Octave supports a number of different array and matrix classes, the majority of
which are based on the Array
class. The exception are the sparse matrix
types discussed separately below. There are three basic matrix types:
Matrix
A double precision matrix class defined in dMatrix.h
ComplexMatrix
A complex matrix class defined in CMatrix.h
BoolMatrix
A boolean matrix class defined in boolMatrix.h
These are the basic two-dimensional matrix types of Octave. In addition there are a number of multi-dimensional array types including
NDArray
A double precision array class defined in dNDArray.h
ComplexNDarray
A complex array class defined in CNDArray.h
boolNDArray
A boolean array class defined in boolNDArray.h
int8NDArray
int16NDArray
int32NDArray
int64NDArray
8, 16, 32, and 64-bit signed array classes defined in int8NDArray.h, int16NDArray.h, etc.
uint8NDArray
uint16NDArray
uint32NDArray
uint64NDArray
8, 16, 32, and 64-bit unsigned array classes defined in uint8NDArray.h, uint16NDArray.h, etc.
There are several basic ways of constructing matrices or multi-dimensional
arrays. Using the class Matrix
as an example one can
Matrix a;
This can be used for all matrix and array types.
size
. For example:
dim_vector dv (2, 3); // 2 rows, 3 columns Matrix a (dv);
This can be used for all matrix and array types.
Matrix a (2, 2)
This constructor can only be used with matrix types.
These types all share a number of basic methods and operators. Many bear a resemblance to functions that exist in the interpreter. A selection of useful methods include
T&
operator () (octave_idx_type)
¶T&
elem (octave_idx_type)
¶The ()
operator or elem
method allow the values of the matrix or
array to be read or set. These methods take a single argument, which is of
type octave_idx_type
, that is the index into the matrix or array.
Additionally, the matrix type allows two argument versions of the ()
operator and elem
method, giving the row and column index of the value
to get or set.
Note that these functions do significant error checking and so in some
circumstances the user might prefer to access the data of the array or matrix
directly through the fortran_vec
method discussed below.
octave_idx_type
numel (void) const
¶The total number of elements in the matrix or array.
size_t
byte_size (void) const
¶The number of bytes used to store the matrix or array.
dim_vector
dims (void) const
¶The dimensions of the matrix or array in value of type dim_vector
.
int
ndims (void) const
¶The number of dimensions of the matrix or array. Matrices are always 2-D, but arrays can be N-dimensional.
void
resize (const dim_vector&)
¶void
resize (nrows, ncols)
¶A method taking either an argument of type dim_vector
, or, in the case
of a matrix, two arguments of type octave_idx_type
defining the number
of rows and columns in the matrix.
T*
fortran_vec (void)
¶This method returns a pointer to the underlying data of the matrix or array so that it can be manipulated directly, either within Octave or by an external library.
Operators such as +
, -
, or *
can be used on the majority
of the matrix and array types. In addition there are a number of methods that
are of interest only for matrices such as transpose
, hermitian
,
solve
, etc.
The typical way to extract a matrix or array from the input arguments of
DEFUN_DLD
function is as follows
#include <octave/oct.h> DEFUN_DLD (addtwomatrices, args, , "Add A to B") { if (args.length () != 2) print_usage (); NDArray A = args(0).array_value (); NDArray B = args(1).array_value (); return octave_value (A + B); }
To avoid segmentation faults causing Octave to abort, this function explicitly
checks that there are sufficient arguments available before accessing these
arguments. It then obtains two multi-dimensional arrays of type NDArray
and adds these together. Note that the array_value
method is called
without using the is_matrix_type
method. If an error occurs when
attempting to extract the value, Octave will print a message and throw an
exception. The reason to prefer this coding structure is that the arguments
might be a type which is not an NDArray
, but for which it would make
sense to convert them to one. The array_value
method allows this
conversion to be performed transparently when possible. If you need to catch
errors like this, and perform some kind of cleanup or other operation, you can
catch the octave_execution_error
exception.
A + B
, operating on two NDArray
objects returns an
NDArray
, which is cast to an octave_value
on the return from the
function. An example of the use of this demonstration function is
addtwomatrices (ones (2, 2), eye (2, 2)) ⇒ 2 1 1 2
A list of the basic Matrix
and Array
types, the methods to
extract these from an octave_value
, and the associated header file is
listed below.
Type | Function | Source Code |
---|---|---|
RowVector | row_vector_value | dRowVector.h |
ComplexRowVector | complex_row_vector_value | CRowVector.h |
ColumnVector | column_vector_value | dColVector.h |
ComplexColumnVector | complex_column_vector_value | CColVector.h |
Matrix | matrix_value | dMatrix.h |
ComplexMatrix | complex_matrix_value | CMatrix.h |
boolMatrix | bool_matrix_value | boolMatrix.h |
charMatrix | char_matrix_value | chMatrix.h |
NDArray | array_value | dNDArray.h |
ComplexNDArray | complex_array_value | CNDArray.h |
boolNDArray | bool_array_value | boolNDArray.h |
charNDArray | char_array_value | charNDArray.h |
int8NDArray | int8_array_value | int8NDArray.h |
int16NDArray | int16_array_value | int16NDArray.h |
int32NDArray | int32_array_value | int32NDArray.h |
int64NDArray | int64_array_value | int64NDArray.h |
uint8NDArray | uint8_array_value | uint8NDArray.h |
uint16NDArray | uint16_array_value | uint16NDArray.h |
uint32NDArray | uint32_array_value | uint32NDArray.h |
uint64NDArray | uint64_array_value | uint64NDArray.h |