Mercurial > octave
view libinterp/corefcn/pow2.cc @ 31607:aac27ad79be6 stable
maint: Re-indent code after switch to using namespace macros.
* build-env.h, build-env.in.cc, Cell.h, __betainc__.cc, __eigs__.cc,
__ftp__.cc, __ichol__.cc, __ilu__.cc, __isprimelarge__.cc, __magick_read__.cc,
__pchip_deriv__.cc, amd.cc, base-text-renderer.cc, base-text-renderer.h,
besselj.cc, bitfcns.cc, bsxfun.cc, c-file-ptr-stream.h, call-stack.cc,
call-stack.h, ccolamd.cc, cellfun.cc, chol.cc, colamd.cc, dasrt.cc, data.cc,
debug.cc, defaults.cc, defaults.h, det.cc, display.cc, display.h, dlmread.cc,
dynamic-ld.cc, dynamic-ld.h, ellipj.cc, environment.cc, environment.h,
error.cc, error.h, errwarn.h, event-manager.cc, event-manager.h,
event-queue.cc, event-queue.h, fcn-info.cc, fcn-info.h, fft.cc, fft2.cc,
file-io.cc, filter.cc, find.cc, ft-text-renderer.cc, ft-text-renderer.h,
gcd.cc, gl-render.cc, gl-render.h, gl2ps-print.cc, gl2ps-print.h,
graphics-toolkit.cc, graphics-toolkit.h, graphics.cc, gsvd.cc, gtk-manager.cc,
gtk-manager.h, help.cc, help.h, hook-fcn.cc, hook-fcn.h, input.cc, input.h,
interpreter-private.cc, interpreter-private.h, interpreter.cc, interpreter.h,
inv.cc, jsondecode.cc, jsonencode.cc, latex-text-renderer.cc,
latex-text-renderer.h, load-path.cc, load-path.h, load-save.cc, load-save.h,
lookup.cc, ls-hdf5.cc, ls-mat4.cc, ls-mat5.cc, lsode.cc, lu.cc, mappers.cc,
matrix_type.cc, max.cc, mex.cc, mexproto.h, mxarray.h, mxtypes.in.h,
oct-errno.in.cc, oct-hdf5-types.cc, oct-hist.cc, oct-hist.h, oct-map.cc,
oct-map.h, oct-opengl.h, oct-prcstrm.h, oct-process.cc, oct-process.h,
oct-stdstrm.h, oct-stream.cc, oct-stream.h, oct-strstrm.h,
octave-default-image.h, ordqz.cc, ordschur.cc, pager.cc, pager.h, pinv.cc,
pow2.cc, pr-output.cc, psi.cc, qr.cc, quadcc.cc, rand.cc, regexp.cc,
settings.cc, settings.h, sighandlers.cc, sighandlers.h, sparse-xpow.cc,
sqrtm.cc, stack-frame.cc, stack-frame.h, stream-euler.cc, strfns.cc, svd.cc,
syminfo.cc, syminfo.h, symrcm.cc, symrec.cc, symrec.h, symscope.cc, symscope.h,
symtab.cc, symtab.h, sysdep.cc, sysdep.h, text-engine.cc, text-engine.h,
text-renderer.cc, text-renderer.h, time.cc, toplev.cc, typecast.cc,
url-handle-manager.cc, url-handle-manager.h, urlwrite.cc, utils.cc, utils.h,
variables.cc, variables.h, xdiv.cc, __delaunayn__.cc, __init_fltk__.cc,
__init_gnuplot__.cc, __ode15__.cc, __voronoi__.cc, audioread.cc, convhulln.cc,
gzip.cc, cdef-class.cc, cdef-class.h, cdef-fwd.h, cdef-manager.cc,
cdef-manager.h, cdef-method.cc, cdef-method.h, cdef-object.cc, cdef-object.h,
cdef-package.cc, cdef-package.h, cdef-property.cc, cdef-property.h,
cdef-utils.cc, cdef-utils.h, ov-base-diag.cc, ov-base-int.cc, ov-base-mat.cc,
ov-base-mat.h, ov-base-scalar.cc, ov-base.cc, ov-base.h, ov-bool-mat.cc,
ov-bool-mat.h, ov-bool-sparse.cc, ov-bool.cc, ov-builtin.h, ov-cell.cc,
ov-ch-mat.cc, ov-class.cc, ov-class.h, ov-classdef.cc, ov-classdef.h,
ov-complex.cc, ov-cx-diag.cc, ov-cx-mat.cc, ov-cx-sparse.cc, ov-dld-fcn.cc,
ov-dld-fcn.h, ov-fcn-handle.cc, ov-fcn-handle.h, ov-fcn.h, ov-float.cc,
ov-flt-complex.cc, ov-flt-cx-diag.cc, ov-flt-cx-mat.cc, ov-flt-re-diag.cc,
ov-flt-re-mat.cc, ov-flt-re-mat.h, ov-intx.h, ov-java.cc, ov-lazy-idx.cc,
ov-legacy-range.cc, ov-magic-int.cc, ov-mex-fcn.cc, ov-mex-fcn.h,
ov-null-mat.cc, ov-perm.cc, ov-range.cc, ov-re-diag.cc, ov-re-mat.cc,
ov-re-mat.h, ov-re-sparse.cc, ov-scalar.cc, ov-str-mat.cc, ov-struct.cc,
ov-typeinfo.cc, ov-typeinfo.h, ov-usr-fcn.cc, ov-usr-fcn.h, ov.cc, ov.h, ovl.h,
octave.cc, octave.h, op-b-sbm.cc, op-bm-sbm.cc, op-cs-scm.cc, op-fm-fcm.cc,
op-fs-fcm.cc, op-s-scm.cc, op-scm-cs.cc, op-scm-s.cc, op-sm-cs.cc, ops.h,
anon-fcn-validator.cc, anon-fcn-validator.h, bp-table.cc, bp-table.h,
comment-list.cc, comment-list.h, filepos.h, lex.h, oct-lvalue.cc, oct-lvalue.h,
parse.h, profiler.cc, profiler.h, pt-anon-scopes.cc, pt-anon-scopes.h,
pt-arg-list.cc, pt-arg-list.h, pt-args-block.cc, pt-args-block.h,
pt-array-list.cc, pt-array-list.h, pt-assign.cc, pt-assign.h, pt-binop.cc,
pt-binop.h, pt-bp.cc, pt-bp.h, pt-cbinop.cc, pt-cbinop.h, pt-cell.cc,
pt-cell.h, pt-check.cc, pt-check.h, pt-classdef.cc, pt-classdef.h, pt-cmd.h,
pt-colon.cc, pt-colon.h, pt-const.cc, pt-const.h, pt-decl.cc, pt-decl.h,
pt-eval.cc, pt-eval.h, pt-except.cc, pt-except.h, pt-exp.cc, pt-exp.h,
pt-fcn-handle.cc, pt-fcn-handle.h, pt-id.cc, pt-id.h, pt-idx.cc, pt-idx.h,
pt-jump.h, pt-loop.cc, pt-loop.h, pt-mat.cc, pt-mat.h, pt-misc.cc, pt-misc.h,
pt-pr-code.cc, pt-pr-code.h, pt-select.cc, pt-select.h, pt-spmd.cc, pt-spmd.h,
pt-stmt.cc, pt-stmt.h, pt-tm-const.cc, pt-tm-const.h, pt-unop.cc, pt-unop.h,
pt-walk.cc, pt-walk.h, pt.cc, pt.h, token.cc, token.h, Range.cc, Range.h,
idx-vector.cc, idx-vector.h, range-fwd.h, CollocWt.cc, CollocWt.h,
aepbalance.cc, aepbalance.h, chol.cc, chol.h, gepbalance.cc, gepbalance.h,
gsvd.cc, gsvd.h, hess.cc, hess.h, lo-mappers.cc, lo-mappers.h, lo-specfun.cc,
lo-specfun.h, lu.cc, lu.h, oct-convn.cc, oct-convn.h, oct-fftw.cc, oct-fftw.h,
oct-norm.cc, oct-norm.h, oct-rand.cc, oct-rand.h, oct-spparms.cc,
oct-spparms.h, qr.cc, qr.h, qrp.cc, qrp.h, randgamma.cc, randgamma.h,
randmtzig.cc, randmtzig.h, randpoisson.cc, randpoisson.h, schur.cc, schur.h,
sparse-chol.cc, sparse-chol.h, sparse-lu.cc, sparse-lu.h, sparse-qr.cc,
sparse-qr.h, svd.cc, svd.h, child-list.cc, child-list.h, dir-ops.cc, dir-ops.h,
file-ops.cc, file-ops.h, file-stat.cc, file-stat.h, lo-sysdep.cc, lo-sysdep.h,
lo-sysinfo.cc, lo-sysinfo.h, mach-info.cc, mach-info.h, oct-env.cc, oct-env.h,
oct-group.cc, oct-group.h, oct-password.cc, oct-password.h, oct-syscalls.cc,
oct-syscalls.h, oct-time.cc, oct-time.h, oct-uname.cc, oct-uname.h,
action-container.cc, action-container.h, base-list.h, cmd-edit.cc, cmd-edit.h,
cmd-hist.cc, cmd-hist.h, f77-fcn.h, file-info.cc, file-info.h,
lo-array-errwarn.cc, lo-array-errwarn.h, lo-hash.cc, lo-hash.h, lo-ieee.h,
lo-regexp.cc, lo-regexp.h, lo-utils.cc, lo-utils.h, oct-base64.cc,
oct-base64.h, oct-glob.cc, oct-glob.h, oct-inttypes.h, oct-mutex.cc,
oct-mutex.h, oct-refcount.h, oct-shlib.cc, oct-shlib.h, oct-sparse.cc,
oct-sparse.h, oct-string.h, octave-preserve-stream-state.h, pathsearch.cc,
pathsearch.h, quit.cc, quit.h, unwind-prot.cc, unwind-prot.h, url-transfer.cc,
url-transfer.h:
Re-indent code after switch to using namespace macros.
author | Rik <rik@octave.org> |
---|---|
date | Thu, 01 Dec 2022 18:02:15 -0800 |
parents | e88a07dec498 |
children | 597f3ee61a48 |
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//////////////////////////////////////////////////////////////////////// // // Copyright (C) 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 <cmath> #include "lo-array-errwarn.h" #include "defun.h" #include "error.h" #include "errwarn.h" // FIXME: According to cppreference.com the implementation of `ldexp (f, e)` // might be less efficient that the corresponding `f * exp2 (e)`. Consider // replacing our implementation with the latter. template <typename T> void map_2_xldexp (Array<T>& y, const Array<T>& f, const Array<T>& e) { if (f.numel () == e.numel () || e.numel () == 1) y = Array<T> (f.dims ()); else if (f.numel () == 1) y = Array<T> (e.dims ()); else octave::err_nonconformant ("pow2", f.dims (), e.dims ()); octave_idx_type f_inc = (f.numel () == 1) ? 0 : 1; octave_idx_type e_inc = (e.numel () == 1) ? 0 : 1; for (octave_idx_type i = 0; i < y.numel (); i++) y.xelem (i) = std::ldexp (f.xelem (i * f_inc), static_cast<int> (e.xelem (i * e_inc))); } void map_2_xldexp_sparse (SparseMatrix& y, const SparseMatrix& f, const SparseMatrix& e) { if (e.numel () == 1) { int ee = static_cast<int> (e.data (0)); for (octave_idx_type i = 0; i < y.nnz (); i++) y.data (i) = std::ldexp (f.data (i), ee); } else if (f.numel () == e.numel ()) { octave_idx_type col = 1; for (octave_idx_type i = 0; i < y.nnz (); i++) { // Determine current column. while (i >= f.cidx (col)) col++; int ee = static_cast<int> (e.xelem (f.ridx (i), col - 1)); y.data (i) = std::ldexp (f.data (i), ee); } } else octave::err_nonconformant ("pow2", f.dims (), e.dims ()); } OCTAVE_BEGIN_NAMESPACE(octave) DEFUN (pow2, args, , doc: /* -*- texinfo -*- @deftypefn {} {@var{y} =} pow2 (@var{x}) @deftypefnx {} {@var{y} =} pow2 (@var{f}, @var{e}) With one input argument, compute @tex $y = 2^x$ @end tex @ifnottex y = 2 .^ x @end ifnottex for each element of @var{x}. With two input arguments, return @tex $y = f \cdot 2^e$, @end tex @ifnottex y = f .* (2 .^ e). @end ifnottex where for complex inputs only the real part of both inputs is regarded and from @var{e} only the real integer part. This calling form corresponds to C/C++ standard function @code{ldexp()}. @seealso{log2, nextpow2, power} @end deftypefn */) { if (args.length () < 1 || args.length () > 2) print_usage (); if (! args(0).isfloat ()) err_wrong_type_arg ("pow2", args(0)); // Call exp2(f) where possible for numerical more accurate results. if (args.length () == 1) { if (args(0).iscomplex ()) { // The C++ standard does not define exp2 for complex arguments. // Therefore call `2.^x`. octave_value retval = octave::binary_op (octave_value::op_el_pow, 2, args(0)); // Preserve sparse datatype, but even for sparse input fill-up // is unavoidable `2^0 == 1` thus cast only. if (args(0).issparse ()) retval = octave_value (retval.sparse_complex_matrix_value ()); return ovl (retval); } else if (args(0).is_single_type ()) { FloatNDArray x = args(0).float_array_value (); FloatNDArray y (x.dims ()); for (octave_idx_type i = 0; i < y.numel (); i++) y.xelem (i) = std::exp2 (x.xelem (i)); return ovl (y); } else { NDArray x = args(0).array_value (); NDArray y (x.dims ()); for (octave_idx_type i = 0; i < y.numel (); i++) y.xelem (i) = std::exp2 (x.xelem (i)); // Preserve sparse datatype, but even for sparse input fill-up // is unavoidable `2^0 == 1` thus cast only. if (args(0).issparse ()) return ovl (SparseMatrix (y)); else return ovl (y); } } // For Matlab compatibility, the two argument call `y = pow2 (f, e)` // corresponds to std::ldexp() (see bug #61968). The resulting y is // computed quickly by adding the integer part of e to the floating-point // exponent of f. if (! args(1).isfloat ()) err_wrong_type_arg ("pow2", args(1)); if (args(0).iscomplex () || args(1).iscomplex ()) warning_with_id ("Octave:pow2:imaginary-ignored", "pow2: imaginary part is ignored"); // Note: Matlab R2021a errors on `pow2 (sparse (f), single (e))`, // but sparsity in f determines output and can significantly // reduce computation, e.g. `N=1e5; pow2(speye(N),sparse(N,N))`. if (args(0).issparse ()) { SparseMatrix f = args(0).sparse_matrix_value (); // Special case: return a sparse zero matrix in size of e. if ((f.numel () == 1) && (f.nnz () == 0)) return ovl (SparseMatrix (args(1).rows (), args(1).columns ())); // Only do sparse computation, if it pays off. For scalar f fill-up // is unavoidable even for sparse e because `f * 2^0 == f`. Use dense // code below in this case. if (f.numel () > 1) { SparseMatrix e = args(1).sparse_matrix_value (); SparseMatrix y = SparseMatrix (f); map_2_xldexp_sparse (y, f, e); return ovl (y); } } if (args(0).is_single_type () || args(1).is_single_type ()) { FloatNDArray f = args(0).float_array_value (); FloatNDArray e = args(1).float_array_value (); FloatNDArray y; map_2_xldexp (y, f, e); return ovl (y); } else { NDArray f = args(0).array_value (); NDArray e = args(1).array_value (); NDArray y; map_2_xldexp (y, f, e); // Preserve sparse datatype. // Cases for efficient use of sparsity were treated above already. if (args(0).issparse ()) return ovl (SparseMatrix (y)); else return ovl (y); } } /* ## Call `y = pow2 (x)` %!test %! fcns = {@double, @single, @complex}; %! x = [3, 0, -3]; %! v = [8, 1, .125]; %! for i = 1:numel (fcns) %! fcn = fcns{i}; %! assert (pow2 (fcn (x)), fcn (v), sqrt (eps)); %! endfor %!test %! fcns = {@double, @single, @complex, @sparse}; %! x = [3, 1, -3]; %! v = [8, 2, .125]; %! for i = 1:numel (fcns) %! fcn = fcns{i}; %! assert (pow2 (fcn (x)), fcn (v), sqrt (eps)); %! endfor %!test %! fcns = {@double, @single, @complex, @sparse}; %! x = [1, 1+1i, 1i]; %! for i = 1:numel (fcns) %! fcn = fcns{i}; %! assert (pow2 (fcn (x)), fcn (2) .^ fcn (x), sqrt (eps)); %! endfor ## Call `y = pow2 (f, e)` %!test %! fcns = {@double, @single, @complex, @sparse}; %! f = [2 2]; %! e = [2 2]; %! z = [8 8]; %! warning ("off", "Octave:pow2:imaginary-ignored", "local"); %! for i = 1:numel (fcns) %! fcn = fcns{i}; %! assert (pow2 (fcn (f), fcn (e)), real (fcn (z))); %! endfor ## Only integer part is taken into account. %!test %! f = 2; %! e = [2, 2.1, 2.2, 2.4, 2.5, 2.8]; %! z = 8 .* ones (1, length (e)); %! assert (pow2 (f, e), z); ## Only real part is taken into account. %!test %! f = [1+1i, 1]; %! e = 2; %! z = [4, 4]; %! warning ("off", "Octave:pow2:imaginary-ignored", "local"); %! assert (pow2 (f, e), z); %!test %! f = 1; %! e = [1+1i, 1]; %! z = [2, 2]; %! warning ("off", "Octave:pow2:imaginary-ignored", "local"); %! assert (pow2 (f, e), z); %!test %! f = [1/2, pi/4, -3/4, 1/2, 1-eps()/2, 1/2]; %! e = [1, 2, 2, -51, 1024, -1021]; %! z = [1, pi, -3, eps(), realmax(), realmin()]; %! assert (pow2 (f, e), z); ## Tests for sparsity. %!assert (pow2 (sparse (0), ones (3)), sparse (3, 3)); %!assert (pow2 (sparse (1), ones (3)), 2 .* sparse (ones (3))); %!assert (pow2 (sparse (1), speye (3)), sparse (ones (3) + eye (3))); %!assert (pow2 (sparse (3, 3), ones (3)), sparse (3, 3)); %!assert (pow2 (speye (3), ones (3)), 2 .* speye (3)); %!assert (pow2 (speye (3), 1), 2 .* speye (3)); %!test %! f = speye (3); %! e = sparse (3, 3); %! e(1,1) = 1; %! e(1,3) = 1; %! z = f; %! z(1,1) = 2; %! assert (pow2 (f, e), z); ## Large sparse matrix (only few real elements). %!test %! ## FIXME: `N = 1e5` would be a better test, but `assert` fills-up somehow. %! N = 1e3; %! assert (pow2 (speye (N), sparse (N,N)), speye (N)); %! assert (pow2 (sparse (0), speye (N)), sparse(N,N)); %!error <Invalid call> pow2 () %!error <Invalid call> pow2 (1,2,3) %!error <wrong type argument> pow2 (int8 (1)) %!error <wrong type argument> pow2 (2, int8 (1)) %!warning <imaginary part is ignored> pow2 (i, 2); %!warning <imaginary part is ignored> pow2 (2, i); %!error <pow2: nonconformant arguments> pow2 ([1,2], [3,4,5]) %!error <pow2: nonconformant arguments> pow2 (sparse ([1,2]), sparse ([3,4,5])) */ OCTAVE_END_NAMESPACE(octave)