Mercurial > octave
view liboctave/numeric/DASSL.cc @ 23577:80c42f4cca13
maint: Deprecate is_empty and replace with isempty.
* ov.h (is_empty): Use OCTAVE_DEPRECATED macro around function.
* ov.h (isempty): New function.
* Array.h (is_empty): Use OCTAVE_DEPRECATED macro around function.
* Array.h (isempty): New function.
* Range.h (is_empty): Use OCTAVE_DEPRECATED macro around function.
* Range.h (isempty): New function.
* Sparse.h (is_empty): Use OCTAVE_DEPRECATED macro around function.
* Sparse.h (isempty): New function.
* Backend.cc, BaseControl.cc, Canvas.cc, Figure.cc, gl-select.cc,
__magick_read__.cc, __qp__.cc, cellfun.cc, daspk.cc, dasrt.cc, dassl.cc,
data.cc, debug.cc, det.cc, eig.cc, error.cc, fft.cc, filter.cc, find.cc,
ft-text-renderer.cc, gl-render.cc, gl2ps-print.cc, graphics.cc, graphics.in.h,
hess.cc, inv.cc, lsode.cc, lu.cc, max.cc, mex.cc, mxarray.in.h, oct-handle.h,
oct-lvalue.cc, oct-map.cc, oct-map.h, oct-stream.cc, pinv.cc, pr-output.cc,
quadcc.cc, qz.cc, strfind.cc, strfns.cc, sylvester.cc, time.cc, toplev.cc,
tril.cc, urlwrite.cc, utils.cc, utils.h, xnorm.cc, __delaunayn__.cc,
__glpk__.cc, __init_fltk__.cc, __init_gnuplot__.cc, __ode15__.cc,
__voronoi__.cc, chol.cc, convhulln.cc, ov-base-diag.cc, ov-base-mat.cc,
ov-base-sparse.cc, ov-base.cc, ov-base.h, ov-bool-mat.cc, ov-bool-sparse.cc,
ov-cell.cc, ov-class.cc, ov-classdef.cc, ov-cx-sparse.cc, ov-fcn-inline.cc,
ov-flt-re-mat.cc, ov-intx.h, ov-java.cc, ov-perm.cc, ov-range.cc, ov-re-mat.cc,
ov-re-sparse.cc, ov-str-mat.cc, ov-struct.cc, ov-usr-fcn.cc, ov.cc, ov.h,
bp-table.cc, oct-parse.in.yy, pt-eval.cc, pt-tm-const.cc, pt-tm-const.h,
Array.cc, Range.cc, Range.h, Sparse.cc, Sparse.h, chNDArray.cc, dNDArray.cc,
fNDArray.cc, DASPK.cc, DASRT.cc, DASSL.cc, LSODE.cc, bsxfun-defs.cc,
eigs-base.cc, oct-convn.cc, qr.cc:
Replace instances of is_empty with isempty.
author | Rik <rik@octave.org> |
---|---|
date | Sun, 11 Jun 2017 22:14:09 -0700 |
parents | d691ed308237 |
children | 336f89b6208b |
line wrap: on
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/* Copyright (C) 1993-2017 John W. Eaton 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 <http://www.gnu.org/licenses/>. */ #if defined (HAVE_CONFIG_H) # include "config.h" #endif #include <sstream> #include "DASSL.h" #include "dMatrix.h" #include "f77-fcn.h" #include "lo-error.h" #include "quit.h" typedef F77_INT (*dassl_fcn_ptr) (const double&, const double*, const double*, double*, F77_INT&, double*, F77_INT*); typedef F77_INT (*dassl_jac_ptr) (const double&, const double*, const double*, double*, const double&, double*, F77_INT*); extern "C" { F77_RET_T F77_FUNC (ddassl, DDASSL) (dassl_fcn_ptr, const F77_INT&, F77_DBLE&, F77_DBLE*, F77_DBLE*, F77_DBLE&, const F77_INT*, const F77_DBLE*, const F77_DBLE*, F77_INT&, F77_DBLE*, const F77_INT&, F77_INT*, const F77_INT&, const F77_DBLE*, const F77_INT*, dassl_jac_ptr); } static DAEFunc::DAERHSFunc user_fun; static DAEFunc::DAEJacFunc user_jac; static F77_INT nn; static F77_INT ddassl_f (const double& time, const double *state, const double *deriv, double *delta, F77_INT& ires, double *, F77_INT *) { BEGIN_INTERRUPT_WITH_EXCEPTIONS; // FIXME: would be nice to avoid copying the data. ColumnVector tmp_deriv (nn); ColumnVector tmp_state (nn); ColumnVector tmp_delta (nn); for (F77_INT i = 0; i < nn; i++) { tmp_deriv.elem (i) = deriv[i]; tmp_state.elem (i) = state[i]; } octave_idx_type tmp_ires = ires; tmp_delta = user_fun (tmp_state, tmp_deriv, time, tmp_ires); ires = octave::to_f77_int (tmp_ires); if (ires >= 0) { if (tmp_delta.isempty ()) ires = -2; else { for (F77_INT i = 0; i < nn; i++) delta[i] = tmp_delta.elem (i); } } END_INTERRUPT_WITH_EXCEPTIONS; return 0; } static F77_INT ddassl_j (const double& time, const double *state, const double *deriv, double *pd, const double& cj, double *, F77_INT *) { BEGIN_INTERRUPT_WITH_EXCEPTIONS; // FIXME: would be nice to avoid copying the data. ColumnVector tmp_state (nn); ColumnVector tmp_deriv (nn); for (F77_INT i = 0; i < nn; i++) { tmp_deriv.elem (i) = deriv[i]; tmp_state.elem (i) = state[i]; } Matrix tmp_pd = user_jac (tmp_state, tmp_deriv, time, cj); for (F77_INT j = 0; j < nn; j++) for (F77_INT i = 0; i < nn; i++) pd[nn * j + i] = tmp_pd.elem (i, j); END_INTERRUPT_WITH_EXCEPTIONS; return 0; } ColumnVector DASSL::do_integrate (double tout) { ColumnVector retval; if (! initialized || restart || DAEFunc::reset || DASSL_options::reset) { integration_error = false; initialized = true; info.resize (dim_vector (15, 1)); for (F77_INT i = 0; i < 15; i++) info(i) = 0; F77_INT n = octave::to_f77_int (size ()); liw = 21 + n; lrw = 40 + 9*n + n*n; nn = n; iwork.resize (dim_vector (liw, 1)); rwork.resize (dim_vector (lrw, 1)); info(0) = 0; if (stop_time_set) { rwork(0) = stop_time; info(3) = 1; } else info(3) = 0; restart = false; // DAEFunc user_fun = DAEFunc::function (); user_jac = DAEFunc::jacobian_function (); if (user_fun) { octave_idx_type ires = 0; ColumnVector res = (*user_fun) (x, xdot, t, ires); if (res.numel () != x.numel ()) { (*current_liboctave_error_handler) ("dassl: inconsistent sizes for state and residual vectors"); integration_error = true; return retval; } } else { (*current_liboctave_error_handler) ("dassl: no user supplied RHS subroutine!"); integration_error = true; return retval; } info(4) = (user_jac ? 1 : 0); DAEFunc::reset = false; // DASSL_options double hmax = maximum_step_size (); if (hmax >= 0.0) { rwork(1) = hmax; info(6) = 1; } else info(6) = 0; double h0 = initial_step_size (); if (h0 >= 0.0) { rwork(2) = h0; info(7) = 1; } else info(7) = 0; F77_INT sl = octave::to_f77_int (step_limit ()); if (sl >= 0) { info(11) = 1; iwork(20) = sl; } else info(11) = 0; F77_INT maxord = octave::to_f77_int (maximum_order ()); if (maxord >= 0) { if (maxord > 0 && maxord < 6) { info(8) = 1; iwork(2) = maxord; } else { (*current_liboctave_error_handler) ("dassl: invalid value for maximum order: %d", maxord); integration_error = true; return retval; } } F77_INT enc = octave::to_f77_int (enforce_nonnegativity_constraints ()); info(9) = (enc ? 1 : 0); F77_INT ccic = octave::to_f77_int (compute_consistent_initial_condition ()); info(10) = (ccic ? 1 : 0); abs_tol = absolute_tolerance (); rel_tol = relative_tolerance (); F77_INT abs_tol_len = octave::to_f77_int (abs_tol.numel ()); F77_INT rel_tol_len = octave::to_f77_int (rel_tol.numel ()); if (abs_tol_len == 1 && rel_tol_len == 1) { info(1) = 0; } else if (abs_tol_len == n && rel_tol_len == n) { info(1) = 1; } else { (*current_liboctave_error_handler) ("dassl: inconsistent sizes for tolerance arrays"); integration_error = true; return retval; } DASSL_options::reset = false; } double *px = x.fortran_vec (); double *pxdot = xdot.fortran_vec (); F77_INT *pinfo = info.fortran_vec (); double *prel_tol = rel_tol.fortran_vec (); double *pabs_tol = abs_tol.fortran_vec (); double *prwork = rwork.fortran_vec (); F77_INT *piwork = iwork.fortran_vec (); double *dummy = nullptr; F77_INT *idummy = nullptr; F77_INT tmp_istate = octave::to_f77_int (istate); F77_XFCN (ddassl, DDASSL, (ddassl_f, nn, t, px, pxdot, tout, pinfo, prel_tol, pabs_tol, tmp_istate, prwork, lrw, piwork, liw, dummy, idummy, ddassl_j)); istate = tmp_istate; switch (istate) { case 1: // A step was successfully taken in intermediate-output // mode. The code has not yet reached TOUT. case 2: // The integration to TSTOP was successfully completed // (T=TSTOP) by stepping exactly to TSTOP. case 3: // The integration to TOUT was successfully completed // (T=TOUT) by stepping past TOUT. Y(*) is obtained by // interpolation. YPRIME(*) is obtained by interpolation. retval = x; t = tout; break; case -1: // A large amount of work has been expended. (~500 steps). case -2: // The error tolerances are too stringent. case -3: // The local error test cannot be satisfied because you // specified a zero component in ATOL and the // corresponding computed solution component is zero. // Thus, a pure relative error test is impossible for // this component. case -6: // DDASSL had repeated error test failures on the last // attempted step. case -7: // The corrector could not converge. case -8: // The matrix of partial derivatives is singular. case -9: // The corrector could not converge. There were repeated // error test failures in this step. case -10: // The corrector could not converge because IRES was // equal to minus one. case -11: // IRES equal to -2 was encountered and control is being // returned to the calling program. case -12: // DDASSL failed to compute the initial YPRIME. case -33: // The code has encountered trouble from which it cannot // recover. A message is printed explaining the trouble // and control is returned to the calling program. For // example, this occurs when invalid input is detected. integration_error = true; break; default: integration_error = true; (*current_liboctave_error_handler) ("unrecognized value of istate (= %d) returned from ddassl", istate); break; } return retval; } Matrix DASSL::do_integrate (const ColumnVector& tout) { Matrix dummy; return integrate (tout, dummy); } Matrix DASSL::integrate (const ColumnVector& tout, Matrix& xdot_out) { Matrix retval; octave_idx_type n_out = tout.numel (); F77_INT n = octave::to_f77_int (size ()); if (n_out > 0 && n > 0) { retval.resize (n_out, n); xdot_out.resize (n_out, n); for (F77_INT i = 0; i < n; i++) { retval.elem (0, i) = x.elem (i); xdot_out.elem (0, i) = xdot.elem (i); } for (octave_idx_type j = 1; j < n_out; j++) { ColumnVector x_next = do_integrate (tout.elem (j)); if (integration_error) return retval; for (F77_INT i = 0; i < n; i++) { retval.elem (j, i) = x_next.elem (i); xdot_out.elem (j, i) = xdot.elem (i); } } } return retval; } Matrix DASSL::do_integrate (const ColumnVector& tout, const ColumnVector& tcrit) { Matrix dummy; return integrate (tout, dummy, tcrit); } Matrix DASSL::integrate (const ColumnVector& tout, Matrix& xdot_out, const ColumnVector& tcrit) { Matrix retval; octave_idx_type n_out = tout.numel (); F77_INT n = octave::to_f77_int (size ()); if (n_out > 0 && n > 0) { retval.resize (n_out, n); xdot_out.resize (n_out, n); for (F77_INT i = 0; i < n; i++) { retval.elem (0, i) = x.elem (i); xdot_out.elem (0, i) = xdot.elem (i); } octave_idx_type n_crit = tcrit.numel (); if (n_crit > 0) { octave_idx_type i_crit = 0; octave_idx_type i_out = 1; double next_crit = tcrit.elem (0); double next_out; while (i_out < n_out) { bool do_restart = false; next_out = tout.elem (i_out); if (i_crit < n_crit) next_crit = tcrit.elem (i_crit); bool save_output; double t_out; if (next_crit == next_out) { set_stop_time (next_crit); t_out = next_out; save_output = true; i_out++; i_crit++; do_restart = true; } else if (next_crit < next_out) { if (i_crit < n_crit) { set_stop_time (next_crit); t_out = next_crit; save_output = false; i_crit++; do_restart = true; } else { clear_stop_time (); t_out = next_out; save_output = true; i_out++; } } else { set_stop_time (next_crit); t_out = next_out; save_output = true; i_out++; } ColumnVector x_next = do_integrate (t_out); if (integration_error) return retval; if (save_output) { for (F77_INT i = 0; i < n; i++) { retval.elem (i_out-1, i) = x_next.elem (i); xdot_out.elem (i_out-1, i) = xdot.elem (i); } } if (do_restart) force_restart (); } } else { retval = integrate (tout, xdot_out); if (integration_error) return retval; } } return retval; } std::string DASSL::error_message (void) const { std::string retval; std::ostringstream buf; buf << t; std::string t_curr = buf.str (); switch (istate) { case 1: retval = "a step was successfully taken in intermediate-output mode."; break; case 2: retval = "integration completed by stepping exactly to TOUT"; break; case 3: retval = "integration to tout completed by stepping past TOUT"; break; case -1: retval = std::string ("a large amount of work has been expended (t =") + t_curr + ")"; break; case -2: retval = "the error tolerances are too stringent"; break; case -3: retval = std::string ("error weight became zero during problem. (t = ") + t_curr + "; solution component i vanished, and atol or atol(i) == 0)"; break; case -6: retval = std::string ("repeated error test failures on the last attempted step (t = ") + t_curr + ")"; break; case -7: retval = std::string ("the corrector could not converge (t = ") + t_curr + ")"; break; case -8: retval = std::string ("the matrix of partial derivatives is singular (t = ") + t_curr + ")"; break; case -9: retval = std::string ("the corrector could not converge (t = ") + t_curr + "; repeated test failures)"; break; case -10: retval = std::string ("corrector could not converge because IRES was -1 (t = ") + t_curr + ")"; break; case -11: retval = std::string ("return requested in user-supplied function (t = ") + t_curr + ")"; break; case -12: retval = "failed to compute consistent initial conditions"; break; case -33: retval = "unrecoverable error (see printed message)"; break; default: retval = "unknown error state"; break; } return retval; }