/* Copyright (C) 2018 arbguest This file is part of Arb. Arb is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. See . */ #include "arb_mat.h" static void _apply_permutation(slong * AP, arb_mat_t A, slong * P, slong n, slong offset) { if (n != 0) { arb_ptr * Atmp; slong * APtmp; slong i; Atmp = flint_malloc(sizeof(arb_ptr) * n); APtmp = flint_malloc(sizeof(slong) * n); for (i = 0; i < n; i++) Atmp[i] = A->rows[P[i] + offset]; for (i = 0; i < n; i++) A->rows[i + offset] = Atmp[i]; for (i = 0; i < n; i++) APtmp[i] = AP[P[i] + offset]; for (i = 0; i < n; i++) AP[i + offset] = APtmp[i]; flint_free(Atmp); flint_free(APtmp); } } void _arb_vec_approx_scalar_addmul(arb_ptr res, arb_srcptr vec, slong len, const arb_t c, slong prec) { slong i; for (i = 0; i < len; i++) arf_addmul(arb_midref(res + i), arb_midref(vec + i), arb_midref(c), prec, ARF_RND_DOWN); } int arb_mat_approx_lu_classical(slong * P, arb_mat_t LU, const arb_mat_t A, slong prec) { arf_t d; arb_t e; arb_ptr * a; slong i, j, m, n, r, row, col; int result; if (arb_mat_is_empty(A)) return 1; m = arb_mat_nrows(A); n = arb_mat_ncols(A); arb_mat_get_mid(LU, A); a = LU->rows; row = col = 0; for (i = 0; i < m; i++) P[i] = i; arf_init(d); arb_init(e); result = 1; while (row < m && col < n) { r = arb_mat_find_pivot_partial(LU, row, m, col); if (r == -1) { result = 0; break; } else if (r != row) arb_mat_swap_rows(LU, P, row, r); arf_ui_div(d, 1, arb_midref(a[row] + col), prec, ARB_RND); for (j = row + 1; j < m; j++) { arf_mul(arb_midref(e), arb_midref(a[j] + col), d, prec, ARB_RND); arb_neg(e, e); _arb_vec_approx_scalar_addmul(a[j] + col, a[row] + col, n - col, e, prec); arf_zero(arb_midref(a[j] + col)); arb_neg(a[j] + row, e); } row++; col++; } arf_clear(d); arb_clear(e); return result; } int arb_mat_approx_lu_recursive(slong * P, arb_mat_t LU, const arb_mat_t A, slong prec) { slong i, m, n, r1, r2, n1; arb_mat_t A0, A1, A00, A01, A10, A11; slong * P1; m = A->r; n = A->c; if (m <= 1 || n <= 1) { return arb_mat_approx_lu_classical(P, LU, A, prec); } arb_mat_get_mid(LU, A); n1 = n / 2; for (i = 0; i < m; i++) P[i] = i; P1 = flint_malloc(sizeof(slong) * m); arb_mat_window_init(A0, LU, 0, 0, m, n1); arb_mat_window_init(A1, LU, 0, n1, m, n); r1 = arb_mat_approx_lu(P1, A0, A0, prec); if (!r1) { flint_free(P1); arb_mat_window_clear(A0); arb_mat_window_clear(A1); return 0; } /* r1 = rank of A0 */ r1 = FLINT_MIN(m, n1); _apply_permutation(P, LU, P1, m, 0); arb_mat_window_init(A00, LU, 0, 0, r1, r1); arb_mat_window_init(A10, LU, r1, 0, m, r1); arb_mat_window_init(A01, LU, 0, n1, r1, n); arb_mat_window_init(A11, LU, r1, n1, m, n); arb_mat_approx_solve_tril(A01, A00, A01, 1, prec); { /* arb_mat_approx_submul(A11, A11, A10, A01, prec); */ arb_mat_t T; arb_mat_init(T, A10->r, A01->c); arb_mat_approx_mul(T, A10, A01, prec); arb_mat_sub(A11, A11, T, prec); arb_mat_get_mid(A11, A11); arb_mat_clear(T); } r2 = arb_mat_approx_lu(P1, A11, A11, prec); if (!r2) r1 = r2 = 0; else _apply_permutation(P, LU, P1, m - r1, r1); flint_free(P1); arb_mat_window_clear(A00); arb_mat_window_clear(A01); arb_mat_window_clear(A10); arb_mat_window_clear(A11); arb_mat_window_clear(A0); arb_mat_window_clear(A1); return r1 && r2; } int arb_mat_approx_lu(slong * P, arb_mat_t LU, const arb_mat_t A, slong prec) { if (arb_mat_nrows(A) < 8 || arb_mat_ncols(A) < 8) return arb_mat_approx_lu_classical(P, LU, A, prec); else return arb_mat_approx_lu_recursive(P, LU, A, prec); }