Scilab is a scientific software package for numerical computations providing a powerful open computing environment for engineering and scientific applications that is mostly compatible with MATLAB. More information can be found at www.scilab.org.
This chapter explains how to use SWIG for Scilab. After this introduction, you should be able to generate with SWIG a Scilab external module from a C/C++ library.
SWIG for Scilab supports Linux. Other operating sytems haven't been tested.
Scilab is supported from version 5.3.3 onwards. The forthcoming version 6, as of January 2015, is also supported.
SWIG for Scilab supports C language. C++ is partially supported. See A basic tour of C/C++ wrapping for further details.
Let's see how to use SWIG for Scilab on a small example.
In this example we bind from C a function and a global variable into Scilab. The SWIG interface (stored in a file named example.i), is the following:
%module example %inline %{ double Foo = 3.0; int fact(int n) { if (n < 0) { return 0; } else if (n == 0) { return 1; } else { return n * fact(n-1); } } %}
Note: a code in an %inline section is both parsed and wrapped by SWIG, and inserted as is in the wrapper source file.
The module is generated using the swig executable and its -scilab option.
$ swig -scilab example.i
This command generates two files:
Note: if the following error is returned:
:1: Error: Unable to find 'swig.swg' :3: Error: Unable to find 'scilab.swg'
it may be because the SWIG library is not found. Check the SWIG_LIB environment variable or your SWIG installation.
Note: SWIG for Scilab can work in two modes related to the way the module is built, see the Building modes section for details. This example uses the builder mode.
The swig executable has several other command line options you can use. See Scilab command line options for further details.
To be loaded in Scilab, the wrapper has to be built into a dynamic module (or shared library).
The commands to compile and link the wrapper (with gcc) into the shared library libexample.so are:
$ gcc -fPIC -c -I/usr/local/include/scilab example_wrap.c $ gcc -shared example_wrap.o -o libexample.so
Note: we supposed in this example that the path to the Scilab include directory is /usr/local/include/scilab (which is the case in a Debian environment), this should be changed for another environment.
Loading a module is done by running the loader script in Scilab:
--> exec loader.sce
Scilab should output the following messages:
Shared archive loaded. Link done.
which means that Scilab has successfully loaded the shared library. The module functions and other symbols are now available in Scilab.
In Scilab, the function fact() is simply called as following:
--> fact(5) ans = 120.
For the Foo global variable, the accessors need to be used:
--> Foo_get ans = 3. --> Foo_set(4); --> Foo_get ans = 4.
Note: for conciseness, we assume in the subsequent Scilab code examples that the modules have been beforehand built and loaded in Scilab.
The following table lists the Scilab specific command line options in addition to the generic SWIG options:
-builder | Generate the Scilab builder script |
-buildercflags <cflags> | Add <cflags> to the builder compiler flags |
-builderldflags <ldflags> | Add <ldlags> to the builder linker flags |
-buildersources <files> | Add the (comma separated) files <files> to the builder sources |
-builderverbositylevel <level> | Set the build verbosity level to <level> (default 0: off, 2: high) |
-builderflagscript <file> | Use the Scilab script <file> to configure the compiler and linker flags |
-gatewayxml <gateway_id> | Generate the gateway XML with the given <gateway_id> |
These options can be displayed with:
$ swig -scilab -help
SWIG for Scilab provides only a low-level C interface for Scilab (see Scripting Languages for the general approach to wrapping). This means that functions, structs, classes, variables, etc... are interfaced through C functions. These C functions are mapped as Scilab functions. There are a few exceptions, such as constants and enumerations, which can be wrapped directly as Scilab variables.
In Scilab 5.x, identifier names are composed of 24 characters maximum (this limitation should disappear from Scilab 6.0 onwards).
Thus long function or variable names may be truncated and this can cause ambiguities.
This happens especially when wrapping structs/classes, for which the wrapped function name is composed of the struct/class name and field names. In these cases, the %rename directive can be used to choose a different Scilab name.
Functions are wrapped as new Scilab built-in functions. For example:
%module example %inline %{ int fact(int n) { if (n > 1) return n * fact(n - 1); else return 1; } %}
creates a built-in function fact(n) in Scilab:
--> fact(4) ans = 24.
In the above example, the function parameter is a primitive type and is marshalled by value. So this function is wrapped without any additional customization. Argument values are converted between C types and Scilab types through type mappings. There are several default type mappings for primitive and complex types, described later in the Scilab typemaps section.
When a parameter is not passed by value, such as a pointer or reference, SWIG does not know if it is an input, output (or both) parameter. The INPUT, OUTPUT, INOUT typemaps defined in the typemaps.i library can be used to specify this.
Let's see this on two simple functions: sub() which has an output parameter, and inc(), which as input/output parameter:
%module example %include <typemaps.i> extern void sub(int *INPUT, int *INPUT, int *OUTPUT); extern void inc(int *INOUT, int *INPUT); %{ void sub(int *x, int *y, int *result) { *result = *x - *y; } void inc(int *x, int *delta) { *x = *x + *delta; } %}
In Scilab, parameters are passed by value. The output (and inout) parameters are returned as the result of the functions:
--> sub(5, 3) ans = 2. --> inc(4, 3) ans = 7.
A C function can have several output parameters. They can all be returned as results of the wrapped function as Scilab supports multiple return values from a function when using the typemaps.i library. If the C function itself returns a result, this is returned first before the parameter outputs.
The example below shows this for a C function returning 2 values and a result:
%module example %include <typemaps.i> int divide(int n, int d, int *OUTPUT, int *OUTPUT); %{ int divide(int n, int d, int q*, int *r) { if (d != 0) { *q = n / d; *r = n % d; return 1; } else { return 0; } } %}
--> [ret, q, r] = divide(20, 6) r = 2. q = 3. ret = 1.
Global variables are manipulated through generated accessor functions. For example, for a given Foo global variable, SWIG actually generates two functions: Foo_get() to get the value of Foo, and Foo_set() to set the value. These functions are used as following:
--> exec loader.sce; --> c = Foo_get(); --> Foo_set(4); --> c c = 3. --> Foo_get() ans = 4.
It works for variables of primitive type, but also for non-primitive types: arrays, and structs/classes which are described later. For now, an example with two global primitive arrays x and y is shown:
%module example %inline %{ int x[10]; double y[7]; void initArrays() { int i; for (i = 0; i < 10; i++) x[i] = 1; for (i = 0; i < 7; i++) y[i] = 1.0f; } %}
It works the same:
--> exec loader.sce --> initArrays(); --> x_get() ans = 1. 1. 1. 1. 1. 1. 1. 1. 1. 1. --> y_set([0:6] / 10); --> y_get() ans = 0. 0.1 0.2 0.3 0.4 0.5 0.6
There is not any constant in Scilab. By default, C/C++ constants are wrapped as getter functions. For example, for the following constants:
%module example #define ICONST 42 #define FCONST 2.1828 #define CCONST 'x' #define CCONST2 '\n' #define SCONST "Hello World" #define SCONST2 "\"Hello World\""
the following getter functions are generated:
--> exec loader.sce; --> ICONST_get(); ans = 42. --> FCONST_get(); ans = 2.1828 --> CCONST_get(); ans = x --> CCONST2_get(); ans = --> SCONST_get(); ans = Hello World --> SCONST2_get(); ans = "Hello World" --> EXPR_get(); ans = 48.5484 --> iconst_get(); ans = 37. --> fconst_get(); ans = 3.14
There is another mode in which constants are wrapped as Scilab variables. The variables are easier to use than functions, but the drawback is that variables are not constant and so can be modified.
This mode can be enabled/disabled at any time in the interface file with %scilabconst(), which works like all the other %feature directives. Use the argument value "1" to enable and "0" to disable this mode. For example in this mode the previous constants:
%module example %scilabconst(1); #define ICONST 42 #define FCONST 2.1828 #define CCONST 'x' #define CCONST2 '\n' #define SCONST "Hello World" #define SCONST2 "\"Hello World\""
are mapped to Scilab variables, with the same name:
--> exec loader.sce; --> ICONST ans = 42 --> FCONST ans = 2.1828 --> CCONST ans = x --> CCONST2 ans = --> SCONST ans = Hello World --> SCONST2 ans = "Hello World" --> EXPR ans = 48.5484 --> iconst ans = 37 --> fconst ans = 3.14
The wrapping of enums is the same as for constants. By default, enums are wrapped as getter functions. For example, with the following enumeration:
%module example typedef enum { RED, BLUE, GREEN } color;
a getter function will be generated for each value of the enumeration:
--> exec loader.sce; --> RED_get() ans = 0. --> BLUE_get() ans = 1. --> GREEN_get() ans = 2.
The %scilabconst() feature is also available for enumerations:
%module example %scilabconst(1) color; typedef enum { RED, BLUE, GREEN } color;
--> exec loader.sce; --> RED ans = 0. --> BLUE ans = 1. --> GREEN ans = 2.
Pointers are supported by SWIG. A pointer can be returned from a wrapped C/C++ function, stored in a Scilab variable, and used in input argument of another C/C++ function.
Also, thanks to the SWIG runtime which stores informations about types, pointer types are tracked between exchanges Scilab and the native code. Indeed pointer types are stored alongside the pointer adress.
A pointer is mapped to a Scilab structure (tlist), which contains as fields the pointer address and the pointer type (in fact a pointer to the type information structure in the SWIG runtime).
Why a native pointer is not mapped to a Scilab pointer (type name: "pointer", type ID: 128) ? The big advantage of mapping to a tlist is that it exposes a new type for the pointer in Scilab, type which can be acessed in Scilab with the typeof function, and manipulated using the overloading mechanism.
Notes:
Following is an example of the wrapping of the C FILE* pointer:
%module example %{ #include <stdio.h> %} FILE *fopen(const char *filename, const char *mode); int fputs(const char *, FILE *); int fclose(FILE *);
These functions can be used the same way as in C from Scilab:
--> example_Init(); --> f = fopen("junk", "w"); --> typeof(f) ans = _p_FILE --> fputs("Hello World", f); --> fclose(f);
Note: the type name _p_FILE which means "pointer to FILE".
The user of a pointer is responsible for freeing it or, like in the example, closing any resources associated with it (just as is required in a C program).
As a scripting language, Scilab does not provide functions to manipulate pointers. However, in some cases it can be useful, such as for testing or debugging.
SWIG comes with two pointer utility functions:
Note: a pointer created by SWIG_ptr() does not have any type and is mapped as a Scilab pointer.
Following we use the utility functions on the previous example:
--> f = fopen("junk", "w"); --> fputs("Hello", f); --> addr = SWIG_this(f) ans = 8219088. --> p = SWIG_ptr(addr); --> typeof(p) ans = pointer --> fputs(" World", p); --> fclose(f);
Using the previous SWIG_this() and SWIG_ptr(), it is possible to create and check null pointers:
--> p = SWIG_ptr(0); --> SWIG_this(p) == 0 ans = T
Structs exist in Scilab, but C structs are not (at least in this version of SWIG) mapped to Scilab structs. A C structure is wrapped through low-level accessor functions, i.e. functions that give access to the member variables of this structure. In Scilab, a structure is manipulated through a pointer which is passed as an argument to the accessor functions.
Let's see it on an example of a struct with two members:
%module example %inline %{ typedef struct { int x; int arr[4]; } Foo; %}
Several functions are generated:
Usage example:
--> f = new_Foo(); --> Foo_x_set(f, 100); --> Foo_x_get(f) ans = 100. --> Foo_arr_set(f, [0:3]); --> Foo_arr_get(f) ans = 0. 1. 2. 3. --> delete_Foo(f);
Members of a structure that are also structures are also accepted and wrapped as a pointer:
%module example %inline %{ typedef struct { int x; } Bar; typedef struct { Bar b; } Foo; %}
--> b = new_Bar(); --> Bar_x_set(b, 20.); --> f = new_Foo(); --> Foo_b_set(f, b); --> b2 = Foo_b_get(f); --> Bar_x_get(b2); ans = 20.
Note: the pointer to the struct works as described in Pointers. For example, the type of the struct pointer can be get with typeof, as following:
--> example_Init(); --> b = new_Bar(); --> typeof(b) ans = _p_Bar --> delete_Bar(b);
Classes do not exist in Scilab. The classes are wrapped the same way as structs. Low-level accessor functions are generated for class members. Also, constructor and destructor functions are generated to create and destroy an instance of the class.
For example, the following class:
%module example %inline %{ class Point { public: int x, y; Point(int _x, int _y) : x(_x), y(_y) {} double distance(const Point& rhs) { return sqrt(pow(x-rhs.x, 2) + pow(y-rhs.y, 2)); } void set(int _x, int _y) { x=_x; y=_y; } }; %}
can be used in Scilab like this:
--> p1 = Point_new(3, 5); --> p2 = Point_new(1, 2); --> p1.distance(p2) ans = 3.6056 --> delete_Point(p1); --> delete_Point(p2);
Note: like structs, class pointers are mapped as described in Pointers. Let's give an example which shows that each class pointer type is a new type in Scilab that can be used for example (through overloading) to implement a custom print for the Point class:
--> function %_p_Point_p(p) --> mprintf('[%d, %d]\n', Point_x_get(p), Point_y_get(p)); --> endfunction --> example_Init(); --> p = new_Point(1, 2) p = [1, 2] --> delete_Point(p);
Inheritance is supported. SWIG knows the inheritance relationship between classes.
A function is only generated for the class in which it is actually declared. But if one of its parameters is a class, any instance of a derived class is accepted as the argument.
This mechanism also applies for accessor functions: they are generated only in the class in which they are defined. But any instance of a derived class can be used as the argument to these accessor functions.
For example, let's take a base class Shape and two derived classes Circle and Square:
%module example %inline %{ class Shape { public: double x, y; void set_location(double _x, double _y) { x = _x; y = _y; } virtual double get_perimeter() { return 0; }; }; class Circle : public Shape { public: int radius; Circle(int _radius): radius(_radius) {}; virtual double get_perimeter() { return 6.28 * radius; } }; class Square : public Shape { public: int size; Square(int _size): size(_size) {}; virtual double get_perimeter() { return 4 * size; } }; %}
To set the location of the Circle, we have to use the function set_location() of the parent Shape. But we can use either use the get_perimeter() function of the parent class or the derived class:
--> c = new_Circle(3); --> Shape_set_location(c, 2, 3); --> Shape_x_get(c) ans = 2. --> Circle_get_perimeter(c) ans = 18.84 --> Shape_get_perimeter(c) ans = 18.84
As explained in 6.15 SWIG provides support for overloaded functions and constructors.
As SWIG knows pointer types, the overloading works also with pointer types, here is is an example with a function magnify overloaded for the previous classes Shape and Circle:
%module example void magnify(Square *square, double factor) { square->size *= factor; }; void magnify(Circle *circle, double factor) { square->radius *= factor; };
--> example_Init(); --> c = new_Circle(3); --> s = new_Square(2); --> magnify(c, 10); --> Circle_get_radius(c) ans = 30; --> magnify(s, 10); --> Square_get_size(s) ans = 20;
In C++ objects can be passed by value, pointer, reference, or by an array:
%module example %{ #include <sciprint.h> %} %inline %{ class Foo { public: Foo(int _x) : x(_x) {} int x; }; void spam1(Foo *f) { sciprint("%d\n", f->x); } // Pass by pointer void spam2(Foo &f) { sciprint("%d\n", f.x); } // Pass by reference void spam3(Foo f) { sciprint("%d\n", f.x); } // Pass by value void spam4(Foo f[]) { sciprint("%d\n", f[0].x); } // Array of objects %}
In SWIG, there is no real distinction between these. So in Scilab, it is perfectly legal to do this:
--> f = new_Foo() --> spam1(f) 3 --> spam2(f) 3 --> spam3(f) 3 --> spam4(f) 3
Similar behaviour occurs for return values. For example, if you had functions like this:
Foo *spam5(); Foo &spam6(); Foo spam7();
All these functions will return a pointer to an instance of Foo. As the function spam7 returns a value, new instance of Foo has to be allocated, and a pointer on this instance is returned.
As in other languages, function and class templates are supported in SWIG Scilab.
You have to tell SWIG to create wrappers for a particular template instantiation. The %template directive is used for this purpose. For example:
%module example template<class T1, class T2, class T3> struct triplet { T1 first; T2 second; T3 third; triplet(const T1& a, const T2& b, const T3& c) { third = a; second = b; third = c; } }; %template(IntTriplet) triplet<int, int, int>;
Then in Scilab:
--> t = new_IntTriplet(3, 4, 1); --> IntTriplet_first_get(t) ans = 3. --> IntTriplet_second_get(t) ans = 4. --> IntTriplet_third_get(t) ans = 1. --> delete_IntTriplet(t);
More details on template support can be found in the templates documentation.
C++ operators are partially supported. Operator overloading exists in Scilab, but a C++ operator is not (in this version) wrapped by SWIG as a Scilab operator, but as a function. It is not automatic, you have to rename each operator (with the instruction %rename) with the suitable wrapper name.
Let's see it with an example of class with two operators + and double():
%module example %rename(plus) operator +; %rename(toDouble) operator double(); %inline %{ class Complex { public: Complex(double re, double im) : real(re), imag(im) {}; Complex operator+(const Complex& other) { double result_real = real + other.real; double result_imaginary = imag + other.imag; return Complex(result_real, result_imaginary); } operator double() { return real; } private: double real; double imag; }; %}
--> c1 = new_Complex(3, 7); --> c2 = Complex_plus(c, new_Complex(1, 1)); --> Complex_toDouble(c2) ans = 4.
SWIG is aware of C++ namespaces, but does not use it for wrappers. The module is not broken into submodules, nor do namespace appear in functions names. All the namespaces are all flattened in the module. For example with one namespace Foo:
%module example %inline %{ namespace foo { int fact(int n) { if (n > 1) return n * fact(n-1); else return 1; } struct Vector { double x, y, z; }; }; %}
In Scilab, there is no need to the specify the Foo namespace:
--> fact(3) ans = 6. --> v = new_Vector(); --> Vector_x_set(v, 3.4); --> Vector_y_get(v) ans = 0.
If your program has more than one namespace, name conflicts can be resolved using %rename. For example:
%rename(Bar_spam) Bar::spam; namespace Foo { int spam(); } namespace Bar { int spam(); }
Note: the nspace feature is not supported.
Scilab does not natively support exceptions, but has errors. When an exception is thrown, SWIG catches it, and sets a Scilab error. An error message is displayed in Scilab. For example:
%module example %inline %{ void throw_exception() throw(char const *) { throw "Bye world !"; } %}
-->throw_exception() !--error 999 SWIG/Scilab: Exception (char const *) occured: Bye world !
Scilab has a try-catch mechanism (and a similar instruction execstr()) to handle exceptions. It can be used with the lasterror() function as following:
--> execstr('throw_exception()', 'errcatch'); ans = 999. --> lasterror() ans = SWIG/Scilab: Exception (char const *) occured: Bye world !
If the function has a throw exception specification, SWIG can automatically map the exception type and set an appropriate Scilab error message. It works for a few primitive types, and also for STL exceptions (the library std_except.i has to be included to get the STL exception support):
%module example %include <std_except.i> %inline %{ void throw_int() throw(int) { throw 12; } void throw_stl_invalid_arg(int i) throw(std::invalid_argument) { if (i < 0) throw std::invalid_argument("argument is negative."); } %}
--> throw_int(); !--error 999 SWIG/Scilab: Exception (int) occured: 12 -->throw_stl_invalid_arg(-1); !--error 999 SWIG/Scilab: ValueError: argument is negative.
More complex or custom exception types require specific exception typemaps to be implemented in order to specifically handle a thrown type. See the SWIG C++ documentation for more details.
The Standard Template Library (STL) is partially supported. See STL for more details.
The following table provides the equivalent Scilab type for C/C++ primitive types.
C/C++ type | Scilab type |
bool | boolean |
char | string |
signed char | double or int8 |
unsigned char | double or uint8 |
short | double or int16 |
unsigned short | double or uint16 |
int | double or int32 |
unsigned int | double or uint32 |
long | double or int32 |
unsigned long | double or uint32 |
signed long long | not supported in Scilab 5.x |
unsigned long long | not supported in Scilab 5.x |
float | double |
double | double |
char * or char[] | string |
Notes:
Typemaps are available by default for arrays. Primitive type arrays are automatically converted to/from Scilab matrices. Typemaps are also provided to handle members of a struct or class that are arrays.
In input, the matrix is usually one-dimensional (it can be either a row or column vector). But it can also be a two-dimensional matrix. Warning: in Scilab, the values are column-major ordered, unlike in C, which is row-major ordered.
The type mappings used for arrays is the same for primitive types, described earlier. This means that, if needed, a Scilab double vector is converted in input into the related C integer array and this C integer array is automatically converted on output into a Scilab double vector. Note that unlike scalars, no control is done for arrays when a double is converted into an integer.
The following example illustrates all this:
%module example %#include <stdio.h> %inline %{ void printArray(int values[], int len) { int i = 0; for (i = 0; i < len; i++) { printf("%s %d %s", i==0?"[":"", values[i], i==len-1?"]\n":""); } } %}
--> printArray([0 1 2 3], 4) [ 0 1 2 3 ] --> printArray([0.2; -1.8; 2; 3.7], 4) [ 0 -1 2 3 ] --> printArray([0 1; 2 3], 4) [ 0 2 1 3 ] --> printArray([0; 1; 2; 3], 4) [ 0 1 2 3 ]
There are no specific typemaps for pointer-to-pointers, they are are mapped as pointers in Scilab.
Pointer-to-pointers are sometimes used to implement matrices in C. The following is a an example of this:
%module example %inline %{ // Returns the matrix [1 2; 3 4]; double **create_matrix() { double **M; int i; M = (double **) malloc(2 * sizeof(double *)); for (i = 0; i < 2; i++) { M[i] = (double *) malloc(2 * sizeof(double)); M[i][0] = 2 * i + 1; M[i][1] = 2 * i + 2; } return M; } // Gets the item M(i, j) value double get_matrix(double **M, int i, int j) { return M[i][j]; } // Sets the item M(i, j) value to be val void set_matrix(double **M, int i, int j, double val) { M[i][j] = val; } // Prints a matrix (2, 2) to console void print_matrix(double **M, int nbRows, int nbCols) { int i, j; for (i = 0; i < 2; i++) { for (j = 0; j < 2; j++) { printf("%3g ", M[i][j]); } printf("\n"); } } %}
These functions are used like this in Scilab:
--> m = create_matrix(); --> print_matrix(m); 1. 2. 3. 4. --> set_matrix(m, 1, 1, 5.); --> get_matrix(m, 1, 1) ans = 5.
The matrix.i library provides a set of typemaps which can be useful when working with one-dimensional and two-dimensional matrices.
In order to use this library, just include it in the interface file:
%include <matrix.i>
Several typemaps are available for the common Scilab matrix types:
For example: for a matrix of int, we have the typemaps, for input:
and output:
They marshall a Scilab matrix type into the appropriate 2 or 3 C parameters. The following is an example using the typemaps in this library:
%module example %include <matrix.i> %apply (int *IN, int IN_ROWCOUNT, int IN_COLCOUNT) { (int *matrix, int matrixNbRow, int matrixNbCol) }; %apply (int **OUT, int *OUT_ROWCOUNT, int *OUT_COLCOUNT) { (int **outMatrix, int *outMatrixNbRow, int *outMatrixNbCol) }; %inline %{ void absolute(int *matrix, int matrixNbRow, int matrixNbCol, int **outMatrix, int *outMatrixNbRow, int *outMatrixNbCol) { int i, j; *outMatrixNbRow = matrixNbRow; *outMatrixNbCol = matrixNbCol; *outMatrix = malloc(matrixNbRow * matrixNbCol * sizeof(int)); for (i=0; i < matrixNbRow * matrixNbCol; i++) { (*outMatrix)[i] = matrix[i] > 0 ? matrix[i]:-matrix[i]; } } %}
--> absolute([-0 1 -2; 3 4 -5]) ans = 0. 1. 2. 3. 4. 5.
The remarks made earlier for arrays also apply here:
The STL library wraps some containers defined in the STL (Standard Template Library), so that they can be manipulated in Scilab. This library also provides the appropriate typemaps to use the containers in functions and variables.
The list of wrapped sequence containers are:
And associative containers are:
Typemaps are available for the following container types:
Containers of other item types are not supported. Using them does not break compilation, but provokes a runtime error. Containers of enum are not supported yet.
In order to use the STL, the library must first be included in the SWIG interface file:
%include <stl.i>
Then for each container used, the appropriate template must be instantiated, in the std namespace:
namespace std { %template(IntVector) vector<int>; %template(DoubleVector) vector<double>; }
Additionally, the module initialization function has to be executed first in Scilab, so that all the types are known to Scilab. See the Module initialization section for more details.
Because in Scilab matrices exist for basic types only, a sequence container of pointers is mapped to a Scilab list. For other item types (double, int, string...) the sequence container is mapped to a Scilab matrix.
The first example below shows how to create a vector (of int) in Scilab, add some values to the vector and pass it as an argument of a function. It also shows, thanks to the typemaps, that we can also pass a Scilab matrix of values directly into the function:
%module example %include <stl.i> namespace std { %template(IntVector) vector<int>; } %{ #include <numeric> %} %inline %{ double average(std::vector<int> v) { return std::accumulate(v.begin(), v.end(), 0.0) / v.size(); } %}
--> example_Init(); --> v = new_IntVector(); --> for i = 1:4 --> IntVector_push_back(v, i); --> end; --> average(v) ans = 2.5 --> average([0 1 2 3]) ans = 2.5 --> delete_IntVector();
In the second example, a set of struct (Person) is wrapped. A function performs a search in this set, and returns a subset. As one can see, the result in Scilab is a list of pointers:
%module example %include <stl.i> %{ #include <string> %} %inline %{ struct Person { Person(std::string _name, int _age) : name(_name), age(_age) {}; std::string name; int age; }; typedef Person * PersonPtr; %} namespace std { %template(PersonPtrSet) set<PersonPtr>; } %inline %{ std::set<PersonPtr> findPersonsByAge(std::set<PersonPtr> persons, int minAge, int maxAge) { std::set<PersonPtr> foundPersons; for (std::set<PersonPtr>::iterator it = persons.begin(); it != persons.end(); it++) { if (((*it)->age >= minAge) && ((*it)->age <= maxAge)) { foundPersons.insert(*it); } } return foundPersons; } %}
--> example_Init(); --> joe = new_Person("Joe", 25); --> susan = new_Person("Susan", 32); --> bill = new_Person("Bill", 50); --> p = new_PersonPtrSet(); --> PersonPtrSet_insert(p, susan); --> PersonPtrSet_insert(p, joe); --> PersonPtrSet_insert(p, bill); --> l = findPersonsByAge(p, 20, 40); --> size(l) ans = 2. --> Person_name_get(l(1)) ans = Susan --> Person_name_get(l(2)) ans = Joe --> delete_PersonPtrSet(p);
The wrapped module contains an initialization function to:
This initialization function should be executed at the start of a script, before the wrapped library has to be used.
The function has the name of the module suffixed by _Init. For example, to initialize the module example:
--> example_Init();
The mechanism to load an external module in Scilab is called Dynamic Link and works with dynamic modules (or shared libraries, .so files).
To produce a dynamic module, when generating the wrapper, there are two possibilities, or build modes:
In this mode, used by default, SWIG generates the wrapper sources, which have to be manually compiled and linked. A loader script loader.sce is also produced, this one is executed further in Scilab to load the module.
This mode is the best option to use when you have to integrate the module build into a larger build process.
In this mode, in addition to the wrapper sources, SWIG produces a builder Scilab script (builder.sce), which is executed in Scilab to build the module. In a few words, the Scilab ilib_build() command is used, which produces the shared library file, and the loader script loader.sce (and also a cleaner script cleaner.sce).
An advantage of this mode is that it hides all the complexity of the build and other platform issues. Also it allows the module to conform to a Scilab external module convention which is that an external module should be simply built by calling a builder script.
The builder mode is activated with the -builder SWIG option. In this mode, the following SWIG options may be used to setup the build:
Let's give an example how to build a module example, composed of two sources, and using a library dependency:
The command is:
$ swig -scilab -builder -buildercflags -I/opt/foo/include -builderldflags "-L/opt/foo/lib -lfoo" -buildersources baa1.cxx, baa2.cxx example.i
In this part we give some details about the generated Scilab scripts.
builder.sce is the name of the builder script generated by SWIG in builder mode. It contains code like this:
ilib_name = "examplelib"; files = ["example_wrap.c"]; libs = []; table = ["fact", "_wrap_fact";"Foo_set", "_wrap_Foo_set";"Foo_get", "_wrap_Foo_get";]; ilib_build(ilib_name, table, files, libs);
ilib_build(lib_name, table, files, libs) is used to create shared libraries, and to generate a loader file used to dynamically load the shared library into Scilab.
The loader script is used to load in Scilab all the module functions. When loaded, these functions can be used as other Scilab functions.
The loader script loader.sce contains code similar to:
// ------------------------------------------------------ // generated by builder.sce: Please do not edit this file // ------------------------------------------------------ libexamplelib_path = get_file_path('loader.sce'); list_functions = [ 'fact'; 'Foo_set'; 'Foo_get'; ]; addinter(libexamplelib_path+'/libexamplelib.so', 'libexamplelib', list_functions); // remove temp. variables on stack clear libexamplelib_path; clear list_functions; clear get_file_path; // ------------------------------------------------------
addinter(files, spname, fcts) performs dynamic linking of a compiled C interface function.