Mercurial > hg > octave-jordi
view liboctave/numeric/lo-mappers.h @ 20790:f7084eae3318
maint: Use Octave coding conventions for #if statements.
* mk-opts.pl, dialog.h, find-files-dialog.h, find-files-model.h,
file-editor-tab.h, octave-qscintilla.h, octave-txt-lexer.h, main-window.h,
octave-cmd.h, octave-dock-widget.h, octave-gui.h, thread-manager.h,
workspace-model.h, workspace-view.h, builtins.h, Cell.h, bitfcns.cc,
c-file-ptr-stream.h, cdisplay.h, comment-list.h, cutils.h, data.h, debug.h,
defaults.in.h, defun-dld.h, defun-int.h, defun.h, dirfns.h, display.h,
dynamic-ld.h, error.h, event-queue.h, file-io.h, filter.cc, getrusage.cc,
gl-render.h, gl2ps-renderer.h, graphics.in.h, gripes.h, help.h, hook-fcn.h,
input.h, jit-ir.h, jit-typeinfo.h, jit-util.h, load-path.h, load-save.h,
ls-ascii-helper.h, ls-hdf5.h, ls-mat-ascii.h, ls-mat4.h, ls-mat5.h,
ls-oct-binary.h, ls-oct-text.h, ls-utils.h, oct-errno.h, oct-fstrm.h,
oct-handle.h, oct-hdf5-types.h, oct-hdf5.h, oct-hist.h, oct-iostrm.h,
oct-lvalue.h, oct-map.h, oct-obj.h, oct-prcstrm.h, oct-procbuf.h,
oct-stdstrm.h, oct-stream.h, oct-strstrm.h, oct.h, octave-link.h, pager.h,
pr-output.h, procstream.h, profiler.h, pt-jit.h, sighandlers.cc, sighandlers.h,
siglist.h, sparse-xdiv.h, sparse-xpow.h, symtab.h, syscalls.cc, sysdep.h,
toplev.cc, toplev.h, utils.h, variables.h, workspace-element.h, xdiv.h,
xnorm.h, xpow.h, dmperm.cc, oct-qhull.h, mkbuiltins, oct-conf.in.h,
ov-base-diag.h, ov-base-int.h, ov-base-mat.h, ov-base-scalar.h,
ov-base-sparse.h, ov-base.h, ov-bool-mat.h, ov-bool-sparse.h, ov-bool.h,
ov-builtin.h, ov-cell.h, ov-ch-mat.h, ov-class.h, ov-classdef.h, ov-colon.h,
ov-complex.h, ov-cs-list.h, ov-cx-diag.h, ov-cx-mat.h, ov-cx-sparse.h,
ov-dld-fcn.h, ov-fcn-handle.h, ov-fcn-inline.h, ov-fcn.h, ov-float.h,
ov-flt-complex.h, ov-flt-cx-diag.h, ov-flt-cx-mat.h, ov-flt-re-diag.h,
ov-flt-re-mat.h, ov-int-traits.h, ov-int16.h, ov-int32.h, ov-int64.h,
ov-int8.h, ov-java.h, ov-lazy-idx.h, ov-mex-fcn.h, ov-null-mat.h, ov-perm.h,
ov-range.h, ov-re-diag.h, ov-re-mat.h, ov-re-sparse.h, ov-scalar.h,
ov-str-mat.h, ov-struct.h, ov-type-conv.h, ov-typeinfo.h, ov-uint16.h,
ov-uint32.h, ov-uint64.h, ov-uint8.h, ov-usr-fcn.h, ov.h, octave.h, ops.h,
options-usage.h, lex.h, parse.h, pt-all.h, pt-arg-list.h, pt-array-list.h,
pt-assign.h, pt-binop.h, pt-bp.h, pt-cbinop.h, pt-cell.h, pt-check.h,
pt-classdef.h, pt-cmd.h, pt-colon.h, pt-const.h, pt-decl.h, pt-eval.h,
pt-except.h, pt-exp.h, pt-fcn-handle.h, pt-funcall.h, pt-id.h, pt-idx.h,
pt-jump.h, pt-loop.h, pt-mat.h, pt-misc.h, pt-pr-code.h, pt-select.h,
pt-stmt.h, pt-unop.h, pt-walk.h, pt.h, token.h, version.in.h, Array-util.h,
Array.h, CColVector.h, CDiagMatrix.h, CMatrix.h, CNDArray.h, CRowVector.h,
CSparse.h, DiagArray2.h, MArray-decl.h, MArray-defs.h, MArray.h, MDiagArray2.h,
MSparse.h, Matrix.h, MatrixType.h, PermMatrix.h, Range.h, Sparse.h,
boolMatrix.h, boolNDArray.h, boolSparse.h, chMatrix.h, chNDArray.h,
dColVector.h, dDiagMatrix.h, dMatrix.h, dNDArray.h, dRowVector.h, dSparse.h,
dim-vector.h, fCColVector.h, fCDiagMatrix.h, fCMatrix.h, fCNDArray.h,
fCRowVector.h, fColVector.h, fDiagMatrix.h, fMatrix.h, fNDArray.h,
fRowVector.h, idx-vector.h, int16NDArray.h, int32NDArray.h, int64NDArray.h,
int8NDArray.h, intNDArray.h, uint16NDArray.h, uint32NDArray.h, uint64NDArray.h,
uint8NDArray.h, f77-fcn.h, lo-error.h, quit.h, CmplxAEPBAL.h, CmplxCHOL.h,
CmplxGEPBAL.h, CmplxHESS.h, CmplxLU.h, CmplxQR.h, CmplxQRP.h, CmplxSCHUR.h,
CmplxSVD.h, CollocWt.h, DAE.h, DAEFunc.h, DAERT.h, DAERTFunc.h, DASPK.h,
DASRT.h, DASSL.h, DET.h, EIG.h, LSODE.h, ODE.h, ODEFunc.h, ODES.h, ODESFunc.h,
Quad.h, SparseCmplxCHOL.h, SparseCmplxLU.h, SparseCmplxQR.cc, SparseCmplxQR.h,
SparseQR.h, SparsedbleCHOL.h, SparsedbleLU.h, base-aepbal.h, base-dae.h,
base-de.h, base-lu.h, base-min.h, base-qr.h, bsxfun-decl.h, bsxfun-defs.cc,
bsxfun.h, dbleAEPBAL.h, dbleCHOL.h, dbleGEPBAL.h, dbleHESS.h, dbleLU.h,
dbleQR.h, dbleQRP.h, dbleSCHUR.h, dbleSVD.h, eigs-base.cc, fCmplxAEPBAL.h,
fCmplxCHOL.h, fCmplxGEPBAL.h, fCmplxHESS.h, fCmplxLU.h, fCmplxQR.h,
fCmplxQRP.h, fCmplxSCHUR.h, fCmplxSVD.h, fEIG.h, floatAEPBAL.h, floatCHOL.h,
floatGEPBAL.h, floatHESS.h, floatLU.h, floatQR.h, floatQRP.h, floatSCHUR.h,
floatSVD.h, lo-mappers.cc, lo-mappers.h, lo-specfun.cc, lo-specfun.h,
oct-convn.h, oct-fftw.h, oct-norm.h, oct-rand.h, oct-spparms.h, randmtzig.c,
sparse-base-chol.h, sparse-base-lu.h, sparse-dmsolve.cc, Sparse-diag-op-defs.h,
Sparse-op-decls.h, Sparse-op-defs.h, Sparse-perm-op-defs.h, mk-ops.awk,
mx-base.h, mx-defs.h, mx-ext.h, mx-inlines.cc, mx-op-decl.h, mx-op-defs.h,
sparse-mk-ops.awk, dir-ops.h, file-ops.h, file-stat.h, lo-sysdep.h,
mach-info.h, oct-env.h, oct-group.h, oct-openmp.h, oct-passwd.h,
oct-syscalls.h, oct-time.cc, oct-time.h, oct-uname.h, pathlen.h, sysdir.h,
syswait.h, action-container.h, base-list.h, byte-swap.h, caseless-str.h,
cmd-edit.h, cmd-hist.h, data-conv.h, functor.h, glob-match.h, kpse.cc,
lo-array-gripes.h, lo-cutils.h, lo-ieee.h, lo-macros.h, lo-math.h, lo-regexp.h,
lo-traits.h, lo-utils.h, oct-alloc.h, oct-base64.h, oct-binmap.h, oct-cmplx.h,
oct-glob.h, oct-inttypes.h, oct-locbuf.h, oct-mutex.h, oct-refcount.h,
oct-rl-edit.h, oct-rl-hist.h, oct-shlib.h, oct-sort.h, oct-sparse.h,
pathsearch.h, singleton-cleanup.h, sparse-sort.h, sparse-util.h, statdefs.h,
str-vec.h, sun-utils.h, unwind-prot.h, url-transfer.h:
Use Octave coding conventions for #if statements.
| author | Rik <rik@octave.org> |
|---|---|
| date | Thu, 03 Dec 2015 10:23:38 -0800 |
| parents | 0cefba1a1030 |
| children |
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/* Copyright (C) 1996-2015 John W. Eaton Copyright (C) 2010 VZLU Prague 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 (octave_lo_mappers_h) #define octave_lo_mappers_h 1 #include <limits> #include "oct-cmplx.h" #include "lo-math.h" #include "lo-ieee.h" // Double Precision extern OCTAVE_API double xtrunc (double x); extern OCTAVE_API double xcopysign (double x, double y); inline double xceil (double x) { return ceil (x); } extern OCTAVE_API double xfloor (double x); inline double arg (double x) { return atan2 (0.0, x); } inline double conj (double x) { return x; } inline double fix (double x) { return xtrunc (x); } inline double imag (double) { return 0.0; } inline double real (double x) { return x; } extern OCTAVE_API double xround (double x); extern OCTAVE_API double xroundb (double x); extern OCTAVE_API double signum (double x); extern OCTAVE_API double xlog2 (double x); extern OCTAVE_API Complex xlog2 (const Complex& x); extern OCTAVE_API double xlog2 (double x, int& exp); extern OCTAVE_API Complex xlog2 (const Complex& x, int& exp); extern OCTAVE_API double xexp2 (double x); // These are used by the BOOL_OP macros in mx-op-defs.h. inline bool xisnan (bool) { return false; } inline bool xisnan (char) { return false; } #if defined (HAVE_CMATH_ISNAN) inline bool xisnan (double x) { return std::isnan (x); } #else extern OCTAVE_API bool xisnan (double x); #endif #if defined (HAVE_CMATH_ISFINITE) inline bool xfinite (double x) { return std::isfinite (x); } #else extern OCTAVE_API bool xfinite (double x); #endif #if defined (HAVE_CMATH_ISINF) inline bool xisinf (double x) { return std::isinf (x); } #else extern OCTAVE_API bool xisinf (double x); #endif extern OCTAVE_API bool octave_is_NA (double x); // Generic xmin, xmax definitions template <class T> inline T xmin (T x, T y) { return x <= y ? x : y; } template <class T> inline T xmax (T x, T y) { return x >= y ? x : y; } // This form is favorable. GCC will translate (x <= y ? x : y) without a // jump, hence the only conditional jump involved will be the first // (xisnan), infrequent and hence friendly to branch prediction. inline double xmin (double x, double y) { return xisnan (y) ? x : (x <= y ? x : y); } inline double xmax (double x, double y) { return xisnan (y) ? x : (x >= y ? x : y); } extern OCTAVE_API Complex acos (const Complex& x); extern OCTAVE_API Complex acosh (const Complex& x); extern OCTAVE_API Complex asin (const Complex& x); extern OCTAVE_API Complex asinh (const Complex& x); extern OCTAVE_API Complex atan (const Complex& x); extern OCTAVE_API Complex atanh (const Complex& x); extern OCTAVE_API bool octave_is_NA (const Complex& x); extern OCTAVE_API bool octave_is_NaN_or_NA (const Complex& x); extern OCTAVE_API Complex xmin (const Complex& x, const Complex& y); extern OCTAVE_API Complex xmax (const Complex& x, const Complex& y); // Single Precision extern OCTAVE_API float xtrunc (float x); extern OCTAVE_API float xcopysign (float x, float y); inline float xceil (float x) { return ceilf (x); } extern OCTAVE_API float xfloor (float x); inline float arg (float x) { return atan2f (0.0f, x); } inline float conj (float x) { return x; } inline float fix (float x) { return xtrunc (x); } inline float imag (float) { return 0.0f; } inline float real (float x) { return x; } extern OCTAVE_API float xround (float x); extern OCTAVE_API float xroundb (float x); extern OCTAVE_API float signum (float x); extern OCTAVE_API float xlog2 (float x); extern OCTAVE_API FloatComplex xlog2 (const FloatComplex& x); extern OCTAVE_API float xlog2 (float x, int& exp); extern OCTAVE_API FloatComplex xlog2 (const FloatComplex& x, int& exp); extern OCTAVE_API float xexp2 (float x); #if defined (HAVE_CMATH_ISNANF) inline bool xisnan (float x) { return std::isnan (x); } #else extern OCTAVE_API bool xisnan (float x); #endif #if defined (HAVE_CMATH_ISFINITEF) inline bool xfinite (float x) { return std::isfinite (x); } #else extern OCTAVE_API bool xfinite (float x); #endif #if defined (HAVE_CMATH_ISINFF) inline bool xisinf (float x) { return std::isinf (x); } #else extern OCTAVE_API bool xisinf (float x); #endif extern OCTAVE_API bool octave_is_NA (float x); inline float xmin (float x, float y) { return xisnan (y) ? x : (x <= y ? x : y); } inline float xmax (float x, float y) { return xisnan (y) ? x : (x >= y ? x : y); } extern OCTAVE_API FloatComplex acos (const FloatComplex& x); extern OCTAVE_API FloatComplex acosh (const FloatComplex& x); extern OCTAVE_API FloatComplex asin (const FloatComplex& x); extern OCTAVE_API FloatComplex asinh (const FloatComplex& x); extern OCTAVE_API FloatComplex atan (const FloatComplex& x); extern OCTAVE_API FloatComplex atanh (const FloatComplex& x); extern OCTAVE_API bool octave_is_NA (const FloatComplex& x); extern OCTAVE_API bool octave_is_NaN_or_NA (const FloatComplex& x); extern OCTAVE_API FloatComplex xmin (const FloatComplex& x, const FloatComplex& y); extern OCTAVE_API FloatComplex xmax (const FloatComplex& x, const FloatComplex& y); // These map reals to Complex. extern OCTAVE_API Complex rc_acos (double); extern OCTAVE_API FloatComplex rc_acos (float); extern OCTAVE_API Complex rc_acosh (double); extern OCTAVE_API FloatComplex rc_acosh (float); extern OCTAVE_API Complex rc_asin (double); extern OCTAVE_API FloatComplex rc_asin (float); extern OCTAVE_API Complex rc_atanh (double); extern OCTAVE_API FloatComplex rc_atanh (float); extern OCTAVE_API Complex rc_log (double); extern OCTAVE_API FloatComplex rc_log (float); extern OCTAVE_API Complex rc_log2 (double); extern OCTAVE_API FloatComplex rc_log2 (float); extern OCTAVE_API Complex rc_log10 (double); extern OCTAVE_API FloatComplex rc_log10 (float); extern OCTAVE_API Complex rc_sqrt (double); extern OCTAVE_API FloatComplex rc_sqrt (float); // Some useful tests, that are commonly repeated. // Test for a finite integer. inline bool xisinteger (double x) { return xfinite (x) && x == xround (x); } inline bool xisinteger (float x) { return xfinite (x) && x == xround (x); } // Test for negative sign. extern OCTAVE_API bool xnegative_sign (double x); extern OCTAVE_API bool xnegative_sign (float x); // Test for positive sign. inline bool xpositive_sign (double x) { return ! xnegative_sign (x); } inline bool xpositive_sign (float x) { return ! xnegative_sign (x); } // Some old rounding functions. extern OCTAVE_API octave_idx_type NINTbig (double x); extern OCTAVE_API octave_idx_type NINTbig (float x); extern OCTAVE_API int NINT (double x); extern OCTAVE_API int NINT (float x); template <typename T> T X_NINT (T x) { return (xfinite (x) ? xfloor (x + 0.5) : x); } inline OCTAVE_API double D_NINT (double x) { return X_NINT (x); } inline OCTAVE_API float F_NINT (float x) { return X_NINT (x); } // Template functions can have either float or double arguments. template <typename T> bool xisnan (const std::complex<T>& x) { return (xisnan (real (x)) || xisnan (imag (x))); } template <typename T> bool xfinite (const std::complex<T>& x) { return (xfinite (real (x)) && xfinite (imag (x))); } template <typename T> bool xisinf (const std::complex<T>& x) { return (xisinf (real (x)) || xisinf (imag (x))); } template <typename T> std::complex<T> fix (const std::complex<T>& x) { return std::complex<T> (fix (real (x)), fix (imag (x))); } template <typename T> std::complex<T> ceil (const std::complex<T>& x) { return std::complex<T> (xceil (real (x)), xceil (imag (x))); } template <typename T> std::complex<T> floor (const std::complex<T>& x) { return std::complex<T> (xfloor (real (x)), xfloor (imag (x))); } template <typename T> std::complex<T> xround (const std::complex<T>& x) { return std::complex<T> (xround (real (x)), xround (imag (x))); } template <typename T> std::complex<T> xroundb (const std::complex<T>& x) { return std::complex<T> (xroundb (real (x)), xroundb (imag (x))); } template <typename T> std::complex<T> signum (const std::complex<T>& x) { T tmp = abs (x); return tmp == 0 ? 0.0 : x / tmp; } template <typename T> T xmod (T x, T y) { T retval; if (y == 0) retval = x; else { T q = x / y; if (X_NINT (y) != y && (std::abs ((q - X_NINT (q)) / X_NINT (q)) < std::numeric_limits<T>::epsilon ())) retval = 0; else { T n = xfloor (q); // Prevent use of extra precision. volatile T tmp = y * n; retval = x - tmp; } } if (x != y && y != 0) retval = xcopysign (retval, y); return retval; } template <typename T> T xrem (T x, T y) { T retval; if (y == 0) retval = octave_NaN; else { T q = x / y; if (X_NINT (y) != y && (std::abs ((q - X_NINT (q)) / X_NINT (q)) < std::numeric_limits<T>::epsilon ())) retval = 0; else { T n = xtrunc (q); // Prevent use of extra precision. volatile T tmp = y * n; retval = x - tmp; } } if (x != y && y != 0) retval = xcopysign (retval, x); return retval; } template <typename T> T xsignbit (T x) { return signbit (x); } #endif