Mercurial > octave
view libinterp/operators/op-fcs-fcm.cc @ 31249:de6fc38c78c6
Make Jacobian types offered by dlsode.f accessible by lsode (bug #31626).
* liboctave/numeric/LSODE-opts.in: Add options "jacobian type", "lower jacobian
subdiagonals", and "upper jacobian subdiagonals".
* liboctave/numeric/LSODE.cc (file scope, lsode_j,
LSODE::do_integrate (double)): Handle new configurable Jacobian types.
* build-aux/mk-opts.pl: Don't implicitly convert to integer in condition.
author | Olaf Till <olaf.till@uni-jena.de> |
---|---|
date | Fri, 12 Nov 2010 08:53:05 +0100 |
parents | 796f54d4ddbf |
children | e88a07dec498 |
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//////////////////////////////////////////////////////////////////////// // // Copyright (C) 1996-2022 The Octave Project Developers // // See the file COPYRIGHT.md in the top-level directory of this // distribution or <https://octave.org/copyright/>. // // This file is part of Octave. // // Octave 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. // // Octave 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 Octave; see the file COPYING. If not, see // <https://www.gnu.org/licenses/>. // //////////////////////////////////////////////////////////////////////// #if defined (HAVE_CONFIG_H) # include "config.h" #endif #include "ovl.h" #include "ov.h" #include "ov-complex.h" #include "ov-flt-complex.h" #include "ov-cx-mat.h" #include "ov-flt-cx-mat.h" #include "ov-typeinfo.h" #include "ops.h" #include "xdiv.h" #include "xpow.h" OCTAVE_NAMESPACE_BEGIN // complex scalar by complex matrix ops. DEFNDBINOP_OP (add, float_complex, float_complex_matrix, float_complex, float_complex_array, +) DEFNDBINOP_OP (sub, float_complex, float_complex_matrix, float_complex, float_complex_array, -) DEFNDBINOP_OP (mul, float_complex, float_complex_matrix, float_complex, float_complex_array, *) DEFBINOP (div, float_complex, float_complex_matrix) { const octave_float_complex& v1 = dynamic_cast<const octave_float_complex&> (a1); const octave_float_complex_matrix& v2 = dynamic_cast<const octave_float_complex_matrix&> (a2); FloatComplexMatrix m1 = v1.float_complex_matrix_value (); FloatComplexMatrix m2 = v2.float_complex_matrix_value (); MatrixType typ = v2.matrix_type (); FloatComplexMatrix ret = xdiv (m1, m2, typ); v2.matrix_type (typ); return ret; } DEFBINOP_FN (pow, float_complex, float_complex_matrix, xpow) DEFBINOP (ldiv, float_complex, float_complex_matrix) { const octave_float_complex& v1 = dynamic_cast<const octave_float_complex&> (a1); const octave_float_complex_matrix& v2 = dynamic_cast<const octave_float_complex_matrix&> (a2); return octave_value (v2.float_complex_array_value () / v1.float_complex_value ()); } DEFNDCMPLXCMPOP_FN (lt, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_lt) DEFNDCMPLXCMPOP_FN (le, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_le) DEFNDCMPLXCMPOP_FN (eq, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_eq) DEFNDCMPLXCMPOP_FN (ge, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_ge) DEFNDCMPLXCMPOP_FN (gt, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_gt) DEFNDCMPLXCMPOP_FN (ne, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_ne) DEFNDBINOP_OP (el_mul, float_complex, float_complex_matrix, float_complex, float_complex_array, *) DEFNDBINOP_FN (el_div, float_complex, float_complex_matrix, float_complex, float_complex_array, elem_xdiv) DEFNDBINOP_FN (el_pow, float_complex, float_complex_matrix, float_complex, float_complex_array, elem_xpow) DEFBINOP (el_ldiv, float_complex, float_complex_matrix) { const octave_float_complex& v1 = dynamic_cast<const octave_float_complex&> (a1); const octave_float_complex_matrix& v2 = dynamic_cast<const octave_float_complex_matrix&> (a2); return octave_value (v2.float_complex_array_value () / v1.float_complex_value ()); } DEFNDBINOP_FN (el_and, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_and) DEFNDBINOP_FN (el_or, float_complex, float_complex_matrix, float_complex, float_complex_array, mx_el_or) DEFNDCATOP_FN (fcs_fcm, float_complex, float_complex_matrix, float_complex_array, float_complex_array, concat) DEFNDCATOP_FN (cs_fcm, complex, float_complex_matrix, float_complex_array, float_complex_array, concat) DEFNDCATOP_FN (fcs_cm, float_complex, complex_matrix, float_complex_array, float_complex_array, concat) DEFCONV (float_complex_matrix_conv, float_complex, float_complex_matrix) { const octave_float_complex& v = dynamic_cast<const octave_float_complex&> (a); return new octave_float_complex_matrix (v.float_complex_matrix_value ()); } void install_fcs_fcm_ops (octave::type_info& ti) { INSTALL_BINOP_TI (ti, op_add, octave_float_complex, octave_float_complex_matrix, add); INSTALL_BINOP_TI (ti, op_sub, octave_float_complex, octave_float_complex_matrix, sub); INSTALL_BINOP_TI (ti, op_mul, octave_float_complex, octave_float_complex_matrix, mul); INSTALL_BINOP_TI (ti, op_div, octave_float_complex, octave_float_complex_matrix, div); INSTALL_BINOP_TI (ti, op_pow, octave_float_complex, octave_float_complex_matrix, pow); INSTALL_BINOP_TI (ti, op_ldiv, octave_float_complex, octave_float_complex_matrix, ldiv); INSTALL_BINOP_TI (ti, op_lt, octave_float_complex, octave_float_complex_matrix, lt); INSTALL_BINOP_TI (ti, op_le, octave_float_complex, octave_float_complex_matrix, le); INSTALL_BINOP_TI (ti, op_eq, octave_float_complex, octave_float_complex_matrix, eq); INSTALL_BINOP_TI (ti, op_ge, octave_float_complex, octave_float_complex_matrix, ge); INSTALL_BINOP_TI (ti, op_gt, octave_float_complex, octave_float_complex_matrix, gt); INSTALL_BINOP_TI (ti, op_ne, octave_float_complex, octave_float_complex_matrix, ne); INSTALL_BINOP_TI (ti, op_el_mul, octave_float_complex, octave_float_complex_matrix, el_mul); INSTALL_BINOP_TI (ti, op_el_div, octave_float_complex, octave_float_complex_matrix, el_div); INSTALL_BINOP_TI (ti, op_el_pow, octave_float_complex, octave_float_complex_matrix, el_pow); INSTALL_BINOP_TI (ti, op_el_ldiv, octave_float_complex, octave_float_complex_matrix, el_ldiv); INSTALL_BINOP_TI (ti, op_el_and, octave_float_complex, octave_float_complex_matrix, el_and); INSTALL_BINOP_TI (ti, op_el_or, octave_float_complex, octave_float_complex_matrix, el_or); INSTALL_CATOP_TI (ti, octave_float_complex, octave_float_complex_matrix, fcs_fcm); INSTALL_CATOP_TI (ti, octave_complex, octave_float_complex_matrix, cs_fcm); INSTALL_CATOP_TI (ti, octave_float_complex, octave_complex_matrix, fcs_cm); INSTALL_ASSIGNCONV_TI (ti, octave_float_complex, octave_float_complex_matrix, octave_float_complex_matrix); INSTALL_ASSIGNCONV_TI (ti, octave_complex, octave_float_complex_matrix, octave_complex_matrix); INSTALL_WIDENOP_TI (ti, octave_float_complex, octave_float_complex_matrix, float_complex_matrix_conv); } OCTAVE_NAMESPACE_END