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The MATLAB Array
The MATLAB® language works with a single object type: the MATLAB array. All MATLAB variables (including scalars, vectors, matrices, character arrays, cell arrays, structures, and objects) are stored as MATLAB arrays. In C/C++, the MATLAB array is declared to be of type mxArray. ThemxArray structure contains the following information about the array:
- Its type
- Its dimensions
- The data associated with this array
- If numeric, whether the variable is real or complex
- If sparse, its indices and nonzero maximum elements
- If a structure or an object, the number of fields and field names
To access the mxArray structure, use functions in the C or Fortran Matrix APIs. These functions allow you to create, read, and query information about the MATLAB data in your MEX files. Matrix APIs use the mwSize and mwIndex types to avoid portability issues and allow MEX source files to be compiled correctly on all systems.
Lifecycle of mxArray
Like MATLAB functions, a MEX-file gateway routine passes MATLAB variables by reference. However, these arguments are C pointers. A_pointer_ to a variable is the_address_ (location in memory) of the variable. MATLAB functions handle data storage for you automatically. When passing data to a MEX-file, you use pointers, which follow specific rules for accessing and manipulating variables. For information about working with pointers, refer to a programming reference, such as The C Programming Language by Kernighan, B. W., and D. M. Ritchie.
Note
Since variables use memory, you need to understand how your MEX-file creates an mxArray and your responsibility for releasing (freeing) the memory. This is important to prevent memory leaks. The lifecycle of anmxArray—and the rules for managing memory—depends on whether it is an input argument, output argument, or local variable. The function you call to deallocate anmxArray depends on the function you used to create it. For more information, look up the functions to create arrays in the C Matrix API.
Input Argument prhs
An mxArray passed to a MEX-file through theprhs input parameter exists outside the scope of the MEX-file. Do not free memory for any mxArray in theprhs parameter. Also, prhs variables are read-only; do not modify them in your MEX-file.
Output Argument plhs
If you create an mxArray (allocate memory and create data) for an output argument, the memory and data exist beyond the scope of the MEX-file. Do not free memory on an mxArray returned in theplhs output parameter.
Local Variable
You allocate memory whenever you use an mxCreate* function to create an mxArray or when you call themxCalloc and associated functions. After observing the rules for handling input and output arguments, the MEX-file should destroy temporary arrays and free dynamically allocated memory. To deallocate memory, use either mxDestroyArray or mxFree. For information about which function to use, see MX Matrix Library.
Data Storage
MATLAB stores data in a column-major (column-wise) numbering scheme, which is how Fortran stores matrices. MATLAB uses this convention because it was originally written in Fortran. MATLAB internally stores data elements from the first column first, then data elements from the second column second, and so on, through the last column.
For example, given the matrix:
a = ['house'; 'floor'; 'porch']
its dimensions are:
and its data is stored as:
If a matrix is N-dimensional, MATLAB represents the data in N-major order. For example, consider a three-dimensional array having dimensions4-by-2-by-3. Although you can visualize the data as:
MATLAB internally represents the data for this three-dimensional array in this order:
| A | B | C | D | E | F | G | H | I | J | K | L | M | N | O | P | Q | R | S | T | U | V | W | X |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | 20 | 21 | 22 | 23 |
The mxCalcSingleSubscript function creates the offset from the first element of an array to the desired element, using N-dimensional subscripting.
MATLAB Data Types
Complex Double-Precision Matrices
The most common data type in MATLAB is the complex double-precision, nonsparse matrix. These matrices are of type double and have dimensionsm-by-n, where m is the number of rows and n is the number of columns. The data is stored as a vector of interleaved, double-precision numbers where the real and imaginary parts are stored next to each other. The pointer to this data is referred to as pa (pointer to array). To test for a noncomplex matrix, call mxIsComplex.
Before MATLAB Version 9.4 (R2018a), MATLAB used a separate storage representation. The data is stored as two vectors of double-precision numbers—one contains the real data and one contains the imaginary data. The pointers to this data are referred to as pr (pointer to real data) and pi (pointer to imaginary data), respectively. A noncomplex matrix is one whose pi isNULL. However, to test for a noncomplex matrix, callmxIsComplex.
Other Numeric Matrices
MATLAB supports single-precision floating-point and 8-, 16-, 32-, and 64-bit integers, both signed and unsigned.
Logical Matrices
The logical data type represents a logical true orfalse state using the numbers 1 and0, respectively. Certain MATLAB functions and operators return logical 1 or logical 0 to indicate whether a certain condition was found to be true or not. For example, the statement (5 * 10) > 40 returns a logical 1 value.
MATLAB char Arrays
MATLABchar arrays store data as unsigned 16-bit integers. To convert a MATLABchar array to a C-style string, call mxArrayToString. To convert a C-style string to a char array, call mxCreateString.
Cell Arrays
Cell arrays are a collection of MATLAB arrays where each mxArray is referred to as a cell. Cell arrays allow MATLAB arrays of different types to be stored together. Cell arrays are stored in a similar manner to numeric matrices, except the data portion contains a single vector of pointers to mxArrays. Members of this vector are called cells. Each cell can be of any supported data type, even another cell array.
Structures
A 1-by-1 structure is stored in the same manner as a 1-by-n cell array wheren is the number of fields in the structure. Members of the data vector are called fields. Each field is associated with a name stored in the mxArray.
Objects
Objects are stored and accessed the same way as structures. In MATLAB, objects are named structures with registered methods. Outside MATLAB, an object is a structure that contains storage for an additional class name that identifies the name of the object.
Multidimensional Arrays
MATLAB arrays of any type can be multidimensional. A vector of integers is stored where each element is the size of the corresponding dimension. The storage method of the data is the same as for matrices.
Empty Arrays
MATLAB arrays of any type can be empty. An emptymxArray is one with at least one dimension equal to zero. For example, a double-precision mxArray of typedouble, where m andn equal 0 and pa isNULL, is an empty array.
Sparse Matrices
Sparse matrices have a different storage convention from full matrices in MATLAB. The parameter pa is still an array of double-precision numbers or logical values, but this array contains only nonzero data elements.
There are three additional parameters: nzmax,ir, and jc. Use the mwSize and mwIndex types when declaring variables for these parameters.
nzmaxis an integer that contains the length ofirandpa. It is the maximum number of nonzero elements in the sparse matrix.irpoints to an integer array of lengthnzmaxcontaining the row indices of the corresponding elements inpa.jcpoints to an integer array of lengthn+1, wherenis the number of columns in the sparse matrix. In C, the first element of anmxArrayhas an index of 0. Thejcarray contains column index information. If thejth column of the sparse matrix has any nonzero elements,jc[j]is the index intoirandpaof the first nonzero element in thejth column. Indexjc[j+1] - 1contains the last nonzero element in that column. For thejth column of the sparse matrix,jc[j]is the total number of nonzero elements in all preceding columns. The last element of thejcarray,jc[n], is equal tonnz, the number of nonzero elements in the entire sparse matrix. Ifnnzis less thannzmax, more nonzero entries can be inserted into the array without allocating more storage.
Do not try to reshape a sparse array using themxSetDimensions function.
Using Data Types
You can write source MEX files, MAT-file applications, and engine applications in C/C++ that accept any class or data type supported by MATLAB (see Data Types). In Fortran, only the creation of double-precision n-by-m arrays and strings are supported. You use binary C/C++ and Fortran MEX files like MATLAB functions.
Caution
MATLAB does not check the validity of MATLAB data structures created in C/C++ or Fortran using one of the Matrix Library create functions (for example,mxCreateStructArray). Using invalid syntax to create a MATLAB data structure can result in unexpected behavior in your C/C++ or Fortran program.
Declaring Data Structures
To handle MATLAB arrays, use type mxArray. The following statement declares an mxArray namedmyData:
To define the values of myData, use one of themxCreate* functions. Some useful array creation routines are mxCreateNumericArray,mxCreateCellArray, andmxCreateCharArray. For example, the following statement allocates an m-by-1 floating-pointmxArray initialized to 0:
myData = mxCreateDoubleMatrix(m, 1, mxREAL);
C/C++ programmers should note that data in a MATLAB array is in column-major order. (For an illustration, see Data Storage.) Use the MATLABmxGet* array access routines to read data from anmxArray.
Manipulating Data
The mxGet* array access routines get references to the data in an mxArray. Use these routines to modify data in your MEX file. Each function provides access to specific information in themxArray. Some useful functions aremxGetDoubles, mxGetComplexDoubles,mxGetM, and mxGetString. Many of these functions have corresponding mxSet* routines to allow you to modify values in the array.
The following statements read the input prhs[0] into a C-style string buf.
char *buf; int buflen; int status; buflen = mxGetN(prhs[0])*sizeof(mxChar)+1; buf = mxMalloc(buflen); status = mxGetString(prhs[0], buf, buflen);
explore Example
There is an example source MEX file included with MATLAB, called explore.c, that identifies the data type of an input variable. The source code for this example is in_matlabroot_/extern/examples/mex, where matlabroot represents the top-level folder where MATLAB is installed on your system.
Note
In platform-independent discussions that refer to folder paths, this documentation uses the UNIX® convention. For example, a general reference to themex folder is_matlabroot_/extern/examples/mex.
To build the example MEX file, first copy the file to a writable folder on your path.
copyfile(fullfile(matlabroot,'extern','examples','mex','explore.c'),'.','f')
Use the mex command to build the MEX file.
Type:
Name: prhs[0] Dimensions: 1x1 Class Name: double
(1,1) = 2explore accepts any data type. Try usingexplore with these examples:
explore([1 2 3 4 5]) explore 1 2 3 4 5 explore({1 2 3 4 5}) explore(int8([1 2 3 4 5])) explore {1 2 3 4 5} explore(sparse(eye(5))) explore(struct('name', 'Joe Jones', 'ext', 7332)) explore(1, 2, 3, 4, 5) explore(complex(3,4))