Mercurial > octave-nkf
view libinterp/corefcn/ls-mat4.cc @ 20587:f90c8372b7ba
eliminate many more simple uses of error_state
* Cell.cc, __ichol__.cc, __ilu__.cc, balance.cc, bsxfun.cc, colloc.cc,
det.cc, dlmread.cc, dynamic-ld.cc, eig.cc, fft.cc, fft2.cc, fftn.cc,
gcd.cc, getgrent.cc, getpwent.cc, givens.cc, hess.cc, input.cc,
levenshtein.cc, load-path.cc, lookup.cc, ls-mat-ascii.cc, ls-mat4.cc,
lsode.cc, lu.cc, max.cc, md5sum.cc, mex.cc, pager.cc, pinv.cc,
pr-output.cc, qz.cc, schur.cc, sparse.cc, sqrtm.cc, str2double.cc,
strfns.cc, sub2ind.cc, sysdep.cc, time.cc, toplev.cc, tril.cc,
tsearch.cc, typecast.cc, __init_gnuplot__.cc, __magick_read__.cc,
__osmesa_print__.cc, amd.cc, audiodevinfo.cc, dmperm.cc, fftw.cc,
symrcm.cc, ov-base-diag.cc, ov-base-sparse.cc, ov-base.cc,
ov-bool-sparse.cc, ov-builtin.cc, ov-complex.cc, ov-cx-diag.cc,
ov-cx-mat.cc, ov-cx-sparse.cc, ov-fcn-handle.cc, ov-fcn-inline.cc,
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-lazy-idx.cc, ov-mex-fcn.cc,
ov-perm.cc, ov-range.cc, ov-re-diag.cc, ov-re-mat.cc, ov-re-sparse.cc,
ov-scalar.cc, ov-str-mat.cc, op-bm-b.cc, op-bm-bm.cc, op-sbm-b.cc,
op-sbm-bm.cc, op-str-m.cc, op-str-s.cc, oct-parse.in.yy, pt-cbinop.cc,
pt-colon.cc, pt-decl.cc, pt-exp.cc, pt-id.cc, pt-misc.cc,
pt-select.cc, pt-unop.cc: Eliminate simple uses of error_state.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Mon, 05 Oct 2015 19:29:36 -0400 |
| parents | 00cf2847355d |
| children |
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/* Copyright (C) 1996-2015 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 <cfloat> #include <cstring> #include <cctype> #include <fstream> #include <iomanip> #include <iostream> #include <string> #include <vector> #include "byte-swap.h" #include "data-conv.h" #include "file-ops.h" #include "glob-match.h" #include "lo-mappers.h" #include "mach-info.h" #include "oct-env.h" #include "oct-time.h" #include "quit.h" #include "str-vec.h" #include "oct-locbuf.h" #include "Cell.h" #include "defun.h" #include "error.h" #include "gripes.h" #include "load-save.h" #include "oct-obj.h" #include "oct-map.h" #include "ov-cell.h" #include "pager.h" #include "pt-exp.h" #include "sysdep.h" #include "unwind-prot.h" #include "utils.h" #include "variables.h" #include "version.h" #include "dMatrix.h" #include "dSparse.h" #include "ls-mat4.h" // Read LEN elements of data from IS in the format specified by // PRECISION, placing the result in DATA. If SWAP is TRUE, swap // the bytes of each element before copying to DATA. FLT_FMT // specifies the format of the data if we are reading floating point // numbers. static void read_mat_binary_data (std::istream& is, double *data, int precision, int len, bool swap, oct_mach_info::float_format flt_fmt) { switch (precision) { case 0: read_doubles (is, data, LS_DOUBLE, len, swap, flt_fmt); break; case 1: read_doubles (is, data, LS_FLOAT, len, swap, flt_fmt); break; case 2: read_doubles (is, data, LS_INT, len, swap, flt_fmt); break; case 3: read_doubles (is, data, LS_SHORT, len, swap, flt_fmt); break; case 4: read_doubles (is, data, LS_U_SHORT, len, swap, flt_fmt); break; case 5: read_doubles (is, data, LS_U_CHAR, len, swap, flt_fmt); break; default: break; } } int read_mat_file_header (std::istream& is, bool& swap, int32_t& mopt, int32_t& nr, int32_t& nc, int32_t& imag, int32_t& len, int quiet) { swap = false; // We expect to fail here, at the beginning of a record, so not // being able to read another mopt value should not result in an // error. is.read (reinterpret_cast<char *> (&mopt), 4); if (! is) return 1; if (! is.read (reinterpret_cast<char *> (&nr), 4)) goto data_read_error; if (! is.read (reinterpret_cast<char *> (&nc), 4)) goto data_read_error; if (! is.read (reinterpret_cast<char *> (&imag), 4)) goto data_read_error; if (! is.read (reinterpret_cast<char *> (&len), 4)) goto data_read_error; // If mopt is nonzero and the byte order is swapped, mopt will be // bigger than we expect, so we swap bytes. // // If mopt is zero, it means the file was written on a little endian // machine, and we only need to swap if we are running on a big endian // machine. // // Gag me. if (oct_mach_info::words_big_endian () && mopt == 0) swap = true; // mopt is signed, therefore byte swap may result in negative value. if (mopt > 9999 || mopt < 0) swap = true; if (swap) { swap_bytes<4> (&mopt); swap_bytes<4> (&nr); swap_bytes<4> (&nc); swap_bytes<4> (&imag); swap_bytes<4> (&len); } if (mopt > 9999 || mopt < 0 || imag > 1 || imag < 0) { if (! quiet) error ("load: can't read binary file"); return -1; } return 0; data_read_error: return -1; } // We don't just use a cast here, because we need to be able to detect // possible errors. oct_mach_info::float_format mopt_digit_to_float_format (int mach) { oct_mach_info::float_format flt_fmt = oct_mach_info::flt_fmt_unknown; switch (mach) { case 0: flt_fmt = oct_mach_info::flt_fmt_ieee_little_endian; break; case 1: flt_fmt = oct_mach_info::flt_fmt_ieee_big_endian; break; case 2: case 3: case 4: default: flt_fmt = oct_mach_info::flt_fmt_unknown; break; } return flt_fmt; } int float_format_to_mopt_digit (oct_mach_info::float_format flt_fmt) { int retval = -1; switch (flt_fmt) { case oct_mach_info::flt_fmt_ieee_little_endian: retval = 0; break; case oct_mach_info::flt_fmt_ieee_big_endian: retval = 1; break; default: break; } return retval; } // Extract one value (scalar, matrix, string, etc.) from stream IS and // place it in TC, returning the name of the variable. // // The data is expected to be in Matlab version 4 .mat format, though // not all the features of that format are supported. // // FILENAME is used for error messages. // // This format provides no way to tag the data as global. std::string read_mat_binary_data (std::istream& is, const std::string& filename, octave_value& tc) { std::string retval; // These are initialized here instead of closer to where they are // first used to avoid errors from gcc about goto crossing // initialization of variable. Matrix re; oct_mach_info::float_format flt_fmt = oct_mach_info::flt_fmt_unknown; bool swap = false; int type = 0; int prec = 0; int order = 0; int mach = 0; int dlen = 0; int32_t mopt, nr, nc, imag, len; int err = read_mat_file_header (is, swap, mopt, nr, nc, imag, len); if (err) { if (err < 0) goto data_read_error; else return retval; } type = mopt % 10; // Full, sparse, etc. mopt /= 10; // Eliminate first digit. prec = mopt % 10; // double, float, int, etc. mopt /= 10; // Eliminate second digit. order = mopt % 10; // Row or column major ordering. mopt /= 10; // Eliminate third digit. mach = mopt % 10; // IEEE, VAX, etc. flt_fmt = mopt_digit_to_float_format (mach); if (flt_fmt == oct_mach_info::flt_fmt_unknown) { error ("load: unrecognized binary format!"); return retval; } if (imag && type == 1) { error ("load: encountered complex matrix with string flag set!"); return retval; } // LEN includes the terminating character, and the file is also // supposed to include it, but apparently not all files do. Either // way, I think this should work. { OCTAVE_LOCAL_BUFFER (char, name, len+1); name[len] = '\0'; if (! is.read (name, len)) goto data_read_error; retval = name; dlen = nr * nc; if (dlen < 0) goto data_read_error; if (order) { octave_idx_type tmp = nr; nr = nc; nc = tmp; } if (type == 2) { if (nc == 4) { octave_idx_type nr_new, nc_new; Array<Complex> data (dim_vector (1, nr - 1)); Array<octave_idx_type> c (dim_vector (1, nr - 1)); Array<octave_idx_type> r (dim_vector (1, nr - 1)); OCTAVE_LOCAL_BUFFER (double, dtmp, nr); OCTAVE_LOCAL_BUFFER (double, ctmp, nr); read_mat_binary_data (is, dtmp, prec, nr, swap, flt_fmt); for (octave_idx_type i = 0; i < nr - 1; i++) r.xelem (i) = dtmp[i] - 1; nr_new = dtmp[nr - 1]; read_mat_binary_data (is, dtmp, prec, nr, swap, flt_fmt); for (octave_idx_type i = 0; i < nr - 1; i++) c.xelem (i) = dtmp[i] - 1; nc_new = dtmp[nr - 1]; read_mat_binary_data (is, dtmp, prec, nr - 1, swap, flt_fmt); read_mat_binary_data (is, ctmp, prec, 1, swap, flt_fmt); read_mat_binary_data (is, ctmp, prec, nr - 1, swap, flt_fmt); for (octave_idx_type i = 0; i < nr - 1; i++) data.xelem (i) = Complex (dtmp[i], ctmp[i]); read_mat_binary_data (is, ctmp, prec, 1, swap, flt_fmt); SparseComplexMatrix smc = SparseComplexMatrix (data, r, c, nr_new, nc_new); tc = order ? smc.transpose () : smc; } else { octave_idx_type nr_new, nc_new; Array<double> data (dim_vector (1, nr - 1)); Array<octave_idx_type> c (dim_vector (1, nr - 1)); Array<octave_idx_type> r (dim_vector (1, nr - 1)); OCTAVE_LOCAL_BUFFER (double, dtmp, nr); read_mat_binary_data (is, dtmp, prec, nr, swap, flt_fmt); for (octave_idx_type i = 0; i < nr - 1; i++) r.xelem (i) = dtmp[i] - 1; nr_new = dtmp[nr - 1]; read_mat_binary_data (is, dtmp, prec, nr, swap, flt_fmt); for (octave_idx_type i = 0; i < nr - 1; i++) c.xelem (i) = dtmp[i] - 1; nc_new = dtmp[nr - 1]; read_mat_binary_data (is, data.fortran_vec (), prec, nr - 1, swap, flt_fmt); read_mat_binary_data (is, dtmp, prec, 1, swap, flt_fmt); SparseMatrix sm = SparseMatrix (data, r, c, nr_new, nc_new); tc = order ? sm.transpose () : sm; } } else { re.resize (nr, nc); read_mat_binary_data (is, re.fortran_vec (), prec, dlen, swap, flt_fmt); if (! is) { error ("load: reading matrix data for '%s'", name); goto data_read_error; } if (imag) { Matrix im (nr, nc); read_mat_binary_data (is, im.fortran_vec (), prec, dlen, swap, flt_fmt); if (! is) { error ("load: reading imaginary matrix data for '%s'", name); goto data_read_error; } ComplexMatrix ctmp (nr, nc); for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = 0; i < nr; i++) ctmp (i, j) = Complex (re (i, j), im (i, j)); tc = order ? ctmp.transpose () : ctmp; } else tc = order ? re.transpose () : re; if (type == 1) tc = tc.convert_to_str (false, true, '\''); } return retval; } data_read_error: error ("load: trouble reading binary file '%s'", filename.c_str ()); return retval; } // Save the data from TC along with the corresponding NAME on stream OS // in the MatLab version 4 binary format. bool save_mat_binary_data (std::ostream& os, const octave_value& tc, const std::string& name) { int32_t mopt = 0; mopt += tc.is_sparse_type () ? 2 : tc.is_string () ? 1 : 0; oct_mach_info::float_format flt_fmt = oct_mach_info::native_float_format ();; mopt += 1000 * float_format_to_mopt_digit (flt_fmt); os.write (reinterpret_cast<char *> (&mopt), 4); octave_idx_type len; int32_t nr = tc.rows (); int32_t nc = tc.columns (); if (tc.is_sparse_type ()) { len = tc.nnz (); uint32_t nnz = len + 1; os.write (reinterpret_cast<char *> (&nnz), 4); uint32_t iscmplx = tc.is_complex_type () ? 4 : 3; os.write (reinterpret_cast<char *> (&iscmplx), 4); uint32_t tmp = 0; os.write (reinterpret_cast<char *> (&tmp), 4); } else { os.write (reinterpret_cast<char *> (&nr), 4); os.write (reinterpret_cast<char *> (&nc), 4); int32_t imag = tc.is_complex_type () ? 1 : 0; os.write (reinterpret_cast<char *> (&imag), 4); len = nr * nc; } // LEN includes the terminating character, and the file is also // supposed to include it. int32_t name_len = name.length () + 1; os.write (reinterpret_cast<char *> (&name_len), 4); os << name << '\0'; if (tc.is_string ()) { unwind_protect frame; charMatrix chm = tc.char_matrix_value (); octave_idx_type nrow = chm.rows (); octave_idx_type ncol = chm.cols (); OCTAVE_LOCAL_BUFFER (double, buf, ncol*nrow); for (octave_idx_type i = 0; i < nrow; i++) { std::string tstr = chm.row_as_string (i); const char *s = tstr.data (); for (octave_idx_type j = 0; j < ncol; j++) buf[j*nrow+i] = static_cast<double> (*s++ & 0x00FF); } std::streamsize n_bytes = static_cast<std::streamsize> (nrow) * static_cast<std::streamsize> (ncol) * sizeof (double); os.write (reinterpret_cast<char *> (buf), n_bytes); } else if (tc.is_range ()) { Range r = tc.range_value (); double base = r.base (); double inc = r.inc (); octave_idx_type nel = r.numel (); for (octave_idx_type i = 0; i < nel; i++) { double x = base + i * inc; os.write (reinterpret_cast<char *> (&x), 8); } } else if (tc.is_real_scalar ()) { double tmp = tc.double_value (); os.write (reinterpret_cast<char *> (&tmp), 8); } else if (tc.is_sparse_type ()) { double ds; OCTAVE_LOCAL_BUFFER (double, dtmp, len); if (tc.is_complex_matrix ()) { SparseComplexMatrix m = tc.sparse_complex_matrix_value (); for (octave_idx_type i = 0; i < len; i++) dtmp[i] = m.ridx (i) + 1; std::streamsize n_bytes = 8 * static_cast<std::streamsize> (len); os.write (reinterpret_cast<const char *> (dtmp), n_bytes); ds = nr; os.write (reinterpret_cast<const char *> (&ds), 8); octave_idx_type ii = 0; for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = m.cidx (j); i < m.cidx (j+1); i++) dtmp[ii++] = j + 1; os.write (reinterpret_cast<const char *> (dtmp), n_bytes); ds = nc; os.write (reinterpret_cast<const char *> (&ds), 8); for (octave_idx_type i = 0; i < len; i++) dtmp[i] = std::real (m.data (i)); os.write (reinterpret_cast<const char *> (dtmp), n_bytes); ds = 0.; os.write (reinterpret_cast<const char *> (&ds), 8); for (octave_idx_type i = 0; i < len; i++) dtmp[i] = std::imag (m.data (i)); os.write (reinterpret_cast<const char *> (dtmp), n_bytes); os.write (reinterpret_cast<const char *> (&ds), 8); } else { SparseMatrix m = tc.sparse_matrix_value (); for (octave_idx_type i = 0; i < len; i++) dtmp[i] = m.ridx (i) + 1; std::streamsize n_bytes = 8 * static_cast<std::streamsize> (len); os.write (reinterpret_cast<const char *> (dtmp), n_bytes); ds = nr; os.write (reinterpret_cast<const char *> (&ds), 8); octave_idx_type ii = 0; for (octave_idx_type j = 0; j < nc; j++) for (octave_idx_type i = m.cidx (j); i < m.cidx (j+1); i++) dtmp[ii++] = j + 1; os.write (reinterpret_cast<const char *> (dtmp), n_bytes); ds = nc; os.write (reinterpret_cast<const char *> (&ds), 8); os.write (reinterpret_cast<const char *> (m.data ()), n_bytes); ds = 0.; os.write (reinterpret_cast<const char *> (&ds), 8); } } else if (tc.is_real_matrix ()) { Matrix m = tc.matrix_value (); std::streamsize n_bytes = 8 * static_cast<std::streamsize> (len); os.write (reinterpret_cast<const char *> (m.data ()), n_bytes); } else if (tc.is_complex_scalar ()) { Complex tmp = tc.complex_value (); os.write (reinterpret_cast<char *> (&tmp), 16); } else if (tc.is_complex_matrix ()) { ComplexMatrix m_cmplx = tc.complex_matrix_value (); Matrix m = ::real (m_cmplx); std::streamsize n_bytes = 8 * static_cast<std::streamsize> (len); os.write (reinterpret_cast<const char *> (m.data ()), n_bytes); m = ::imag (m_cmplx); os.write (reinterpret_cast<const char *> (m.data ()), n_bytes); } else gripe_wrong_type_arg ("save", tc, false); return ! os.fail (); }