Mercurial > hg > octave-nkf
view src/ov.h @ 5210:996a08a3eb06 ss-2-9-0
[project @ 2005-03-15 20:46:03 by jwe]
| author | jwe |
|---|---|
| date | Tue, 15 Mar 2005 20:46:03 +0000 |
| parents | 57077d0ddc8e |
| children | 23b37da9fd5b |
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/* Copyright (C) 1996, 1997 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 2, 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, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #if !defined (octave_value_h) #define octave_value_h 1 #include <cstdlib> #include <iostream> #include <string> #include <list> #if defined (HAVE_HDF5) #include <hdf5.h> #endif #include "Range.h" #include "idx-vector.h" #include "mx-base.h" #include "oct-alloc.h" #include "oct-time.h" #include "str-vec.h" #include "SparseType.h" class Cell; class streamoff_array; class Octave_map; class octave_stream; class octave_streamoff; class octave_function; class octave_user_function; class octave_fcn_handle; class octave_fcn_inline; class octave_value_list; class octave_lvalue; // Constants. // This just provides a way to avoid infinite recursion when building // octave_value objects. class octave_xvalue { public: octave_xvalue (void) { } }; class octave_value; // XXX FIXME XXX -- these should probably really be inside the scope // of the octave_value class, but the cygwin32 beta16 version of g++ // can't handle that. typedef octave_value (*unary_op_fcn) (const octave_value&); typedef void (*non_const_unary_op_fcn) (octave_value&); typedef octave_value (*binary_op_fcn) (const octave_value&, const octave_value&); typedef octave_value (*cat_op_fcn) (octave_value&, const octave_value&, const Array<int>& ra_idx); typedef octave_value (*assign_op_fcn) (octave_value&, const octave_value_list&, const octave_value&); typedef octave_value * (*type_conv_fcn) (const octave_value&); class octave_value { public: enum unary_op { op_not, op_uplus, op_uminus, op_transpose, op_hermitian, op_incr, op_decr, num_unary_ops, unknown_unary_op }; enum binary_op { op_add, op_sub, op_mul, op_div, op_pow, op_ldiv, op_lshift, op_rshift, op_lt, op_le, op_eq, op_ge, op_gt, op_ne, op_el_mul, op_el_div, op_el_pow, op_el_ldiv, op_el_and, op_el_or, op_struct_ref, num_binary_ops, unknown_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 std::string unary_op_as_string (unary_op); static std::string binary_op_as_string (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 }; enum all_va_args { all_va_args_t }; octave_value (void); 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); // XXX FIXME XXX -- 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 (const ArrayN<octave_value>& a, bool is_cs_list = false); octave_value (const Cell& c, bool is_cs_list = false); octave_value (const Matrix& m); octave_value (const NDArray& nda); octave_value (const ArrayN<double>& m); octave_value (const DiagMatrix& d); octave_value (const RowVector& v); octave_value (const ColumnVector& v); octave_value (const Complex& C); octave_value (const ComplexMatrix& m); octave_value (const ComplexNDArray& cnda); octave_value (const ArrayN<Complex>& m); octave_value (const ComplexDiagMatrix& d); octave_value (const ComplexRowVector& v); octave_value (const ComplexColumnVector& v); octave_value (bool b); octave_value (const boolMatrix& bm); octave_value (const boolNDArray& bnda); octave_value (char c); octave_value (const char *s); octave_value (const std::string& s); octave_value (const string_vector& s); octave_value (const charMatrix& chm, bool is_string = false); octave_value (const charNDArray& chnda, bool is_string = false); octave_value (const ArrayN<char>& chnda, bool is_string = false); octave_value (const SparseMatrix& m, const SparseType& t = SparseType ()); octave_value (const SparseComplexMatrix& m, const SparseType& t = SparseType ()); octave_value (const SparseBoolMatrix& bm, const SparseType& t = SparseType ()); 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 int16NDArray& inda); octave_value (const int32NDArray& inda); octave_value (const int64NDArray& inda); octave_value (const uint8NDArray& inda); octave_value (const uint16NDArray& inda); octave_value (const uint32NDArray& inda); octave_value (const uint64NDArray& inda); octave_value (double base, double limit, double inc); octave_value (const Range& r); octave_value (const Octave_map& m); octave_value (const octave_stream& s, int n); octave_value (const streamoff_array& off); octave_value (const octave_value_list& m, bool is_cs_list = false); octave_value (octave_value::magic_colon); octave_value (octave_value::all_va_args); octave_value (octave_value *new_rep, int count = 1); // Copy constructor. octave_value (const octave_value& a) { rep = a.rep; rep->count++; } // This should only be called for derived types. virtual octave_value *clone (void) const; virtual octave_value *empty_clone (void) const { return rep->empty_clone (); } // Delete the representation of this constant if the count drops to // zero. virtual ~octave_value (void); void make_unique (void) { if (rep->count > 1) { --rep->count; rep = rep->clone (); rep->count = 1; } } // 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; } int get_count (void) const { return rep->count; } virtual type_conv_fcn numeric_conversion_function (void) const { return rep->numeric_conversion_function (); } void maybe_mutate (void); virtual octave_value squeeze (void) const { return rep->squeeze (); } virtual octave_value *try_narrowing_conversion (void) { return rep->try_narrowing_conversion (); } octave_value single_subsref (const std::string& type, const octave_value_list& idx); virtual octave_value subsref (const std::string& type, const std::list<octave_value_list>& idx) { return rep->subsref (type, idx); } virtual octave_value_list subsref (const std::string& type, const std::list<octave_value_list>& idx, int nargout); 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); virtual octave_value do_index_op (const octave_value_list& idx, int resize_ok) { return rep->do_index_op (idx, resize_ok); } octave_value do_index_op (const octave_value_list& idx) { return do_index_op (idx, 0); } virtual octave_value_list do_multi_index_op (int nargout, const octave_value_list& idx); virtual octave_value 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); const octave_value& assign (assign_op, const octave_value& rhs); virtual idx_vector index_vector (void) const { return rep->index_vector (); } // Size. virtual dim_vector dims (void) const { return rep->dims (); } int rows (void) const; int columns (void) const; int length (void) const; int ndims (void) const; bool all_zero_dims (void) const { return dims().all_zero (); } virtual int numel (void) const { return rep->numel (); } virtual int capacity (void) const { return rep->capacity (); } virtual size_t byte_size (void) const { return rep->byte_size (); } virtual octave_value reshape (const dim_vector& dv) const { return rep->reshape (dv); } virtual 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); } virtual octave_value resize (const dim_vector& dv) const { return rep->resize (dv);} // 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(). virtual bool is_defined (void) const { return rep->is_defined (); } bool is_undefined (void) const { return ! is_defined (); } bool is_empty (void) const { return numel () == 0; } virtual bool is_cell (void) const { return rep->is_cell (); } virtual bool is_real_scalar (void) const { return rep->is_real_scalar (); } virtual bool is_real_matrix (void) const { return rep->is_real_matrix (); } virtual bool is_real_nd_array (void) const { return rep->is_real_nd_array (); } virtual bool is_complex_scalar (void) const { return rep->is_complex_scalar (); } virtual bool is_complex_matrix (void) const { return rep->is_complex_matrix (); } virtual bool is_bool_matrix (void) const { return rep->is_bool_matrix (); } virtual bool is_char_matrix (void) const { return rep->is_char_matrix (); } virtual bool is_string (void) const { return rep->is_string (); } virtual bool is_range (void) const { return rep->is_range (); } virtual bool is_map (void) const { return rep->is_map (); } virtual bool is_stream (void) const { return rep->is_stream (); } virtual bool is_streamoff (void) const { return rep->is_streamoff (); } virtual bool is_cs_list (void) const { return rep->is_cs_list (); } virtual bool is_list (void) const { return rep->is_list (); } virtual bool is_magic_colon (void) const { return rep->is_magic_colon (); } virtual bool is_all_va_args (void) const { return rep->is_all_va_args (); } // Are any or all of the elements in this constant nonzero? virtual octave_value all (int dim = 0) const { return rep->all (dim); } virtual octave_value any (int dim = 0) const { return rep->any (dim); } // Other type stuff. virtual bool is_bool_type (void) const { return rep->is_bool_type (); } virtual bool is_real_type (void) const { return rep->is_real_type (); } virtual bool is_complex_type (void) const { return rep->is_complex_type (); } virtual bool is_scalar_type (void) const { return rep->is_scalar_type (); } virtual bool is_matrix_type (void) const { return rep->is_matrix_type (); } virtual bool is_numeric_type (void) const { return rep->is_numeric_type (); } virtual bool valid_as_scalar_index (void) const { return rep->valid_as_scalar_index (); } virtual bool valid_as_zero_index (void) const { return rep->valid_as_zero_index (); } // Does this constant correspond to a truth value? virtual bool is_true (void) const { return rep->is_true (); } // Are the dimensions of this constant zero by zero? virtual bool is_zero_by_zero (void) const { return rep->is_zero_by_zero (); } virtual bool is_constant (void) const { return rep->is_constant (); } virtual bool is_function_handle (void) const { return rep->is_function_handle (); } virtual bool is_inline_function (void) const { return rep->is_inline_function (); } virtual bool is_function (void) const { return rep->is_function (); } virtual bool is_builtin_function (void) const { return rep->is_builtin_function (); } virtual bool is_dld_function (void) const { return rep->is_dld_function (); } // Values. octave_value eval (void) { return *this; } virtual short int short_value (bool req_int = false, bool frc_str_conv = false) const { return rep->short_value (req_int, frc_str_conv); } virtual unsigned short int ushort_value (bool req_int = false, bool frc_str_conv = false) const { return rep->ushort_value (req_int, frc_str_conv); } virtual int int_value (bool req_int = false, bool frc_str_conv = false) const { return rep->int_value (req_int, frc_str_conv); } virtual unsigned int uint_value (bool req_int = false, bool frc_str_conv = false) const { return rep->uint_value (req_int, frc_str_conv); } virtual int nint_value (bool frc_str_conv = false) const { return rep->nint_value (frc_str_conv); } virtual long int long_value (bool req_int = false, bool frc_str_conv = false) const { return rep->long_value (req_int, frc_str_conv); } virtual unsigned long int ulong_value (bool req_int = false, bool frc_str_conv = false) const { return rep->ulong_value (req_int, frc_str_conv); } virtual double double_value (bool frc_str_conv = false) const { return rep->double_value (frc_str_conv); } virtual double scalar_value (bool frc_str_conv = false) const { return rep->scalar_value (frc_str_conv); } virtual Cell cell_value (void) const; virtual Matrix matrix_value (bool frc_str_conv = false) const { return rep->matrix_value (frc_str_conv); } virtual NDArray array_value (bool frc_str_conv = false) const { return rep->array_value (frc_str_conv); } virtual Complex complex_value (bool frc_str_conv = false) const { return rep->complex_value (frc_str_conv); } virtual ComplexMatrix complex_matrix_value (bool frc_str_conv = false) const { return rep->complex_matrix_value (frc_str_conv); } virtual ComplexNDArray complex_array_value (bool frc_str_conv = false) const { return rep->complex_array_value (frc_str_conv); } virtual bool bool_value (void) const { return rep->bool_value (); } virtual boolMatrix bool_matrix_value (void) const { return rep->bool_matrix_value (); } virtual boolNDArray bool_array_value (void) const { return rep->bool_array_value (); } virtual charMatrix char_matrix_value (bool frc_str_conv = false) const { return rep->char_matrix_value (frc_str_conv); } virtual charNDArray char_array_value (bool frc_str_conv = false) const { return rep->char_array_value (frc_str_conv); } virtual SparseMatrix sparse_matrix_value (bool frc_str_conv = false) const { return rep->sparse_matrix_value (frc_str_conv); } virtual SparseComplexMatrix sparse_complex_matrix_value (bool frc_str_conv = false) const { return rep->sparse_complex_matrix_value (frc_str_conv); } virtual SparseBoolMatrix sparse_bool_matrix_value (bool frc_str_conv = false) const { return rep->sparse_bool_matrix_value (frc_str_conv); } virtual octave_int8 int8_scalar_value (void) const { return rep->int8_scalar_value (); } virtual octave_int16 int16_scalar_value (void) const { return rep->int16_scalar_value (); } virtual octave_int32 int32_scalar_value (void) const { return rep->int32_scalar_value (); } virtual octave_int64 int64_scalar_value (void) const { return rep->int64_scalar_value (); } virtual octave_uint8 uint8_scalar_value (void) const { return rep->uint8_scalar_value (); } virtual octave_uint16 uint16_scalar_value (void) const { return rep->uint16_scalar_value (); } virtual octave_uint32 uint32_scalar_value (void) const { return rep->uint32_scalar_value (); } virtual octave_uint64 uint64_scalar_value (void) const { return rep->uint64_scalar_value (); } virtual int8NDArray int8_array_value (void) const { return rep->int8_array_value (); } virtual int16NDArray int16_array_value (void) const { return rep->int16_array_value (); } virtual int32NDArray int32_array_value (void) const { return rep->int32_array_value (); } virtual int64NDArray int64_array_value (void) const { return rep->int64_array_value (); } virtual uint8NDArray uint8_array_value (void) const { return rep->uint8_array_value (); } virtual uint16NDArray uint16_array_value (void) const { return rep->uint16_array_value (); } virtual uint32NDArray uint32_array_value (void) const { return rep->uint32_array_value (); } virtual uint64NDArray uint64_array_value (void) const { return rep->uint64_array_value (); } virtual string_vector all_strings (bool pad = false, bool force = false) const { return rep->all_strings (pad, force); } virtual std::string string_value (bool force = false) const { return rep->string_value (force); } virtual Range range_value (void) const { return rep->range_value (); } virtual Octave_map map_value (void) const; virtual string_vector map_keys (void) const { return rep->map_keys (); } virtual octave_stream stream_value (void) const; virtual int stream_number (void) const; virtual std::streamoff streamoff_value (void) const; virtual streamoff_array streamoff_array_value (void) const; virtual octave_function *function_value (bool silent = false); virtual octave_user_function *user_function_value (bool silent = false); virtual octave_fcn_handle *fcn_handle_value (bool silent = false); virtual octave_fcn_inline *fcn_inline_value (bool silent = false); virtual 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; Array<int> int_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; // 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) const; virtual octave_value convert_to_str_internal (bool pad, bool force) const { return rep->convert_to_str_internal (pad, force); } virtual void convert_to_row_or_column_vector (void) { rep->convert_to_row_or_column_vector (); } virtual bool print_as_scalar (void) const { return rep->print_as_scalar (); } virtual void print (std::ostream& os, bool pr_as_read_syntax = false) const { rep->print (os, pr_as_read_syntax); } virtual void print_raw (std::ostream& os, bool pr_as_read_syntax = false) const { rep->print_raw (os, pr_as_read_syntax); } virtual 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, bool print_padding = true) const; virtual int type_id (void) const { return rep->type_id (); } virtual std::string type_name (void) const { return rep->type_name (); } virtual std::string class_name (void) const { return rep->class_name (); } // Unary and binary operations. friend octave_value do_unary_op (unary_op op, const octave_value& a); const octave_value& do_non_const_unary_op (unary_op op); void do_non_const_unary_op (unary_op op, const octave_value_list& idx); octave_value do_non_const_unary_op (unary_op op, const std::string& type, const std::list<octave_value_list>& idx); friend octave_value do_binary_op (binary_op op, const octave_value& a, const octave_value& b); friend octave_value do_cat_op (const octave_value& a, const octave_value& b, const Array<int>& ra_idx); const octave_value& get_rep (void) const { return *rep; } virtual void print_info (std::ostream& os, const std::string& prefix = std::string ()) const; virtual bool save_ascii (std::ostream& os, bool& infnan_warned, bool strip_nan_and_inf) { return rep->save_ascii (os, infnan_warned, strip_nan_and_inf); } virtual bool load_ascii (std::istream& is) { return rep->load_ascii (is); } virtual bool save_binary (std::ostream& os, bool& save_as_floats) { return rep->save_binary (os, save_as_floats); } virtual bool load_binary (std::istream& is, bool swap, oct_mach_info::float_format fmt) { return rep->load_binary (is, swap, fmt); } #if defined (HAVE_HDF5) virtual bool save_hdf5 (hid_t loc_id, const char *name, bool save_as_floats) { return rep->save_hdf5 (loc_id, name, save_as_floats); } virtual bool load_hdf5 (hid_t loc_id, const char *name, bool have_h5giterate_bug) { return rep->load_hdf5 (loc_id, name, have_h5giterate_bug); } #endif virtual 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_value *internal_rep (void) const { return rep; } protected: octave_value (const octave_xvalue&) : rep (0) { } // This should only be called for derived types. octave_value numeric_assign (const std::string& type, const std::list<octave_value_list>& idx, const octave_value& rhs); void reset_indent_level (void) const { curr_print_indent_level = 0; } void increment_indent_level (void) const { curr_print_indent_level += 2; } void decrement_indent_level (void) const { curr_print_indent_level -= 2; } int current_print_indent_level (void) const { return curr_print_indent_level; } void newline (std::ostream& os) const; void indent (std::ostream& os) const; void reset (void) const; union { octave_value *rep; // The real representation. int count; // A reference count. }; private: static int curr_print_indent_level; static bool beginning_of_line; assign_op unary_op_to_assign_op (unary_op op); binary_op op_eq_to_binary_op (assign_op op); DECLARE_OCTAVE_ALLOCATOR octave_value *nil_rep (void) const; }; #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_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) // T_ID is the type id of struct objects, set by register_type(). // T_NAME is the type name of struct objects. #define DECLARE_OV_TYPEID_FUNCTIONS_AND_DATA \ public: \ int type_id (void) const { return t_id; } \ std::string type_name (void) const { return t_name; } \ std::string class_name (void) const { return c_name; } \ static int static_type_id (void) { return t_id; } \ static std::string static_type_name (void) { return t_name; } \ static std::string static_class_name (void) { return c_name; } \ static void register_type (void); \ \ private: \ static int t_id; \ static const std::string t_name; \ static const std::string c_name; #define DEFINE_OV_TYPEID_FUNCTIONS_AND_DATA(t, n, c) \ int t::t_id (-1); \ const std::string t::t_name (n); \ const std::string t::c_name (c); \ void t::register_type (void) \ { \ t_id = octave_value_typeinfo::register_type (t::t_name, \ t::c_name, \ octave_value (new t ())); \ } // If TRUE, print a warning for assignments like // // octave> A(1) = 3; A(2) = 5 // // for A already defined and a matrix type. extern bool Vwarn_fortran_indexing; // Should we print a warning when converting `[97, 98, 99, "123"]' // to a character string? extern bool Vwarn_num_to_str; // If TRUE, warn for operations like // // octave> 'abc' + 0 // 97 98 99 // extern int Vwarn_str_to_num; // Should we warn about conversions from complex to real? extern int Vwarn_imag_to_real; // If TRUE, print the name along with the value. extern bool Vprint_answer_id_name; // How many levels of structure elements should we print? extern int Vstruct_levels_to_print; // Allow divide by zero errors to be suppressed. extern bool Vwarn_divide_by_zero; // If TRUE, print a warning when a matrix is resized by an indexed // assignment with indices outside the current bounds. extern bool Vwarn_resize_on_range_error; // Indentation level for structures. extern int struct_indent; extern void increment_struct_indent (void); extern void decrement_struct_indent (void); // Indentation level for lists. extern int list_indent; extern void increment_list_indent (void); extern void decrement_list_indent (void); extern void install_types (void); // XXX FIXME XXX -- these trait classes probably belong somehwere else... template <typename T> class octave_type_traits { public: typedef T val_type; }; #define OCTAVE_TYPE_TRAIT(T, VAL_T) \ template <> \ class \ octave_type_traits<T> \ { \ public: \ typedef VAL_T val_type; \ } OCTAVE_TYPE_TRAIT (octave_int8, octave_int8::val_type); OCTAVE_TYPE_TRAIT (octave_uint8, octave_uint8::val_type); OCTAVE_TYPE_TRAIT (octave_int16, octave_int16::val_type); OCTAVE_TYPE_TRAIT (octave_uint16, octave_uint16::val_type); OCTAVE_TYPE_TRAIT (octave_int32, octave_int32::val_type); OCTAVE_TYPE_TRAIT (octave_uint32, octave_uint32::val_type); OCTAVE_TYPE_TRAIT (octave_int64, octave_int64::val_type); OCTAVE_TYPE_TRAIT (octave_uint64, octave_uint64::val_type); template <typename T> class octave_array_type_traits { public: typedef T element_type; }; #define OCTAVE_ARRAY_TYPE_TRAIT(T, ELT_T) \ template <> \ class \ octave_array_type_traits<T> \ { \ public: \ typedef ELT_T element_type; \ } OCTAVE_ARRAY_TYPE_TRAIT (charNDArray, char); OCTAVE_ARRAY_TYPE_TRAIT (boolNDArray, bool); OCTAVE_ARRAY_TYPE_TRAIT (int8NDArray, octave_int8); OCTAVE_ARRAY_TYPE_TRAIT (uint8NDArray, octave_uint8); OCTAVE_ARRAY_TYPE_TRAIT (int16NDArray, octave_int16); OCTAVE_ARRAY_TYPE_TRAIT (uint16NDArray, octave_uint16); OCTAVE_ARRAY_TYPE_TRAIT (int32NDArray, octave_int32); OCTAVE_ARRAY_TYPE_TRAIT (uint32NDArray, octave_uint32); OCTAVE_ARRAY_TYPE_TRAIT (int64NDArray, octave_int64); OCTAVE_ARRAY_TYPE_TRAIT (uint64NDArray, octave_uint64); OCTAVE_ARRAY_TYPE_TRAIT (NDArray, double); #endif /* ;; Local Variables: *** ;; mode: C++ *** ;; End: *** */