#ifndef Magnum_Math_Algorithms_Svd_h #define Magnum_Math_Algorithms_Svd_h /* This file is part of Magnum. Copyright © 2010, 2011, 2012, 2013 Vladimír Vondruš Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /** @file * @brief Function Magnum::Math::Algorithms::svd() */ #include #include "Math/Functions.h" #include "Math/Matrix.h" namespace Magnum { namespace Math { namespace Algorithms { #ifndef DOXYGEN_GENERATING_OUTPUT namespace Implementation { template T pythagoras(T a, T b) { T absa = std::abs(a); T absb = std::abs(b); if(absa > absb) return absa*std::sqrt(T(1) + Math::pow<2>(absb/absa)); else if(absb == T(0)) /** @todo epsilon comparison? */ return T(0); else return absb*std::sqrt(T(1) + Math::pow<2>(absa/absb)); } template T smallestDelta(); template<> inline constexpr Float smallestDelta() { return 1.0e-32; } template<> inline constexpr Double smallestDelta() { return 1.0e-64; } } #endif /** @brief Singular Value Decomposition Performs Thin SVD on given matrix where @p rows >= @p cols: @f[ M = U \Sigma V^* @f] Returns first @p cols column vectors of @f$ U @f$, diagonal of @f$ \Sigma @f$ and non-transposed @f$ V @f$. If the solution doesn't converge, returns zero matrices. Full @f$ U @f$, @f$ \Sigma @f$ matrices and original @f$ M @f$ matrix can be reconstructed from the values as following: @code RectangularMatrix m; RectangularMatrix uPart; Vector wDiagonal; Matrix v; std::tie(uPart, wDiagonal, v) = Math::Algorithms::svd(m); // Extend U Matrix u(Matrix::Zero); for(std::size_t i = 0; i != rows; ++i) u[i] = uPart[i]; // Diagonal W RectangularMatrix w = RectangularMatrix::fromDiagonal(wDiagonal); // u*w*v.transposed() == m @endcode Implementation based on *Golub, G. H.; Reinsch, C. (1970). "Singular value decomposition and least squares solutions"*. */ /* The matrix is passed by value because it is changed inside */ template std::tuple, Vector, Matrix> svd(RectangularMatrix m) { static_assert(rows >= cols, "Unsupported matrix aspect ratio"); static_assert(T(1)+MathTypeTraits::epsilon() > T(1), "Epsilon too small"); constexpr T tol = Implementation::smallestDelta()/MathTypeTraits::epsilon(); static_assert(tol > T(0), "Tol too small"); constexpr std::size_t maxIterations = 50; Matrix v(Matrix::Zero); Vector e, q; /* Householder's reduction to bidiagonal form */ T g = T(0); T epsilonX = T(0); for(std::size_t i = 0; i != cols; ++i) { const std::size_t l = i+1; e[i] = g; T s1 = T(0); for(std::size_t j = i; j != rows; ++j) s1 += Math::pow<2>(m[i][j]); if(s1 > tol) { const T f = m[i][i]; g = (f < T(0) ? std::sqrt(s1) : -std::sqrt(s1)); const T h = f*g - s1; m[i][i] = f - g; for(std::size_t j = l; j != cols; ++j) { T s = T(0); for(std::size_t k = i; k != rows; ++k) s += m[i][k]*m[j][k]; const T f = s/h; for(std::size_t k = i; k != rows; ++k) m[j][k] += f*m[i][k]; } } else g = T(0); q[i] = g; T s2 = T(0); for(std::size_t j = l; j != cols; ++j) s2 += Math::pow<2>(m[j][i]); if(s2 > tol) { const T f = m[i+1][i]; g = (f < T(0) ? std::sqrt(s2) : -std::sqrt(s2)); const T h = f*g - s2; m[i+1][i] = f - g; for(std::size_t j = l; j != cols; ++j) e[j] = m[j][i]/h; for(std::size_t j = l; j != rows; ++j) { T s = T(0); for(std::size_t k = l; k != cols; ++k) s += m[k][j]*m[k][i]; for(std::size_t k = l; k != cols; ++k) m[k][j] += s*e[k]; } } else g = T(0); const T y = std::abs(q[i]) + std::abs(e[i]); if(y > epsilonX) epsilonX = y; } /* Accumulation of right hand transformations */ for(std::size_t l = cols; l != 0; --l) { const std::size_t i = l-1; if(g != T(0)) { /** @todo epsilon check? */ const T h = g*m[i+1][i]; for(std::size_t j = l; j != cols; ++j) v[i][j] = m[j][i]/h; for(std::size_t j = l; j != cols; ++j) { T s = T(0); for(std::size_t k = l; k != cols; ++k) s += m[k][i]*v[j][k]; for(std::size_t k = l; k != cols; ++k) v[j][k] += s*v[i][k]; } } for(std::size_t j = l; j != cols; ++j) v[j][i] = v[i][j] = T(0); v[i][i] = T(1); g = e[i]; } /* Accumulation of left hand transformations */ for(std::size_t l = cols; l != 0; --l) { const std::size_t i = l-1; for(std::size_t j = l; j != cols; ++j) m[j][i] = T(0); const T d = q[i]; if(d != T(0)) { /** @todo epsilon check? */ const T h = m[i][i]*d; for(std::size_t j = l; j != cols; ++j) { T s = T(0); for(std::size_t k = l; k != rows; ++k) s += m[i][k]*m[j][k]; const T f = s/h; for(std::size_t k = i; k != rows; ++k) m[j][k] += f*m[i][k]; } for(std::size_t j = i; j != rows; ++j) m[i][j] /= d; } else for(std::size_t j = i; j != rows; ++j) m[i][j] = T(0); m[i][i] += T(1); } /* Diagonalization of the bidiagonal form */ const T epsilon = MathTypeTraits::epsilon()*epsilonX; for(std::size_t k2 = cols; k2 != 0; --k2) { const std::size_t k = k2 - 1; for(std::size_t iteration = 0; iteration != maxIterations; ++iteration) { /* Test for splitting */ bool doCancellation = true; std::size_t l = 0; for(std::size_t l2 = k2; l2 != 0; --l2) { l = l2 - 1; if(std::abs(e[l]) <= epsilon) { doCancellation = false; break; } else if(std::abs(q[l-1]) <= epsilon) { break; } } /* Cancellation */ if(doCancellation) { const std::size_t l1 = l - 1; T c = T(0); T s = T(1); for(std::size_t i = l; i != k+1; ++i) { CORRADE_INTERNAL_ASSERT(i <= k+1); const T f = s*e[i]; e[i] = c*e[i]; if(std::abs(f) <= epsilon) break; const T g = q[i]; const T h = Implementation::pythagoras(f, g); q[i] = h; c = g/h; s = -f/h; const Vector a = m[l1]; const Vector b = m[i]; m[l1] = a*c+b*s; m[i] = -a*s+b*c; } } /* Test for convergence */ const T z = q[k]; if(l == k) { /* Invert to non-negative */ if(z < T(0)) { q[k] = -z; v[k] = -v[k]; } break; /* Exceeded iteration count, done */ } else if(iteration >= maxIterations-1) { Corrade::Utility::Error() << "Magnum::Math::Algorithms::svd(): no convergence"; return std::make_tuple(RectangularMatrix(), Vector(), Matrix(Matrix::Zero)); } /* Shift from bottom 2x2 minor */ const T y = q[k-1]; const T h = e[k]; const T d = e[k-1]; T x = q[l]; T f = ((y - z)*(y + z) + (d - h)*(d + h))/(T(2)*h*y); const T b = Implementation::pythagoras(f, T(1)); if(f < T(0)) f = ((x - z)*(x + z) + h*(y/(f - b) - h))/x; else f = ((x - z)*(x + z) + h*(y/(f + b) - h))/x; /* Next QR transformation */ /** @todo isn't this extractable elsewhere? */ T c = T(1); T s = T(1); for(std::size_t i = l+1; i != k+1; ++i) { CORRADE_INTERNAL_ASSERT(i <= k+1); const T g1 = c*e[i]; const T h1 = s*e[i]; const T y1 = q[i]; const T z1 = Implementation::pythagoras(f, h1); e[i-1] = z1; c = f/z1; s = h1/z1; f = x*c + g1*s; const T g2 = -x*s + g1*c; const T h2 = y1*s; const T y2 = y1*c; const Vector a1 = v[i-1]; const Vector b1 = v[i]; v[i-1] = a1*c+b1*s; v[i] = -a1*s+b1*c; const T z2 = Implementation::pythagoras(f, h2); q[i-1] = z2; c = f/z2; s = h2/z2; f = c*g2 + s*y2; x = -s*g2 + c*y2; const Vector a2 = m[i-1]; const Vector b2 = m[i]; m[i-1] = a2*c+b2*s; m[i] = -a2*s+b2*c; } e[l] = T(0); e[k] = f; q[k] = x; } } return std::make_tuple(m, q, v); } }}} #endif