Mercurial > octave-nkf
view libinterp/octave-value/ov.h @ 20611:40ed9b46a800
new octave_value::string_value method with optional error message
* ov.h (octave_value::string_vector): New method.
ov-base.cc, ov-base.h (octave_base_value::string_vector):
New default method.
ov-str-mat.cc, ov-str-mat.h (octave_char_matrix_str::string_value):
New method.
| author | John W. Eaton <jwe@octave.org> |
|---|---|
| date | Thu, 08 Oct 2015 16:43:22 -0400 |
| parents | 5dfaaaae784f |
| children | e5986cba4ca8 |
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/* Copyright (C) 1996-2015 John W. Eaton Copyright (C) 2009-2010 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_ov_h) #define octave_ov_h 1 #include <cstdlib> #include <iosfwd> #include <string> #include <list> #include "Range.h" #include "data-conv.h" #include "idx-vector.h" #include "mach-info.h" #include "mx-base.h" #include "oct-time.h" #include "str-vec.h" #include "oct-sort.h" class Cell; class mxArray; class octave_map; class octave_scalar_map; class octave_stream; class octave_function; class octave_user_function; class octave_fcn_handle; class octave_fcn_inline; class octave_value_list; class octave_lvalue; #include "ov-base.h" // Forward declarations of friend functions that have default arguments. OCTINTERP_API octave_value do_colon_op (const octave_value& base, const octave_value& limit, bool is_for_cmd_expr = false); OCTINTERP_API octave_value do_colon_op (const octave_value& base, const octave_value& increment, const octave_value& limit, bool is_for_cmd_expr = false); class OCTINTERP_API octave_value { public: enum unary_op { op_not, // not op_uplus, // uplus op_uminus, // uminus op_transpose, // transpose op_hermitian, // ctranspose op_incr, op_decr, num_unary_ops, unknown_unary_op }; enum binary_op { op_add, // plus op_sub, // minus op_mul, // mtimes op_div, // mrdivide op_pow, // mpower op_ldiv, // mldivide op_lshift, op_rshift, op_lt, // lt op_le, // le op_eq, // eq op_ge, // ge op_gt, // gt op_ne, // ne op_el_mul, // times op_el_div, // rdivide op_el_pow, // power op_el_ldiv, // ldivide op_el_and, // and op_el_or, // or op_struct_ref, num_binary_ops, unknown_binary_op }; enum compound_binary_op { // ** compound operations ** op_trans_mul, op_mul_trans, op_herm_mul, op_mul_herm, op_trans_ldiv, op_herm_ldiv, op_el_not_and, op_el_not_or, op_el_and_not, op_el_or_not, num_compound_binary_ops, unknown_compound_binary_op }; enum assign_op { op_asn_eq, op_add_eq, op_sub_eq, op_mul_eq, op_div_eq, op_ldiv_eq, op_pow_eq, op_lshift_eq, op_rshift_eq, op_el_mul_eq, op_el_div_eq, op_el_ldiv_eq, op_el_pow_eq, op_el_and_eq, op_el_or_eq, num_assign_ops, unknown_assign_op }; static binary_op assign_op_to_binary_op (assign_op); static assign_op binary_op_to_assign_op (binary_op); static std::string unary_op_as_string (unary_op); static std::string unary_op_fcn_name (unary_op); static std::string binary_op_as_string (binary_op); static std::string binary_op_fcn_name (binary_op); static std::string binary_op_fcn_name (compound_binary_op); static std::string assign_op_as_string (assign_op); static octave_value empty_conv (const std::string& type, const octave_value& rhs = octave_value ()); enum magic_colon { magic_colon_t }; octave_value (void) { static octave_base_value nil_rep; rep = &nil_rep; rep->count++; } octave_value (short int i); octave_value (unsigned short int i); octave_value (int i); octave_value (unsigned int i); octave_value (long int i); octave_value (unsigned long int i); // FIXME: these are kluges. They turn into doubles // internally, which will break for very large values. We just use // them to store things like 64-bit ino_t, etc, and hope that those // values are never actually larger than can be represented exactly // in a double. #if defined (HAVE_LONG_LONG_INT) octave_value (long long int i); #endif #if defined (HAVE_UNSIGNED_LONG_LONG_INT) octave_value (unsigned long long int i); #endif octave_value (octave_time t); octave_value (double d); octave_value (float d); octave_value (const Array<octave_value>& a, bool is_cs_list = false); octave_value (const Cell& c, bool is_cs_list = false); octave_value (const Matrix& m, const MatrixType& t = MatrixType ()); octave_value (const FloatMatrix& m, const MatrixType& t = MatrixType ()); octave_value (const NDArray& nda); octave_value (const FloatNDArray& nda); octave_value (const Array<double>& m); octave_value (const Array<float>& m); octave_value (const DiagMatrix& d); octave_value (const DiagArray2<double>& d); octave_value (const DiagArray2<float>& d); octave_value (const DiagArray2<Complex>& d); octave_value (const DiagArray2<FloatComplex>& d); octave_value (const FloatDiagMatrix& d); octave_value (const RowVector& v); octave_value (const FloatRowVector& v); octave_value (const ColumnVector& v); octave_value (const FloatColumnVector& v); octave_value (const Complex& C); octave_value (const FloatComplex& C); octave_value (const ComplexMatrix& m, const MatrixType& t = MatrixType ()); octave_value (const FloatComplexMatrix& m, const MatrixType& t = MatrixType ()); octave_value (const ComplexNDArray& cnda); octave_value (const FloatComplexNDArray& cnda); octave_value (const Array<Complex>& m); octave_value (const Array<FloatComplex>& m); octave_value (const ComplexDiagMatrix& d); octave_value (const FloatComplexDiagMatrix& d); octave_value (const ComplexRowVector& v); octave_value (const FloatComplexRowVector& v); octave_value (const ComplexColumnVector& v); octave_value (const FloatComplexColumnVector& v); octave_value (const PermMatrix& p); octave_value (bool b); octave_value (const boolMatrix& bm, const MatrixType& t = MatrixType ()); octave_value (const boolNDArray& bnda); octave_value (const Array<bool>& bnda); octave_value (char c, char type = '\''); octave_value (const char *s, char type = '\''); octave_value (const std::string& s, char type = '\''); octave_value (const string_vector& s, char type = '\''); octave_value (const charMatrix& chm, char type = '\''); octave_value (const charNDArray& chnda, char type = '\''); octave_value (const Array<char>& chnda, char type = '\''); octave_value (const charMatrix& chm, bool is_string, char type = '\'') GCC_ATTR_DEPRECATED; octave_value (const charNDArray& chnda, bool is_string, char type = '\'') GCC_ATTR_DEPRECATED; octave_value (const Array<char>& chnda, bool is_string, char type = '\'') GCC_ATTR_DEPRECATED; octave_value (const SparseMatrix& m, const MatrixType& t = MatrixType ()); octave_value (const Sparse<double>& m, const MatrixType& t = MatrixType ()); octave_value (const SparseComplexMatrix& m, const MatrixType& t = MatrixType ()); octave_value (const Sparse<Complex>& m, const MatrixType& t = MatrixType ()); octave_value (const SparseBoolMatrix& bm, const MatrixType& t = MatrixType ()); octave_value (const Sparse<bool>& m, const MatrixType& t = MatrixType ()); octave_value (const octave_int8& i); octave_value (const octave_int16& i); octave_value (const octave_int32& i); octave_value (const octave_int64& i); octave_value (const octave_uint8& i); octave_value (const octave_uint16& i); octave_value (const octave_uint32& i); octave_value (const octave_uint64& i); octave_value (const int8NDArray& inda); octave_value (const Array<octave_int8>& inda); octave_value (const int16NDArray& inda); octave_value (const Array<octave_int16>& inda); octave_value (const int32NDArray& inda); octave_value (const Array<octave_int32>& inda); octave_value (const int64NDArray& inda); octave_value (const Array<octave_int64>& inda); octave_value (const uint8NDArray& inda); octave_value (const Array<octave_uint8>& inda); octave_value (const uint16NDArray& inda); octave_value (const Array<octave_uint16>& inda); octave_value (const uint32NDArray& inda); octave_value (const Array<octave_uint32>& inda); octave_value (const uint64NDArray& inda); octave_value (const Array<octave_uint64>& inda); octave_value (const Array<octave_idx_type>& inda, bool zero_based = false, bool cache_index = false); octave_value (const Array<std::string>& cellstr); octave_value (const idx_vector& idx, bool lazy = true); octave_value (double base, double limit, double inc); octave_value (const Range& r, bool force_range = false); octave_value (const octave_map& m); octave_value (const octave_scalar_map& m); octave_value (const octave_map& m, const std::string& id, const std::list<std::string>& plist); octave_value (const octave_scalar_map& m, const std::string& id, const std::list<std::string>& plist); octave_value (const octave_value_list& m, bool = false); octave_value (octave_value::magic_colon); octave_value (octave_base_value *new_rep, bool borrow = false); octave_value (octave_base_value *new_rep, int xcount) GCC_ATTR_DEPRECATED; // Copy constructor. octave_value (const octave_value& a) { rep = a.rep; rep->count++; } // This should only be called for derived types. octave_base_value *clone (void) const; octave_base_value *empty_clone (void) const { return rep->empty_clone (); } // Delete the representation of this constant if the count drops to // zero. ~octave_value (void) { if (--rep->count == 0) delete rep; } void make_unique (void) { if (rep->count > 1) { octave_base_value *r = rep->unique_clone (); if (--rep->count == 0) delete rep; rep = r; } } // This uniquifies the value if it is referenced by more than a certain // number of shallow copies. This is useful for optimizations where we // know a certain copy, typically within a cell array, to be obsolete. void make_unique (int obsolete_copies) { if (rep->count > obsolete_copies + 1) { octave_base_value *r = rep->unique_clone (); if (--rep->count == 0) delete rep; rep = r; } } // Simple assignment. octave_value& operator = (const octave_value& a) { if (rep != a.rep) { if (--rep->count == 0) delete rep; rep = a.rep; rep->count++; } return *this; } octave_idx_type get_count (void) const { return rep->count; } octave_base_value::type_conv_info numeric_conversion_function (void) const { return rep->numeric_conversion_function (); } octave_base_value::type_conv_info numeric_demotion_function (void) const { return rep->numeric_demotion_function (); } void maybe_mutate (void); octave_value squeeze (void) const { return rep->squeeze (); } // The result of full(). octave_value full_value (void) const { return rep->full_value (); } octave_base_value *try_narrowing_conversion (void) { return rep->try_narrowing_conversion (); } // Close to dims (), but can be overloaded for classes. Matrix size (void) { return rep->size (); } octave_idx_type numel (const octave_value_list& idx) { return rep->numel (idx); } octave_value single_subsref (const std::string& type, const octave_value_list& idx); octave_value subsref (const std::string& type, const std::list<octave_value_list>& idx) { return rep->subsref (type, idx); } octave_value subsref (const std::string& type, const std::list<octave_value_list>& idx, bool auto_add) { return rep->subsref (type, idx, auto_add); } octave_value_list subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout); octave_value_list subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout, const std::list<octave_lvalue> *lvalue_list); octave_value next_subsref (const std::string& type, const std::list<octave_value_list>& idx, size_t skip = 1); octave_value_list next_subsref (int nargout, const std::string& type, const std::list<octave_value_list>& idx, size_t skip = 1); octave_value_list next_subsref (int nargout, const std::string& type, const std::list<octave_value_list>& idx, const std::list<octave_lvalue> *lvalue_list, size_t skip = 1); octave_value next_subsref (bool auto_add, const std::string& type, const std::list<octave_value_list>& idx, size_t skip = 1); octave_value do_index_op (const octave_value_list& idx, bool resize_ok = false) { return rep->do_index_op (idx, resize_ok); } octave_value_list do_multi_index_op (int nargout, const octave_value_list& idx); octave_value_list do_multi_index_op (int nargout, const octave_value_list& idx, const std::list<octave_lvalue> *lvalue_list); octave_value subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs); octave_value undef_subsasgn (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs); octave_value& assign (assign_op op, const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs); octave_value& assign (assign_op, const octave_value& rhs); idx_vector index_vector (bool require_integers = false) const { return rep->index_vector (require_integers); } // Size. dim_vector dims (void) const { return rep->dims (); } octave_idx_type rows (void) const { return rep->rows (); } octave_idx_type columns (void) const { return rep->columns (); } octave_idx_type length (void) const; int ndims (void) const { return rep->ndims (); } bool all_zero_dims (void) const { return dims ().all_zero (); } octave_idx_type numel (void) const { return rep->numel (); } GCC_ATTR_DEPRECATED octave_idx_type capacity (void) const { return rep->numel (); } size_t byte_size (void) const { return rep->byte_size (); } octave_idx_type nnz (void) const { return rep->nnz (); } octave_idx_type nzmax (void) const { return rep->nzmax (); } octave_idx_type nfields (void) const { return rep->nfields (); } octave_value reshape (const dim_vector& dv) const { return rep->reshape (dv); } octave_value permute (const Array<int>& vec, bool inv = false) const { return rep->permute (vec, inv); } octave_value ipermute (const Array<int>& vec) const { return rep->permute (vec, true); } octave_value resize (const dim_vector& dv, bool fill = false) const { return rep->resize (dv, fill);} MatrixType matrix_type (void) const { return rep->matrix_type (); } MatrixType matrix_type (const MatrixType& typ) const { return rep->matrix_type (typ); } // Does this constant have a type? Both of these are provided since // it is sometimes more natural to write is_undefined() instead of // ! is_defined(). bool is_defined (void) const { return rep->is_defined (); } bool is_undefined (void) const { return ! is_defined (); } bool is_empty (void) const { return rep->is_empty (); } bool is_cell (void) const { return rep->is_cell (); } bool is_cellstr (void) const { return rep->is_cellstr (); } bool is_real_scalar (void) const { return rep->is_real_scalar (); } bool is_real_matrix (void) const { return rep->is_real_matrix (); } bool is_complex_scalar (void) const { return rep->is_complex_scalar (); } bool is_complex_matrix (void) const { return rep->is_complex_matrix (); } bool is_bool_scalar (void) const { return rep->is_bool_scalar (); } bool is_bool_matrix (void) const { return rep->is_bool_matrix (); } bool is_char_matrix (void) const { return rep->is_char_matrix (); } bool is_diag_matrix (void) const { return rep->is_diag_matrix (); } bool is_perm_matrix (void) const { return rep->is_perm_matrix (); } bool is_string (void) const { return rep->is_string (); } bool is_sq_string (void) const { return rep->is_sq_string (); } bool is_dq_string (void) const { return rep->is_string () && ! rep->is_sq_string (); } bool is_range (void) const { return rep->is_range (); } bool is_map (void) const { return rep->is_map (); } bool is_object (void) const { return rep->is_object (); } bool is_classdef_object (void) const { return rep->is_classdef_object (); } bool is_java (void) const { return rep->is_java (); } bool is_cs_list (void) const { return rep->is_cs_list (); } bool is_magic_colon (void) const { return rep->is_magic_colon (); } bool is_null_value (void) const { return rep->is_null_value (); } // Are any or all of the elements in this constant nonzero? octave_value all (int dim = 0) const { return rep->all (dim); } octave_value any (int dim = 0) const { return rep->any (dim); } builtin_type_t builtin_type (void) const { return rep->builtin_type (); } // Floating point types. bool is_double_type (void) const { return rep->is_double_type (); } bool is_single_type (void) const { return rep->is_single_type (); } bool is_float_type (void) const { return rep->is_float_type (); } // Integer types. bool is_int8_type (void) const { return rep->is_int8_type (); } bool is_int16_type (void) const { return rep->is_int16_type (); } bool is_int32_type (void) const { return rep->is_int32_type (); } bool is_int64_type (void) const { return rep->is_int64_type (); } bool is_uint8_type (void) const { return rep->is_uint8_type (); } bool is_uint16_type (void) const { return rep->is_uint16_type (); } bool is_uint32_type (void) const { return rep->is_uint32_type (); } bool is_uint64_type (void) const { return rep->is_uint64_type (); } // Other type stuff. bool is_bool_type (void) const { return rep->is_bool_type (); } bool is_integer_type (void) const { return rep->is_integer_type (); } bool is_real_type (void) const { return rep->is_real_type (); } bool is_complex_type (void) const { return rep->is_complex_type (); } bool is_scalar_type (void) const { return rep->is_scalar_type (); } bool is_matrix_type (void) const { return rep->is_matrix_type (); } bool is_numeric_type (void) const { return rep->is_numeric_type (); } bool is_sparse_type (void) const { return rep->is_sparse_type (); } // Does this constant correspond to a truth value? bool is_true (void) const { return rep->is_true (); } // Do two constants match (in a switch statement)? bool is_equal (const octave_value&) const; // Are the dimensions of this constant zero by zero? bool is_zero_by_zero (void) const { return (rows () == 0 && columns () == 0); } bool is_constant (void) const { return rep->is_constant (); } bool is_function_handle (void) const { return rep->is_function_handle (); } bool is_anonymous_function (void) const { return rep->is_anonymous_function (); } bool is_inline_function (void) const { return rep->is_inline_function (); } bool is_function (void) const { return rep->is_function (); } bool is_user_script (void) const { return rep->is_user_script (); } bool is_user_function (void) const { return rep->is_user_function (); } bool is_user_code (void) const { return rep->is_user_code (); } bool is_builtin_function (void) const { return rep->is_builtin_function (); } bool is_dld_function (void) const { return rep->is_dld_function (); } bool is_mex_function (void) const { return rep->is_mex_function (); } void erase_subfunctions (void) { rep->erase_subfunctions (); } // Values. octave_value eval (void) { return *this; } short int short_value (bool req_int = false, bool frc_str_conv = false) const { return rep->short_value (req_int, frc_str_conv); } unsigned short int ushort_value (bool req_int = false, bool frc_str_conv = false) const { return rep->ushort_value (req_int, frc_str_conv); } int int_value (bool req_int = false, bool frc_str_conv = false) const { return rep->int_value (req_int, frc_str_conv); } unsigned int uint_value (bool req_int = false, bool frc_str_conv = false) const { return rep->uint_value (req_int, frc_str_conv); } int nint_value (bool frc_str_conv = false) const { return rep->nint_value (frc_str_conv); } long int long_value (bool req_int = false, bool frc_str_conv = false) const { return rep->long_value (req_int, frc_str_conv); } unsigned long int ulong_value (bool req_int = false, bool frc_str_conv = false) const { return rep->ulong_value (req_int, frc_str_conv); } int64_t int64_value (bool req_int = false, bool frc_str_conv = false) const { return rep->int64_value (req_int, frc_str_conv); } uint64_t uint64_value (bool req_int = false, bool frc_str_conv = false) const { return rep->uint64_value (req_int, frc_str_conv); } octave_idx_type idx_type_value (bool req_int = false, bool frc_str_conv = false) const; double double_value (bool frc_str_conv = false) const { return rep->double_value (frc_str_conv); } float float_value (bool frc_str_conv = false) const { return rep->float_value (frc_str_conv); } double scalar_value (bool frc_str_conv = false) const { return rep->scalar_value (frc_str_conv); } float float_scalar_value (bool frc_str_conv = false) const { return rep->float_scalar_value (frc_str_conv); } Cell cell_value (void) const; Matrix matrix_value (bool frc_str_conv = false) const { return rep->matrix_value (frc_str_conv); } FloatMatrix float_matrix_value (bool frc_str_conv = false) const { return rep->float_matrix_value (frc_str_conv); } NDArray array_value (bool frc_str_conv = false) const { return rep->array_value (frc_str_conv); } FloatNDArray float_array_value (bool frc_str_conv = false) const { return rep->float_array_value (frc_str_conv); } Complex complex_value (bool frc_str_conv = false) const { return rep->complex_value (frc_str_conv); } FloatComplex float_complex_value (bool frc_str_conv = false) const { return rep->float_complex_value (frc_str_conv); } ComplexMatrix complex_matrix_value (bool frc_str_conv = false) const { return rep->complex_matrix_value (frc_str_conv); } FloatComplexMatrix float_complex_matrix_value (bool frc_str_conv = false) const { return rep->float_complex_matrix_value (frc_str_conv); } ComplexNDArray complex_array_value (bool frc_str_conv = false) const { return rep->complex_array_value (frc_str_conv); } FloatComplexNDArray float_complex_array_value (bool frc_str_conv = false) const { return rep->float_complex_array_value (frc_str_conv); } bool bool_value (bool warn = false) const { return rep->bool_value (warn); } boolMatrix bool_matrix_value (bool warn = false) const { return rep->bool_matrix_value (warn); } boolNDArray bool_array_value (bool warn = false) const { return rep->bool_array_value (warn); } charMatrix char_matrix_value (bool frc_str_conv = false) const { return rep->char_matrix_value (frc_str_conv); } charNDArray char_array_value (bool frc_str_conv = false) const { return rep->char_array_value (frc_str_conv); } SparseMatrix sparse_matrix_value (bool frc_str_conv = false) const { return rep->sparse_matrix_value (frc_str_conv); } SparseComplexMatrix sparse_complex_matrix_value (bool frc_str_conv = false) const { return rep->sparse_complex_matrix_value (frc_str_conv); } SparseBoolMatrix sparse_bool_matrix_value (bool warn = false) const { return rep->sparse_bool_matrix_value (warn); } DiagMatrix diag_matrix_value (bool force = false) const { return rep->diag_matrix_value (force); } FloatDiagMatrix float_diag_matrix_value (bool force = false) const { return rep->float_diag_matrix_value (force); } ComplexDiagMatrix complex_diag_matrix_value (bool force = false) const { return rep->complex_diag_matrix_value (force); } FloatComplexDiagMatrix float_complex_diag_matrix_value (bool force = false) const { return rep->float_complex_diag_matrix_value (force); } PermMatrix perm_matrix_value (void) const { return rep->perm_matrix_value (); } octave_int8 int8_scalar_value (void) const { return rep->int8_scalar_value (); } octave_int16 int16_scalar_value (void) const { return rep->int16_scalar_value (); } octave_int32 int32_scalar_value (void) const { return rep->int32_scalar_value (); } octave_int64 int64_scalar_value (void) const { return rep->int64_scalar_value (); } octave_uint8 uint8_scalar_value (void) const { return rep->uint8_scalar_value (); } octave_uint16 uint16_scalar_value (void) const { return rep->uint16_scalar_value (); } octave_uint32 uint32_scalar_value (void) const { return rep->uint32_scalar_value (); } octave_uint64 uint64_scalar_value (void) const { return rep->uint64_scalar_value (); } int8NDArray int8_array_value (void) const { return rep->int8_array_value (); } int16NDArray int16_array_value (void) const { return rep->int16_array_value (); } int32NDArray int32_array_value (void) const { return rep->int32_array_value (); } int64NDArray int64_array_value (void) const { return rep->int64_array_value (); } uint8NDArray uint8_array_value (void) const { return rep->uint8_array_value (); } uint16NDArray uint16_array_value (void) const { return rep->uint16_array_value (); } uint32NDArray uint32_array_value (void) const { return rep->uint32_array_value (); } uint64NDArray uint64_array_value (void) const { return rep->uint64_array_value (); } string_vector all_strings (bool pad = false) const { return rep->all_strings (pad); } std::string string_value (bool force = false) const { return rep->string_value (force); } std::string string_value (const char *fmt, ...) const { va_list args; va_start (args,fmt); return rep->string_value (fmt, args); va_end (args); } Array<std::string> cellstr_value (void) const { return rep->cellstr_value (); } Range range_value (void) const { return rep->range_value (); } octave_map map_value (void) const; octave_scalar_map scalar_map_value (void) const; string_vector map_keys (void) const { return rep->map_keys (); } size_t nparents (void) const { return rep->nparents (); } std::list<std::string> parent_class_name_list (void) const { return rep->parent_class_name_list (); } string_vector parent_class_names (void) const { return rep->parent_class_names (); } octave_base_value * find_parent_class (const std::string& parent_class_name) { return rep->find_parent_class (parent_class_name); } bool is_instance_of (const std::string& cls_name) const { return rep->is_instance_of (cls_name); } octave_function *function_value (bool silent = false) const; octave_user_function *user_function_value (bool silent = false) const; octave_user_script *user_script_value (bool silent = false) const; octave_user_code *user_code_value (bool silent = false) const; octave_fcn_handle *fcn_handle_value (bool silent = false) const; octave_fcn_inline *fcn_inline_value (bool silent = false) const; octave_value_list list_value (void) const; ColumnVector column_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; ComplexColumnVector complex_column_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; RowVector row_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; ComplexRowVector complex_row_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; FloatColumnVector float_column_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; FloatComplexColumnVector float_complex_column_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; FloatRowVector float_row_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; FloatComplexRowVector float_complex_row_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<int> int_vector_value (bool req_int = false, bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<octave_idx_type> octave_idx_type_vector_value (bool req_int = false, bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<double> vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<Complex> complex_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<float> float_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; Array<FloatComplex> float_complex_vector_value (bool frc_str_conv = false, bool frc_vec_conv = false) const; // Possibly economize a lazy-indexed value. void maybe_economize (void) { rep->maybe_economize (); } // The following two hook conversions are called on any octave_value prior to // storing it to a "permanent" location, like a named variable, a cell or a // struct component, or a return value of a function. octave_value storable_value (void) const; // Ditto, but in place, i.e. equivalent to *this = this->storable_value (), // but possibly more efficient. void make_storable_value (void); // Conversions. These should probably be private. If a user of this // class wants a certain kind of constant, he should simply ask for // it, and we should convert it if possible. octave_value convert_to_str (bool pad = false, bool force = false, char type = '\'') const { return rep->convert_to_str (pad, force, type); } octave_value convert_to_str_internal (bool pad, bool force, char type) const { return rep->convert_to_str_internal (pad, force, type); } void convert_to_row_or_column_vector (void) { rep->convert_to_row_or_column_vector (); } bool print_as_scalar (void) const { return rep->print_as_scalar (); } void print (std::ostream& os, bool pr_as_read_syntax = false) { rep->print (os, pr_as_read_syntax); } void print_raw (std::ostream& os, bool pr_as_read_syntax = false) const { rep->print_raw (os, pr_as_read_syntax); } bool print_name_tag (std::ostream& os, const std::string& name) const { return rep->print_name_tag (os, name); } void print_with_name (std::ostream& os, const std::string& name) const { rep->print_with_name (os, name, true); } void short_disp (std::ostream& os) const { rep->short_disp (os); } int type_id (void) const { return rep->type_id (); } std::string type_name (void) const { return rep->type_name (); } std::string class_name (void) const { return rep->class_name (); } // Unary and binary operations. friend OCTINTERP_API octave_value do_unary_op (unary_op op, const octave_value& a); octave_value& do_non_const_unary_op (unary_op op); octave_value& do_non_const_unary_op (unary_op op, const std::string& type, const std::list<octave_value_list>& idx); friend OCTINTERP_API octave_value do_binary_op (binary_op op, const octave_value& a, const octave_value& b); friend OCTINTERP_API octave_value do_binary_op (compound_binary_op op, const octave_value& a, const octave_value& b); friend OCTINTERP_API octave_value do_cat_op (const octave_value& a, const octave_value& b, const Array<octave_idx_type>& ra_idx); friend OCTINTERP_API octave_value do_colon_op (const octave_value& base, const octave_value& limit, bool is_for_cmd_expr) { return do_colon_op (base, octave_value (), limit, is_for_cmd_expr); } friend OCTINTERP_API octave_value do_colon_op (const octave_value& base, const octave_value& increment, const octave_value& limit, bool is_for_cmd_expr); const octave_base_value& get_rep (void) const { return *rep; } bool is_copy_of (const octave_value &val) const { return rep == val.rep; } void print_info (std::ostream& os, const std::string& prefix = std::string ()) const; bool save_ascii (std::ostream& os) { return rep->save_ascii (os); } bool load_ascii (std::istream& is) { return rep->load_ascii (is); } bool save_binary (std::ostream& os, bool& save_as_floats) { return rep->save_binary (os, save_as_floats); } bool load_binary (std::istream& is, bool swap, oct_mach_info::float_format fmt) { return rep->load_binary (is, swap, fmt); } bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats) { return rep->save_hdf5 (loc_id, name, save_as_floats); } bool load_hdf5 (octave_hdf5_id loc_id, const char *name) { return rep->load_hdf5 (loc_id, name); } int write (octave_stream& os, int block_size, oct_data_conv::data_type output_type, int skip, oct_mach_info::float_format flt_fmt) const; octave_base_value *internal_rep (void) const { return rep; } // Unsafe. These functions exist to support the MEX interface. // You should not use them anywhere else. void *mex_get_data (void) const { return rep->mex_get_data (); } octave_idx_type *mex_get_ir (void) const { return rep->mex_get_ir (); } octave_idx_type *mex_get_jc (void) const { return rep->mex_get_jc (); } mxArray *as_mxArray (void) const { return rep->as_mxArray (); } octave_value diag (octave_idx_type k = 0) const { return rep->diag (k); } octave_value diag (octave_idx_type m, octave_idx_type n) const { return rep->diag (m, n); } octave_value sort (octave_idx_type dim = 0, sortmode mode = ASCENDING) const { return rep->sort (dim, mode); } octave_value sort (Array<octave_idx_type> &sidx, octave_idx_type dim = 0, sortmode mode = ASCENDING) const { return rep->sort (sidx, dim, mode); } sortmode is_sorted (sortmode mode = UNSORTED) const { return rep->is_sorted (mode); } Array<octave_idx_type> sort_rows_idx (sortmode mode = ASCENDING) const { return rep->sort_rows_idx (mode); } sortmode is_sorted_rows (sortmode mode = UNSORTED) const { return rep->is_sorted_rows (mode); } void lock (void) { rep->lock (); } void unlock (void) { rep->unlock (); } bool islocked (void) const { return rep->islocked (); } void dump (std::ostream& os) const { rep->dump (os); } #define MAPPER_FORWARD(F) \ octave_value F (void) const { return rep->map (octave_base_value::umap_ ## F); } MAPPER_FORWARD (abs) MAPPER_FORWARD (acos) MAPPER_FORWARD (acosh) MAPPER_FORWARD (angle) MAPPER_FORWARD (arg) MAPPER_FORWARD (asin) MAPPER_FORWARD (asinh) MAPPER_FORWARD (atan) MAPPER_FORWARD (atanh) MAPPER_FORWARD (cbrt) MAPPER_FORWARD (ceil) MAPPER_FORWARD (conj) MAPPER_FORWARD (cos) MAPPER_FORWARD (cosh) MAPPER_FORWARD (erf) MAPPER_FORWARD (erfinv) MAPPER_FORWARD (erfcinv) MAPPER_FORWARD (erfc) MAPPER_FORWARD (erfcx) MAPPER_FORWARD (erfi) MAPPER_FORWARD (dawson) MAPPER_FORWARD (exp) MAPPER_FORWARD (expm1) MAPPER_FORWARD (finite) MAPPER_FORWARD (fix) MAPPER_FORWARD (floor) MAPPER_FORWARD (gamma) MAPPER_FORWARD (imag) MAPPER_FORWARD (isinf) MAPPER_FORWARD (isna) MAPPER_FORWARD (isnan) MAPPER_FORWARD (lgamma) MAPPER_FORWARD (log) MAPPER_FORWARD (log2) MAPPER_FORWARD (log10) MAPPER_FORWARD (log1p) MAPPER_FORWARD (real) MAPPER_FORWARD (round) MAPPER_FORWARD (roundb) MAPPER_FORWARD (signum) MAPPER_FORWARD (sin) MAPPER_FORWARD (sinh) MAPPER_FORWARD (sqrt) MAPPER_FORWARD (tan) MAPPER_FORWARD (tanh) // These functions are prefixed with X to avoid potential macro // conflicts. MAPPER_FORWARD (xisalnum) MAPPER_FORWARD (xisalpha) MAPPER_FORWARD (xisascii) MAPPER_FORWARD (xiscntrl) MAPPER_FORWARD (xisdigit) MAPPER_FORWARD (xisgraph) MAPPER_FORWARD (xislower) MAPPER_FORWARD (xisprint) MAPPER_FORWARD (xispunct) MAPPER_FORWARD (xisspace) MAPPER_FORWARD (xisupper) MAPPER_FORWARD (xisxdigit) MAPPER_FORWARD (xsignbit) MAPPER_FORWARD (xtoascii) MAPPER_FORWARD (xtolower) MAPPER_FORWARD (xtoupper) #undef MAPPER_FORWARD octave_value map (octave_base_value::unary_mapper_t umap) const { return rep->map (umap); } // Extract the n-th element, aka val(n). Result is undefined if val is not an // array type or n is out of range. Never error. octave_value fast_elem_extract (octave_idx_type n) const { return rep->fast_elem_extract (n); } // Assign the n-th element, aka val(n) = x. Returns false if val is not an // array type, x is not a matching scalar type, or n is out of range. // Never error. virtual bool fast_elem_insert (octave_idx_type n, const octave_value& x) { make_unique (); return rep->fast_elem_insert (n, x); } protected: // The real representation. octave_base_value *rep; private: assign_op unary_op_to_assign_op (unary_op op); binary_op op_eq_to_binary_op (assign_op op); // This declaration protects against constructing octave_value from // const octave_base_value* which actually silently calls octave_value (bool). octave_value (const octave_base_value *); }; // Publish externally used friend functions. extern OCTINTERP_API octave_value do_unary_op (octave_value::unary_op op, const octave_value& a); extern OCTINTERP_API octave_value do_binary_op (octave_value::binary_op op, const octave_value& a, const octave_value& b); extern OCTINTERP_API octave_value do_binary_op (octave_value::compound_binary_op op, const octave_value& a, const octave_value& b); #define OV_UNOP_FN(name) \ inline octave_value \ name (const octave_value& a) \ { \ return do_unary_op (octave_value::name, a); \ } #define OV_UNOP_OP(name, op) \ inline octave_value \ operator op (const octave_value& a) \ { \ return name (a); \ } #define OV_UNOP_FN_OP(name, op) \ OV_UNOP_FN (name) \ OV_UNOP_OP (name, op) OV_UNOP_FN_OP (op_not, !) OV_UNOP_FN_OP (op_uplus, +) OV_UNOP_FN_OP (op_uminus, -) OV_UNOP_FN (op_transpose) OV_UNOP_FN (op_hermitian) // No simple way to define these for prefix and suffix ops? // // incr // decr #define OV_BINOP_FN(name) \ inline octave_value \ name (const octave_value& a1, const octave_value& a2) \ { \ return do_binary_op (octave_value::name, a1, a2); \ } #define OV_BINOP_OP(name, op) \ inline octave_value \ operator op (const octave_value& a1, const octave_value& a2) \ { \ return name (a1, a2); \ } #define OV_BINOP_FN_OP(name, op) \ OV_BINOP_FN (name) \ OV_BINOP_OP (name, op) OV_BINOP_FN_OP (op_add, +) OV_BINOP_FN_OP (op_sub, -) OV_BINOP_FN_OP (op_mul, *) OV_BINOP_FN_OP (op_div, /) OV_BINOP_FN (op_pow) OV_BINOP_FN (op_ldiv) OV_BINOP_FN (op_lshift) OV_BINOP_FN (op_rshift) OV_BINOP_FN_OP (op_lt, <) OV_BINOP_FN_OP (op_le, <=) OV_BINOP_FN_OP (op_eq, ==) OV_BINOP_FN_OP (op_ge, >=) OV_BINOP_FN_OP (op_gt, >) OV_BINOP_FN_OP (op_ne, !=) OV_BINOP_FN (op_el_mul) OV_BINOP_FN (op_el_div) OV_BINOP_FN (op_el_pow) OV_BINOP_FN (op_el_ldiv) OV_BINOP_FN (op_el_and) OV_BINOP_FN (op_el_or) OV_BINOP_FN (op_struct_ref) #define OV_COMP_BINOP_FN(name) \ inline octave_value \ name (const octave_value& a1, const octave_value& a2) \ { \ return do_binary_op (octave_value::name, a1, a2); \ } OV_COMP_BINOP_FN (op_trans_mul) OV_COMP_BINOP_FN (op_mul_trans) OV_COMP_BINOP_FN (op_herm_mul) OV_COMP_BINOP_FN (op_mul_herm) extern OCTINTERP_API void install_types (void); // This will eventually go away, but for now it can be used to // simplify the transition to the new octave_value class hierarchy, // which uses octave_base_value instead of octave_value for the type // of octave_value::rep. #define OV_REP_TYPE octave_base_value // Templated value extractors. template<class Value> inline Value octave_value_extract (const octave_value&) { assert (false); } #define DEF_VALUE_EXTRACTOR(VALUE,MPREFIX) \ template<> \ inline VALUE octave_value_extract<VALUE> (const octave_value& v) \ { return v.MPREFIX ## _value (); } DEF_VALUE_EXTRACTOR (double, scalar) DEF_VALUE_EXTRACTOR (float, float_scalar) DEF_VALUE_EXTRACTOR (Complex, complex) DEF_VALUE_EXTRACTOR (FloatComplex, float_complex) DEF_VALUE_EXTRACTOR (bool, bool) DEF_VALUE_EXTRACTOR (octave_int8, int8_scalar) DEF_VALUE_EXTRACTOR (octave_int16, int16_scalar) DEF_VALUE_EXTRACTOR (octave_int32, int32_scalar) DEF_VALUE_EXTRACTOR (octave_int64, int64_scalar) DEF_VALUE_EXTRACTOR (octave_uint8, uint8_scalar) DEF_VALUE_EXTRACTOR (octave_uint16, uint16_scalar) DEF_VALUE_EXTRACTOR (octave_uint32, uint32_scalar) DEF_VALUE_EXTRACTOR (octave_uint64, uint64_scalar) DEF_VALUE_EXTRACTOR (NDArray, array) DEF_VALUE_EXTRACTOR (FloatNDArray, float_array) DEF_VALUE_EXTRACTOR (ComplexNDArray, complex_array) DEF_VALUE_EXTRACTOR (FloatComplexNDArray, float_complex_array) DEF_VALUE_EXTRACTOR (boolNDArray, bool_array) DEF_VALUE_EXTRACTOR (charNDArray, char_array) DEF_VALUE_EXTRACTOR (int8NDArray, int8_array) DEF_VALUE_EXTRACTOR (int16NDArray, int16_array) DEF_VALUE_EXTRACTOR (int32NDArray, int32_array) DEF_VALUE_EXTRACTOR (int64NDArray, int64_array) DEF_VALUE_EXTRACTOR (uint8NDArray, uint8_array) DEF_VALUE_EXTRACTOR (uint16NDArray, uint16_array) DEF_VALUE_EXTRACTOR (uint32NDArray, uint32_array) DEF_VALUE_EXTRACTOR (uint64NDArray, uint64_array) DEF_VALUE_EXTRACTOR (Matrix, matrix) DEF_VALUE_EXTRACTOR (FloatMatrix, float_matrix) DEF_VALUE_EXTRACTOR (ComplexMatrix, complex_matrix) DEF_VALUE_EXTRACTOR (FloatComplexMatrix, float_complex_matrix) DEF_VALUE_EXTRACTOR (boolMatrix, bool_matrix) DEF_VALUE_EXTRACTOR (ColumnVector, column_vector) DEF_VALUE_EXTRACTOR (FloatColumnVector, float_column_vector) DEF_VALUE_EXTRACTOR (ComplexColumnVector, complex_column_vector) DEF_VALUE_EXTRACTOR (FloatComplexColumnVector, float_complex_column_vector) DEF_VALUE_EXTRACTOR (RowVector, row_vector) DEF_VALUE_EXTRACTOR (FloatRowVector, float_row_vector) DEF_VALUE_EXTRACTOR (ComplexRowVector, complex_row_vector) DEF_VALUE_EXTRACTOR (FloatComplexRowVector, float_complex_row_vector) DEF_VALUE_EXTRACTOR (DiagMatrix, diag_matrix) DEF_VALUE_EXTRACTOR (FloatDiagMatrix, float_diag_matrix) DEF_VALUE_EXTRACTOR (ComplexDiagMatrix, complex_diag_matrix) DEF_VALUE_EXTRACTOR (FloatComplexDiagMatrix, float_complex_diag_matrix) DEF_VALUE_EXTRACTOR (PermMatrix, perm_matrix) DEF_VALUE_EXTRACTOR (SparseMatrix, sparse_matrix) DEF_VALUE_EXTRACTOR (SparseComplexMatrix, sparse_complex_matrix) DEF_VALUE_EXTRACTOR (SparseBoolMatrix, sparse_bool_matrix) #undef DEF_VALUE_EXTRACTOR #define DEF_DUMMY_VALUE_EXTRACTOR(VALUE,DEFVAL) \ template<> \ inline VALUE octave_value_extract<VALUE> (const octave_value&) \ { assert (false); return DEFVAL; } DEF_DUMMY_VALUE_EXTRACTOR (char, 0) DEF_DUMMY_VALUE_EXTRACTOR (octave_value, octave_value ()) #undef DEF_DUMMY_VALUE_EXTRACTOR #endif