Mercurial > octave
view liboctave/numeric/oct-rand.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 | 7cac4e7458f2 |
| children | 40de9f8f23a6 |
line wrap: on
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/* Copyright (C) 2003-2015 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/>. */ #ifdef HAVE_CONFIG_H # include <config.h> #endif #include <map> #include <vector> #include <stdint.h> #include "data-conv.h" #include "f77-fcn.h" #include "lo-error.h" #include "lo-ieee.h" #include "lo-mappers.h" #include "mach-info.h" #include "oct-locbuf.h" #include "oct-rand.h" #include "oct-time.h" #include "randgamma.h" #include "randmtzig.h" #include "randpoisson.h" #include "singleton-cleanup.h" extern "C" { F77_RET_T F77_FUNC (dgennor, DGENNOR) (const double&, const double&, double&); F77_RET_T F77_FUNC (dgenunf, DGENUNF) (const double&, const double&, double&); F77_RET_T F77_FUNC (dgenexp, DGENEXP) (const double&, double&); F77_RET_T F77_FUNC (dignpoi, DIGNPOI) (const double&, double&); F77_RET_T F77_FUNC (dgengam, DGENGAM) (const double&, const double&, double&); F77_RET_T F77_FUNC (setall, SETALL) (const int32_t&, const int32_t&); F77_RET_T F77_FUNC (getsd, GETSD) (int32_t&, int32_t&); F77_RET_T F77_FUNC (setsd, SETSD) (const int32_t&, const int32_t&); F77_RET_T F77_FUNC (setcgn, SETCGN) (const int32_t&); } octave_rand *octave_rand::instance = 0; octave_rand::octave_rand (void) : current_distribution (uniform_dist), use_old_generators (false), rand_states () { initialize_ranlib_generators (); initialize_mersenne_twister (); } bool octave_rand::instance_ok (void) { bool retval = true; if (! instance) { instance = new octave_rand (); if (instance) singleton_cleanup_list::add (cleanup_instance); } if (! instance) (*current_liboctave_error_handler) ("unable to create octave_rand object!"); return retval; } double octave_rand::do_seed (void) { union d2i { double d; int32_t i[2]; }; union d2i u; oct_mach_info::float_format ff = oct_mach_info::native_float_format (); switch (ff) { case oct_mach_info::flt_fmt_ieee_big_endian: F77_FUNC (getsd, GETSD) (u.i[1], u.i[0]); break; default: F77_FUNC (getsd, GETSD) (u.i[0], u.i[1]); break; } return u.d; } static int32_t force_to_fit_range (int32_t i, int32_t lo, int32_t hi) { assert (hi > lo && lo >= 0 && hi > lo); i = i > 0 ? i : -i; if (i < lo) i = lo; else if (i > hi) i = i % hi; return i; } void octave_rand::do_seed (double s) { use_old_generators = true; int i0, i1; union d2i { double d; int32_t i[2]; }; union d2i u; u.d = s; oct_mach_info::float_format ff = oct_mach_info::native_float_format (); switch (ff) { case oct_mach_info::flt_fmt_ieee_big_endian: i1 = force_to_fit_range (u.i[0], 1, 2147483563); i0 = force_to_fit_range (u.i[1], 1, 2147483399); break; default: i0 = force_to_fit_range (u.i[0], 1, 2147483563); i1 = force_to_fit_range (u.i[1], 1, 2147483399); break; } F77_FUNC (setsd, SETSD) (i0, i1); } void octave_rand::do_reset (void) { use_old_generators = true; initialize_ranlib_generators (); } ColumnVector octave_rand::do_state (const std::string& d) { return rand_states[d.empty () ? current_distribution : get_dist_id (d)]; } void octave_rand::do_state (const ColumnVector& s, const std::string& d) { use_old_generators = false; int old_dist = current_distribution; int new_dist = d.empty () ? current_distribution : get_dist_id (d); ColumnVector saved_state; if (old_dist != new_dist) saved_state = get_internal_state (); set_internal_state (s); rand_states[new_dist] = get_internal_state (); if (old_dist != new_dist) rand_states[old_dist] = saved_state; } void octave_rand::do_reset (const std::string& d) { use_old_generators = false; int old_dist = current_distribution; int new_dist = d.empty () ? current_distribution : get_dist_id (d); ColumnVector saved_state; if (old_dist != new_dist) saved_state = get_internal_state (); oct_init_by_entropy (); rand_states[new_dist] = get_internal_state (); if (old_dist != new_dist) rand_states[old_dist] = saved_state; } std::string octave_rand::do_distribution (void) { std::string retval; switch (current_distribution) { case uniform_dist: retval = "uniform"; break; case normal_dist: retval = "normal"; break; case expon_dist: retval = "exponential"; break; case poisson_dist: retval = "poisson"; break; case gamma_dist: retval = "gamma"; break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } return retval; } void octave_rand::do_distribution (const std::string& d) { int id = get_dist_id (d); switch (id) { case uniform_dist: octave_rand::uniform_distribution (); break; case normal_dist: octave_rand::normal_distribution (); break; case expon_dist: octave_rand::exponential_distribution (); break; case poisson_dist: octave_rand::poisson_distribution (); break; case gamma_dist: octave_rand::gamma_distribution (); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", id); break; } } void octave_rand::do_uniform_distribution (void) { switch_to_generator (uniform_dist); F77_FUNC (setcgn, SETCGN) (uniform_dist); } void octave_rand::do_normal_distribution (void) { switch_to_generator (normal_dist); F77_FUNC (setcgn, SETCGN) (normal_dist); } void octave_rand::do_exponential_distribution (void) { switch_to_generator (expon_dist); F77_FUNC (setcgn, SETCGN) (expon_dist); } void octave_rand::do_poisson_distribution (void) { switch_to_generator (poisson_dist); F77_FUNC (setcgn, SETCGN) (poisson_dist); } void octave_rand::do_gamma_distribution (void) { switch_to_generator (gamma_dist); F77_FUNC (setcgn, SETCGN) (gamma_dist); } double octave_rand::do_scalar (double a) { double retval = 0.0; if (use_old_generators) { switch (current_distribution) { case uniform_dist: F77_FUNC (dgenunf, DGENUNF) (0.0, 1.0, retval); break; case normal_dist: F77_FUNC (dgennor, DGENNOR) (0.0, 1.0, retval); break; case expon_dist: F77_FUNC (dgenexp, DGENEXP) (1.0, retval); break; case poisson_dist: if (a < 0.0 || ! xfinite (a)) retval = octave_NaN; else { // workaround bug in ignpoi, by calling with different Mu F77_FUNC (dignpoi, DIGNPOI) (a + 1, retval); F77_FUNC (dignpoi, DIGNPOI) (a, retval); } break; case gamma_dist: if (a <= 0.0 || ! xfinite (a)) retval = octave_NaN; else F77_FUNC (dgengam, DGENGAM) (1.0, a, retval); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } } else { switch (current_distribution) { case uniform_dist: retval = oct_randu (); break; case normal_dist: retval = oct_randn (); break; case expon_dist: retval = oct_rande (); break; case poisson_dist: retval = oct_randp (a); break; case gamma_dist: retval = oct_randg (a); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } save_state (); } return retval; } float octave_rand::do_float_scalar (float a) { float retval = 0.0; if (use_old_generators) { double da = a; double dretval = 0.0; switch (current_distribution) { case uniform_dist: F77_FUNC (dgenunf, DGENUNF) (0.0, 1.0, dretval); break; case normal_dist: F77_FUNC (dgennor, DGENNOR) (0.0, 1.0, dretval); break; case expon_dist: F77_FUNC (dgenexp, DGENEXP) (1.0, dretval); break; case poisson_dist: if (da < 0.0 || ! xfinite (a)) dretval = octave_NaN; else { // workaround bug in ignpoi, by calling with different Mu F77_FUNC (dignpoi, DIGNPOI) (da + 1, dretval); F77_FUNC (dignpoi, DIGNPOI) (da, dretval); } break; case gamma_dist: if (da <= 0.0 || ! xfinite (a)) dretval = octave_NaN; else F77_FUNC (dgengam, DGENGAM) (1.0, da, dretval); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } retval = dretval; } else { switch (current_distribution) { case uniform_dist: retval = oct_float_randu (); break; case normal_dist: retval = oct_float_randn (); break; case expon_dist: retval = oct_float_rande (); break; case poisson_dist: // Keep poisson distribution in double precision for accuracy retval = oct_randp (a); break; case gamma_dist: retval = oct_float_randg (a); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } save_state (); } return retval; } Array<double> octave_rand::do_vector (octave_idx_type n, double a) { Array<double> retval; if (n > 0) { retval.clear (n, 1); fill (retval.numel (), retval.fortran_vec (), a); } else if (n < 0) (*current_liboctave_error_handler) ("rand: invalid negative argument"); return retval; } Array<float> octave_rand::do_float_vector (octave_idx_type n, float a) { Array<float> retval; if (n > 0) { retval.clear (n, 1); fill (retval.numel (), retval.fortran_vec (), a); } else if (n < 0) (*current_liboctave_error_handler) ("rand: invalid negative argument"); return retval; } NDArray octave_rand::do_nd_array (const dim_vector& dims, double a) { NDArray retval; if (! dims.all_zero ()) { retval.clear (dims); fill (retval.numel (), retval.fortran_vec (), a); } return retval; } FloatNDArray octave_rand::do_float_nd_array (const dim_vector& dims, float a) { FloatNDArray retval; if (! dims.all_zero ()) { retval.clear (dims); fill (retval.numel (), retval.fortran_vec (), a); } return retval; } // Make the random number generator give us a different sequence every // time we start octave unless we specifically set the seed. The // technique used below will cycle monthly, but it it does seem to // work ok to give fairly different seeds each time Octave starts. void octave_rand::initialize_ranlib_generators (void) { octave_localtime tm; int stored_distribution = current_distribution; F77_FUNC (setcgn, SETCGN) (uniform_dist); int hour = tm.hour () + 1; int minute = tm.min () + 1; int second = tm.sec () + 1; int32_t s0 = tm.mday () * hour * minute * second; int32_t s1 = hour * minute * second; s0 = force_to_fit_range (s0, 1, 2147483563); s1 = force_to_fit_range (s1, 1, 2147483399); F77_FUNC (setall, SETALL) (s0, s1); F77_FUNC (setcgn, SETCGN) (stored_distribution); } void octave_rand::initialize_mersenne_twister (void) { oct_init_by_entropy (); ColumnVector s = get_internal_state (); rand_states[uniform_dist] = s; oct_init_by_entropy (); s = get_internal_state (); rand_states[normal_dist] = s; oct_init_by_entropy (); s = get_internal_state (); rand_states[expon_dist] = s; oct_init_by_entropy (); s = get_internal_state (); rand_states[poisson_dist] = s; oct_init_by_entropy (); s = get_internal_state (); rand_states[gamma_dist] = s; } ColumnVector octave_rand::get_internal_state (void) { ColumnVector s (MT_N + 1); OCTAVE_LOCAL_BUFFER (uint32_t, tmp, MT_N + 1); oct_get_state (tmp); for (octave_idx_type i = 0; i <= MT_N; i++) s.elem (i) = static_cast<double> (tmp[i]); return s; } void octave_rand::save_state (void) { rand_states[current_distribution] = get_internal_state ();; } int octave_rand::get_dist_id (const std::string& d) { int retval = unknown_dist; if (d == "uniform" || d == "rand") retval = uniform_dist; else if (d == "normal" || d == "randn") retval = normal_dist; else if (d == "exponential" || d == "rande") retval = expon_dist; else if (d == "poisson" || d == "randp") retval = poisson_dist; else if (d == "gamma" || d == "randg") retval = gamma_dist; else (*current_liboctave_error_handler) ("rand: invalid distribution '%s'", d.c_str ()); return retval; } // Guarantee reproducible conversion of negative initialization values to // random number algorithm. Note that Matlab employs slightly different rules. // 1) Seed saturates at 2^32-1 for any value larger than that. // 2) NaN, Inf are translated to 2^32-1. // 3) -Inf is translated to 0. static uint32_t double2uint32 (double d) { uint32_t u; static const double TWOUP32 = std::numeric_limits<uint32_t>::max() + 1.0; if (! xfinite (d)) u = 0; else { d = fmod (d, TWOUP32); if (d < 0) d += TWOUP32; u = static_cast<uint32_t> (d); } return u; } void octave_rand::set_internal_state (const ColumnVector& s) { octave_idx_type len = s.numel (); octave_idx_type n = len < MT_N + 1 ? len : MT_N + 1; OCTAVE_LOCAL_BUFFER (uint32_t, tmp, MT_N + 1); for (octave_idx_type i = 0; i < n; i++) tmp[i] = double2uint32 (s.elem (i)); if (len == MT_N + 1 && tmp[MT_N] <= MT_N && tmp[MT_N] > 0) oct_set_state (tmp); else oct_init_by_array (tmp, len); } void octave_rand::switch_to_generator (int dist) { if (dist != current_distribution) { current_distribution = dist; set_internal_state (rand_states[dist]); } } #define MAKE_RAND(len) \ do \ { \ double val; \ for (volatile octave_idx_type i = 0; i < len; i++) \ { \ octave_quit (); \ RAND_FUNC (val); \ v[i] = val; \ } \ } \ while (0) void octave_rand::fill (octave_idx_type len, double *v, double a) { if (len < 1) return; switch (current_distribution) { case uniform_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgenunf, DGENUNF) (0.0, 1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_randu (len, v); break; case normal_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgennor, DGENNOR) (0.0, 1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_randn (len, v); break; case expon_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgenexp, DGENEXP) (1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_rande (len, v); break; case poisson_dist: if (use_old_generators) { if (a < 0.0 || ! xfinite (a)) #define RAND_FUNC(x) x = octave_NaN; MAKE_RAND (len); #undef RAND_FUNC else { // workaround bug in ignpoi, by calling with different Mu double tmp; F77_FUNC (dignpoi, DIGNPOI) (a + 1, tmp); #define RAND_FUNC(x) F77_FUNC (dignpoi, DIGNPOI) (a, x) MAKE_RAND (len); #undef RAND_FUNC } } else oct_fill_randp (a, len, v); break; case gamma_dist: if (use_old_generators) { if (a <= 0.0 || ! xfinite (a)) #define RAND_FUNC(x) x = octave_NaN; MAKE_RAND (len); #undef RAND_FUNC else #define RAND_FUNC(x) F77_FUNC (dgengam, DGENGAM) (1.0, a, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_randg (a, len, v); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } save_state (); return; } void octave_rand::fill (octave_idx_type len, float *v, float a) { if (len < 1) return; switch (current_distribution) { case uniform_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgenunf, DGENUNF) (0.0, 1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_float_randu (len, v); break; case normal_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgennor, DGENNOR) (0.0, 1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_float_randn (len, v); break; case expon_dist: if (use_old_generators) { #define RAND_FUNC(x) F77_FUNC (dgenexp, DGENEXP) (1.0, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_float_rande (len, v); break; case poisson_dist: if (use_old_generators) { double da = a; if (da < 0.0 || ! xfinite (a)) #define RAND_FUNC(x) x = octave_NaN; MAKE_RAND (len); #undef RAND_FUNC else { // workaround bug in ignpoi, by calling with different Mu double tmp; F77_FUNC (dignpoi, DIGNPOI) (da + 1, tmp); #define RAND_FUNC(x) F77_FUNC (dignpoi, DIGNPOI) (da, x) MAKE_RAND (len); #undef RAND_FUNC } } else oct_fill_float_randp (a, len, v); break; case gamma_dist: if (use_old_generators) { double da = a; if (da <= 0.0 || ! xfinite (a)) #define RAND_FUNC(x) x = octave_NaN; MAKE_RAND (len); #undef RAND_FUNC else #define RAND_FUNC(x) F77_FUNC (dgengam, DGENGAM) (1.0, da, x) MAKE_RAND (len); #undef RAND_FUNC } else oct_fill_float_randg (a, len, v); break; default: (*current_liboctave_error_handler) ("rand: invalid distribution ID = %d", current_distribution); break; } save_state (); return; }