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Diffstat (limited to 'kaldi_io/src/kaldi/matrix/jama-svd.h')
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diff --git a/kaldi_io/src/kaldi/matrix/jama-svd.h b/kaldi_io/src/kaldi/matrix/jama-svd.h new file mode 100644 index 0000000..8304dac --- /dev/null +++ b/kaldi_io/src/kaldi/matrix/jama-svd.h @@ -0,0 +1,531 @@ +// matrix/jama-svd.h + +// Copyright 2009-2011 Microsoft Corporation + +// See ../../COPYING for clarification regarding multiple authors +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// http://www.apache.org/licenses/LICENSE-2.0 +// +// THIS CODE IS PROVIDED *AS IS* BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY +// KIND, EITHER EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED +// WARRANTIES OR CONDITIONS OF TITLE, FITNESS FOR A PARTICULAR PURPOSE, +// MERCHANTABLITY OR NON-INFRINGEMENT. +// See the Apache 2 License for the specific language governing permissions and +// limitations under the License. + +// This file consists of a port and modification of materials from +// JAMA: A Java Matrix Package +// under the following notice: This software is a cooperative product of +// The MathWorks and the National Institute of Standards and Technology (NIST) +// which has been released to the public. This notice and the original code are +// available at http://math.nist.gov/javanumerics/jama/domain.notice + + +#ifndef KALDI_MATRIX_JAMA_SVD_H_ +#define KALDI_MATRIX_JAMA_SVD_H_ 1 + + +#include "matrix/kaldi-matrix.h" +#include "matrix/sp-matrix.h" +#include "matrix/cblas-wrappers.h" + +namespace kaldi { + +#if defined(HAVE_ATLAS) || defined(USE_KALDI_SVD) +// using ATLAS as our math library, which doesn't have SVD -> need +// to implement it. + +// This routine is a modified form of jama_svd.h which is part of the TNT distribution. +// (originally comes from JAMA). + +/** Singular Value Decomposition. + * <P> + * For an m-by-n matrix A with m >= n, the singular value decomposition is + * an m-by-n orthogonal matrix U, an n-by-n diagonal matrix S, and + * an n-by-n orthogonal matrix V so that A = U*S*V'. + * <P> + * The singular values, sigma[k] = S(k, k), are ordered so that + * sigma[0] >= sigma[1] >= ... >= sigma[n-1]. + * <P> + * The singular value decompostion always exists, so the constructor will + * never fail. The matrix condition number and the effective numerical + * rank can be computed from this decomposition. + + * <p> + * (Adapted from JAMA, a Java Matrix Library, developed by jointly + * by the Mathworks and NIST; see http://math.nist.gov/javanumerics/jama). + */ + + +template<typename Real> +bool MatrixBase<Real>::JamaSvd(VectorBase<Real> *s_in, + MatrixBase<Real> *U_in, + MatrixBase<Real> *V_in) { // Destructive! + KALDI_ASSERT(s_in != NULL && U_in != this && V_in != this); + int wantu = (U_in != NULL), wantv = (V_in != NULL); + Matrix<Real> Utmp, Vtmp; + MatrixBase<Real> &U = (U_in ? *U_in : Utmp), &V = (V_in ? *V_in : Vtmp); + VectorBase<Real> &s = *s_in; + + int m = num_rows_, n = num_cols_; + KALDI_ASSERT(m>=n && m != 0 && n != 0); + if (wantu) KALDI_ASSERT((int)U.num_rows_ == m && (int)U.num_cols_ == n); + if (wantv) KALDI_ASSERT((int)V.num_rows_ == n && (int)V.num_cols_ == n); + KALDI_ASSERT((int)s.Dim() == n); // n<=m so n is min. + + int nu = n; + U.SetZero(); // make sure all zero. + Vector<Real> e(n); + Vector<Real> work(m); + MatrixBase<Real> &A(*this); + Real *adata = A.Data(), *workdata = work.Data(), *edata = e.Data(), + *udata = U.Data(), *vdata = V.Data(); + int astride = static_cast<int>(A.Stride()), + ustride = static_cast<int>(U.Stride()), + vstride = static_cast<int>(V.Stride()); + int i = 0, j = 0, k = 0; + + // Reduce A to bidiagonal form, storing the diagonal elements + // in s and the super-diagonal elements in e. + + int nct = std::min(m-1, n); + int nrt = std::max(0, std::min(n-2, m)); + for (k = 0; k < std::max(nct, nrt); k++) { + if (k < nct) { + + // Compute the transformation for the k-th column and + // place the k-th diagonal in s(k). + // Compute 2-norm of k-th column without under/overflow. + s(k) = 0; + for (i = k; i < m; i++) { + s(k) = hypot(s(k), A(i, k)); + } + if (s(k) != 0.0) { + if (A(k, k) < 0.0) { + s(k) = -s(k); + } + for (i = k; i < m; i++) { + A(i, k) /= s(k); + } + A(k, k) += 1.0; + } + s(k) = -s(k); + } + for (j = k+1; j < n; j++) { + if ((k < nct) && (s(k) != 0.0)) { + + // Apply the transformation. + + Real t = cblas_Xdot(m - k, adata + astride*k + k, astride, + adata + astride*k + j, astride); + /*for (i = k; i < m; i++) { + t += adata[i*astride + k]*adata[i*astride + j]; // A(i, k)*A(i, j); // 3 + }*/ + t = -t/A(k, k); + cblas_Xaxpy(m - k, t, adata + k*astride + k, astride, + adata + k*astride + j, astride); + /*for (i = k; i < m; i++) { + adata[i*astride + j] += t*adata[i*astride + k]; // A(i, j) += t*A(i, k); // 5 + }*/ + } + + // Place the k-th row of A into e for the + // subsequent calculation of the row transformation. + + e(j) = A(k, j); + } + if (wantu & (k < nct)) { + + // Place the transformation in U for subsequent back + // multiplication. + + for (i = k; i < m; i++) { + U(i, k) = A(i, k); + } + } + if (k < nrt) { + + // Compute the k-th row transformation and place the + // k-th super-diagonal in e(k). + // Compute 2-norm without under/overflow. + e(k) = 0; + for (i = k+1; i < n; i++) { + e(k) = hypot(e(k), e(i)); + } + if (e(k) != 0.0) { + if (e(k+1) < 0.0) { + e(k) = -e(k); + } + for (i = k+1; i < n; i++) { + e(i) /= e(k); + } + e(k+1) += 1.0; + } + e(k) = -e(k); + if ((k+1 < m) & (e(k) != 0.0)) { + + // Apply the transformation. + + for (i = k+1; i < m; i++) { + work(i) = 0.0; + } + for (j = k+1; j < n; j++) { + for (i = k+1; i < m; i++) { + workdata[i] += edata[j] * adata[i*astride + j]; // work(i) += e(j)*A(i, j); // 5 + } + } + for (j = k+1; j < n; j++) { + Real t(-e(j)/e(k+1)); + cblas_Xaxpy(m - (k+1), t, workdata + (k+1), 1, + adata + (k+1)*astride + j, astride); + /* + for (i = k+1; i < m; i++) { + adata[i*astride + j] += t*workdata[i]; // A(i, j) += t*work(i); // 5 + }*/ + } + } + if (wantv) { + + // Place the transformation in V for subsequent + // back multiplication. + + for (i = k+1; i < n; i++) { + V(i, k) = e(i); + } + } + } + } + + // Set up the final bidiagonal matrix or order p. + + int p = std::min(n, m+1); + if (nct < n) { + s(nct) = A(nct, nct); + } + if (m < p) { + s(p-1) = 0.0; + } + if (nrt+1 < p) { + e(nrt) = A(nrt, p-1); + } + e(p-1) = 0.0; + + // If required, generate U. + + if (wantu) { + for (j = nct; j < nu; j++) { + for (i = 0; i < m; i++) { + U(i, j) = 0.0; + } + U(j, j) = 1.0; + } + for (k = nct-1; k >= 0; k--) { + if (s(k) != 0.0) { + for (j = k+1; j < nu; j++) { + Real t = cblas_Xdot(m - k, udata + k*ustride + k, ustride, udata + k*ustride + j, ustride); + //for (i = k; i < m; i++) { + // t += udata[i*ustride + k]*udata[i*ustride + j]; // t += U(i, k)*U(i, j); // 8 + // } + t = -t/U(k, k); + cblas_Xaxpy(m - k, t, udata + ustride*k + k, ustride, + udata + k*ustride + j, ustride); + /*for (i = k; i < m; i++) { + udata[i*ustride + j] += t*udata[i*ustride + k]; // U(i, j) += t*U(i, k); // 4 + }*/ + } + for (i = k; i < m; i++ ) { + U(i, k) = -U(i, k); + } + U(k, k) = 1.0 + U(k, k); + for (i = 0; i < k-1; i++) { + U(i, k) = 0.0; + } + } else { + for (i = 0; i < m; i++) { + U(i, k) = 0.0; + } + U(k, k) = 1.0; + } + } + } + + // If required, generate V. + + if (wantv) { + for (k = n-1; k >= 0; k--) { + if ((k < nrt) & (e(k) != 0.0)) { + for (j = k+1; j < nu; j++) { + Real t = cblas_Xdot(n - (k+1), vdata + (k+1)*vstride + k, vstride, + vdata + (k+1)*vstride + j, vstride); + /*Real t (0.0); + for (i = k+1; i < n; i++) { + t += vdata[i*vstride + k]*vdata[i*vstride + j]; // t += V(i, k)*V(i, j); // 7 + }*/ + t = -t/V(k+1, k); + cblas_Xaxpy(n - (k+1), t, vdata + (k+1)*vstride + k, vstride, + vdata + (k+1)*vstride + j, vstride); + /*for (i = k+1; i < n; i++) { + vdata[i*vstride + j] += t*vdata[i*vstride + k]; // V(i, j) += t*V(i, k); // 7 + }*/ + } + } + for (i = 0; i < n; i++) { + V(i, k) = 0.0; + } + V(k, k) = 1.0; + } + } + + // Main iteration loop for the singular values. + + int pp = p-1; + int iter = 0; + // note: -52.0 is from Jama code; the -23 is the extension + // to float, because mantissa length in (double, float) + // is (52, 23) bits respectively. + Real eps(pow(2.0, sizeof(Real) == 4 ? -23.0 : -52.0)); + // Note: the -966 was taken from Jama code, but the -120 is a guess + // of how to extend this to float... the exponent in double goes + // from -1022 .. 1023, and in float from -126..127. I'm not sure + // what the significance of 966 is, so -120 just represents a number + // that's a bit less negative than -126. If we get convergence + // failure in float only, this may mean that we have to make the + // -120 value less negative. + Real tiny(pow(2.0, sizeof(Real) == 4 ? -120.0: -966.0 )); + + while (p > 0) { + int k = 0; + int kase = 0; + + if (iter == 500 || iter == 750) { + KALDI_WARN << "Svd taking a long time: making convergence criterion less exact."; + eps = pow(static_cast<Real>(0.8), eps); + tiny = pow(static_cast<Real>(0.8), tiny); + } + if (iter > 1000) { + KALDI_WARN << "Svd not converging on matrix of size " << m << " by " <<n; + return false; + } + + // This section of the program inspects for + // negligible elements in the s and e arrays. On + // completion the variables kase and k are set as follows. + + // kase = 1 if s(p) and e(k-1) are negligible and k < p + // kase = 2 if s(k) is negligible and k < p + // kase = 3 if e(k-1) is negligible, k < p, and + // s(k), ..., s(p) are not negligible (qr step). + // kase = 4 if e(p-1) is negligible (convergence). + + for (k = p-2; k >= -1; k--) { + if (k == -1) { + break; + } + if (std::abs(e(k)) <= + tiny + eps*(std::abs(s(k)) + std::abs(s(k+1)))) { + e(k) = 0.0; + break; + } + } + if (k == p-2) { + kase = 4; + } else { + int ks; + for (ks = p-1; ks >= k; ks--) { + if (ks == k) { + break; + } + Real t( (ks != p ? std::abs(e(ks)) : 0.) + + (ks != k+1 ? std::abs(e(ks-1)) : 0.)); + if (std::abs(s(ks)) <= tiny + eps*t) { + s(ks) = 0.0; + break; + } + } + if (ks == k) { + kase = 3; + } else if (ks == p-1) { + kase = 1; + } else { + kase = 2; + k = ks; + } + } + k++; + + // Perform the task indicated by kase. + + switch (kase) { + + // Deflate negligible s(p). + + case 1: { + Real f(e(p-2)); + e(p-2) = 0.0; + for (j = p-2; j >= k; j--) { + Real t( hypot(s(j), f)); + Real cs(s(j)/t); + Real sn(f/t); + s(j) = t; + if (j != k) { + f = -sn*e(j-1); + e(j-1) = cs*e(j-1); + } + if (wantv) { + for (i = 0; i < n; i++) { + t = cs*V(i, j) + sn*V(i, p-1); + V(i, p-1) = -sn*V(i, j) + cs*V(i, p-1); + V(i, j) = t; + } + } + } + } + break; + + // Split at negligible s(k). + + case 2: { + Real f(e(k-1)); + e(k-1) = 0.0; + for (j = k; j < p; j++) { + Real t(hypot(s(j), f)); + Real cs( s(j)/t); + Real sn(f/t); + s(j) = t; + f = -sn*e(j); + e(j) = cs*e(j); + if (wantu) { + for (i = 0; i < m; i++) { + t = cs*U(i, j) + sn*U(i, k-1); + U(i, k-1) = -sn*U(i, j) + cs*U(i, k-1); + U(i, j) = t; + } + } + } + } + break; + + // Perform one qr step. + + case 3: { + + // Calculate the shift. + + Real scale = std::max(std::max(std::max(std::max( + std::abs(s(p-1)), std::abs(s(p-2))), std::abs(e(p-2))), + std::abs(s(k))), std::abs(e(k))); + Real sp = s(p-1)/scale; + Real spm1 = s(p-2)/scale; + Real epm1 = e(p-2)/scale; + Real sk = s(k)/scale; + Real ek = e(k)/scale; + Real b = ((spm1 + sp)*(spm1 - sp) + epm1*epm1)/2.0; + Real c = (sp*epm1)*(sp*epm1); + Real shift = 0.0; + if ((b != 0.0) || (c != 0.0)) { + shift = std::sqrt(b*b + c); + if (b < 0.0) { + shift = -shift; + } + shift = c/(b + shift); + } + Real f = (sk + sp)*(sk - sp) + shift; + Real g = sk*ek; + + // Chase zeros. + + for (j = k; j < p-1; j++) { + Real t = hypot(f, g); + Real cs = f/t; + Real sn = g/t; + if (j != k) { + e(j-1) = t; + } + f = cs*s(j) + sn*e(j); + e(j) = cs*e(j) - sn*s(j); + g = sn*s(j+1); + s(j+1) = cs*s(j+1); + if (wantv) { + cblas_Xrot(n, vdata + j, vstride, vdata + j+1, vstride, cs, sn); + /*for (i = 0; i < n; i++) { + t = cs*vdata[i*vstride + j] + sn*vdata[i*vstride + j+1]; // t = cs*V(i, j) + sn*V(i, j+1); // 13 + vdata[i*vstride + j+1] = -sn*vdata[i*vstride + j] + cs*vdata[i*vstride + j+1]; // V(i, j+1) = -sn*V(i, j) + cs*V(i, j+1); // 5 + vdata[i*vstride + j] = t; // V(i, j) = t; // 4 + }*/ + } + t = hypot(f, g); + cs = f/t; + sn = g/t; + s(j) = t; + f = cs*e(j) + sn*s(j+1); + s(j+1) = -sn*e(j) + cs*s(j+1); + g = sn*e(j+1); + e(j+1) = cs*e(j+1); + if (wantu && (j < m-1)) { + cblas_Xrot(m, udata + j, ustride, udata + j+1, ustride, cs, sn); + /*for (i = 0; i < m; i++) { + t = cs*udata[i*ustride + j] + sn*udata[i*ustride + j+1]; // t = cs*U(i, j) + sn*U(i, j+1); // 7 + udata[i*ustride + j+1] = -sn*udata[i*ustride + j] +cs*udata[i*ustride + j+1]; // U(i, j+1) = -sn*U(i, j) + cs*U(i, j+1); // 8 + udata[i*ustride + j] = t; // U(i, j) = t; // 1 + }*/ + } + } + e(p-2) = f; + iter = iter + 1; + } + break; + + // Convergence. + + case 4: { + + // Make the singular values positive. + + if (s(k) <= 0.0) { + s(k) = (s(k) < 0.0 ? -s(k) : 0.0); + if (wantv) { + for (i = 0; i <= pp; i++) { + V(i, k) = -V(i, k); + } + } + } + + // Order the singular values. + + while (k < pp) { + if (s(k) >= s(k+1)) { + break; + } + Real t = s(k); + s(k) = s(k+1); + s(k+1) = t; + if (wantv && (k < n-1)) { + for (i = 0; i < n; i++) { + t = V(i, k+1); V(i, k+1) = V(i, k); V(i, k) = t; + } + } + if (wantu && (k < m-1)) { + for (i = 0; i < m; i++) { + t = U(i, k+1); U(i, k+1) = U(i, k); U(i, k) = t; + } + } + k++; + } + iter = 0; + p--; + } + break; + } + } + return true; +} + +#endif // defined(HAVE_ATLAS) || defined(USE_KALDI_SVD) + +} // namespace kaldi + +#endif // KALDI_MATRIX_JAMA_SVD_H_ |