Mercurial > octave-nkf
view liboctave/lo-specfun.cc @ 5307:4c8a2e4e0717
[project @ 2005-04-26 19:24:27 by jwe]
| author | jwe |
|---|---|
| date | Tue, 26 Apr 2005 19:24:47 +0000 |
| parents | fe23ec6763b7 |
| children | 67118c88cee7 |
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/* Copyright (C) 1996 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 2, 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, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include "Range.h" #include "CColVector.h" #include "CMatrix.h" #include "dRowVector.h" #include "dMatrix.h" #include "dNDArray.h" #include "CNDArray.h" #include "f77-fcn.h" #include "lo-error.h" #include "lo-ieee.h" #include "lo-specfun.h" #include "mx-inlines.cc" #ifndef M_PI #define M_PI 3.14159265358979323846 #endif extern "C" { F77_RET_T F77_FUNC (zbesj, ZBESJ) (const double&, const double&, const double&, const octave_idx_type&, const octave_idx_type&, double*, double*, octave_idx_type&, octave_idx_type&); F77_RET_T F77_FUNC (zbesy, ZBESY) (const double&, const double&, const double&, const octave_idx_type&, const octave_idx_type&, double*, double*, octave_idx_type&, double*, double*, octave_idx_type&); F77_RET_T F77_FUNC (zbesi, ZBESI) (const double&, const double&, const double&, const octave_idx_type&, const octave_idx_type&, double*, double*, octave_idx_type&, octave_idx_type&); F77_RET_T F77_FUNC (zbesk, ZBESK) (const double&, const double&, const double&, const octave_idx_type&, const octave_idx_type&, double*, double*, octave_idx_type&, octave_idx_type&); F77_RET_T F77_FUNC (zbesh, ZBESH) (const double&, const double&, const double&, const octave_idx_type&, const octave_idx_type&, const octave_idx_type&, double*, double*, octave_idx_type&, octave_idx_type&); F77_RET_T F77_FUNC (zairy, ZAIRY) (const double&, const double&, const octave_idx_type&, const octave_idx_type&, double&, double&, octave_idx_type&, octave_idx_type&); F77_RET_T F77_FUNC (zbiry, ZBIRY) (const double&, const double&, const octave_idx_type&, const octave_idx_type&, double&, double&, octave_idx_type&); F77_RET_T F77_FUNC (xdacosh, XDACOSH) (const double&, double&); F77_RET_T F77_FUNC (xdasinh, XDASINH) (const double&, double&); F77_RET_T F77_FUNC (xdatanh, XDATANH) (const double&, double&); F77_RET_T F77_FUNC (xderf, XDERF) (const double&, double&); F77_RET_T F77_FUNC (xderfc, XDERFC) (const double&, double&); F77_RET_T F77_FUNC (xdbetai, XDBETAI) (const double&, const double&, const double&, double&); F77_RET_T F77_FUNC (xdgamma, XDGAMMA) (const double&, double&); F77_RET_T F77_FUNC (xgammainc, XGAMMAINC) (const double&, const double&, double&); F77_RET_T F77_FUNC (dlgams, DLGAMS) (const double&, double&, double&); } #if !defined (HAVE_ACOSH) double acosh (double x) { double retval; F77_XFCN (xdacosh, XDACOSH, (x, retval)); return retval; } #endif #if !defined (HAVE_ASINH) double asinh (double x) { double retval; F77_XFCN (xdasinh, XDASINH, (x, retval)); return retval; } #endif #if !defined (HAVE_ATANH) double atanh (double x) { double retval; F77_XFCN (xdatanh, XDATANH, (x, retval)); return retval; } #endif #if !defined (HAVE_ERF) double erf (double x) { double retval; F77_XFCN (xderf, XDERF, (x, retval)); return retval; } #endif #if !defined (HAVE_ERFC) double erfc (double x) { double retval; F77_XFCN (xderfc, XDERFC, (x, retval)); return retval; } #endif double xgamma (double x) { double result; F77_XFCN (xdgamma, XDGAMMA, (x, result)); return result; } double xlgamma (double x) { double result; double sgngam; if (x < 0) (*current_liboctave_error_handler) ("xlgamma: argument must be nonnegative"); F77_XFCN (dlgams, DLGAMS, (x, result, sgngam)); return result; } static inline Complex zbesj (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex zbesy (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex zbesi (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex zbesk (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex zbesh1 (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex zbesh2 (const Complex& z, double alpha, int kode, octave_idx_type& ierr); static inline Complex bessel_return_value (const Complex& val, octave_idx_type ierr) { static const Complex inf_val = Complex (octave_Inf, octave_Inf); static const Complex nan_val = Complex (octave_NaN, octave_NaN); Complex retval; switch (ierr) { case 0: case 3: retval = val; break; case 2: retval = inf_val; break; default: retval = nan_val; break; } return retval; } static inline bool is_integer_value (double x) { return x == static_cast<double> (static_cast<long> (x)); } static inline Complex zbesj (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); F77_FUNC (zbesj, ZBESJ) (zr, zi, alpha, 2, 1, &yr, &yi, nz, ierr); if (kode != 2) { double expz = exp (std::abs (zi)); yr *= expz; yi *= expz; } if (zi == 0.0 && zr >= 0.0) yi = 0.0; retval = bessel_return_value (Complex (yr, yi), ierr); } else if (is_integer_value (alpha)) { // zbesy can overflow as z->0, and cause troubles for generic case below alpha = -alpha; Complex tmp = zbesj (z, alpha, kode, ierr); if ((static_cast <long> (alpha)) & 1) tmp = - tmp; retval = bessel_return_value (tmp, ierr); } else { alpha = -alpha; Complex tmp = cos (M_PI * alpha) * zbesj (z, alpha, kode, ierr); if (ierr == 0 || ierr == 3) { tmp -= sin (M_PI * alpha) * zbesy (z, alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } else retval = Complex (octave_NaN, octave_NaN); } return retval; } static inline Complex zbesy (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double wr, wi; double zr = z.real (); double zi = z.imag (); ierr = 0; if (zr == 0.0 && zi == 0.0) { yr = -octave_Inf; yi = 0.0; } else { F77_FUNC (zbesy, ZBESY) (zr, zi, alpha, 2, 1, &yr, &yi, nz, &wr, &wi, ierr); if (kode != 2) { double expz = exp (std::abs (zi)); yr *= expz; yi *= expz; } if (zi == 0.0 && zr >= 0.0) yi = 0.0; } return bessel_return_value (Complex (yr, yi), ierr); } else if (is_integer_value (alpha - 0.5)) { // zbesy can overflow as z->0, and cause troubles for generic case below alpha = -alpha; Complex tmp = zbesj (z, alpha, kode, ierr); if ((static_cast <long> (alpha - 0.5)) & 1) tmp = - tmp; retval = bessel_return_value (tmp, ierr); } else { alpha = -alpha; Complex tmp = cos (M_PI * alpha) * zbesy (z, alpha, kode, ierr); if (ierr == 0 || ierr == 3) { tmp += sin (M_PI * alpha) * zbesj (z, alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } else retval = Complex (octave_NaN, octave_NaN); } return retval; } static inline Complex zbesi (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); F77_FUNC (zbesi, ZBESI) (zr, zi, alpha, 2, 1, &yr, &yi, nz, ierr); if (kode != 2) { double expz = exp (std::abs (zr)); yr *= expz; yi *= expz; } if (zi == 0.0 && zr >= 0.0) yi = 0.0; retval = bessel_return_value (Complex (yr, yi), ierr); } else { alpha = -alpha; Complex tmp = zbesi (z, alpha, kode, ierr); if (ierr == 0 || ierr == 3) { if (! is_integer_value (alpha - 0.5)) tmp += (2.0 / M_PI) * sin (M_PI * alpha) * zbesk (z, alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } else retval = Complex (octave_NaN, octave_NaN); } return retval; } static inline Complex zbesk (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); ierr = 0; if (zr == 0.0 && zi == 0.0) { yr = octave_Inf; yi = 0.0; } else { F77_FUNC (zbesk, ZBESK) (zr, zi, alpha, 2, 1, &yr, &yi, nz, ierr); if (kode != 2) { Complex expz = exp (-z); double rexpz = real (expz); double iexpz = imag (expz); double tmp = yr*rexpz - yi*iexpz; yi = yr*iexpz + yi*rexpz; yr = tmp; } if (zi == 0.0 && zr >= 0.0) yi = 0.0; } retval = bessel_return_value (Complex (yr, yi), ierr); } else { Complex tmp = zbesk (z, -alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } return retval; } static inline Complex zbesh1 (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); F77_FUNC (zbesh, ZBESH) (zr, zi, alpha, 2, 1, 1, &yr, &yi, nz, ierr); if (kode != 2) { Complex expz = exp (Complex (0.0, 1.0) * z); double rexpz = real (expz); double iexpz = imag (expz); double tmp = yr*rexpz - yi*iexpz; yi = yr*iexpz + yi*rexpz; yr = tmp; } retval = bessel_return_value (Complex (yr, yi), ierr); } else { alpha = -alpha; static const Complex eye = Complex (0.0, 1.0); Complex tmp = exp (M_PI * alpha * eye) * zbesh1 (z, alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } return retval; } static inline Complex zbesh2 (const Complex& z, double alpha, int kode, octave_idx_type& ierr) { Complex retval; if (alpha >= 0.0) { double yr = 0.0; double yi = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); F77_FUNC (zbesh, ZBESH) (zr, zi, alpha, 2, 2, 1, &yr, &yi, nz, ierr); if (kode != 2) { Complex expz = exp (-Complex (0.0, 1.0) * z); double rexpz = real (expz); double iexpz = imag (expz); double tmp = yr*rexpz - yi*iexpz; yi = yr*iexpz + yi*rexpz; yr = tmp; } retval = bessel_return_value (Complex (yr, yi), ierr); } else { alpha = -alpha; static const Complex eye = Complex (0.0, 1.0); Complex tmp = exp (-M_PI * alpha * eye) * zbesh2 (z, alpha, kode, ierr); retval = bessel_return_value (tmp, ierr); } return retval; } typedef Complex (*fptr) (const Complex&, double, int, octave_idx_type&); static inline Complex do_bessel (fptr f, const char *, double alpha, const Complex& x, bool scaled, octave_idx_type& ierr) { Complex retval; retval = f (x, alpha, (scaled ? 2 : 1), ierr); return retval; } static inline ComplexMatrix do_bessel (fptr f, const char *, double alpha, const ComplexMatrix& x, bool scaled, Array2<octave_idx_type>& ierr) { octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); ComplexMatrix retval (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = f (x(i,j), alpha, (scaled ? 2 : 1), ierr(i,j)); return retval; } static inline ComplexMatrix do_bessel (fptr f, const char *, const Matrix& alpha, const Complex& x, bool scaled, Array2<octave_idx_type>& ierr) { octave_idx_type nr = alpha.rows (); octave_idx_type nc = alpha.cols (); ComplexMatrix retval (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = f (x, alpha(i,j), (scaled ? 2 : 1), ierr(i,j)); return retval; } static inline ComplexMatrix do_bessel (fptr f, const char *fn, const Matrix& alpha, const ComplexMatrix& x, bool scaled, Array2<octave_idx_type>& ierr) { ComplexMatrix retval; octave_idx_type x_nr = x.rows (); octave_idx_type x_nc = x.cols (); octave_idx_type alpha_nr = alpha.rows (); octave_idx_type alpha_nc = alpha.cols (); if (x_nr == alpha_nr && x_nc == alpha_nc) { octave_idx_type nr = x_nr; octave_idx_type nc = x_nc; retval.resize (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = f (x(i,j), alpha(i,j), (scaled ? 2 : 1), ierr(i,j)); } else (*current_liboctave_error_handler) ("%s: the sizes of alpha and x must conform", fn); return retval; } static inline ComplexNDArray do_bessel (fptr f, const char *, double alpha, const ComplexNDArray& x, bool scaled, ArrayN<octave_idx_type>& ierr) { dim_vector dv = x.dims (); octave_idx_type nel = dv.numel (); ComplexNDArray retval (dv); ierr.resize (dv); for (octave_idx_type i = 0; i < nel; i++) retval(i) = f (x(i), alpha, (scaled ? 2 : 1), ierr(i)); return retval; } static inline ComplexNDArray do_bessel (fptr f, const char *, const NDArray& alpha, const Complex& x, bool scaled, ArrayN<octave_idx_type>& ierr) { dim_vector dv = alpha.dims (); octave_idx_type nel = dv.numel (); ComplexNDArray retval (dv); ierr.resize (dv); for (octave_idx_type i = 0; i < nel; i++) retval(i) = f (x, alpha(i), (scaled ? 2 : 1), ierr(i)); return retval; } static inline ComplexNDArray do_bessel (fptr f, const char *fn, const NDArray& alpha, const ComplexNDArray& x, bool scaled, ArrayN<octave_idx_type>& ierr) { dim_vector dv = x.dims (); ComplexNDArray retval; if (dv == alpha.dims ()) { octave_idx_type nel = dv.numel (); retval.resize (dv); ierr.resize (dv); for (octave_idx_type i = 0; i < nel; i++) retval(i) = f (x(i), alpha(i), (scaled ? 2 : 1), ierr(i)); } else (*current_liboctave_error_handler) ("%s: the sizes of alpha and x must conform", fn); return retval; } static inline ComplexMatrix do_bessel (fptr f, const char *, const RowVector& alpha, const ComplexColumnVector& x, bool scaled, Array2<octave_idx_type>& ierr) { octave_idx_type nr = x.length (); octave_idx_type nc = alpha.length (); ComplexMatrix retval (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = f (x(i), alpha(j), (scaled ? 2 : 1), ierr(i,j)); return retval; } #define SS_BESSEL(name, fcn) \ Complex \ name (double alpha, const Complex& x, bool scaled, octave_idx_type& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define SM_BESSEL(name, fcn) \ ComplexMatrix \ name (double alpha, const ComplexMatrix& x, bool scaled, \ Array2<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define MS_BESSEL(name, fcn) \ ComplexMatrix \ name (const Matrix& alpha, const Complex& x, bool scaled, \ Array2<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define MM_BESSEL(name, fcn) \ ComplexMatrix \ name (const Matrix& alpha, const ComplexMatrix& x, bool scaled, \ Array2<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define SN_BESSEL(name, fcn) \ ComplexNDArray \ name (double alpha, const ComplexNDArray& x, bool scaled, \ ArrayN<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define NS_BESSEL(name, fcn) \ ComplexNDArray \ name (const NDArray& alpha, const Complex& x, bool scaled, \ ArrayN<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define NN_BESSEL(name, fcn) \ ComplexNDArray \ name (const NDArray& alpha, const ComplexNDArray& x, bool scaled, \ ArrayN<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define RC_BESSEL(name, fcn) \ ComplexMatrix \ name (const RowVector& alpha, const ComplexColumnVector& x, bool scaled, \ Array2<octave_idx_type>& ierr) \ { \ return do_bessel (fcn, #name, alpha, x, scaled, ierr); \ } #define ALL_BESSEL(name, fcn) \ SS_BESSEL (name, fcn) \ SM_BESSEL (name, fcn) \ MS_BESSEL (name, fcn) \ MM_BESSEL (name, fcn) \ SN_BESSEL (name, fcn) \ NS_BESSEL (name, fcn) \ NN_BESSEL (name, fcn) \ RC_BESSEL (name, fcn) ALL_BESSEL (besselj, zbesj) ALL_BESSEL (bessely, zbesy) ALL_BESSEL (besseli, zbesi) ALL_BESSEL (besselk, zbesk) ALL_BESSEL (besselh1, zbesh1) ALL_BESSEL (besselh2, zbesh2) Complex airy (const Complex& z, bool deriv, bool scaled, octave_idx_type& ierr) { double ar = 0.0; double ai = 0.0; octave_idx_type nz; double zr = z.real (); double zi = z.imag (); octave_idx_type id = deriv ? 1 : 0; F77_FUNC (zairy, ZAIRY) (zr, zi, id, 2, ar, ai, nz, ierr); if (! scaled) { Complex expz = exp (- 2.0 / 3.0 * z * sqrt(z)); double rexpz = real (expz); double iexpz = imag (expz); double tmp = ar*rexpz - ai*iexpz; ai = ar*iexpz + ai*rexpz; ar = tmp; } if (zi == 0.0 && (! scaled || zr >= 0.0)) ai = 0.0; return bessel_return_value (Complex (ar, ai), ierr); } Complex biry (const Complex& z, bool deriv, bool scaled, octave_idx_type& ierr) { double ar = 0.0; double ai = 0.0; double zr = z.real (); double zi = z.imag (); octave_idx_type id = deriv ? 1 : 0; F77_FUNC (zbiry, ZBIRY) (zr, zi, id, 2, ar, ai, ierr); if (! scaled) { Complex expz = exp (std::abs (real (2.0 / 3.0 * z * sqrt (z)))); double rexpz = real (expz); double iexpz = imag (expz); double tmp = ar*rexpz - ai*iexpz; ai = ar*iexpz + ai*rexpz; ar = tmp; } if (zi == 0.0 && (! scaled || zr >= 0.0)) ai = 0.0; return bessel_return_value (Complex (ar, ai), ierr); } ComplexMatrix airy (const ComplexMatrix& z, bool deriv, bool scaled, Array2<octave_idx_type>& ierr) { octave_idx_type nr = z.rows (); octave_idx_type nc = z.cols (); ComplexMatrix retval (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = airy (z(i,j), deriv, scaled, ierr(i,j)); return retval; } ComplexMatrix biry (const ComplexMatrix& z, bool deriv, bool scaled, Array2<octave_idx_type>& ierr) { octave_idx_type nr = z.rows (); octave_idx_type nc = z.cols (); ComplexMatrix retval (nr, nc); ierr.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = biry (z(i,j), deriv, scaled, ierr(i,j)); return retval; } ComplexNDArray airy (const ComplexNDArray& z, bool deriv, bool scaled, ArrayN<octave_idx_type>& ierr) { dim_vector dv = z.dims (); octave_idx_type nel = dv.numel (); ComplexNDArray retval (dv); ierr.resize (dv); for (octave_idx_type i = 0; i < nel; i++) retval (i) = airy (z(i), deriv, scaled, ierr(i)); return retval; } ComplexNDArray biry (const ComplexNDArray& z, bool deriv, bool scaled, ArrayN<octave_idx_type>& ierr) { dim_vector dv = z.dims (); octave_idx_type nel = dv.numel (); ComplexNDArray retval (dv); ierr.resize (dv); for (octave_idx_type i = 0; i < nel; i++) retval (i) = biry (z(i), deriv, scaled, ierr(i)); return retval; } static void gripe_betainc_nonconformant (octave_idx_type r1, octave_idx_type c1, octave_idx_type r2, octave_idx_type c2, octave_idx_type r3, octave_idx_type c3) { (*current_liboctave_error_handler) ("betainc: nonconformant arguments (x is %dx%d, a is %dx%d, b is %dx%d)", r1, c1, r2, c2, r3, c3); } static dim_vector null_dims (0); static void gripe_betainc_nonconformant (const dim_vector& d1, const dim_vector& d2, const dim_vector& d3) { std::string d1_str = d1.str (); std::string d2_str = d2.str (); std::string d3_str = d3.str (); (*current_liboctave_error_handler) ("betainc: nonconformant arguments (x is %s, a is %s, b is %s)", d1_str.c_str (), d2_str.c_str (), d3_str.c_str ()); } double betainc (double x, double a, double b) { double retval; F77_FUNC (xdbetai, XDBETAI) (x, a, b, retval); return retval; } Matrix betainc (double x, double a, const Matrix& b) { octave_idx_type nr = b.rows (); octave_idx_type nc = b.cols (); Matrix retval (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x, a, b(i,j)); return retval; } Matrix betainc (double x, const Matrix& a, double b) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); Matrix retval (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x, a(i,j), b); return retval; } Matrix betainc (double x, const Matrix& a, const Matrix& b) { Matrix retval; octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (a_nr == b_nr && a_nc == b_nc) { retval.resize (a_nr, a_nc); for (octave_idx_type j = 0; j < a_nc; j++) for (octave_idx_type i = 0; i < a_nr; i++) retval(i,j) = betainc (x, a(i,j), b(i,j)); } else gripe_betainc_nonconformant (1, 1, a_nr, a_nc, b_nr, b_nc); return retval; } NDArray betainc (double x, double a, const NDArray& b) { dim_vector dv = b.dims (); int nel = dv.numel (); NDArray retval (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x, a, b(i)); return retval; } NDArray betainc (double x, const NDArray& a, double b) { dim_vector dv = a.dims (); int nel = dv.numel (); NDArray retval (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x, a(i), b); return retval; } NDArray betainc (double x, const NDArray& a, const NDArray& b) { NDArray retval; dim_vector dv = a.dims (); if (dv == b.dims ()) { int nel = dv.numel (); retval.resize (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x, a(i), b(i)); } else gripe_betainc_nonconformant (dim_vector (0), dv, b.dims ()); return retval; } Matrix betainc (const Matrix& x, double a, double b) { octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); Matrix retval (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x(i,j), a, b); return retval; } Matrix betainc (const Matrix& x, double a, const Matrix& b) { Matrix retval; octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (nr == b_nr && nc == b_nc) { retval.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x(i,j), a, b(i,j)); } else gripe_betainc_nonconformant (nr, nc, 1, 1, b_nr, b_nc); return retval; } Matrix betainc (const Matrix& x, const Matrix& a, double b) { Matrix retval; octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); if (nr == a_nr && nc == a_nc) { retval.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x(i,j), a(i,j), b); } else gripe_betainc_nonconformant (nr, nc, a_nr, a_nc, 1, 1); return retval; } Matrix betainc (const Matrix& x, const Matrix& a, const Matrix& b) { Matrix retval; octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); octave_idx_type b_nr = b.rows (); octave_idx_type b_nc = b.cols (); if (nr == a_nr && nr == b_nr && nc == a_nc && nc == b_nc) { retval.resize (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) retval(i,j) = betainc (x(i,j), a(i,j), b(i,j)); } else gripe_betainc_nonconformant (nr, nc, a_nr, a_nc, b_nr, b_nc); return retval; } NDArray betainc (const NDArray& x, double a, double b) { dim_vector dv = x.dims (); int nel = dv.numel (); NDArray retval (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x(i), a, b); return retval; } NDArray betainc (const NDArray& x, double a, const NDArray& b) { NDArray retval; dim_vector dv = x.dims (); if (dv == b.dims ()) { int nel = dv.numel (); retval.resize (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x(i), a, b(i)); } else gripe_betainc_nonconformant (dv, dim_vector (0), b.dims ()); return retval; } NDArray betainc (const NDArray& x, const NDArray& a, double b) { NDArray retval; dim_vector dv = x.dims (); if (dv == a.dims ()) { int nel = dv.numel (); retval.resize (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x(i), a(i), b); } else gripe_betainc_nonconformant (dv, a.dims (), dim_vector (0)); return retval; } NDArray betainc (const NDArray& x, const NDArray& a, const NDArray& b) { NDArray retval; dim_vector dv = x.dims (); if (dv == a.dims () && dv == b.dims ()) { int nel = dv.numel (); retval.resize (dv); for (int i = 0; i < nel; i++) retval (i) = betainc (x(i), a(i), b(i)); } else gripe_betainc_nonconformant (dv, a.dims (), b.dims ()); return retval; } // XXX FIXME XXX -- there is still room for improvement here... double gammainc (double x, double a, bool& err) { double retval; err = false; if (a < 0.0 || x < 0.0) { (*current_liboctave_error_handler) ("gammainc: A and X must be non-negative"); err = true; } else F77_XFCN (xgammainc, XGAMMAINC, (a, x, retval)); return retval; } Matrix gammainc (double x, const Matrix& a) { octave_idx_type nr = a.rows (); octave_idx_type nc = a.cols (); Matrix result (nr, nc); Matrix retval; bool err; for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) { result(i,j) = gammainc (x, a(i,j), err); if (err) goto done; } retval = result; done: return retval; } Matrix gammainc (const Matrix& x, double a) { octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); Matrix result (nr, nc); Matrix retval; bool err; for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) { result(i,j) = gammainc (x(i,j), a, err); if (err) goto done; } retval = result; done: return retval; } Matrix gammainc (const Matrix& x, const Matrix& a) { Matrix result; Matrix retval; octave_idx_type nr = x.rows (); octave_idx_type nc = x.cols (); octave_idx_type a_nr = a.rows (); octave_idx_type a_nc = a.cols (); if (nr == a_nr && nc == a_nc) { result.resize (nr, nc); bool err; for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) { result(i,j) = gammainc (x(i,j), a(i,j), err); if (err) goto done; } retval = result; } else (*current_liboctave_error_handler) ("gammainc: nonconformant arguments (arg 1 is %dx%d, arg 2 is %dx%d)", nr, nc, a_nr, a_nc); done: return retval; } NDArray gammainc (double x, const NDArray& a) { dim_vector dv = a.dims (); int nel = dv.numel (); NDArray retval; NDArray result (dv); bool err; for (int i = 0; i < nel; i++) { result (i) = gammainc (x, a(i), err); if (err) goto done; } retval = result; done: return retval; } NDArray gammainc (const NDArray& x, double a) { dim_vector dv = x.dims (); int nel = dv.numel (); NDArray retval; NDArray result (dv); bool err; for (int i = 0; i < nel; i++) { result (i) = gammainc (x(i), a, err); if (err) goto done; } retval = result; done: return retval; } NDArray gammainc (const NDArray& x, const NDArray& a) { dim_vector dv = x.dims (); int nel = dv.numel (); NDArray retval; NDArray result; if (dv == a.dims ()) { result.resize (dv); bool err; for (int i = 0; i < nel; i++) { result (i) = gammainc (x(i), a(i), err); if (err) goto done; } retval = result; } else { std::string x_str = dv.str (); std::string a_str = a.dims ().str (); (*current_liboctave_error_handler) ("gammainc: nonconformant arguments (arg 1 is %s, arg 2 is %s)", x_str.c_str (), a_str. c_str ()); } done: return retval; } /* ;;; Local Variables: *** ;;; mode: C++ *** ;;; End: *** */