#include #include #include #include /* See Golub and Reinsch, * "Handbook for Automatic Computation vol II - Linear Algebra", * Springer, 1971 */ #define MAX_ITERATION_COUNT 30 /* Perform Householder reduction to bidiagonal form * * Input: Matrix A of size nrows x ncols * * Output: Matrices and vectors such that * A = U*Bidiag(diagonal, superdiagonal)*Vt * * All matrices are allocated by the caller * * Sizes: * A, U: nrows x ncols * diagonal, superdiagonal: ncols * V: ncols x ncols */ static void householder_reduction (double *A, int nrows, int ncols, double *U, double *V, double *diagonal, double *superdiagonal) { int i, j, k, ip1; double s, s2, si, scale; double *pu, *pui, *pv, *pvi; double half_norm_squared; memcpy (U, A, sizeof (double) * nrows * ncols); diagonal[0] = 0.0; s = 0.0; scale = 0.0; for (i = 0, pui = U, ip1 = 1; i < ncols; pui += ncols, i++, ip1++) { superdiagonal[i] = scale * s; for (j = i, pu = pui, scale = 0.0; j < nrows; j++, pu += ncols) scale += fabs( *(pu + i) ); if (scale > 0.0) { for (j = i, pu = pui, s2 = 0.0; j < nrows; j++, pu += ncols) { *(pu + i) /= scale; s2 += *(pu + i) * *(pu + i); } s = *(pui + i) < 0.0 ? sqrt (s2) : -sqrt (s2); half_norm_squared = *(pui + i) * s - s2; *(pui + i) -= s; for (j = ip1; j < ncols; j++) { for (k = i, si = 0.0, pu = pui; k < nrows; k++, pu += ncols) si += *(pu + i) * *(pu + j); si /= half_norm_squared; for (k = i, pu = pui; k < nrows; k++, pu += ncols) *(pu + j) += si * *(pu + i); } } for (j = i, pu = pui; j < nrows; j++, pu += ncols) *(pu + i) *= scale; diagonal[i] = s * scale; s = 0.0; scale = 0.0; if (i >= nrows || i == ncols - 1) continue; for (j = ip1; j < ncols; j++) scale += fabs (*(pui + j)); if (scale > 0.0) { for (j = ip1, s2 = 0.0; j < ncols; j++) { *(pui + j) /= scale; s2 += *(pui + j) * *(pui + j); } s = *(pui + ip1) < 0.0 ? sqrt (s2) : -sqrt (s2); half_norm_squared = *(pui + ip1) * s - s2; *(pui + ip1) -= s; for (k = ip1; k < ncols; k++) superdiagonal[k] = *(pui + k) / half_norm_squared; if (i < (nrows - 1)) { for (j = ip1, pu = pui + ncols; j < nrows; j++, pu += ncols) { for (k = ip1, si = 0.0; k < ncols; k++) si += *(pui + k) * *(pu + k); for (k = ip1; k < ncols; k++) *(pu + k) += si * superdiagonal[k]; } } for (k = ip1; k < ncols; k++) *(pui + k) *= scale; } } pui = U + ncols * (ncols - 2); pvi = V + ncols * (ncols - 1); *(pvi + ncols - 1) = 1.0; s = superdiagonal[ncols - 1]; pvi -= ncols; for (i = ncols - 2, ip1 = ncols - 1; i >= 0; i--, pui -= ncols, pvi -= ncols, ip1--) { if (s != 0.0) { pv = pvi + ncols; for (j = ip1; j < ncols; j++, pv += ncols) *(pv + i) = ( *(pui + j) / *(pui + ip1) ) / s; for (j = ip1; j < ncols; j++) { si = 0.0; for (k = ip1, pv = pvi + ncols; k < ncols; k++, pv += ncols) si += *(pui + k) * *(pv + j); for (k = ip1, pv = pvi + ncols; k < ncols; k++, pv += ncols) *(pv + j) += si * *(pv + i); } } pv = pvi + ncols; for (j = ip1; j < ncols; j++, pv += ncols) { *(pvi + j) = 0.0; *(pv + i) = 0.0; } *(pvi + i) = 1.0; s = superdiagonal[i]; } pui = U + ncols * (ncols - 1); for (i = ncols - 1, ip1 = ncols; i >= 0; ip1 = i, i--, pui -= ncols) { s = diagonal[i]; for (j = ip1; j < ncols; j++) *(pui + j) = 0.0; if (s != 0.0) { for (j = ip1; j < ncols; j++) { si = 0.0; pu = pui + ncols; for (k = ip1; k < nrows; k++, pu += ncols) si += *(pu + i) * *(pu + j); si = (si / *(pui + i)) / s; for (k = i, pu = pui; k < nrows; k++, pu += ncols) *(pu + j) += si * *(pu + i); } for (j = i, pu = pui; j < nrows; j++, pu += ncols) *(pu + i) /= s; } else for (j = i, pu = pui; j < nrows; j++, pu += ncols) *(pu + i) = 0.0; *(pui + i) += 1.0; } } /* Perform Givens reduction * * Input: Matrices such that * A = U*Bidiag(diagonal,superdiagonal)*Vt * * Output: The same, with superdiagonal = 0 * * All matrices are allocated by the caller * * Sizes: * U: nrows x ncols * diagonal, superdiagonal: ncols * V: ncols x ncols */ static int givens_reduction (int nrows, int ncols, double *U, double *V, double *diagonal, double *superdiagonal) { double epsilon; double c, s; double f,g,h; double x,y,z; double *pu, *pv; int i,j,k,m; int rotation_test; int iteration_count; for (i = 0, x = 0.0; i < ncols; i++) { y = fabs (diagonal[i]) + fabs (superdiagonal[i]); if (x < y) x = y; } epsilon = x * DBL_EPSILON; for (k = ncols - 1; k >= 0; k--) { iteration_count = 0; while (1) { rotation_test = 1; for (m = k; m >= 0; m--) { if (fabs (superdiagonal[m]) <= epsilon) { rotation_test = 0; break; } if (fabs (diagonal[m-1]) <= epsilon) break; } if (rotation_test) { c = 0.0; s = 1.0; for (i = m; i <= k; i++) { f = s * superdiagonal[i]; superdiagonal[i] *= c; if (fabs (f) <= epsilon) break; g = diagonal[i]; h = sqrt (f*f + g*g); diagonal[i] = h; c = g / h; s = -f / h; for (j = 0, pu = U; j < nrows; j++, pu += ncols) { y = *(pu + m - 1); z = *(pu + i); *(pu + m - 1 ) = y * c + z * s; *(pu + i) = -y * s + z * c; } } } z = diagonal[k]; if (m == k) { if (z < 0.0) { diagonal[k] = -z; for (j = 0, pv = V; j < ncols; j++, pv += ncols) *(pv + k) = - *(pv + k); } break; } else { if (iteration_count >= MAX_ITERATION_COUNT) return -1; iteration_count++; x = diagonal[m]; y = diagonal[k-1]; g = superdiagonal[k-1]; h = superdiagonal[k]; f = ((y - z) * ( y + z ) + (g - h) * (g + h))/(2.0 * h * y); g = sqrt (f * f + 1.0); if (f < 0.0) g = -g; f = ((x - z) * (x + z) + h * (y / (f + g) - h)) / x; c = 1.0; s = 1.0; for (i = m + 1; i <= k; i++) { g = superdiagonal[i]; y = diagonal[i]; h = s * g; g *= c; z = sqrt (f * f + h * h); superdiagonal[i-1] = z; c = f / z; s = h / z; f = x * c + g * s; g = -x * s + g * c; h = y * s; y *= c; for (j = 0, pv = V; j < ncols; j++, pv += ncols) { x = *(pv + i - 1); z = *(pv + i); *(pv + i - 1) = x * c + z * s; *(pv + i) = -x * s + z * c; } z = sqrt (f * f + h * h); diagonal[i - 1] = z; if (z != 0.0) { c = f / z; s = h / z; } f = c * g + s * y; x = -s * g + c * y; for (j = 0, pu = U; j < nrows; j++, pu += ncols) { y = *(pu + i - 1); z = *(pu + i); *(pu + i - 1) = c * y + s * z; *(pu + i) = -s * y + c * z; } } superdiagonal[m] = 0.0; superdiagonal[k] = f; diagonal[k] = x; } } } return 0; } /* Given a singular value decomposition * of an nrows x ncols matrix A = U*Diag(S)*Vt, * sort the values of S by decreasing value, * permuting V to match. */ static void sort_singular_values (int nrows, int ncols, double *S, double *U, double *V) { int i, j, max_index; double temp; double *p1, *p2; for (i = 0; i < ncols - 1; i++) { max_index = i; for (j = i + 1; j < ncols; j++) if (S[j] > S[max_index]) max_index = j; if (max_index == i) continue; temp = S[i]; S[i] = S[max_index]; S[max_index] = temp; p1 = U + max_index; p2 = U + i; for (j = 0; j < nrows; j++, p1 += ncols, p2 += ncols) { temp = *p1; *p1 = *p2; *p2 = temp; } p1 = V + max_index; p2 = V + i; for (j = 0; j < ncols; j++, p1 += ncols, p2 += ncols) { temp = *p1; *p1 = *p2; *p2 = temp; } } } /* Compute a singular value decomposition of A, * A = U*Diag(S)*Vt * * All matrices are allocated by the caller * * Sizes: * A, U: nrows x ncols * S: ncols * V: ncols x ncols */ int singular_value_decomposition (double *A, int nrows, int ncols, double *U, double *S, double *V) { double *superdiagonal; superdiagonal = g_alloca (sizeof (double) * ncols); if (nrows < ncols) return -1; householder_reduction (A, nrows, ncols, U, V, S, superdiagonal); if (givens_reduction (nrows, ncols, U, V, S, superdiagonal) < 0) return -1; sort_singular_values (nrows, ncols, S, U, V); return 0; } /* * Given a singular value decomposition of A = U*Diag(S)*Vt, * compute the best approximation x to A*x = B. * * All matrices are allocated by the caller * * Sizes: * U: nrows x ncols * S: ncols * V: ncols x ncols * B, x: ncols */ void singular_value_decomposition_solve (double *U, double *S, double *V, int nrows, int ncols, double *B, double *x) { int i, j, k; double *pu, *pv; double d; double tolerance; tolerance = DBL_EPSILON * S[0] * (double) ncols; for ( i = 0, pv = V; i < ncols; i++, pv += ncols) { x[i] = 0.0; for (j = 0; j < ncols; j++) { if (S[j] > tolerance) { for (k = 0, d = 0.0, pu = U; k < nrows; k++, pu += ncols) d += *(pu + j) * B[k]; x[i] += d * *(pv + j) / S[j]; } } } }