/* * Copyright © 2004-2011 Ondra Kamenik * Copyright © 2019-2022 Dynare Team * * This file is part of Dynare. * * Dynare is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * Dynare is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with Dynare. If not, see . */ #include "SylvException.hh" #include "QuasiTriangular.hh" #include "QuasiTriangularZero.hh" #include "Vector.hh" #include "KronVector.hh" #include "KronUtils.hh" #include "TriangularSylvester.hh" #include "GeneralSylvester.hh" #include "SchurDecompEig.hh" #include "SimilarityDecomp.hh" #include "IterativeSylvester.hh" #include "SylvMatrix.hh" #include "int_power.hh" #include "MMMatrix.hh" #include #include #include #include #include #include #include class TestRunnable { public: const std::string name; static constexpr double eps_norm = 1.0e-10; TestRunnable(std::string n) : name(std::move(n)) { } virtual ~TestRunnable() = default; bool test() const; virtual bool run() const = 0; protected: // declaration of auxiliary static methods static bool quasi_solve(bool trans, const std::string &mname, const std::string &vname); static bool mult_kron(bool trans, const std::string &mname, const std::string &vname, const std::string &cname, int m, int n, int depth); static bool level_kron(bool trans, const std::string &mname, const std::string &vname, const std::string &cname, int level, int m, int n, int depth); static bool kron_power(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth); static bool lin_eval(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth, double alpha, double beta1, double beta2); static bool qua_eval(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth, double alpha, double betas, double gamma, double delta1, double delta2); static bool tri_sylv(const std::string &m1name, const std::string &m2name, const std::string &vname, int m, int n, int depth); static bool gen_sylv(const std::string &aname, const std::string &bname, const std::string &cname, const std::string &dname, int m, int n, int order); static bool eig_bubble(const std::string &aname, int from, int to); static bool block_diag(const std::string &aname, double log10norm = 3.0); static bool iter_sylv(const std::string &m1name, const std::string &m2name, const std::string &vname, int m, int n, int depth); }; bool TestRunnable::test() const { std::cout << "Running test <" << name << '>' << std::endl; clock_t start = clock(); bool passed = run(); clock_t end = clock(); std::cout << "CPU time " << (static_cast(end-start))/CLOCKS_PER_SEC << " (CPU seconds).................."; if (passed) std::cout << "passed"; else std::cout << "FAILED"; std::cout << std::endl << std::endl; return passed; } /**********************************************************/ /* auxiliary methods */ /**********************************************************/ bool TestRunnable::quasi_solve(bool trans, const std::string &mname, const std::string &vname) { MMMatrixIn mmt(mname); MMMatrixIn mmv(vname); std::unique_ptr t; std::unique_ptr tsave; if (mmt.row() == mmt.col()) { t = std::make_unique(mmt.getData(), mmt.row()); tsave = std::make_unique(*t); } else if (mmt.row() > mmt.col()) { t = std::make_unique(mmt.row()-mmt.col(), mmt.getData(), mmt.col()); tsave = std::make_unique(const_cast(dynamic_cast(*t))); } else { std::cout << " Wrong quasi triangular dimensions, rows must be >= cols.\n"; return false; } ConstVector v{mmv.getData()}; Vector x(v.length()); double eig_min = 1.0e20; if (trans) t->solveTrans(x, v, eig_min); else t->solve(x, v, eig_min); std::cout << "eig_min = " << eig_min << std::endl; Vector xx(v.length()); if (trans) tsave->multVecTrans(xx, ConstVector(x)); else tsave->multVec(xx, ConstVector(x)); xx.add(-1.0, v); xx.add(1.0, x); double norm = xx.getNorm(); std::cout << "\terror norm = " << norm << std::endl; return (norm < eps_norm); } bool TestRunnable::mult_kron(bool trans, const std::string &mname, const std::string &vname, const std::string &cname, int m, int n, int depth) { MMMatrixIn mmt(mname); MMMatrixIn mmv(vname); MMMatrixIn mmc(cname); int length = power(m, depth)*n; if (mmt.row() != m || mmv.row() != length || mmc.row() != length) { std::cout << " Incompatible sizes for kron mult action, len=" << length << ", matrow=" << mmt.row() << ", m=" << m << ", vrow=" << mmv.row() << ", crow=" << mmc.row() << std::endl; return false; } QuasiTriangular t(mmt.getData(), mmt.row()); Vector vraw{mmv.getData()}; KronVector v(vraw, m, n, depth); Vector craw{mmc.getData()}; KronVector c(craw, m, n, depth); if (trans) t.multKronTrans(v); else t.multKron(v); c.add(-1.0, v); double norm = c.getNorm(); std::cout << "\terror norm = " << norm << std::endl; return (norm < eps_norm); } bool TestRunnable::level_kron(bool trans, const std::string &mname, const std::string &vname, const std::string &cname, int level, int m, int n, int depth) { MMMatrixIn mmt(mname); MMMatrixIn mmv(vname); MMMatrixIn mmc(cname); int length = power(m, depth)*n; if ((level > 0 && mmt.row() != m) || (level == 0 && mmt.row() != n) || mmv.row() != length || mmc.row() != length) { std::cout << " Incompatible sizes for kron mult action, len=" << length << ", matrow=" << mmt.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << ", crow=" << mmc.row() << std::endl; return false; } QuasiTriangular t(mmt.getData(), mmt.row()); Vector vraw{mmv.getData()}; ConstKronVector v(vraw, m, n, depth); Vector craw{mmc.getData()}; KronVector c(craw, m, n, depth); KronVector x(v); if (trans) KronUtils::multAtLevelTrans(level, t, x); else KronUtils::multAtLevel(level, t, x); x.add(-1, c); double norm = x.getNorm(); std::cout << "\terror norm = " << norm << std::endl; return (norm < eps_norm); } bool TestRunnable::kron_power(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth) { MMMatrixIn mmt1(m1name); MMMatrixIn mmt2(m2name); MMMatrixIn mmv(vname); MMMatrixIn mmc(cname); int length = power(m, depth)*n; if (mmt1.row() != m || mmt2.row() != n || mmv.row() != length || mmc.row() != length) { std::cout << " Incompatible sizes for kron power mult action, len=" << length << ", row1=" << mmt1.row() << ", row2=" << mmt2.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << ", crow=" << mmc.row() << std::endl; return false; } QuasiTriangular t1(mmt1.getData(), mmt1.row()); QuasiTriangular t2(mmt2.getData(), mmt2.row()); Vector vraw{mmv.getData()}; ConstKronVector v(vraw, m, n, depth); Vector craw{mmc.getData()}; KronVector c(craw, m, n, depth); KronVector x(v); KronUtils::multKron(t1, t2, x); x.add(-1, c); double norm = x.getNorm(); std::cout << "\terror norm = " << norm << std::endl; return (norm < eps_norm); } bool TestRunnable::lin_eval(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth, double alpha, double beta1, double beta2) { MMMatrixIn mmt1(m1name); MMMatrixIn mmt2(m2name); MMMatrixIn mmv(vname); MMMatrixIn mmc(cname); int length = power(m, depth)*n; if (mmt1.row() != m || mmt2.row() != n || mmv.row() != 2*length || mmc.row() != 2*length) { std::cout << " Incompatible sizes for lin eval action, len=" << length << ", row1=" << mmt1.row() << ", row2=" << mmt2.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << ", crow=" << mmc.row() << std::endl; return false; } QuasiTriangular t1(mmt1.getData(), mmt1.row()); QuasiTriangular t2(mmt2.getData(), mmt2.row()); TriangularSylvester ts(t2, t1); ConstVector vraw1{mmv.getData(), 0, length}; ConstKronVector v1(vraw1, m, n, depth); ConstVector vraw2{mmv.getData(), length, length}; ConstKronVector v2(vraw2, m, n, depth); ConstVector craw1{mmc.getData(), 0, length}; ConstKronVector c1(craw1, m, n, depth); ConstVector craw2{mmc.getData(), length, length}; ConstKronVector c2(craw2, m, n, depth); KronVector x1(m, n, depth); KronVector x2(m, n, depth); ts.linEval(alpha, beta1, beta2, x1, x2, v1, v2); x1.add(-1, c1); x2.add(-1, c2); double norm1 = x1.getNorm(); double norm2 = x2.getNorm(); std::cout << "\terror norm1 = " << norm1 << "\n\terror norm2 = " << norm2 << '\n'; return (norm1*norm1+norm2*norm2 < eps_norm*eps_norm); } bool TestRunnable::qua_eval(const std::string &m1name, const std::string &m2name, const std::string &vname, const std::string &cname, int m, int n, int depth, double alpha, double betas, double gamma, double delta1, double delta2) { MMMatrixIn mmt1(m1name); MMMatrixIn mmt2(m2name); MMMatrixIn mmv(vname); MMMatrixIn mmc(cname); int length = power(m, depth)*n; if (mmt1.row() != m || mmt2.row() != n || mmv.row() != 2*length || mmc.row() != 2*length) { std::cout << " Incompatible sizes for qua eval action, len=" << length << ", row1=" << mmt1.row() << ", row2=" << mmt2.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << ", crow=" << mmc.row() << std::endl; return false; } QuasiTriangular t1(mmt1.getData(), mmt1.row()); QuasiTriangular t2(mmt2.getData(), mmt2.row()); TriangularSylvester ts(t2, t1); ConstVector vraw1{mmv.getData(), 0, length}; ConstKronVector v1(vraw1, m, n, depth); ConstVector vraw2{mmv.getData(), length, length}; ConstKronVector v2(vraw2, m, n, depth); ConstVector craw1{mmc.getData(), 0, length}; ConstKronVector c1(craw1, m, n, depth); ConstVector craw2{mmc.getData(), length, length}; ConstKronVector c2(craw2, m, n, depth); KronVector x1(m, n, depth); KronVector x2(m, n, depth); ts.quaEval(alpha, betas, gamma, delta1, delta2, x1, x2, v1, v2); x1.add(-1, c1); x2.add(-1, c2); double norm1 = x1.getNorm(); double norm2 = x2.getNorm(); std::cout << "\terror norm1 = " << norm1 << "\n\terror norm2 = " << norm2 << std::endl; return (norm1*norm1+norm2*norm2 < 100*eps_norm*eps_norm); // relax norm } bool TestRunnable::tri_sylv(const std::string &m1name, const std::string &m2name, const std::string &vname, int m, int n, int depth) { MMMatrixIn mmt1(m1name); MMMatrixIn mmt2(m2name); MMMatrixIn mmv(vname); int length = power(m, depth)*n; if (mmt1.row() != m || mmt2.row() != n || mmv.row() != length) { std::cout << " Incompatible sizes for triangular sylvester action, len=" << length << ", row1=" << mmt1.row() << ", row2=" << mmt2.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << std::endl; return false; } QuasiTriangular t1(mmt1.getData(), mmt1.row()); QuasiTriangular t2(mmt2.getData(), mmt2.row()); TriangularSylvester ts(t2, t1); Vector vraw{mmv.getData()}; ConstKronVector v(vraw, m, n, depth); KronVector d(v); // copy of v SylvParams pars; ts.solve(pars, d); pars.print("\t"); KronVector dcheck(const_cast(d)); KronUtils::multKron(t1, t2, dcheck); dcheck.add(1.0, d); dcheck.add(-1.0, v); double norm = dcheck.getNorm(); double xnorm = v.getNorm(); std::cout << "\trel. error norm = " << norm/xnorm << std::endl; double max = dcheck.getMax(); double xmax = v.getMax(); std::cout << "\trel. error max = " << max/xmax << std::endl; return (norm < xnorm*eps_norm); } bool TestRunnable::gen_sylv(const std::string &aname, const std::string &bname, const std::string &cname, const std::string &dname, int m, int n, int order) { MMMatrixIn mma(aname); MMMatrixIn mmb(bname); MMMatrixIn mmc(cname); MMMatrixIn mmd(dname); if (m != mmc.row() || m != mmc.col() || n != mma.row() || n != mma.col() || n != mmb.row() || n < mmb.col() || n != mmd.row() || power(m, order) != mmd.col()) { std::cout << " Incompatible sizes for gen_sylv.\n"; return false; } SylvParams ps(true); GeneralSylvester gs(order, n, m, n-mmb.col(), mma.getData(), mmb.getData(), mmc.getData(), mmd.getData(), ps); gs.solve(); gs.check(mmd.getData()); const SylvParams &pars = gs.getParams(); pars.print("\t"); return (*(pars.mat_err1) < eps_norm && *(pars.mat_errI) < eps_norm && *(pars.mat_errF) < eps_norm && *(pars.vec_err1) < eps_norm && *(pars.vec_errI) < eps_norm); } bool TestRunnable::eig_bubble(const std::string &aname, int from, int to) { MMMatrixIn mma(aname); if (mma.row() != mma.col()) { std::cout << " Matrix is not square\n"; return false; } int n = mma.row(); QuasiTriangular orig(mma.getData(), n); SchurDecompEig dec(const_cast(orig)); QuasiTriangular::diag_iter itf = dec.getT().diag_begin(); QuasiTriangular::diag_iter itt = dec.getT().diag_begin(); for (int i = 0; i < from; i++) ++itf; for (int i = 0; i < to; i++) ++itt; itt = dec.bubbleEigen(itf, itt); SqSylvMatrix check(dec.getQ() * dec.getT()); check.multRightTrans(dec.getQ()); check.add(-1, orig); double norm1 = check.getNorm1(); double normInf = check.getNormInf(); double onorm1 = orig.getNorm1(); double onormInf = orig.getNormInf(); std::cout << "\tabs. error1 = " << norm1 << std::endl << "\tabs. error∞ = " << normInf << std::endl << "\trel. error1 = " << norm1/onorm1 << std::endl << "\trel. error∞ = " << normInf/onormInf << std::endl; return (norm1 < eps_norm*onorm1 && normInf < eps_norm*onormInf); } bool TestRunnable::block_diag(const std::string &aname, double log10norm) { MMMatrixIn mma(aname); if (mma.row() != mma.col()) { std::cout << " Matrix is not square\n"; return false; } int n = mma.row(); SqSylvMatrix orig(mma.getData(), n); SimilarityDecomp dec(orig.getData(), orig.nrows(), log10norm); dec.getB().printInfo(); SqSylvMatrix check(dec.getQ() * dec.getB()); check.multRight(dec.getInvQ()); check.add(-1, orig); double norm1 = check.getNorm1(); double normInf = check.getNormInf(); double onorm1 = orig.getNorm1(); double onormInf = orig.getNormInf(); std::cout << "\terror Q·B·Q⁻¹:" << std::endl << "\tabs. error1 = " << norm1 << std::endl << "\tabs. error∞ = " << normInf << std::endl << "\trel. error1 = " << norm1/onorm1 << std::endl << "\trel. error∞ = " << normInf/onormInf << std::endl; SqSylvMatrix check2(dec.getQ() * dec.getInvQ()); SqSylvMatrix in(n); in.setUnit(); check2.add(-1, in); double nor1 = check2.getNorm1(); double norInf = check2.getNormInf(); std::cout << "\terror Q·Q⁻¹:" << std::endl << "\tabs. error1 = " << nor1 << std::endl << "\tabs. error∞ = " << norInf << std::endl; return (norm1 < eps_norm*pow(10, log10norm)*onorm1); } bool TestRunnable::iter_sylv(const std::string &m1name, const std::string &m2name, const std::string &vname, int m, int n, int depth) { MMMatrixIn mmt1(m1name); MMMatrixIn mmt2(m2name); MMMatrixIn mmv(vname); int length = power(m, depth)*n; if (mmt1.row() != m || mmt2.row() != n || mmv.row() != length) { std::cout << " Incompatible sizes for triangular sylvester iteration, len=" << length << ", row1=" << mmt1.row() << ", row2=" << mmt2.row() << ", m=" << m << ", n=" << n << ", vrow=" << mmv.row() << std::endl; return false; } QuasiTriangular t1(mmt1.getData(), mmt1.row()); QuasiTriangular t2(mmt2.getData(), mmt2.row()); IterativeSylvester is(t2, t1); Vector vraw{mmv.getData()}; ConstKronVector v(vraw, m, n, depth); KronVector d(v); // copy of v SylvParams pars; pars.method = SylvParams::solve_method::iter; is.solve(pars, d); pars.print("\t"); KronVector dcheck(const_cast(d)); KronUtils::multKron(t1, t2, dcheck); dcheck.add(1.0, d); dcheck.add(-1.0, v); double cnorm = dcheck.getNorm(); double xnorm = v.getNorm(); std::cout << "\trel. error norm = " << cnorm/xnorm << std::endl; double max = dcheck.getMax(); double xmax = v.getMax(); std::cout << "\trel. error max = " << max/xmax << std::endl; return (cnorm < xnorm*eps_norm); } /**********************************************************/ /* sub classes declarations */ /**********************************************************/ class PureTriangTest : public TestRunnable { public: PureTriangTest() : TestRunnable("pure triangular solve (5)") { } bool run() const override; }; class PureTriangTransTest : public TestRunnable { public: PureTriangTransTest() : TestRunnable("pure triangular solve trans (5)") { } bool run() const override; }; class PureTrLargeTest : public TestRunnable { public: PureTrLargeTest() : TestRunnable("pure triangular large solve (300)") { } bool run() const override; }; class PureTrLargeTransTest : public TestRunnable { public: PureTrLargeTransTest() : TestRunnable("pure triangular large solve trans (300)") { } bool run() const override; }; class QuasiTriangTest : public TestRunnable { public: QuasiTriangTest() : TestRunnable("quasi triangular solve (7)") { } bool run() const override; }; class QuasiTriangTransTest : public TestRunnable { public: QuasiTriangTransTest() : TestRunnable("quasi triangular solve trans (7)") { } bool run() const override; }; class QuasiTrLargeTest : public TestRunnable { public: QuasiTrLargeTest() : TestRunnable("quasi triangular solve large (250)") { } bool run() const override; }; class QuasiTrLargeTransTest : public TestRunnable { public: QuasiTrLargeTransTest() : TestRunnable("quasi triangular solve large trans (250)") { } bool run() const override; }; class QuasiZeroSmallTest : public TestRunnable { public: QuasiZeroSmallTest() : TestRunnable("quasi tr. zero small test (2×1)") { } bool run() const override; }; class MultKronSmallTest : public TestRunnable { public: MultKronSmallTest() : TestRunnable("kronecker small mult (2=2×1)") { } bool run() const override; }; class MultKronTest : public TestRunnable { public: MultKronTest() : TestRunnable("kronecker mult (245=7×7×5)") { } bool run() const override; }; class MultKronSmallTransTest : public TestRunnable { public: MultKronSmallTransTest() : TestRunnable("kronecker small trans mult (2=2×1)") { } bool run() const override; }; class MultKronTransTest : public TestRunnable { public: MultKronTransTest() : TestRunnable("kronecker trans mult (245=7×7×5)") { } bool run() const override; }; class LevelKronTest : public TestRunnable { public: LevelKronTest() : TestRunnable("kronecker level mult (1715=7×[7]×7×5)") { } bool run() const override; }; class LevelKronTransTest : public TestRunnable { public: LevelKronTransTest() : TestRunnable("kronecker level trans mult (1715=7×[7]×7×5)") { } bool run() const override; }; class LevelZeroKronTest : public TestRunnable { public: LevelZeroKronTest() : TestRunnable("kronecker level mult (1715=7×7×7×[5])") { } bool run() const override; }; class LevelZeroKronTransTest : public TestRunnable { public: LevelZeroKronTransTest() : TestRunnable("kronecker level trans mult (1715=7×7×7×[5])") { } bool run() const override; }; class KronPowerTest : public TestRunnable { public: KronPowerTest() : TestRunnable("kronecker power mult (1715=7×7×7×5)") { } bool run() const override; }; class SmallLinEvalTest : public TestRunnable { public: SmallLinEvalTest() : TestRunnable("lin eval (24=2 × 2×2×3)") { } bool run() const override; }; class LinEvalTest : public TestRunnable { public: LinEvalTest() : TestRunnable("lin eval (490=2 × 7×7×5)") { } bool run() const override; }; class SmallQuaEvalTest : public TestRunnable { public: SmallQuaEvalTest() : TestRunnable("qua eval (24=2 × 2×2×3)") { } bool run() const override; }; class QuaEvalTest : public TestRunnable { public: QuaEvalTest() : TestRunnable("qua eval (490=2 × 7×7×5)") { } bool run() const override; }; class TriSylvSmallRealTest : public TestRunnable { public: TriSylvSmallRealTest() : TestRunnable("triangular sylvester small real solve (12=2×2×3)") { } bool run() const override; }; class TriSylvSmallComplexTest : public TestRunnable { public: TriSylvSmallComplexTest() : TestRunnable("triangular sylvester small complx solve (12=2×2×3)") { } bool run() const override; }; class TriSylvTest : public TestRunnable { public: TriSylvTest() : TestRunnable("triangular sylvester solve (245=7×7×5)") { } bool run() const override; }; class TriSylvBigTest : public TestRunnable { public: TriSylvBigTest() : TestRunnable("triangular sylvester big solve (48000=40×40×30)") { } bool run() const override; }; class TriSylvLargeTest : public TestRunnable { public: TriSylvLargeTest() : TestRunnable("triangular sylvester large solve (1920000=40×40×40×30)") { } bool run() const override; }; class IterSylvTest : public TestRunnable { public: IterSylvTest() : TestRunnable("iterative sylvester solve (245=7×7×5)") { } bool run() const override; }; class IterSylvLargeTest : public TestRunnable { public: IterSylvLargeTest() : TestRunnable("iterative sylvester large solve (1920000=40×40×40×30)") { } bool run() const override; }; class GenSylvSmallTest : public TestRunnable { public: GenSylvSmallTest() : TestRunnable("general sylvester small solve (18=3×3×2)") { } bool run() const override; }; class GenSylvTest : public TestRunnable { public: GenSylvTest() : TestRunnable("general sylvester solve (12000=20×20×30)") { } bool run() const override; }; class GenSylvSingTest : public TestRunnable { public: GenSylvSingTest() : TestRunnable("general sylvester solve for sing. C (2500000=50×50×50×20)") { } bool run() const override; }; class GenSylvLargeTest : public TestRunnable { public: GenSylvLargeTest() : TestRunnable("general sylvester solve (2500000=50×50×50×20)") { } bool run() const override; }; class EigBubFrankTest : public TestRunnable { public: EigBubFrankTest() : TestRunnable("eig. bubble frank test (12×12)") { } bool run() const override; }; class EigBubSplitTest : public TestRunnable { // complex eigenvalue is split by swapping it with real public: EigBubSplitTest() : TestRunnable("eig. bubble complex split test (3×3)") { } bool run() const override; }; class EigBubSameTest : public TestRunnable { // complex eigenevalue bypasses the same complex eigenvalue public: EigBubSameTest() : TestRunnable("eig. bubble same test (5×5)") { } bool run() const override; }; class BlockDiagSmallTest : public TestRunnable { public: BlockDiagSmallTest() : TestRunnable("block diagonalization small test (7×7)") { } bool run() const override; }; class BlockDiagFrankTest : public TestRunnable { public: BlockDiagFrankTest() : TestRunnable("block diagonalization of frank (12×12)") { } bool run() const override; }; class BlockDiagIllCondTest : public TestRunnable { public: BlockDiagIllCondTest() : TestRunnable("block diagonalization of ill conditioned (15×15)") { } bool run() const override; }; class BlockDiagBigTest : public TestRunnable { public: BlockDiagBigTest() : TestRunnable("block diagonalization big test (50×50)") { } bool run() const override; }; /**********************************************************/ /* run methods of sub classes */ /**********************************************************/ bool PureTriangTest::run() const { return quasi_solve(false, "tr5x5.mm", "v5.mm"); } bool PureTriangTransTest::run() const { return quasi_solve(true, "tr5x5.mm", "v5.mm"); } bool PureTrLargeTest::run() const { return quasi_solve(false, "tr300x300.mm", "v300.mm"); } bool PureTrLargeTransTest::run() const { return quasi_solve(true, "tr300x300.mm", "v300.mm"); } bool QuasiTriangTest::run() const { return quasi_solve(false, "qt7x7.mm", "v7.mm"); } bool QuasiTriangTransTest::run() const { return quasi_solve(true, "qt7x7.mm", "v7.mm"); } bool QuasiTrLargeTest::run() const { return quasi_solve(false, "qt250x250.mm", "v250.mm"); } bool QuasiTrLargeTransTest::run() const { return quasi_solve(true, "qt250x250.mm", "v250.mm"); } bool QuasiZeroSmallTest::run() const { return quasi_solve(false, "b2x1.mm", "v2.mm"); } bool MultKronSmallTest::run() const { return mult_kron(false, "tr2x2.mm", "v2.mm", "vcheck2.mm", 2, 1, 1); } bool MultKronTest::run() const { return mult_kron(false, "qt7x7.mm", "v245.mm", "vcheck245.mm", 7, 5, 2); } bool MultKronSmallTransTest::run() const { return mult_kron(true, "tr2x2.mm", "v2.mm", "vcheck2a.mm", 2, 1, 1); } bool MultKronTransTest::run() const { return mult_kron(true, "qt7x7.mm", "v245.mm", "vcheck245a.mm", 7, 5, 2); } bool LevelKronTest::run() const { return level_kron(false, "qt7x7.mm", "v1715.mm", "vcheck1715.mm", 2, 7, 5, 3); } bool LevelKronTransTest::run() const { return level_kron(true, "qt7x7.mm", "v1715.mm", "vcheck1715a.mm", 2, 7, 5, 3); } bool LevelZeroKronTest::run() const { return level_kron(false, "tr5x5.mm", "v1715.mm", "vcheck1715b.mm", 0, 7, 5, 3); } bool LevelZeroKronTransTest::run() const { return level_kron(true, "tr5x5.mm", "v1715.mm", "vcheck1715c.mm", 0, 7, 5, 3); } bool KronPowerTest::run() const { return kron_power("qt7x7.mm", "tr5x5.mm", "v1715.mm", "vcheck1715d.mm", 7, 5, 3); } bool SmallLinEvalTest::run() const { return lin_eval("qt2x2.mm", "qt3x3.mm", "v24.mm", "vcheck24.mm", 2, 3, 2, 2, 1, 3); } bool LinEvalTest::run() const { return lin_eval("qt7x7.mm", "tr5x5.mm", "v490.mm", "vcheck490.mm", 7, 5, 2, 2, 1, 3); } bool SmallQuaEvalTest::run() const { return qua_eval("qt2x2.mm", "qt3x3.mm", "v24.mm", "vcheck24q.mm", 2, 3, 2, -0.5, 3, 2, 1, 3); } bool QuaEvalTest::run() const { return qua_eval("qt7x7.mm", "tr5x5.mm", "v490.mm", "vcheck490q.mm", 7, 5, 2, -0.5, 3, 2, 1, 3); } bool TriSylvSmallRealTest::run() const { return tri_sylv("tr2x2.mm", "qt3x3.mm", "v12r.mm", 2, 3, 2); } bool TriSylvSmallComplexTest::run() const { return tri_sylv("qt2x2.mm", "qt3x3.mm", "v12r.mm", 2, 3, 2); } bool TriSylvTest::run() const { return tri_sylv("qt7x7eig06-09.mm", "tr5x5.mm", "v245r.mm", 7, 5, 2); } bool TriSylvBigTest::run() const { return tri_sylv("qt40x40.mm", "qt30x30eig011-095.mm", "v48000.mm", 40, 30, 2); } bool TriSylvLargeTest::run() const { return tri_sylv("qt40x40.mm", "qt30x30eig011-095.mm", "v1920000.mm", 40, 30, 3); } bool IterSylvTest::run() const { return iter_sylv("qt7x7eig06-09.mm", "qt5x5.mm", "v245r.mm", 7, 5, 2); } bool IterSylvLargeTest::run() const { return iter_sylv("qt40x40.mm", "qt30x30eig011-095.mm", "v1920000.mm", 40, 30, 3); } bool GenSylvSmallTest::run() const { return gen_sylv("a2x2.mm", "b2x1.mm", "c3x3.mm", "d2x9.mm", 3, 2, 2); } bool GenSylvTest::run() const { return gen_sylv("a30x30.mm", "b30x25.mm", "c20x20.mm", "d30x400.mm", 20, 30, 2); } bool GenSylvSingTest::run() const { return gen_sylv("a20x20.mm", "b20x4.mm", "c50x50sing.mm", "d20x125000.mm", 50, 20, 3); } bool GenSylvLargeTest::run() const { return gen_sylv("a20x20.mm", "b20x15.mm", "c50x50.mm", "d20x125000.mm", 50, 20, 3); } bool EigBubFrankTest::run() const { return eig_bubble("qt_frank12x12.mm", 8, 0); } bool EigBubSplitTest::run() const { return eig_bubble("qt_eps3x3.mm", 1, 0); } bool EigBubSameTest::run() const { return eig_bubble("qt5x5.mm", 2, 0); } bool BlockDiagSmallTest::run() const { return block_diag("qt7x7.mm", 0.1); } bool BlockDiagFrankTest::run() const { return block_diag("qt_frank12x12.mm", 5); } bool BlockDiagIllCondTest::run() const { return block_diag("ill_cond15x15.mm", 4.14); } bool BlockDiagBigTest::run() const { return block_diag("c50x50.mm", 1.3); } /**********************************************************/ /* main */ /**********************************************************/ int main() { std::vector> all_tests; // fill in vector of all tests all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); all_tests.push_back(std::make_unique()); // launch the tests std::cout << std::setprecision(4); int success = 0; for (const auto &test : all_tests) { try { if (test->test()) success++; } catch (const MMException &e) { std::cout << "Caught MM exception in <" << test->name << ">:\n" << e.getMessage(); } catch (SylvException &e) { std::cout << "Caught Sylv exception in " << test->name << ":\n"; e.printMessage(); } } int nfailed = all_tests.size() - success; std::cout << "There were " << nfailed << " tests that failed out of " << all_tests.size() << " tests run." << std::endl; if (nfailed) return EXIT_FAILURE; else return EXIT_SUCCESS; }