Mercurial > octave
view liboctave/array/fCNDArray.cc @ 21202:f7121e111991
maint: indent #ifdef blocks in liboctave and src directories.
* Array-C.cc, Array-b.cc, Array-ch.cc, Array-d.cc, Array-f.cc, Array-fC.cc,
Array-i.cc, Array-idx-vec.cc, Array-s.cc, Array-str.cc, Array-util.cc,
Array-voidp.cc, Array.cc, CColVector.cc, CDiagMatrix.cc, CMatrix.cc,
CNDArray.cc, CRowVector.cc, CSparse.cc, CSparse.h, DiagArray2.cc, MArray-C.cc,
MArray-d.cc, MArray-f.cc, MArray-fC.cc, MArray-i.cc, MArray-s.cc, MArray.cc,
MDiagArray2.cc, MSparse-C.cc, MSparse-d.cc, MSparse.h, MatrixType.cc,
PermMatrix.cc, Range.cc, Sparse-C.cc, Sparse-b.cc, Sparse-d.cc, Sparse.cc,
boolMatrix.cc, boolNDArray.cc, boolSparse.cc, chMatrix.cc, chNDArray.cc,
dColVector.cc, dDiagMatrix.cc, dMatrix.cc, dNDArray.cc, dRowVector.cc,
dSparse.cc, dSparse.h, dim-vector.cc, fCColVector.cc, fCDiagMatrix.cc,
fCMatrix.cc, fCNDArray.cc, fCRowVector.cc, fColVector.cc, fDiagMatrix.cc,
fMatrix.cc, fNDArray.cc, fRowVector.cc, idx-vector.cc, int16NDArray.cc,
int32NDArray.cc, int64NDArray.cc, int8NDArray.cc, intNDArray.cc,
uint16NDArray.cc, uint32NDArray.cc, uint64NDArray.cc, uint8NDArray.cc,
blaswrap.c, cquit.c, f77-extern.cc, f77-fcn.c, f77-fcn.h, lo-error.c, quit.cc,
quit.h, CmplxAEPBAL.cc, CmplxCHOL.cc, CmplxGEPBAL.cc, CmplxHESS.cc, CmplxLU.cc,
CmplxQR.cc, CmplxQRP.cc, CmplxSCHUR.cc, CmplxSVD.cc, CollocWt.cc, DASPK.cc,
DASRT.cc, DASSL.cc, EIG.cc, LSODE.cc, ODES.cc, Quad.cc, base-lu.cc, base-qr.cc,
dbleAEPBAL.cc, dbleCHOL.cc, dbleGEPBAL.cc, dbleHESS.cc, dbleLU.cc, dbleQR.cc,
dbleQRP.cc, dbleSCHUR.cc, dbleSVD.cc, eigs-base.cc, fCmplxAEPBAL.cc,
fCmplxCHOL.cc, fCmplxGEPBAL.cc, fCmplxHESS.cc, fCmplxLU.cc, fCmplxQR.cc,
fCmplxQRP.cc, fCmplxSCHUR.cc, fCmplxSVD.cc, fEIG.cc, floatAEPBAL.cc,
floatCHOL.cc, floatGEPBAL.cc, floatHESS.cc, floatLU.cc, floatQR.cc,
floatQRP.cc, floatSCHUR.cc, floatSVD.cc, lo-mappers.cc, lo-specfun.cc,
oct-convn.cc, oct-fftw.cc, oct-fftw.h, oct-norm.cc, oct-rand.cc,
oct-spparms.cc, randgamma.c, randmtzig.c, randpoisson.c, sparse-chol.cc,
sparse-dmsolve.cc, sparse-lu.cc, sparse-qr.cc, mx-defs.h, dir-ops.cc,
file-ops.cc, file-stat.cc, lo-sysdep.cc, mach-info.cc, oct-env.cc,
oct-group.cc, oct-openmp.h, oct-passwd.cc, oct-syscalls.cc, oct-time.cc,
oct-uname.cc, pathlen.h, sysdir.h, syswait.h, cmd-edit.cc, cmd-hist.cc,
data-conv.cc, f2c-main.c, glob-match.cc, lo-array-errwarn.cc,
lo-array-gripes.cc, lo-cutils.c, lo-cutils.h, lo-ieee.cc, lo-math.h,
lo-regexp.cc, lo-utils.cc, oct-base64.cc, oct-glob.cc, oct-inttypes.cc,
oct-inttypes.h, oct-locbuf.cc, oct-mutex.cc, oct-refcount.h, oct-rl-edit.c,
oct-rl-hist.c, oct-shlib.cc, oct-sort.cc, pathsearch.cc, singleton-cleanup.cc,
sparse-sort.cc, sparse-util.cc, statdefs.h, str-vec.cc, unwind-prot.cc,
url-transfer.cc, display-available.h, main-cli.cc, main-gui.cc, main.in.cc,
mkoctfile.in.cc, octave-config.in.cc, shared-fcns.h:
indent #ifdef blocks in liboctave and src directories.
author | Rik <rik@octave.org> |
---|---|
date | Sat, 06 Feb 2016 06:40:13 -0800 |
parents | 40051830f89b |
children | 40de9f8f23a6 |
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line source
// N-D Array manipulations. /* Copyright (C) 1996-2015 John W. Eaton Copyright (C) 2009 VZLU Prague, a.s. 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/>. */ #ifdef HAVE_CONFIG_H # include <config.h> #endif #include <cfloat> #include <vector> #include "Array-util.h" #include "f77-fcn.h" #include "fCNDArray.h" #include "functor.h" #include "lo-ieee.h" #include "lo-mappers.h" #include "mx-base.h" #include "mx-op-defs.h" #include "mx-fcnda-fs.h" #include "oct-fftw.h" #include "oct-locbuf.h" #include "bsxfun-defs.cc" FloatComplexNDArray::FloatComplexNDArray (const charNDArray& a) : MArray<FloatComplex> (a.dims ()) { octave_idx_type n = a.numel (); for (octave_idx_type i = 0; i < n; i++) xelem (i) = static_cast<unsigned char> (a(i)); } #if defined (HAVE_FFTW) FloatComplexNDArray FloatComplexNDArray::fourier (int dim) const { dim_vector dv = dims (); if (dim > dv.length () || dim < 0) return FloatComplexNDArray (); octave_idx_type stride = 1; octave_idx_type n = dv(dim); for (int i = 0; i < dim; i++) stride *= dv(i); octave_idx_type howmany = numel () / dv(dim); howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / dv(dim) / stride); octave_idx_type dist = (stride == 1 ? n : 1); const FloatComplex *in (fortran_vec ()); FloatComplexNDArray retval (dv); FloatComplex *out (retval.fortran_vec ()); // Need to be careful here about the distance between fft's for (octave_idx_type k = 0; k < nloop; k++) octave_fftw::fft (in + k * stride * n, out + k * stride * n, n, howmany, stride, dist); return retval; } FloatComplexNDArray FloatComplexNDArray::ifourier (int dim) const { dim_vector dv = dims (); if (dim > dv.length () || dim < 0) return FloatComplexNDArray (); octave_idx_type stride = 1; octave_idx_type n = dv(dim); for (int i = 0; i < dim; i++) stride *= dv(i); octave_idx_type howmany = numel () / dv(dim); howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / dv(dim) / stride); octave_idx_type dist = (stride == 1 ? n : 1); const FloatComplex *in (fortran_vec ()); FloatComplexNDArray retval (dv); FloatComplex *out (retval.fortran_vec ()); // Need to be careful here about the distance between fft's for (octave_idx_type k = 0; k < nloop; k++) octave_fftw::ifft (in + k * stride * n, out + k * stride * n, n, howmany, stride, dist); return retval; } FloatComplexNDArray FloatComplexNDArray::fourier2d (void) const { dim_vector dv = dims (); if (dv.length () < 2) return FloatComplexNDArray (); dim_vector dv2 (dv(0), dv(1)); const FloatComplex *in = fortran_vec (); FloatComplexNDArray retval (dv); FloatComplex *out = retval.fortran_vec (); octave_idx_type howmany = numel () / dv(0) / dv(1); octave_idx_type dist = dv(0) * dv(1); for (octave_idx_type i=0; i < howmany; i++) octave_fftw::fftNd (in + i*dist, out + i*dist, 2, dv2); return retval; } FloatComplexNDArray FloatComplexNDArray::ifourier2d (void) const { dim_vector dv = dims (); if (dv.length () < 2) return FloatComplexNDArray (); dim_vector dv2 (dv(0), dv(1)); const FloatComplex *in = fortran_vec (); FloatComplexNDArray retval (dv); FloatComplex *out = retval.fortran_vec (); octave_idx_type howmany = numel () / dv(0) / dv(1); octave_idx_type dist = dv(0) * dv(1); for (octave_idx_type i=0; i < howmany; i++) octave_fftw::ifftNd (in + i*dist, out + i*dist, 2, dv2); return retval; } FloatComplexNDArray FloatComplexNDArray::fourierNd (void) const { dim_vector dv = dims (); int rank = dv.length (); const FloatComplex *in (fortran_vec ()); FloatComplexNDArray retval (dv); FloatComplex *out (retval.fortran_vec ()); octave_fftw::fftNd (in, out, rank, dv); return retval; } FloatComplexNDArray FloatComplexNDArray::ifourierNd (void) const { dim_vector dv = dims (); int rank = dv.length (); const FloatComplex *in (fortran_vec ()); FloatComplexNDArray retval (dv); FloatComplex *out (retval.fortran_vec ()); octave_fftw::ifftNd (in, out, rank, dv); return retval; } #else extern "C" { F77_RET_T F77_FUNC (cffti, CFFTI) (const octave_idx_type&, FloatComplex*); F77_RET_T F77_FUNC (cfftf, CFFTF) (const octave_idx_type&, FloatComplex*, FloatComplex*); F77_RET_T F77_FUNC (cfftb, CFFTB) (const octave_idx_type&, FloatComplex*, FloatComplex*); } FloatComplexNDArray FloatComplexNDArray::fourier (int dim) const { dim_vector dv = dims (); if (dim > dv.length () || dim < 0) return FloatComplexNDArray (); FloatComplexNDArray retval (dv); octave_idx_type npts = dv(dim); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); OCTAVE_LOCAL_BUFFER (FloatComplex, tmp, npts); octave_idx_type stride = 1; for (int i = 0; i < dim; i++) stride *= dv(i); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type i = 0; i < npts; i++) tmp[i] = elem ((i + k*npts)*stride + j*dist); F77_FUNC (cfftf, CFFTF) (npts, tmp, pwsave); for (octave_idx_type i = 0; i < npts; i++) retval((i + k*npts)*stride + j*dist) = tmp[i]; } } return retval; } FloatComplexNDArray FloatComplexNDArray::ifourier (int dim) const { dim_vector dv = dims (); if (dim > dv.length () || dim < 0) return FloatComplexNDArray (); FloatComplexNDArray retval (dv); octave_idx_type npts = dv(dim); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); OCTAVE_LOCAL_BUFFER (FloatComplex, tmp, npts); octave_idx_type stride = 1; for (int i = 0; i < dim; i++) stride *= dv(i); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type i = 0; i < npts; i++) tmp[i] = elem ((i + k*npts)*stride + j*dist); F77_FUNC (cfftb, CFFTB) (npts, tmp, pwsave); for (octave_idx_type i = 0; i < npts; i++) retval((i + k*npts)*stride + j*dist) = tmp[i] / static_cast<float> (npts); } } return retval; } FloatComplexNDArray FloatComplexNDArray::fourier2d (void) const { dim_vector dv = dims (); dim_vector dv2 (dv(0), dv(1)); int rank = 2; FloatComplexNDArray retval (*this); octave_idx_type stride = 1; for (int i = 0; i < rank; i++) { octave_idx_type npts = dv2(i); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); Array<FloatComplex> row (dim_vector (npts, 1)); FloatComplex *prow = row.fortran_vec (); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type l = 0; l < npts; l++) prow[l] = retval((l + k*npts)*stride + j*dist); F77_FUNC (cfftf, CFFTF) (npts, prow, pwsave); for (octave_idx_type l = 0; l < npts; l++) retval((l + k*npts)*stride + j*dist) = prow[l]; } } stride *= dv2(i); } return retval; } FloatComplexNDArray FloatComplexNDArray::ifourier2d (void) const { dim_vector dv = dims (); dim_vector dv2 (dv(0), dv(1)); int rank = 2; FloatComplexNDArray retval (*this); octave_idx_type stride = 1; for (int i = 0; i < rank; i++) { octave_idx_type npts = dv2(i); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); Array<FloatComplex> row (dim_vector (npts, 1)); FloatComplex *prow = row.fortran_vec (); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type l = 0; l < npts; l++) prow[l] = retval((l + k*npts)*stride + j*dist); F77_FUNC (cfftb, CFFTB) (npts, prow, pwsave); for (octave_idx_type l = 0; l < npts; l++) retval((l + k*npts)*stride + j*dist) = prow[l] / static_cast<float> (npts); } } stride *= dv2(i); } return retval; } FloatComplexNDArray FloatComplexNDArray::fourierNd (void) const { dim_vector dv = dims (); int rank = dv.length (); FloatComplexNDArray retval (*this); octave_idx_type stride = 1; for (int i = 0; i < rank; i++) { octave_idx_type npts = dv(i); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); Array<FloatComplex> row (dim_vector (npts, 1)); FloatComplex *prow = row.fortran_vec (); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type l = 0; l < npts; l++) prow[l] = retval((l + k*npts)*stride + j*dist); F77_FUNC (cfftf, CFFTF) (npts, prow, pwsave); for (octave_idx_type l = 0; l < npts; l++) retval((l + k*npts)*stride + j*dist) = prow[l]; } } stride *= dv(i); } return retval; } FloatComplexNDArray FloatComplexNDArray::ifourierNd (void) const { dim_vector dv = dims (); int rank = dv.length (); FloatComplexNDArray retval (*this); octave_idx_type stride = 1; for (int i = 0; i < rank; i++) { octave_idx_type npts = dv(i); octave_idx_type nn = 4*npts+15; Array<FloatComplex> wsave (dim_vector (nn, 1)); FloatComplex *pwsave = wsave.fortran_vec (); Array<FloatComplex> row (dim_vector (npts, 1)); FloatComplex *prow = row.fortran_vec (); octave_idx_type howmany = numel () / npts; howmany = (stride == 1 ? howmany : (howmany > stride ? stride : howmany)); octave_idx_type nloop = (stride == 1 ? 1 : numel () / npts / stride); octave_idx_type dist = (stride == 1 ? npts : 1); F77_FUNC (cffti, CFFTI) (npts, pwsave); for (octave_idx_type k = 0; k < nloop; k++) { for (octave_idx_type j = 0; j < howmany; j++) { octave_quit (); for (octave_idx_type l = 0; l < npts; l++) prow[l] = retval((l + k*npts)*stride + j*dist); F77_FUNC (cfftb, CFFTB) (npts, prow, pwsave); for (octave_idx_type l = 0; l < npts; l++) retval((l + k*npts)*stride + j*dist) = prow[l] / static_cast<float> (npts); } } stride *= dv(i); } return retval; } #endif // unary operations boolNDArray FloatComplexNDArray::operator ! (void) const { if (any_element_is_nan ()) err_nan_to_logical_conversion (); return do_mx_unary_op<bool, FloatComplex> (*this, mx_inline_not); } // FIXME: this is not quite the right thing. bool FloatComplexNDArray::any_element_is_nan (void) const { return do_mx_check<FloatComplex> (*this, mx_inline_any_nan); } bool FloatComplexNDArray::any_element_is_inf_or_nan (void) const { return ! do_mx_check<FloatComplex> (*this, mx_inline_all_finite); } // Return true if no elements have imaginary components. bool FloatComplexNDArray::all_elements_are_real (void) const { return do_mx_check<FloatComplex> (*this, mx_inline_all_real); } // Return nonzero if any element of CM has a non-integer real or // imaginary part. Also extract the largest and smallest (real or // imaginary) values and return them in MAX_VAL and MIN_VAL. bool FloatComplexNDArray::all_integers (float& max_val, float& min_val) const { octave_idx_type nel = numel (); if (nel > 0) { FloatComplex val = elem (0); float r_val = std::real (val); float i_val = std::imag (val); max_val = r_val; min_val = r_val; if (i_val > max_val) max_val = i_val; if (i_val < max_val) min_val = i_val; } else return false; for (octave_idx_type i = 0; i < nel; i++) { FloatComplex val = elem (i); float r_val = std::real (val); float i_val = std::imag (val); if (r_val > max_val) max_val = r_val; if (i_val > max_val) max_val = i_val; if (r_val < min_val) min_val = r_val; if (i_val < min_val) min_val = i_val; if (D_NINT (r_val) != r_val || D_NINT (i_val) != i_val) return false; } return true; } bool FloatComplexNDArray::too_large_for_float (void) const { return false; } boolNDArray FloatComplexNDArray::all (int dim) const { return do_mx_red_op<bool, FloatComplex> (*this, dim, mx_inline_all); } boolNDArray FloatComplexNDArray::any (int dim) const { return do_mx_red_op<bool, FloatComplex> (*this, dim, mx_inline_any); } FloatComplexNDArray FloatComplexNDArray::cumprod (int dim) const { return do_mx_cum_op<FloatComplex, FloatComplex> (*this, dim, mx_inline_cumprod); } FloatComplexNDArray FloatComplexNDArray::cumsum (int dim) const { return do_mx_cum_op<FloatComplex, FloatComplex> (*this, dim, mx_inline_cumsum); } FloatComplexNDArray FloatComplexNDArray::prod (int dim) const { return do_mx_red_op<FloatComplex, FloatComplex> (*this, dim, mx_inline_prod); } ComplexNDArray FloatComplexNDArray::dprod (int dim) const { return do_mx_red_op<Complex, FloatComplex> (*this, dim, mx_inline_dprod); } FloatComplexNDArray FloatComplexNDArray::sum (int dim) const { return do_mx_red_op<FloatComplex, FloatComplex> (*this, dim, mx_inline_sum); } ComplexNDArray FloatComplexNDArray::dsum (int dim) const { return do_mx_red_op<Complex, FloatComplex> (*this, dim, mx_inline_dsum); } FloatComplexNDArray FloatComplexNDArray::sumsq (int dim) const { return do_mx_red_op<float, FloatComplex> (*this, dim, mx_inline_sumsq); } FloatComplexNDArray FloatComplexNDArray::diff (octave_idx_type order, int dim) const { return do_mx_diff_op<FloatComplex> (*this, dim, order, mx_inline_diff); } FloatComplexNDArray FloatComplexNDArray::concat (const FloatComplexNDArray& rb, const Array<octave_idx_type>& ra_idx) { if (rb.numel () > 0) insert (rb, ra_idx); return *this; } FloatComplexNDArray FloatComplexNDArray::concat (const FloatNDArray& rb, const Array<octave_idx_type>& ra_idx) { FloatComplexNDArray tmp (rb); if (rb.numel () > 0) insert (tmp, ra_idx); return *this; } FloatComplexNDArray concat (NDArray& ra, FloatComplexNDArray& rb, const Array<octave_idx_type>& ra_idx) { FloatComplexNDArray retval (ra); if (rb.numel () > 0) retval.insert (rb, ra_idx); return retval; } static const FloatComplex FloatComplex_NaN_result (octave_Float_NaN, octave_Float_NaN); FloatComplexNDArray FloatComplexNDArray::max (int dim) const { return do_mx_minmax_op<FloatComplex> (*this, dim, mx_inline_max); } FloatComplexNDArray FloatComplexNDArray::max (Array<octave_idx_type>& idx_arg, int dim) const { return do_mx_minmax_op<FloatComplex> (*this, idx_arg, dim, mx_inline_max); } FloatComplexNDArray FloatComplexNDArray::min (int dim) const { return do_mx_minmax_op<FloatComplex> (*this, dim, mx_inline_min); } FloatComplexNDArray FloatComplexNDArray::min (Array<octave_idx_type>& idx_arg, int dim) const { return do_mx_minmax_op<FloatComplex> (*this, idx_arg, dim, mx_inline_min); } FloatComplexNDArray FloatComplexNDArray::cummax (int dim) const { return do_mx_cumminmax_op<FloatComplex> (*this, dim, mx_inline_cummax); } FloatComplexNDArray FloatComplexNDArray::cummax (Array<octave_idx_type>& idx_arg, int dim) const { return do_mx_cumminmax_op<FloatComplex> (*this, idx_arg, dim, mx_inline_cummax); } FloatComplexNDArray FloatComplexNDArray::cummin (int dim) const { return do_mx_cumminmax_op<FloatComplex> (*this, dim, mx_inline_cummin); } FloatComplexNDArray FloatComplexNDArray::cummin (Array<octave_idx_type>& idx_arg, int dim) const { return do_mx_cumminmax_op<FloatComplex> (*this, idx_arg, dim, mx_inline_cummin); } FloatNDArray FloatComplexNDArray::abs (void) const { return do_mx_unary_map<float, FloatComplex, std::abs> (*this); } boolNDArray FloatComplexNDArray::isnan (void) const { return do_mx_unary_map<bool, FloatComplex, xisnan> (*this); } boolNDArray FloatComplexNDArray::isinf (void) const { return do_mx_unary_map<bool, FloatComplex, xisinf> (*this); } boolNDArray FloatComplexNDArray::isfinite (void) const { return do_mx_unary_map<bool, FloatComplex, xfinite> (*this); } FloatComplexNDArray conj (const FloatComplexNDArray& a) { return do_mx_unary_map<FloatComplex, FloatComplex, std::conj<float> > (a); } FloatComplexNDArray& FloatComplexNDArray::insert (const NDArray& a, octave_idx_type r, octave_idx_type c) { dim_vector a_dv = a.dims (); int n = a_dv.length (); if (n == dimensions.length ()) { Array<octave_idx_type> a_ra_idx (dim_vector (a_dv.length (), 1), 0); a_ra_idx.elem (0) = r; a_ra_idx.elem (1) = c; for (int i = 0; i < n; i++) { if (a_ra_idx(i) < 0 || (a_ra_idx(i) + a_dv(i)) > dimensions(i)) (*current_liboctave_error_handler) ("Array<T>::insert: range error for insert"); } a_ra_idx.elem (0) = 0; a_ra_idx.elem (1) = 0; octave_idx_type n_elt = a.numel (); // IS make_unique () NECESSARY HERE? for (octave_idx_type i = 0; i < n_elt; i++) { Array<octave_idx_type> ra_idx = a_ra_idx; ra_idx.elem (0) = a_ra_idx(0) + r; ra_idx.elem (1) = a_ra_idx(1) + c; elem (ra_idx) = a.elem (a_ra_idx); increment_index (a_ra_idx, a_dv); } } else (*current_liboctave_error_handler) ("Array<T>::insert: invalid indexing operation"); return *this; } FloatComplexNDArray& FloatComplexNDArray::insert (const FloatComplexNDArray& a, octave_idx_type r, octave_idx_type c) { Array<FloatComplex>::insert (a, r, c); return *this; } FloatComplexNDArray& FloatComplexNDArray::insert (const FloatComplexNDArray& a, const Array<octave_idx_type>& ra_idx) { Array<FloatComplex>::insert (a, ra_idx); return *this; } void FloatComplexNDArray::increment_index (Array<octave_idx_type>& ra_idx, const dim_vector& dimensions, int start_dimension) { ::increment_index (ra_idx, dimensions, start_dimension); } octave_idx_type FloatComplexNDArray::compute_index (Array<octave_idx_type>& ra_idx, const dim_vector& dimensions) { return ::compute_index (ra_idx, dimensions); } FloatComplexNDArray FloatComplexNDArray::diag (octave_idx_type k) const { return MArray<FloatComplex>::diag (k); } FloatComplexNDArray FloatComplexNDArray::diag (octave_idx_type m, octave_idx_type n) const { return MArray<FloatComplex>::diag (m, n); } // This contains no information on the array structure !!! std::ostream& operator << (std::ostream& os, const FloatComplexNDArray& a) { octave_idx_type nel = a.numel (); for (octave_idx_type i = 0; i < nel; i++) { os << " "; octave_write_complex (os, a.elem (i)); os << "\n"; } return os; } std::istream& operator >> (std::istream& is, FloatComplexNDArray& a) { octave_idx_type nel = a.numel (); if (nel > 0) { FloatComplex tmp; for (octave_idx_type i = 0; i < nel; i++) { tmp = octave_read_value<FloatComplex> (is); if (is) a.elem (i) = tmp; else return is; } } return is; } MINMAX_FCNS (FloatComplexNDArray, FloatComplex) NDS_CMP_OPS (FloatComplexNDArray, FloatComplex) NDS_BOOL_OPS (FloatComplexNDArray, FloatComplex) SND_CMP_OPS (FloatComplex, FloatComplexNDArray) SND_BOOL_OPS (FloatComplex, FloatComplexNDArray) NDND_CMP_OPS (FloatComplexNDArray, FloatComplexNDArray) NDND_BOOL_OPS (FloatComplexNDArray, FloatComplexNDArray) FloatComplexNDArray& operator *= (FloatComplexNDArray& a, float s) { if (a.is_shared ()) a = a * s; else do_ms_inplace_op<FloatComplex, float> (a, s, mx_inline_mul2); return a; } FloatComplexNDArray& operator /= (FloatComplexNDArray& a, float s) { if (a.is_shared ()) a = a / s; else do_ms_inplace_op<FloatComplex, float> (a, s, mx_inline_div2); return a; } BSXFUN_STDOP_DEFS_MXLOOP (FloatComplexNDArray) BSXFUN_STDREL_DEFS_MXLOOP (FloatComplexNDArray) BSXFUN_OP_DEF_MXLOOP (pow, FloatComplexNDArray, mx_inline_pow)