Mercurial > mm7
view lib/swig/swigwin-2.0.11/Lib/constraints.i @ 2327:5e4d90305d06
EventCastSpell removing duplicate code for handling empty pObjectList->pObjects array or not finding the correct value + moving everything into the main switch
author | Grumpy7 |
---|---|
date | Tue, 01 Apr 2014 23:20:15 +0200 |
parents | b3009adc0e2f |
children |
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/* ----------------------------------------------------------------------------- * constraints.i * * SWIG constraints library. * * SWIG library file containing typemaps for implementing various kinds of * constraints. Depends upon the SWIG exception library for generating * errors in a language-independent manner. * ----------------------------------------------------------------------------- */ #ifdef AUTODOC %text %{ %include <constraints.i> This library provides support for applying constraints to function arguments. Using a constraint, you can restrict arguments to be positive numbers, non-NULL pointers, and so on. The following constraints are available : Number POSITIVE - Positive number (not zero) Number NEGATIVE - Negative number (not zero) Number NONZERO - Nonzero number Number NONNEGATIVE - Positive number (including zero) Number NONPOSITIVE - Negative number (including zero) Pointer NONNULL - Non-NULL pointer Pointer ALIGN8 - 8-byte aligned pointer Pointer ALIGN4 - 4-byte aligned pointer Pointer ALIGN2 - 2-byte aligned pointer To use the constraints, you need to "apply" them to specific function arguments in your code. This is done using the %apply directive. For example : %apply Number NONNEGATIVE { double nonneg }; double sqrt(double nonneg); // Name of argument must match %apply Pointer NONNULL { void *ptr }; void *malloc(int POSITIVE); // May return a NULL pointer void free(void *ptr); // May not accept a NULL pointer Any function argument of the type you specify with the %apply directive will be checked with the appropriate constraint. Multiple types may be specified as follows : %apply Pointer NONNULL { void *, Vector *, List *, double *}; In this case, all of the types listed would be checked for non-NULL pointers. The common datatypes of int, short, long, unsigned int, unsigned long, unsigned short, unsigned char, signed char, float, and double can be checked without using the %apply directive by simply using the constraint name as the parameter name. For example : double sqrt(double NONNEGATIVE); double log(double POSITIVE); If you have used typedef to change type-names, you can also do this : %apply double { Real }; // Make everything defined for doubles // work for Reals. Real sqrt(Real NONNEGATIVE); Real log(Real POSITIVE); %} #endif %include <exception.i> #ifdef SWIGCSHARP // Required attribute for C# exception handling #define SWIGCSHARPCANTHROW , canthrow=1 #else #define SWIGCSHARPCANTHROW #endif // Positive numbers %typemap(check SWIGCSHARPCANTHROW) int POSITIVE, short POSITIVE, long POSITIVE, unsigned int POSITIVE, unsigned short POSITIVE, unsigned long POSITIVE, signed char POSITIVE, unsigned char POSITIVE, float POSITIVE, double POSITIVE, Number POSITIVE { if ($1 <= 0) { SWIG_exception(SWIG_ValueError,"Expected a positive value."); } } // Negative numbers %typemap(check SWIGCSHARPCANTHROW) int NEGATIVE, short NEGATIVE, long NEGATIVE, unsigned int NEGATIVE, unsigned short NEGATIVE, unsigned long NEGATIVE, signed char NEGATIVE, unsigned char NEGATIVE, float NEGATIVE, double NEGATIVE, Number NEGATIVE { if ($1 >= 0) { SWIG_exception(SWIG_ValueError,"Expected a negative value."); } } // Nonzero numbers %typemap(check SWIGCSHARPCANTHROW) int NONZERO, short NONZERO, long NONZERO, unsigned int NONZERO, unsigned short NONZERO, unsigned long NONZERO, signed char NONZERO, unsigned char NONZERO, float NONZERO, double NONZERO, Number NONZERO { if ($1 == 0) { SWIG_exception(SWIG_ValueError,"Expected a nonzero value."); } } // Nonnegative numbers %typemap(check SWIGCSHARPCANTHROW) int NONNEGATIVE, short NONNEGATIVE, long NONNEGATIVE, unsigned int NONNEGATIVE, unsigned short NONNEGATIVE, unsigned long NONNEGATIVE, signed char NONNEGATIVE, unsigned char NONNEGATIVE, float NONNEGATIVE, double NONNEGATIVE, Number NONNEGATIVE { if ($1 < 0) { SWIG_exception(SWIG_ValueError,"Expected a non-negative value."); } } // Nonpositive numbers %typemap(check SWIGCSHARPCANTHROW) int NONPOSITIVE, short NONPOSITIVE, long NONPOSITIVE, unsigned int NONPOSITIVE, unsigned short NONPOSITIVE, unsigned long NONPOSITIVE, signed char NONPOSITIVE, unsigned char NONPOSITIVE, float NONPOSITIVE, double NONPOSITIVE, Number NONPOSITIVE { if ($1 > 0) { SWIG_exception(SWIG_ValueError,"Expected a non-positive value."); } } // Non-NULL pointer %typemap(check SWIGCSHARPCANTHROW) void * NONNULL, Pointer NONNULL { if (!$1) { SWIG_exception(SWIG_ValueError,"Received a NULL pointer."); } } // Aligned pointers %typemap(check SWIGCSHARPCANTHROW) void * ALIGN8, Pointer ALIGN8 { unsigned long long tmp; tmp = (unsigned long long) $1; if (tmp & 7) { SWIG_exception(SWIG_ValueError,"Pointer must be 8-byte aligned."); } } %typemap(check SWIGCSHARPCANTHROW) void * ALIGN4, Pointer ALIGN4 { unsigned long long tmp; tmp = (unsigned long long) $1; if (tmp & 3) { SWIG_exception(SWIG_ValueError,"Pointer must be 4-byte aligned."); } } %typemap(check SWIGCSHARPCANTHROW) void * ALIGN2, Pointer ALIGN2 { unsigned long long tmp; tmp = (unsigned long long) $1; if (tmp & 1) { SWIG_exception(SWIG_ValueError,"Pointer must be 2-byte aligned."); } }