Mercurial > octave-nkf
view libinterp/octave-value/ov-intx.h @ 20530:bf6c4433ed5f
Clean up isa() function.
* ov-class.cc (Fisa): Remove not strictly necessary const modifiers on
variables. Use more meaningful variable names. Put direct test for
class name first in if tree since this is the most likely test to
succeed.
| author | Rik <rik@octave.org> |
|---|---|
| date | Tue, 22 Sep 2015 01:38:40 -0700 |
| parents | 4197fc428c7d |
| children |
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/* Copyright (C) 2004-2015 John W. Eaton Copyright (C) 2010 VZLU Prague This file is part of Octave. Octave is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. Octave is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Octave; see the file COPYING. If not, see <http://www.gnu.org/licenses/>. */ #include <cstdlib> #include <iosfwd> #include <string> #include "mx-base.h" #include "str-vec.h" #include "error.h" #include "mxarray.h" #include "oct-stream.h" #include "ov-base.h" #include "ov-base-int.h" #include "ov-typeinfo.h" #include "gripes.h" #include "ov-re-mat.h" #include "ov-scalar.h" class OCTINTERP_API OCTAVE_VALUE_INT_MATRIX_T : public octave_base_int_matrix<intNDArray<OCTAVE_INT_T> > { public: OCTAVE_VALUE_INT_MATRIX_T (void) : octave_base_int_matrix<intNDArray<OCTAVE_INT_T> > () { } OCTAVE_VALUE_INT_MATRIX_T (const intNDArray<OCTAVE_INT_T>& nda) : octave_base_int_matrix<intNDArray<OCTAVE_INT_T> > (nda) { } OCTAVE_VALUE_INT_MATRIX_T (const Array<OCTAVE_INT_T>& nda) : octave_base_int_matrix<intNDArray<OCTAVE_INT_T> > (intNDArray<OCTAVE_INT_T> (nda)) { } ~OCTAVE_VALUE_INT_MATRIX_T (void) { } octave_base_value *clone (void) const { return new OCTAVE_VALUE_INT_MATRIX_T (*this); } octave_base_value *empty_clone (void) const { return new OCTAVE_VALUE_INT_MATRIX_T (); } bool OCTAVE_TYPE_PREDICATE_FUNCTION (void) const { return true; } bool is_integer_type (void) const { return true; } builtin_type_t builtin_type (void) const { return OCTAVE_INT_BTYP; } public: int8NDArray int8_array_value (void) const { return int8NDArray (matrix); } int16NDArray int16_array_value (void) const { return int16NDArray (matrix); } int32NDArray int32_array_value (void) const { return int32NDArray (matrix); } int64NDArray int64_array_value (void) const { return int64NDArray (matrix); } uint8NDArray uint8_array_value (void) const { return uint8NDArray (matrix); } uint16NDArray uint16_array_value (void) const { return uint16NDArray (matrix); } uint32NDArray uint32_array_value (void) const { return uint32NDArray (matrix); } uint64NDArray uint64_array_value (void) const { return uint64NDArray (matrix); } double double_value (bool = false) const { double retval = lo_ieee_nan_value (); if (numel () > 0) { gripe_implicit_conversion ("Octave:array-to-scalar", type_name (), "real scalar"); retval = matrix(0).double_value (); } else gripe_invalid_conversion (type_name (), "real scalar"); return retval; } float float_value (bool = false) const { float retval = lo_ieee_float_nan_value (); if (numel () > 0) { gripe_implicit_conversion ("Octave:array-to-scalar", type_name (), "real scalar"); retval = matrix(0).float_value (); } else gripe_invalid_conversion (type_name (), "real scalar"); return retval; } double scalar_value (bool = false) const { return double_value (); } float float_scalar_value (bool = false) const { return float_value (); } Matrix matrix_value (bool = false) const { Matrix retval; dim_vector dv = dims (); if (dv.length () > 2) error ("invalid conversion of %s to Matrix", type_name ().c_str ()); else { retval = Matrix (dv(0), dv(1)); double *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).double_value (); } return retval; } FloatMatrix float_matrix_value (bool = false) const { FloatMatrix retval; dim_vector dv = dims (); if (dv.length () > 2) error ("invalid conversion of %s to FloatMatrix", type_name ().c_str ()); else { retval = FloatMatrix (dv(0), dv(1)); float *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).float_value (); } return retval; } ComplexMatrix complex_matrix_value (bool = false) const { ComplexMatrix retval; dim_vector dv = dims (); if (dv.length () > 2) error ("invalid conversion of %s to Matrix", type_name ().c_str ()); else { retval = ComplexMatrix (dv(0), dv(1)); Complex *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = Complex (matrix(i).double_value ()); } return retval; } FloatComplexMatrix float_complex_matrix_value (bool = false) const { FloatComplexMatrix retval; dim_vector dv = dims (); if (dv.length () > 2) error ("invalid conversion of %s to FloatMatrix", type_name ().c_str ()); else { retval = FloatComplexMatrix (dv(0), dv(1)); FloatComplex *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = FloatComplex (matrix(i).float_value ()); } return retval; } NDArray array_value (bool = false) const { NDArray retval (matrix.dims ()); double *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).double_value (); return retval; } FloatNDArray float_array_value (bool = false) const { FloatNDArray retval (matrix.dims ()); float *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).float_value (); return retval; } ComplexNDArray complex_array_value (bool = false) const { ComplexNDArray retval (matrix.dims ()); Complex *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = Complex (matrix(i).double_value ()); return retval; } FloatComplexNDArray float_complex_array_value (bool = false) const { FloatComplexNDArray retval (matrix.dims ()); FloatComplex *vec = retval.fortran_vec (); octave_idx_type nel = matrix.numel (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = FloatComplex (matrix(i).float_value ()); return retval; } boolNDArray bool_array_value (bool warn = false) const { boolNDArray retval (dims ()); octave_idx_type nel = numel (); if (warn && matrix.any_element_not_one_or_zero ()) gripe_logical_conversion (); bool *vec = retval.fortran_vec (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).bool_value (); return retval; } charNDArray char_array_value (bool = false) const { charNDArray retval (dims ()); octave_idx_type nel = numel (); char *vec = retval.fortran_vec (); for (octave_idx_type i = 0; i < nel; i++) vec[i] = matrix(i).char_value (); return retval; } // Use matrix_ref here to clear index cache. void increment (void) { matrix_ref () += OCTAVE_INT_T (1); } void decrement (void) { matrix_ref () -= OCTAVE_INT_T (1); } void changesign (void) { matrix_ref ().changesign (); } idx_vector index_vector (bool /* require_integers */ = false) const { return idx_cache ? *idx_cache : set_idx_cache (idx_vector (matrix)); } 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 { return os.write (matrix, block_size, output_type, skip, flt_fmt); } // Unsafe. This function exists to support the MEX interface. // You should not use it anywhere else. void *mex_get_data (void) const { return matrix.mex_get_data (); } mxArray *as_mxArray (void) const { mxArray *retval = new mxArray (OCTAVE_INT_MX_CLASS, dims (), mxREAL); OCTAVE_INT_T::val_type *pr = static_cast<OCTAVE_INT_T::val_type *> (retval->get_data ()); mwSize nel = numel (); const OCTAVE_INT_T *p = matrix.data (); for (mwIndex i = 0; i < nel; i++) pr[i] = p[i].value (); return retval; } octave_value map (unary_mapper_t umap) const { switch (umap) { case umap_abs: return matrix.abs (); case umap_signum: return matrix.signum (); case umap_ceil: case umap_conj: case umap_fix: case umap_floor: case umap_real: case umap_round: return matrix; case umap_imag: return intNDArray<OCTAVE_INT_T> (matrix.dims (), OCTAVE_INT_T ()); case umap_isnan: case umap_isna: case umap_isinf: return boolNDArray (matrix.dims (), false); case umap_finite: return boolNDArray (matrix.dims (), true); // Special cases for Matlab compatibility. case umap_xtolower: case umap_xtoupper: return matrix; default: { // FIXME: we should be able to do better than converting to // double here. octave_matrix m (array_value ()); return m.map (umap); } } } private: DECLARE_OV_TYPEID_FUNCTIONS_AND_DATA }; class OCTINTERP_API OCTAVE_VALUE_INT_SCALAR_T : public octave_base_int_scalar<OCTAVE_INT_T> { public: OCTAVE_VALUE_INT_SCALAR_T (void) : octave_base_int_scalar<OCTAVE_INT_T> () { } OCTAVE_VALUE_INT_SCALAR_T (const OCTAVE_INT_T& nda) : octave_base_int_scalar<OCTAVE_INT_T> (nda) { } ~OCTAVE_VALUE_INT_SCALAR_T (void) { } octave_base_value *clone (void) const { return new OCTAVE_VALUE_INT_SCALAR_T (*this); } octave_base_value *empty_clone (void) const { return new OCTAVE_VALUE_INT_MATRIX_T (); } octave_value do_index_op (const octave_value_list& idx, bool resize_ok = false) { // FIXME: this doesn't solve the problem of // // a = 1; a([1,1], [1,1], [1,1]) // // and similar constructions. Hmm... // FIXME: using this constructor avoids narrowing the // 1x1 matrix back to a scalar value. Need a better solution // to this problem. octave_value tmp (new OCTAVE_VALUE_INT_MATRIX_T (OCTAVE_VALUE_INT_NDARRAY_EXTRACTOR_FUNCTION ())); return tmp.do_index_op (idx, resize_ok); } bool OCTAVE_TYPE_PREDICATE_FUNCTION (void) const { return true; } bool is_integer_type (void) const { return true; } builtin_type_t builtin_type (void) const { return OCTAVE_INT_BTYP; } public: octave_int8 int8_scalar_value (void) const { return octave_int8 (scalar); } octave_int16 int16_scalar_value (void) const { return octave_int16 (scalar); } octave_int32 int32_scalar_value (void) const { return octave_int32 (scalar); } octave_int64 int64_scalar_value (void) const { return octave_int64 (scalar); } octave_uint8 uint8_scalar_value (void) const { return octave_uint8 (scalar); } octave_uint16 uint16_scalar_value (void) const { return octave_uint16 (scalar); } octave_uint32 uint32_scalar_value (void) const { return octave_uint32 (scalar); } octave_uint64 uint64_scalar_value (void) const { return octave_uint64 (scalar); } int8NDArray int8_array_value (void) const { return int8NDArray (dim_vector (1, 1), int8_scalar_value ()); } int16NDArray int16_array_value (void) const { return int16NDArray (dim_vector (1, 1), int16_scalar_value ()); } int32NDArray int32_array_value (void) const { return int32NDArray (dim_vector (1, 1), int32_scalar_value ()); } int64NDArray int64_array_value (void) const { return int64NDArray (dim_vector (1, 1), int64_scalar_value ()); } uint8NDArray uint8_array_value (void) const { return uint8NDArray (dim_vector (1, 1), uint8_scalar_value ()); } uint16NDArray uint16_array_value (void) const { return uint16NDArray (dim_vector (1, 1), uint16_scalar_value ()); } uint32NDArray uint32_array_value (void) const { return uint32NDArray (dim_vector (1, 1), uint32_scalar_value ()); } uint64NDArray uint64_array_value (void) const { return uint64NDArray (dim_vector (1, 1), uint64_scalar_value ()); } octave_value resize (const dim_vector& dv, bool fill = false) const { if (fill) { intNDArray<OCTAVE_INT_T> retval (dv, 0); if (dv.numel ()) retval(0) = scalar; return retval; } else { intNDArray<OCTAVE_INT_T> retval (dv); if (dv.numel ()) retval(0) = scalar; return retval; } } double double_value (bool = false) const { return scalar.double_value (); } float float_value (bool = false) const { return scalar.float_value (); } double scalar_value (bool = false) const { return scalar.double_value (); } float float_scalar_value (bool = false) const { return scalar.float_value (); } Matrix matrix_value (bool = false) const { Matrix retval (1, 1); retval(0,0) = scalar.double_value (); return retval; } FloatMatrix float_matrix_value (bool = false) const { FloatMatrix retval (1, 1); retval(0,0) = scalar.float_value (); return retval; } ComplexMatrix complex_matrix_value (bool = false) const { ComplexMatrix retval (1, 1); retval(0,0) = Complex (scalar.double_value ()); return retval; } FloatComplexMatrix float_complex_matrix_value (bool = false) const { FloatComplexMatrix retval (1, 1); retval(0,0) = FloatComplex (scalar.float_value ()); return retval; } NDArray array_value (bool = false) const { NDArray retval (dim_vector (1, 1)); retval(0) = scalar.double_value (); return retval; } FloatNDArray float_array_value (bool = false) const { FloatNDArray retval (dim_vector (1, 1)); retval(0) = scalar.float_value (); return retval; } ComplexNDArray complex_array_value (bool = false) const { ComplexNDArray retval (dim_vector (1, 1)); retval(0) = FloatComplex (scalar.double_value ()); return retval; } FloatComplexNDArray float_complex_array_value (bool = false) const { FloatComplexNDArray retval (dim_vector (1, 1)); retval(0) = FloatComplex (scalar.float_value ()); return retval; } bool bool_value (bool warn = false) const { if (warn && scalar != 0.0 && scalar != 1.0) gripe_logical_conversion (); return scalar.bool_value (); } boolNDArray bool_array_value (bool warn = false) const { boolNDArray retval (dim_vector (1, 1)); if (warn && scalar != 0.0 && scalar != 1.0) gripe_logical_conversion (); retval(0) = scalar.bool_value (); return retval; } charNDArray char_array_value (bool = false) const { charNDArray retval (dim_vector (1, 1)); retval(0) = scalar.char_value (); return retval; } void increment (void) { scalar += OCTAVE_INT_T (1); } void decrement (void) { scalar -= OCTAVE_INT_T (1); } idx_vector index_vector (bool /* require_integers */ = false) const { return idx_vector (scalar); } int write (octave_stream& os, int block_size, oct_data_conv::data_type output_type, octave_idx_type skip, oct_mach_info::float_format flt_fmt) const { return os.write (OCTAVE_VALUE_INT_NDARRAY_EXTRACTOR_FUNCTION (), block_size, output_type, skip, flt_fmt); } // Unsafe. This function exists to support the MEX interface. // You should not use it anywhere else. void *mex_get_data (void) const { return scalar.mex_get_data (); } mxArray *as_mxArray (void) const { mxArray *retval = new mxArray (OCTAVE_INT_MX_CLASS, 1, 1, mxREAL); OCTAVE_INT_T::val_type *pr = static_cast<OCTAVE_INT_T::val_type *> (retval->get_data ()); pr[0] = scalar.value (); return retval; } octave_value map (unary_mapper_t umap) const { switch (umap) { case umap_abs: return scalar.abs (); case umap_signum: return scalar.signum (); case umap_ceil: case umap_conj: case umap_fix: case umap_floor: case umap_real: case umap_round: return scalar; case umap_imag: return OCTAVE_INT_T (); case umap_isnan: case umap_isna: case umap_isinf: return false; case umap_finite: return true; // Special cases for Matlab compatibility. case umap_xtolower: case umap_xtoupper: return scalar; default: { octave_scalar m (scalar_value ()); return m.map (umap); } } } private: DECLARE_OV_TYPEID_FUNCTIONS_AND_DATA };