Mercurial > octave
view libinterp/corefcn/lsode.cc @ 30896:c9788d7f6e65
maint: Use "fcn" as preferred abbreviation for "function" in libinterp/.
* __eigs__.cc, bsxfun.cc, cellfun.cc, daspk.cc, dasrt.cc, dassl.cc, data.cc,
debug.cc, error.cc, graphics.cc, graphics.in.h, gzfstream.h, ls-hdf5.cc,
lsode.cc, max.cc, oct-opengl.h, quad.cc, strfns.cc, utils.cc, utils.h,
variables.cc, __ode15__.cc, gzip.cc, cdef-manager.cc, ov-fcn-handle.cc,
ov-java.cc, ov-usr-fcn.cc, bp-table.cc, bp-table.h, lex.h, lex.ll,
oct-parse.yy, pt-eval.cc:
Replace "func", "fun", "fn" in documentation and variable names with "fcn".
| author | Rik <rik@octave.org> |
|---|---|
| date | Tue, 05 Apr 2022 08:33:58 -0700 |
| parents | 796f54d4ddbf |
| children | 773a361bc476 |
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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 <list> #include <string> #include "LSODE.h" #include "lo-mappers.h" #include "defun.h" #include "error.h" #include "errwarn.h" #include "interpreter-private.h" #include "ovl.h" #include "ov-fcn.h" #include "ov-cell.h" #include "pager.h" #include "parse.h" #include "pr-output.h" #include "unwind-prot.h" #include "utils.h" #include "variables.h" #include "LSODE-opts.cc" OCTAVE_NAMESPACE_BEGIN // Global pointer for user defined function required by lsode. static octave_value lsode_fcn; // Global pointer for optional user defined jacobian function used by lsode. static octave_value lsode_jac; // Have we warned about imaginary values returned from user function? static bool warned_fcn_imaginary = false; static bool warned_jac_imaginary = false; // Is this a recursive call? static int call_depth = 0; static ColumnVector lsode_user_function (const ColumnVector& x, double t) { ColumnVector retval; octave_value_list args; args(1) = t; args(0) = x; if (lsode_fcn.is_defined ()) { octave_value_list tmp; try { tmp = octave::feval (lsode_fcn, args, 1); } catch (octave::execution_exception& ee) { err_user_supplied_eval (ee, "lsode"); } if (tmp.empty () || ! tmp(0).is_defined ()) err_user_supplied_eval ("lsode"); if (! warned_fcn_imaginary && tmp(0).iscomplex ()) { warning ("lsode: ignoring imaginary part returned from user-supplied function"); warned_fcn_imaginary = true; } retval = tmp(0).xvector_value ("lsode: expecting user supplied function to return numeric vector"); if (retval.isempty ()) err_user_supplied_eval ("lsode"); } return retval; } static Matrix lsode_user_jacobian (const ColumnVector& x, double t) { Matrix retval; octave_value_list args; args(1) = t; args(0) = x; if (lsode_jac.is_defined ()) { octave_value_list tmp; try { tmp = octave::feval (lsode_jac, args, 1); } catch (octave::execution_exception& ee) { err_user_supplied_eval (ee, "lsode"); } if (tmp.empty () || ! tmp(0).is_defined ()) err_user_supplied_eval ("lsode"); if (! warned_jac_imaginary && tmp(0).iscomplex ()) { warning ("lsode: ignoring imaginary part returned from user-supplied jacobian function"); warned_jac_imaginary = true; } retval = tmp(0).xmatrix_value ("lsode: expecting user supplied jacobian function to return numeric array"); if (retval.isempty ()) err_user_supplied_eval ("lsode"); } return retval; } DEFMETHOD (lsode, interp, args, nargout, doc: /* -*- texinfo -*- @deftypefn {} {[@var{x}, @var{istate}, @var{msg}] =} lsode (@var{fcn}, @var{x_0}, @var{t}) @deftypefnx {} {[@var{x}, @var{istate}, @var{msg}] =} lsode (@var{fcn}, @var{x_0}, @var{t}, @var{t_crit}) Ordinary Differential Equation (ODE) solver. The set of differential equations to solve is @tex $$ {dx \over dt} = f (x, t) $$ with $$ x(t_0) = x_0 $$ @end tex @ifnottex @example @group dx -- = f (x, t) dt @end group @end example @noindent with @example x(t_0) = x_0 @end example @end ifnottex The solution is returned in the matrix @var{x}, with each row corresponding to an element of the vector @var{t}. The first element of @var{t} should be @math{t_0} and should correspond to the initial state of the system @var{x_0}, so that the first row of the output is @var{x_0}. The first argument, @var{fcn}, is a string, inline, or function handle that names the function @math{f} to call to compute the vector of right hand sides for the set of equations. The function must have the form @example @var{xdot} = f (@var{x}, @var{t}) @end example @noindent in which @var{xdot} and @var{x} are vectors and @var{t} is a scalar. If @var{fcn} is a two-element string array or a two-element cell array of strings, inline functions, or function handles, the first element names the function @math{f} described above, and the second element names a function to compute the Jacobian of @math{f}. The Jacobian function must have the form @example @var{jac} = j (@var{x}, @var{t}) @end example @noindent in which @var{jac} is the matrix of partial derivatives @tex $$ J = {\partial f_i \over \partial x_j} = \left[\matrix{ {\partial f_1 \over \partial x_1} & {\partial f_1 \over \partial x_2} & \cdots & {\partial f_1 \over \partial x_N} \cr {\partial f_2 \over \partial x_1} & {\partial f_2 \over \partial x_2} & \cdots & {\partial f_2 \over \partial x_N} \cr \vdots & \vdots & \ddots & \vdots \cr {\partial f_3 \over \partial x_1} & {\partial f_3 \over \partial x_2} & \cdots & {\partial f_3 \over \partial x_N} \cr}\right]$$ @end tex @ifnottex @example @group | df_1 df_1 df_1 | | ---- ---- ... ---- | | dx_1 dx_2 dx_N | | | | df_2 df_2 df_2 | | ---- ---- ... ---- | df_i | dx_1 dx_2 dx_N | jac = ---- = | | dx_j | . . . . | | . . . . | | . . . . | | | | df_N df_N df_N | | ---- ---- ... ---- | | dx_1 dx_2 dx_N | @end group @end example @end ifnottex The second argument specifies the initial state of the system @math{x_0}. The third argument is a vector, @var{t}, specifying the time values for which a solution is sought. The fourth argument is optional, and may be used to specify a set of times that the ODE solver should not integrate past. It is useful for avoiding difficulties with singularities and points where there is a discontinuity in the derivative. After a successful computation, the value of @var{istate} will be 2 (consistent with the Fortran version of @sc{lsode}). If the computation is not successful, @var{istate} will be something other than 2 and @var{msg} will contain additional information. You can use the function @code{lsode_options} to set optional parameters for @code{lsode}. See @nospell{Alan C. Hindmarsh}, @cite{ODEPACK, A Systematized Collection of ODE Solvers}, in Scientific Computing, @nospell{R. S. Stepleman}, editor, (1983) or @url{https://computing.llnl.gov/projects/odepack} for more information about the inner workings of @code{lsode}. Example: Solve the @nospell{Van der Pol} equation @example @group fvdp = @@(@var{y},@var{t}) [@var{y}(2); (1 - @var{y}(1)^2) * @var{y}(2) - @var{y}(1)]; @var{t} = linspace (0, 20, 100); @var{y} = lsode (fvdp, [2; 0], @var{t}); @end group @end example @seealso{daspk, dassl, dasrt} @end deftypefn */) { int nargin = args.length (); if (nargin < 3 || nargin > 4) print_usage (); warned_fcn_imaginary = false; warned_jac_imaginary = false; unwind_protect_var<int> restore_var (call_depth); call_depth++; if (call_depth > 1) error ("lsode: invalid recursive call"); symbol_table& symtab = interp.get_symbol_table (); std::string fcn_name, fname, jac_name, jname; lsode_fcn = octave_value (); lsode_jac = octave_value (); octave_value f_arg = args(0); std::list<std::string> parameter_names ({"x", "t"}); if (f_arg.iscell ()) { Cell c = f_arg.cell_value (); if (c.numel () == 1) f_arg = c(0); else if (c.numel () == 2) { lsode_fcn = get_function_handle (interp, c(0), parameter_names); if (lsode_fcn.is_defined ()) { lsode_jac = get_function_handle (interp, c(1), parameter_names); if (lsode_jac.is_undefined ()) lsode_fcn = octave_value (); } } else error ("lsode: incorrect number of elements in cell array"); } if (lsode_fcn.is_undefined () && ! f_arg.iscell ()) { if (f_arg.is_function_handle () || f_arg.is_inline_function ()) lsode_fcn = f_arg; else { switch (f_arg.rows ()) { case 1: lsode_fcn = get_function_handle (interp, f_arg, parameter_names); break; case 2: { string_vector tmp = f_arg.string_vector_value (); lsode_fcn = get_function_handle (interp, tmp(0), parameter_names); if (lsode_fcn.is_defined ()) { lsode_jac = get_function_handle (interp, tmp(1), parameter_names); if (lsode_jac.is_undefined ()) lsode_fcn = octave_value (); } } break; default: error ("lsode: first arg should be a string or 2-element string array"); } } } if (lsode_fcn.is_undefined ()) error ("lsode: FCN argument is not a valid function name or handle"); ColumnVector state = args(1).xvector_value ("lsode: initial state X_0 must be a vector"); ColumnVector out_times = args(2).xvector_value ("lsode: output time variable T must be a vector"); ColumnVector crit_times; int crit_times_set = 0; if (nargin > 3) { crit_times = args(3).xvector_value ("lsode: list of critical times T_CRIT must be a vector"); crit_times_set = 1; } double tzero = out_times (0); ODEFunc fcn (lsode_user_function); if (lsode_jac.is_defined ()) fcn.set_jacobian_function (lsode_user_jacobian); LSODE ode (state, tzero, fcn); ode.set_options (lsode_opts); Matrix output; if (crit_times_set) output = ode.integrate (out_times, crit_times); else output = ode.integrate (out_times); if (fcn_name.length ()) symtab.clear_function (fcn_name); if (jac_name.length ()) symtab.clear_function (jac_name); std::string msg = ode.error_message (); octave_value_list retval (3); if (ode.integration_ok ()) retval(0) = output; else if (nargout < 2) error ("lsode: %s", msg.c_str ()); else retval(0) = Matrix (); retval(1) = static_cast<double> (ode.integration_state ()); retval(2) = msg; return retval; } /* ## dassl-1.m ## ## Test lsode() function ## ## Author: David Billinghurst (David.Billinghurst@riotinto.com.au) ## Comalco Research and Technology ## 20 May 1998 ## ## Problem ## ## y1' = -y2, y1(0) = 1 ## y2' = y1, y2(0) = 0 ## ## Solution ## ## y1(t) = cos(t) ## y2(t) = sin(t) ## %!function xdot = __f (x, t) %! xdot = [-x(2); x(1)]; %!endfunction %!test %! %! x0 = [1; 0]; %! xdot0 = [0; 1]; %! t = (0:1:10)'; %! %! tol = 500 * lsode_options ("relative tolerance"); %! %! x = lsode ("__f", x0, t); %! %! y = [cos(t), sin(t)]; %! %! assert (x, y, tol); %!function xdotdot = __f (x, t) %! xdotdot = [x(2); -x(1)]; %!endfunction %!test %! %! x0 = [1; 0]; %! t = [0; 2*pi]; %! tol = 100 * dassl_options ("relative tolerance"); %! %! x = lsode ("__f", x0, t); %! %! y = [1, 0; 1, 0]; %! %! assert (x, y, tol); %!function xdot = __f (x, t) %! xdot = x; %!endfunction %!test %! %! x0 = 1; %! t = [0; 1]; %! tol = 100 * dassl_options ("relative tolerance"); %! %! x = lsode ("__f", x0, t); %! %! y = [1; e]; %! %! assert (x, y, tol); %!test %! lsode_options ("absolute tolerance", eps); %! assert (lsode_options ("absolute tolerance") == eps); %!error lsode_options ("foo", 1, 2) */ OCTAVE_NAMESPACE_END