The C function (C static library) created by codegen takes an input argument of type const emxArray_uint32_T and return values of type emxArray_stru
If you've used C++, the emxArray
data types are like generated C equivalents of std::vector
. Namely, this is how the generated code represents dynamically allocated arrays. They store data and size pointers as well as a few other details.
If you look in the directory where you generated code you should find a file named <functionName>_emxAPI.h
. This file declares some utility functions which make constructing and destroying emxArray
values simpler. Using them to create emxArray
values ensures that all of the fields are properly initialized and insulates your code from any possible changes to the emxArray
type.
In an example I made which takes an array of uint32
values and also returns such an array, I see the following functions:
extern emxArray_uint32_T *emxCreateWrapperND_uint32_T(unsigned int *data, int
numDimensions, int *size);
extern emxArray_uint32_T *emxCreateWrapper_uint32_T(unsigned int *data, int rows,
int cols);
extern emxArray_uint32_T *emxCreateND_uint32_T(int numDimensions, int *size);
extern emxArray_uint32_T *emxCreate_uint32_T(int rows, int cols);
extern void emxDestroyArray_uint32_T(emxArray_uint32_T *emxArray);
The first four functions can be used to create emxArray
values in different situations.
The first pair, i.e. emxCreateWrapper_uint32_T, emxCreateWrapperND_uint32_T
, can be used to create a uint32
emxArray
with the specified number of dimensions and sizes from existing data. So if you already have the input data allocated in some memory, these functions wrap that data up into an emxArray
of the specified size without allocating extra memory for your data.
/* Create a 10-by-10 C array of uint32 values and wrap an emxArray around it */
uint32_T x[100];
emxArray *pEmx = NULL;
int k = 0;
for (k = 0; k < 100; k++) {
x[k] = (uint32_T) k;
}
pEmx = emxCreateWrapper_uint32_T(x, 10, 10);
/* Use pEmx here*/
/* Deallocate any memory allocated in pEmx. */
/* This DOES NOT free pEmx->data because the "wrapper" function was used */
emxDestroyArray_uint32_T(pEmx);
The second pair, i.e. emxCreate_uint32_T, emxCreateND_uint32_T
, also create emxArray
values. However, they also heap allocate storage for the data
field of the emxArray
. This memory will be large enough to hold the number of elements specified in their respective size arguments After calling these, you will need to populate the data stored in the data
field of the returned emxArray
struct:
/* Allocate a 10-by-10 uint32 emxArray and fill the values */
int k = 0;
emxArray *pEmx = emxCreate_uint32_T(10, 10);
for (k = 0; k < 100; ++k) {
pEmx->data[k] = (uint32_T) k;
}
/* Use pEmx here*/
/* Deallocate any memory allocated in pEmx. */
/* This DOES free pEmx->data */
emxDestroyArray_uint32_T(pEmx);
The last, emxDestroyArray_uint32_T
, will be used to destroy the array and deallocate any memory allocated by the previous methods.
Finally, to capture your output, you could use emxCreate_struct_T
or emxCreateND_struct_T
to create an empty emxArray
of struct_T
values with the proper number of dimensions by passing 0 for one or more sizes where appropriate. The generated code will allocate enough memory to hold the resulting data in your output emxArray
at runtime. You can then check the size
field of this output emxArray
to view the sizes of the dimensions of the data
field and extract the data as you wish.
The documentation for using emxArray
arguments is available here.
You need to use emxArray_uint32_T and emxArray_struct_T. All of the MATLAB Coder defined datatypes that the code uses (and you need to use) are defined in the YourLibName_types.h header file.