vector &x, const ConstVector &b) const
|
||
{
|
||
x = b;
|
||
blas_int nn = diagonal.getSize();
|
||
blas_int lda = ld;
|
||
blas_int incx = x.skip();
|
||
dtrmv("U", "T", "N", &nn, getData().base(), &lda, x.base(), &incx);
|
||
for (const_diag_iter di = diag_begin(); di != diag_end(); ++di)
|
||
if (!di->isReal())
|
||
{
|
||
int jbar = di->getIndex();
|
||
x[jbar] += di->getBeta2()*b[jbar+1];
|
||
}
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multaVec(Vector &x, const ConstVector &b) const
|
||
{
|
||
Vector tmp(const_cast<const Vector &>(x)); // new copy
|
||
multVec(x, b);
|
||
x.add(1.0, tmp);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multaVecTrans(Vector &x, const ConstVector &b) const
|
||
{
|
||
Vector tmp(const_cast<const Vector &>(x)); // new copy
|
||
multVecTrans(x, b);
|
||
x.add(1.0, tmp);
|
||
}
|
||
|
||
// Calculates x=x+(this⊗I)·b, where size of I is given by b (KronVector)
|
||
void
|
||
QuasiTriangular::multaKron(KronVector &x, const ConstKronVector &b) const
|
||
{
|
||
int id = b.getN()*power(b.getM(), b.getDepth()-1);
|
||
ConstGeneralMatrix b_resh(b, id, b.getM());
|
||
GeneralMatrix x_resh(x, id, b.getM());
|
||
x_resh.multAndAdd(b_resh, ConstGeneralMatrix(*this), "trans");
|
||
}
|
||
|
||
// Calculates x=x+(this⊗I)·b, where size of I is given by b (KronVector)
|
||
void
|
||
QuasiTriangular::multaKronTrans(KronVector &x, const ConstKronVector &b) const
|
||
{
|
||
int id = b.getN()*power(b.getM(), b.getDepth()-1);
|
||
ConstGeneralMatrix b_resh(b, id, b.getM());
|
||
GeneralMatrix x_resh(x, id, b.getM());
|
||
x_resh.multAndAdd(b_resh, ConstGeneralMatrix(*this));
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multKron(KronVector &x) const
|
||
{
|
||
KronVector b(const_cast<const KronVector &>(x)); // make copy
|
||
x.zeros();
|
||
multaKron(x, b);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multKronTrans(KronVector &x) const
|
||
{
|
||
KronVector b(const_cast<const KronVector &>(x)); // make copy
|
||
x.zeros();
|
||
multaKronTrans(x, b);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multLeftOther(GeneralMatrix &a) const
|
||
{
|
||
a.multLeft(*this);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::multLeftOtherTrans(GeneralMatrix &a) const
|
||
{
|
||
a.multLeftTrans(*this);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::swapDiagLogically(diag_iter it)
|
||
{
|
||
diagonal.swapLogically(it);
|
||
}
|
||
|
||
void
|
||
QuasiTriangular::checkDiagConsistency(diag_iter it)
|
||
{
|
||
diagonal.checkConsistency(it);
|
||
}
|
||
|
||
double
|
||
QuasiTriangular::getAverageDiagSize(diag_iter start, diag_iter end)
|
||
{
|
||
return diagonal.getAverageSize(start, end);
|
||
}
|
||
|
||
QuasiTriangular::diag_iter
|
||
QuasiTriangular::findClosestDiagBlock(diag_iter start, diag_iter end, double a)
|
||
{
|
||
return diagonal.findClosestBlock(start, end, a);
|
||
}
|
||
|
||
QuasiTriangular::diag_iter
|
||
QuasiTriangular::findNextLargerBlock(diag_iter start, diag_iter end, double a)
|
||
{
|
||
return diagonal.findNextLargerBlock(start, end, a);
|
||
}
|
||
|
||
int
|
||
QuasiTriangular::getNumOffdiagonal() const
|
||
{
|
||
return diagonal.getSize()*(diagonal.getSize()-1)/2 - diagonal.getNumComplex();
|
||
}
|