swigrun.swg - chromium/deps/swig/Lib - Git at Google

 /* -----------------------------------------------------------------------------
  * swigrun.swg
  *
  * This file contains generic C API SWIG runtime support for pointer
  * type checking.
  * ----------------------------------------------------------------------------- */

 /* This should only be incremented when either the layout of swig_type_info changes,
    or for whatever reason, the runtime changes incompatibly */
 #define SWIG_RUNTIME_VERSION "4"

 /* define SWIG_TYPE_TABLE_NAME as "SWIG_TYPE_TABLE" */
 #ifdef SWIG_TYPE_TABLE
 # define SWIG_QUOTE_STRING(x) #x
 # define SWIG_EXPAND_AND_QUOTE_STRING(x) SWIG_QUOTE_STRING(x)
 # define SWIG_TYPE_TABLE_NAME SWIG_EXPAND_AND_QUOTE_STRING(SWIG_TYPE_TABLE)
 #else
 # define SWIG_TYPE_TABLE_NAME
 #endif

 /*
   You can use the SWIGRUNTIME and SWIGRUNTIMEINLINE macros for
   creating a static or dynamic library from the SWIG runtime code.
   In 99.9% of the cases, SWIG just needs to declare them as 'static'.

   But only do this if strictly necessary, ie, if you have problems
   with your compiler or suchlike.
 */

 #ifndef SWIGRUNTIME
 # define SWIGRUNTIME SWIGINTERN
 #endif

 #ifndef SWIGRUNTIMEINLINE
 # define SWIGRUNTIMEINLINE SWIGRUNTIME SWIGINLINE
 #endif

 /*  Generic buffer size */
 #ifndef SWIG_BUFFER_SIZE
 # define SWIG_BUFFER_SIZE 1024
 #endif

 /* Flags for pointer conversions */
 #define SWIG_POINTER_DISOWN        0x1
 #define SWIG_CAST_NEW_MEMORY       0x2

 /* Flags for new pointer objects */
 #define SWIG_POINTER_OWN           0x1


 /*
    Flags/methods for returning states.

    The SWIG conversion methods, as ConvertPtr, return and integer
    that tells if the conversion was successful or not. And if not,
    an error code can be returned (see swigerrors.swg for the codes).

    Use the following macros/flags to set or process the returning
    states.

    In old versions of SWIG, code such as the following was usually written:

      if (SWIG_ConvertPtr(obj,vptr,ty.flags) != -1) {
        // success code
      } else {
        //fail code
      }

    Now you can be more explicit:

     int res = SWIG_ConvertPtr(obj,vptr,ty.flags);
     if (SWIG_IsOK(res)) {
       // success code
     } else {
       // fail code
     }

    which is the same really, but now you can also do

     Type *ptr;
     int res = SWIG_ConvertPtr(obj,(void **)(&ptr),ty.flags);
     if (SWIG_IsOK(res)) {
       // success code
       if (SWIG_IsNewObj(res) {
         ...
 	delete *ptr;
       } else {
         ...
       }
     } else {
       // fail code
     }

    I.e., now SWIG_ConvertPtr can return new objects and you can
    identify the case and take care of the deallocation. Of course that
    also requires SWIG_ConvertPtr to return new result values, such as

       int SWIG_ConvertPtr(obj, ptr,...) {
         if (<obj is ok>) {
           if (<need new object>) {
             *ptr = <ptr to new allocated object>;
             return SWIG_NEWOBJ;
           } else {
             *ptr = <ptr to old object>;
             return SWIG_OLDOBJ;
           }
         } else {
           return SWIG_BADOBJ;
         }
       }

    Of course, returning the plain '0(success)/-1(fail)' still works, but you can be
    more explicit by returning SWIG_BADOBJ, SWIG_ERROR or any of the
    SWIG errors code.

    Finally, if the SWIG_CASTRANK_MODE is enabled, the result code
    allows to return the 'cast rank', for example, if you have this

        int food(double)
        int fooi(int);

    and you call

       food(1)   // cast rank '1'  (1 -> 1.0)
       fooi(1)   // cast rank '0'

    just use the SWIG_AddCast()/SWIG_CheckState()
 */

 #define SWIG_OK                    (0)
 #define SWIG_ERROR                 (-1)
 #define SWIG_IsOK(r)               (r >= 0)
 #define SWIG_ArgError(r)           ((r != SWIG_ERROR) ? r : SWIG_TypeError)

 /* The CastRankLimit says how many bits are used for the cast rank */
 #define SWIG_CASTRANKLIMIT         (1 << 8)
 /* The NewMask denotes the object was created (using new/malloc) */
 #define SWIG_NEWOBJMASK            (SWIG_CASTRANKLIMIT  << 1)
 /* The TmpMask is for in/out typemaps that use temporal objects */
 #define SWIG_TMPOBJMASK            (SWIG_NEWOBJMASK << 1)
 /* Simple returning values */
 #define SWIG_BADOBJ                (SWIG_ERROR)
 #define SWIG_OLDOBJ                (SWIG_OK)
 #define SWIG_NEWOBJ                (SWIG_OK | SWIG_NEWOBJMASK)
 #define SWIG_TMPOBJ                (SWIG_OK | SWIG_TMPOBJMASK)
 /* Check, add and del mask methods */
 #define SWIG_AddNewMask(r)         (SWIG_IsOK(r) ? (r | SWIG_NEWOBJMASK) : r)
 #define SWIG_DelNewMask(r)         (SWIG_IsOK(r) ? (r & ~SWIG_NEWOBJMASK) : r)
 #define SWIG_IsNewObj(r)           (SWIG_IsOK(r) && (r & SWIG_NEWOBJMASK))
 #define SWIG_AddTmpMask(r)         (SWIG_IsOK(r) ? (r | SWIG_TMPOBJMASK) : r)
 #define SWIG_DelTmpMask(r)         (SWIG_IsOK(r) ? (r & ~SWIG_TMPOBJMASK) : r)
 #define SWIG_IsTmpObj(r)           (SWIG_IsOK(r) && (r & SWIG_TMPOBJMASK))

 /* Cast-Rank Mode */
 #if defined(SWIG_CASTRANK_MODE)
 #  ifndef SWIG_TypeRank
 #    define SWIG_TypeRank             unsigned long
 #  endif
 #  ifndef SWIG_MAXCASTRANK            /* Default cast allowed */
 #    define SWIG_MAXCASTRANK          (2)
 #  endif
 #  define SWIG_CASTRANKMASK          ((SWIG_CASTRANKLIMIT) -1)
 #  define SWIG_CastRank(r)           (r & SWIG_CASTRANKMASK)
 SWIGINTERNINLINE int SWIG_AddCast(int r) {
   return SWIG_IsOK(r) ? ((SWIG_CastRank(r) < SWIG_MAXCASTRANK) ? (r + 1) : SWIG_ERROR) : r;
 }
 SWIGINTERNINLINE int SWIG_CheckState(int r) {
   return SWIG_IsOK(r) ? SWIG_CastRank(r) + 1 : 0;
 }
 #else /* no cast-rank mode */
 #  define SWIG_AddCast
 #  define SWIG_CheckState(r) (SWIG_IsOK(r) ? 1 : 0)
 #endif


 #include <string.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 typedef void *(*swig_converter_func)(void *, int *);
 typedef struct swig_type_info *(*swig_dycast_func)(void **);

 /* Structure to store information on one type */
 typedef struct swig_type_info {
   const char             *name;			/* mangled name of this type */
   const char             *str;			/* human readable name of this type */
   swig_dycast_func        dcast;		/* dynamic cast function down a hierarchy */
   struct swig_cast_info  *cast;			/* linked list of types that can cast into this type */
   void                   *clientdata;		/* language specific type data */
   int                    owndata;		/* flag if the structure owns the clientdata */
 } swig_type_info;

 /* Structure to store a type and conversion function used for casting */
 typedef struct swig_cast_info {
   swig_type_info         *type;			/* pointer to type that is equivalent to this type */
   swig_converter_func     converter;		/* function to cast the void pointers */
   struct swig_cast_info  *next;			/* pointer to next cast in linked list */
   struct swig_cast_info  *prev;			/* pointer to the previous cast */
 } swig_cast_info;

 /* Structure used to store module information
  * Each module generates one structure like this, and the runtime collects
  * all of these structures and stores them in a circularly linked list.*/
 typedef struct swig_module_info {
   swig_type_info         **types;		/* Array of pointers to swig_type_info structures that are in this module */
   size_t                 size;		        /* Number of types in this module */
   struct swig_module_info *next;		/* Pointer to next element in circularly linked list */
   swig_type_info         **type_initial;	/* Array of initially generated type structures */
   swig_cast_info         **cast_initial;	/* Array of initially generated casting structures */
   void                    *clientdata;		/* Language specific module data */
 } swig_module_info;

 /*
   Compare two type names skipping the space characters, therefore
   "char*" == "char *" and "Class<int>" == "Class<int >", etc.

   Return 0 when the two name types are equivalent, as in
   strncmp, but skipping ' '.
 */
 SWIGRUNTIME int
 SWIG_TypeNameComp(const char *f1, const char *l1,
 		  const char *f2, const char *l2) {
   for (;(f1 != l1) && (f2 != l2); ++f1, ++f2) {
     while ((*f1 == ' ') && (f1 != l1)) ++f1;
     while ((*f2 == ' ') && (f2 != l2)) ++f2;
     if (*f1 != *f2) return (*f1 > *f2) ? 1 : -1;
   }
   return (int)((l1 - f1) - (l2 - f2));
 }

 /*
   Check type equivalence in a name list like <name1>|<name2>|...
   Return 0 if not equal, 1 if equal
 */
 SWIGRUNTIME int
 SWIG_TypeEquiv(const char *nb, const char *tb) {
   int equiv = 0;
   const char* te = tb + strlen(tb);
   const char* ne = nb;
   while (!equiv && *ne) {
     for (nb = ne; *ne; ++ne) {
       if (*ne == '|') break;
     }
     equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
     if (*ne) ++ne;
   }
   return equiv;
 }

 /*
   Check type equivalence in a name list like <name1>|<name2>|...
   Return 0 if equal, -1 if nb < tb, 1 if nb > tb
 */
 SWIGRUNTIME int
 SWIG_TypeCompare(const char *nb, const char *tb) {
   int equiv = 0;
   const char* te = tb + strlen(tb);
   const char* ne = nb;
   while (!equiv && *ne) {
     for (nb = ne; *ne; ++ne) {
       if (*ne == '|') break;
     }
     equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
     if (*ne) ++ne;
   }
   return equiv;
 }


 /*
   Check the typename
 */
 SWIGRUNTIME swig_cast_info *
 SWIG_TypeCheck(const char *c, swig_type_info *ty) {
   if (ty) {
     swig_cast_info *iter = ty->cast;
     while (iter) {
       if (strcmp(iter->type->name, c) == 0) {
         if (iter == ty->cast)
           return iter;
         /* Move iter to the top of the linked list */
         iter->prev->next = iter->next;
         if (iter->next)
           iter->next->prev = iter->prev;
         iter->next = ty->cast;
         iter->prev = 0;
         if (ty->cast) ty->cast->prev = iter;
         ty->cast = iter;
         return iter;
       }
       iter = iter->next;
     }
   }
   return 0;
 }

 /*
   Identical to SWIG_TypeCheck, except strcmp is replaced with a pointer comparison
 */
 SWIGRUNTIME swig_cast_info *
 SWIG_TypeCheckStruct(swig_type_info *from, swig_type_info *ty) {
   if (ty) {
     swig_cast_info *iter = ty->cast;
     while (iter) {
       if (iter->type == from) {
         if (iter == ty->cast)
           return iter;
         /* Move iter to the top of the linked list */
         iter->prev->next = iter->next;
         if (iter->next)
           iter->next->prev = iter->prev;
         iter->next = ty->cast;
         iter->prev = 0;
         if (ty->cast) ty->cast->prev = iter;
         ty->cast = iter;
         return iter;
       }
       iter = iter->next;
     }
   }
   return 0;
 }

 /*
   Cast a pointer up an inheritance hierarchy
 */
 SWIGRUNTIMEINLINE void *
 SWIG_TypeCast(swig_cast_info *ty, void *ptr, int *newmemory) {
   return ((!ty) || (!ty->converter)) ? ptr : (*ty->converter)(ptr, newmemory);
 }

 /*
    Dynamic pointer casting. Down an inheritance hierarchy
 */
 SWIGRUNTIME swig_type_info *
 SWIG_TypeDynamicCast(swig_type_info *ty, void **ptr) {
   swig_type_info *lastty = ty;
   if (!ty || !ty->dcast) return ty;
   while (ty && (ty->dcast)) {
     ty = (*ty->dcast)(ptr);
     if (ty) lastty = ty;
   }
   return lastty;
 }

 /*
   Return the name associated with this type
 */
 SWIGRUNTIMEINLINE const char *
 SWIG_TypeName(const swig_type_info *ty) {
   return ty->name;
 }

 /*
   Return the pretty name associated with this type,
   that is an unmangled type name in a form presentable to the user.
 */
 SWIGRUNTIME const char *
 SWIG_TypePrettyName(const swig_type_info *type) {
   /* The "str" field contains the equivalent pretty names of the
      type, separated by vertical-bar characters.  We choose
      to print the last name, as it is often (?) the most
      specific. */
   if (!type) return NULL;
   if (type->str != NULL) {
     const char *last_name = type->str;
     const char *s;
     for (s = type->str; *s; s++)
       if (*s == '|') last_name = s+1;
     return last_name;
   }
   else
     return type->name;
 }

 /*
    Set the clientdata field for a type
 */
 SWIGRUNTIME void
 SWIG_TypeClientData(swig_type_info *ti, void *clientdata) {
   swig_cast_info *cast = ti->cast;
   /* if (ti->clientdata == clientdata) return; */
   ti->clientdata = clientdata;

   while (cast) {
     if (!cast->converter) {
       swig_type_info *tc = cast->type;
       if (!tc->clientdata) {
 	SWIG_TypeClientData(tc, clientdata);
       }
     }
     cast = cast->next;
   }
 }
 SWIGRUNTIME void
 SWIG_TypeNewClientData(swig_type_info *ti, void *clientdata) {
   SWIG_TypeClientData(ti, clientdata);
   ti->owndata = 1;
 }

 /*
   Search for a swig_type_info structure only by mangled name
   Search is a O(log #types)

   We start searching at module start, and finish searching when start == end.
   Note: if start == end at the beginning of the function, we go all the way around
   the circular list.
 */
 SWIGRUNTIME swig_type_info *
 SWIG_MangledTypeQueryModule(swig_module_info *start,
                             swig_module_info *end,
 		            const char *name) {
   swig_module_info *iter = start;
   do {
     if (iter->size) {
       register size_t l = 0;
       register size_t r = iter->size - 1;
       do {
 	/* since l+r >= 0, we can (>> 1) instead (/ 2) */
 	register size_t i = (l + r) >> 1;
 	const char *iname = iter->types[i]->name;
 	if (iname) {
 	  register int compare = strcmp(name, iname);
 	  if (compare == 0) {
 	    return iter->types[i];
 	  } else if (compare < 0) {
 	    if (i) {
 	      r = i - 1;
 	    } else {
 	      break;
 	    }
 	  } else if (compare > 0) {
 	    l = i + 1;
 	  }
 	} else {
 	  break; /* should never happen */
 	}
       } while (l <= r);
     }
     iter = iter->next;
   } while (iter != end);
   return 0;
 }

 /*
   Search for a swig_type_info structure for either a mangled name or a human readable name.
   It first searches the mangled names of the types, which is a O(log #types)
   If a type is not found it then searches the human readable names, which is O(#types).

   We start searching at module start, and finish searching when start == end.
   Note: if start == end at the beginning of the function, we go all the way around
   the circular list.
 */
 SWIGRUNTIME swig_type_info *
 SWIG_TypeQueryModule(swig_module_info *start,
                      swig_module_info *end,
 		     const char *name) {
   /* STEP 1: Search the name field using binary search */
   swig_type_info *ret = SWIG_MangledTypeQueryModule(start, end, name);
   if (ret) {
     return ret;
   } else {
     /* STEP 2: If the type hasn't been found, do a complete search
        of the str field (the human readable name) */
     swig_module_info *iter = start;
     do {
       register size_t i = 0;
       for (; i < iter->size; ++i) {
 	if (iter->types[i]->str && (SWIG_TypeEquiv(iter->types[i]->str, name)))
 	  return iter->types[i];
       }
       iter = iter->next;
     } while (iter != end);
   }

   /* neither found a match */
   return 0;
 }

 /*
    Pack binary data into a string
 */
 SWIGRUNTIME char *
 SWIG_PackData(char *c, void *ptr, size_t sz) {
   static const char hex[17] = "0123456789abcdef";
   register const unsigned char *u = (unsigned char *) ptr;
   register const unsigned char *eu =  u + sz;
   for (; u != eu; ++u) {
     register unsigned char uu = *u;
     *(c++) = hex[(uu & 0xf0) >> 4];
     *(c++) = hex[uu & 0xf];
   }
   return c;
 }

 /*
    Unpack binary data from a string
 */
 SWIGRUNTIME const char *
 SWIG_UnpackData(const char *c, void *ptr, size_t sz) {
   register unsigned char *u = (unsigned char *) ptr;
   register const unsigned char *eu = u + sz;
   for (; u != eu; ++u) {
     register char d = *(c++);
     register unsigned char uu;
     if ((d >= '0') && (d <= '9'))
       uu = ((d - '0') << 4);
     else if ((d >= 'a') && (d <= 'f'))
       uu = ((d - ('a'-10)) << 4);
     else
       return (char *) 0;
     d = *(c++);
     if ((d >= '0') && (d <= '9'))
       uu |= (d - '0');
     else if ((d >= 'a') && (d <= 'f'))
       uu |= (d - ('a'-10));
     else
       return (char *) 0;
     *u = uu;
   }
   return c;
 }

 /*
    Pack 'void *' into a string buffer.
 */
 SWIGRUNTIME char *
 SWIG_PackVoidPtr(char *buff, void *ptr, const char *name, size_t bsz) {
   char *r = buff;
   if ((2*sizeof(void *) + 2) > bsz) return 0;
   *(r++) = '_';
   r = SWIG_PackData(r,&ptr,sizeof(void *));
   if (strlen(name) + 1 > (bsz - (r - buff))) return 0;
   strcpy(r,name);
   return buff;
 }

 SWIGRUNTIME const char *
 SWIG_UnpackVoidPtr(const char *c, void **ptr, const char *name) {
   if (*c != '_') {
     if (strcmp(c,"NULL") == 0) {
       *ptr = (void *) 0;
       return name;
     } else {
       return 0;
     }
   }
   return SWIG_UnpackData(++c,ptr,sizeof(void *));
 }

 SWIGRUNTIME char *
 SWIG_PackDataName(char *buff, void *ptr, size_t sz, const char *name, size_t bsz) {
   char *r = buff;
   size_t lname = (name ? strlen(name) : 0);
   if ((2*sz + 2 + lname) > bsz) return 0;
   *(r++) = '_';
   r = SWIG_PackData(r,ptr,sz);
   if (lname) {
     strncpy(r,name,lname+1);
   } else {
     *r = 0;
   }
   return buff;
 }

 SWIGRUNTIME const char *
 SWIG_UnpackDataName(const char *c, void *ptr, size_t sz, const char *name) {
   if (*c != '_') {
     if (strcmp(c,"NULL") == 0) {
       memset(ptr,0,sz);
       return name;
     } else {
       return 0;
     }
   }
   return SWIG_UnpackData(++c,ptr,sz);
 }

 #ifdef __cplusplus
 }
 #endif
	/* -----------------------------------------------------------------------------
	* swigrun.swg
	*
	* This file contains generic C API SWIG runtime support for pointer
	* type checking.
	* ----------------------------------------------------------------------------- */

	/* This should only be incremented when either the layout of swig_type_info changes,
	or for whatever reason, the runtime changes incompatibly */
	#define SWIG_RUNTIME_VERSION "4"

	/* define SWIG_TYPE_TABLE_NAME as "SWIG_TYPE_TABLE" */
	#ifdef SWIG_TYPE_TABLE
	# define SWIG_QUOTE_STRING(x) #x
	# define SWIG_EXPAND_AND_QUOTE_STRING(x) SWIG_QUOTE_STRING(x)
	# define SWIG_TYPE_TABLE_NAME SWIG_EXPAND_AND_QUOTE_STRING(SWIG_TYPE_TABLE)
	#else
	# define SWIG_TYPE_TABLE_NAME
	#endif

	/*
	You can use the SWIGRUNTIME and SWIGRUNTIMEINLINE macros for
	creating a static or dynamic library from the SWIG runtime code.
	In 99.9% of the cases, SWIG just needs to declare them as 'static'.

	But only do this if strictly necessary, ie, if you have problems
	with your compiler or suchlike.
	*/

	#ifndef SWIGRUNTIME
	# define SWIGRUNTIME SWIGINTERN
	#endif

	#ifndef SWIGRUNTIMEINLINE
	# define SWIGRUNTIMEINLINE SWIGRUNTIME SWIGINLINE
	#endif

	/* Generic buffer size */
	#ifndef SWIG_BUFFER_SIZE
	# define SWIG_BUFFER_SIZE 1024
	#endif

	/* Flags for pointer conversions */
	#define SWIG_POINTER_DISOWN 0x1
	#define SWIG_CAST_NEW_MEMORY 0x2

	/* Flags for new pointer objects */
	#define SWIG_POINTER_OWN 0x1


	/*
	Flags/methods for returning states.

	The SWIG conversion methods, as ConvertPtr, return and integer
	that tells if the conversion was successful or not. And if not,
	an error code can be returned (see swigerrors.swg for the codes).

	Use the following macros/flags to set or process the returning
	states.

	In old versions of SWIG, code such as the following was usually written:

	if (SWIG_ConvertPtr(obj,vptr,ty.flags) != -1) {
	// success code
	} else {
	//fail code
	}

	Now you can be more explicit:

	int res = SWIG_ConvertPtr(obj,vptr,ty.flags);
	if (SWIG_IsOK(res)) {
	// success code
	} else {
	// fail code
	}

	which is the same really, but now you can also do

	Type *ptr;
	int res = SWIG_ConvertPtr(obj,(void **)(&ptr),ty.flags);
	if (SWIG_IsOK(res)) {
	// success code
	if (SWIG_IsNewObj(res) {
	...
	delete *ptr;
	} else {
	...
	}
	} else {
	// fail code
	}

	I.e., now SWIG_ConvertPtr can return new objects and you can
	identify the case and take care of the deallocation. Of course that
	also requires SWIG_ConvertPtr to return new result values, such as

	int SWIG_ConvertPtr(obj, ptr,...) {
	if (<obj is ok>) {
	if (<need new object>) {
	*ptr = <ptr to new allocated object>;
	return SWIG_NEWOBJ;
	} else {
	*ptr = <ptr to old object>;
	return SWIG_OLDOBJ;
	}
	} else {
	return SWIG_BADOBJ;
	}
	}

	Of course, returning the plain '0(success)/-1(fail)' still works, but you can be
	more explicit by returning SWIG_BADOBJ, SWIG_ERROR or any of the
	SWIG errors code.

	Finally, if the SWIG_CASTRANK_MODE is enabled, the result code
	allows to return the 'cast rank', for example, if you have this

	int food(double)
	int fooi(int);

	and you call

	food(1) // cast rank '1' (1 -> 1.0)
	fooi(1) // cast rank '0'

	just use the SWIG_AddCast()/SWIG_CheckState()
	*/

	#define SWIG_OK (0)
	#define SWIG_ERROR (-1)
	#define SWIG_IsOK(r) (r >= 0)
	#define SWIG_ArgError(r) ((r != SWIG_ERROR) ? r : SWIG_TypeError)

	/* The CastRankLimit says how many bits are used for the cast rank */
	#define SWIG_CASTRANKLIMIT (1 << 8)
	/* The NewMask denotes the object was created (using new/malloc) */
	#define SWIG_NEWOBJMASK (SWIG_CASTRANKLIMIT << 1)
	/* The TmpMask is for in/out typemaps that use temporal objects */
	#define SWIG_TMPOBJMASK (SWIG_NEWOBJMASK << 1)
	/* Simple returning values */
	#define SWIG_BADOBJ (SWIG_ERROR)
	#define SWIG_OLDOBJ (SWIG_OK)
	#define SWIG_NEWOBJ (SWIG_OK \| SWIG_NEWOBJMASK)
	#define SWIG_TMPOBJ (SWIG_OK \| SWIG_TMPOBJMASK)
	/* Check, add and del mask methods */
	#define SWIG_AddNewMask(r) (SWIG_IsOK(r) ? (r \| SWIG_NEWOBJMASK) : r)
	#define SWIG_DelNewMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_NEWOBJMASK) : r)
	#define SWIG_IsNewObj(r) (SWIG_IsOK(r) && (r & SWIG_NEWOBJMASK))
	#define SWIG_AddTmpMask(r) (SWIG_IsOK(r) ? (r \| SWIG_TMPOBJMASK) : r)
	#define SWIG_DelTmpMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_TMPOBJMASK) : r)
	#define SWIG_IsTmpObj(r) (SWIG_IsOK(r) && (r & SWIG_TMPOBJMASK))

	/* Cast-Rank Mode */
	#if defined(SWIG_CASTRANK_MODE)
	# ifndef SWIG_TypeRank
	# define SWIG_TypeRank unsigned long
	# endif
	# ifndef SWIG_MAXCASTRANK /* Default cast allowed */
	# define SWIG_MAXCASTRANK (2)
	# endif
	# define SWIG_CASTRANKMASK ((SWIG_CASTRANKLIMIT) -1)
	# define SWIG_CastRank(r) (r & SWIG_CASTRANKMASK)
	SWIGINTERNINLINE int SWIG_AddCast(int r) {
	return SWIG_IsOK(r) ? ((SWIG_CastRank(r) < SWIG_MAXCASTRANK) ? (r + 1) : SWIG_ERROR) : r;
	}
	SWIGINTERNINLINE int SWIG_CheckState(int r) {
	return SWIG_IsOK(r) ? SWIG_CastRank(r) + 1 : 0;
	}
	#else /* no cast-rank mode */
	# define SWIG_AddCast
	# define SWIG_CheckState(r) (SWIG_IsOK(r) ? 1 : 0)
	#endif


	#include <string.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	typedef void (swig_converter_func)(void , int );
	typedef struct swig_type_info (swig_dycast_func)(void **);

	/* Structure to store information on one type */
	typedef struct swig_type_info {
	const char name; / mangled name of this type */
	const char str; / human readable name of this type */
	swig_dycast_func dcast; /* dynamic cast function down a hierarchy */
	struct swig_cast_info cast; / linked list of types that can cast into this type */
	void clientdata; / language specific type data */
	int owndata; /* flag if the structure owns the clientdata */
	} swig_type_info;

	/* Structure to store a type and conversion function used for casting */
	typedef struct swig_cast_info {
	swig_type_info type; / pointer to type that is equivalent to this type */
	swig_converter_func converter; /* function to cast the void pointers */
	struct swig_cast_info next; / pointer to next cast in linked list */
	struct swig_cast_info prev; / pointer to the previous cast */
	} swig_cast_info;

	/* Structure used to store module information
	* Each module generates one structure like this, and the runtime collects
	* all of these structures and stores them in a circularly linked list.*/
	typedef struct swig_module_info {
	swig_type_info *types; / Array of pointers to swig_type_info structures that are in this module */
	size_t size; /* Number of types in this module */
	struct swig_module_info next; / Pointer to next element in circularly linked list */
	swig_type_info *type_initial; / Array of initially generated type structures */
	swig_cast_info *cast_initial; / Array of initially generated casting structures */
	void clientdata; / Language specific module data */
	} swig_module_info;

	/*
	Compare two type names skipping the space characters, therefore
	"char" == "char " and "Class<int>" == "Class<int >", etc.

	Return 0 when the two name types are equivalent, as in
	strncmp, but skipping ' '.
	*/
	SWIGRUNTIME int
	SWIG_TypeNameComp(const char f1, const char l1,
	const char f2, const char l2) {
	for (;(f1 != l1) && (f2 != l2); ++f1, ++f2) {
	while ((*f1 == ' ') && (f1 != l1)) ++f1;
	while ((*f2 == ' ') && (f2 != l2)) ++f2;
	if (f1 != f2) return (f1 > f2) ? 1 : -1;
	}
	return (int)((l1 - f1) - (l2 - f2));
	}

	/*
	Check type equivalence in a name list like <name1>\|<name2>\|...
	Return 0 if not equal, 1 if equal
	*/
	SWIGRUNTIME int
	SWIG_TypeEquiv(const char nb, const char tb) {
	int equiv = 0;
	const char* te = tb + strlen(tb);
	const char* ne = nb;
	while (!equiv && *ne) {
	for (nb = ne; *ne; ++ne) {
	if (*ne == '\|') break;
	}
	equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
	if (*ne) ++ne;
	}
	return equiv;
	}

	/*
	Check type equivalence in a name list like <name1>\|<name2>\|...
	Return 0 if equal, -1 if nb < tb, 1 if nb > tb
	*/
	SWIGRUNTIME int
	SWIG_TypeCompare(const char nb, const char tb) {
	int equiv = 0;
	const char* te = tb + strlen(tb);
	const char* ne = nb;
	while (!equiv && *ne) {
	for (nb = ne; *ne; ++ne) {
	if (*ne == '\|') break;
	}
	equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
	if (*ne) ++ne;
	}
	return equiv;
	}


	/*
	Check the typename
	*/
	SWIGRUNTIME swig_cast_info *
	SWIG_TypeCheck(const char c, swig_type_info ty) {
	if (ty) {
	swig_cast_info *iter = ty->cast;
	while (iter) {
	if (strcmp(iter->type->name, c) == 0) {
	if (iter == ty->cast)
	return iter;
	/* Move iter to the top of the linked list */
	iter->prev->next = iter->next;
	if (iter->next)
	iter->next->prev = iter->prev;
	iter->next = ty->cast;
	iter->prev = 0;
	if (ty->cast) ty->cast->prev = iter;
	ty->cast = iter;
	return iter;
	}
	iter = iter->next;
	}
	}
	return 0;
	}

	/*
	Identical to SWIG_TypeCheck, except strcmp is replaced with a pointer comparison
	*/
	SWIGRUNTIME swig_cast_info *
	SWIG_TypeCheckStruct(swig_type_info from, swig_type_info ty) {
	if (ty) {
	swig_cast_info *iter = ty->cast;
	while (iter) {
	if (iter->type == from) {
	if (iter == ty->cast)
	return iter;
	/* Move iter to the top of the linked list */
	iter->prev->next = iter->next;
	if (iter->next)
	iter->next->prev = iter->prev;
	iter->next = ty->cast;
	iter->prev = 0;
	if (ty->cast) ty->cast->prev = iter;
	ty->cast = iter;
	return iter;
	}
	iter = iter->next;
	}
	}
	return 0;
	}

	/*
	Cast a pointer up an inheritance hierarchy
	*/
	SWIGRUNTIMEINLINE void *
	SWIG_TypeCast(swig_cast_info ty, void ptr, int *newmemory) {
	return ((!ty) \|\| (!ty->converter)) ? ptr : (*ty->converter)(ptr, newmemory);
	}

	/*
	Dynamic pointer casting. Down an inheritance hierarchy
	*/
	SWIGRUNTIME swig_type_info *
	SWIG_TypeDynamicCast(swig_type_info ty, void *ptr) {
	swig_type_info *lastty = ty;
	if (!ty \|\| !ty->dcast) return ty;
	while (ty && (ty->dcast)) {
	ty = (*ty->dcast)(ptr);
	if (ty) lastty = ty;
	}
	return lastty;
	}

	/*
	Return the name associated with this type
	*/
	SWIGRUNTIMEINLINE const char *
	SWIG_TypeName(const swig_type_info *ty) {
	return ty->name;
	}

	/*
	Return the pretty name associated with this type,
	that is an unmangled type name in a form presentable to the user.
	*/
	SWIGRUNTIME const char *
	SWIG_TypePrettyName(const swig_type_info *type) {
	/* The "str" field contains the equivalent pretty names of the
	type, separated by vertical-bar characters. We choose
	to print the last name, as it is often (?) the most
	specific. */
	if (!type) return NULL;
	if (type->str != NULL) {
	const char *last_name = type->str;
	const char *s;
	for (s = type->str; *s; s++)
	if (*s == '\|') last_name = s+1;
	return last_name;
	}
	else
	return type->name;
	}

	/*
	Set the clientdata field for a type
	*/
	SWIGRUNTIME void
	SWIG_TypeClientData(swig_type_info ti, void clientdata) {
	swig_cast_info *cast = ti->cast;
	/* if (ti->clientdata == clientdata) return; */
	ti->clientdata = clientdata;

	while (cast) {
	if (!cast->converter) {
	swig_type_info *tc = cast->type;
	if (!tc->clientdata) {
	SWIG_TypeClientData(tc, clientdata);
	}
	}
	cast = cast->next;
	}
	}
	SWIGRUNTIME void
	SWIG_TypeNewClientData(swig_type_info ti, void clientdata) {
	SWIG_TypeClientData(ti, clientdata);
	ti->owndata = 1;
	}

	/*
	Search for a swig_type_info structure only by mangled name
	Search is a O(log #types)

	We start searching at module start, and finish searching when start == end.
	Note: if start == end at the beginning of the function, we go all the way around
	the circular list.
	*/
	SWIGRUNTIME swig_type_info *
	SWIG_MangledTypeQueryModule(swig_module_info *start,
	swig_module_info *end,
	const char *name) {
	swig_module_info *iter = start;
	do {
	if (iter->size) {
	register size_t l = 0;
	register size_t r = iter->size - 1;
	do {
	/* since l+r >= 0, we can (>> 1) instead (/ 2) */
	register size_t i = (l + r) >> 1;
	const char *iname = iter->types[i]->name;
	if (iname) {
	register int compare = strcmp(name, iname);
	if (compare == 0) {
	return iter->types[i];
	} else if (compare < 0) {
	if (i) {
	r = i - 1;
	} else {
	break;
	}
	} else if (compare > 0) {
	l = i + 1;
	}
	} else {
	break; /* should never happen */
	}
	} while (l <= r);
	}
	iter = iter->next;
	} while (iter != end);
	return 0;
	}

	/*
	Search for a swig_type_info structure for either a mangled name or a human readable name.
	It first searches the mangled names of the types, which is a O(log #types)
	If a type is not found it then searches the human readable names, which is O(#types).

	We start searching at module start, and finish searching when start == end.
	Note: if start == end at the beginning of the function, we go all the way around
	the circular list.
	*/
	SWIGRUNTIME swig_type_info *
	SWIG_TypeQueryModule(swig_module_info *start,
	swig_module_info *end,
	const char *name) {
	/* STEP 1: Search the name field using binary search */
	swig_type_info *ret = SWIG_MangledTypeQueryModule(start, end, name);
	if (ret) {
	return ret;
	} else {
	/* STEP 2: If the type hasn't been found, do a complete search
	of the str field (the human readable name) */
	swig_module_info *iter = start;
	do {
	register size_t i = 0;
	for (; i < iter->size; ++i) {
	if (iter->types[i]->str && (SWIG_TypeEquiv(iter->types[i]->str, name)))
	return iter->types[i];
	}
	iter = iter->next;
	} while (iter != end);
	}

	/* neither found a match */
	return 0;
	}

	/*
	Pack binary data into a string
	*/
	SWIGRUNTIME char *
	SWIG_PackData(char c, void ptr, size_t sz) {
	static const char hex[17] = "0123456789abcdef";
	register const unsigned char u = (unsigned char ) ptr;
	register const unsigned char *eu = u + sz;
	for (; u != eu; ++u) {
	register unsigned char uu = *u;
	*(c++) = hex[(uu & 0xf0) >> 4];
	*(c++) = hex[uu & 0xf];
	}
	return c;
	}

	/*
	Unpack binary data from a string
	*/
	SWIGRUNTIME const char *
	SWIG_UnpackData(const char c, void ptr, size_t sz) {
	register unsigned char u = (unsigned char ) ptr;
	register const unsigned char *eu = u + sz;
	for (; u != eu; ++u) {
	register char d = *(c++);
	register unsigned char uu;
	if ((d >= '0') && (d <= '9'))
	uu = ((d - '0') << 4);
	else if ((d >= 'a') && (d <= 'f'))
	uu = ((d - ('a'-10)) << 4);
	else
	return (char *) 0;
	d = *(c++);
	if ((d >= '0') && (d <= '9'))
	uu \|= (d - '0');
	else if ((d >= 'a') && (d <= 'f'))
	uu \|= (d - ('a'-10));
	else
	return (char *) 0;
	*u = uu;
	}
	return c;
	}

	/*
	Pack 'void *' into a string buffer.
	*/
	SWIGRUNTIME char *
	SWIG_PackVoidPtr(char buff, void ptr, const char *name, size_t bsz) {
	char *r = buff;
	if ((2sizeof(void ) + 2) > bsz) return 0;
	*(r++) = '_';
	r = SWIG_PackData(r,&ptr,sizeof(void *));
	if (strlen(name) + 1 > (bsz - (r - buff))) return 0;
	strcpy(r,name);
	return buff;
	}

	SWIGRUNTIME const char *
	SWIG_UnpackVoidPtr(const char c, void ptr, const char name) {
	if (*c != '_') {
	if (strcmp(c,"NULL") == 0) {
	ptr = (void ) 0;
	return name;
	} else {
	return 0;
	}
	}
	return SWIG_UnpackData(++c,ptr,sizeof(void *));
	}

	SWIGRUNTIME char *
	SWIG_PackDataName(char buff, void ptr, size_t sz, const char *name, size_t bsz) {
	char *r = buff;
	size_t lname = (name ? strlen(name) : 0);
	if ((2*sz + 2 + lname) > bsz) return 0;
	*(r++) = '_';
	r = SWIG_PackData(r,ptr,sz);
	if (lname) {
	strncpy(r,name,lname+1);
	} else {
	*r = 0;
	}
	return buff;
	}

	SWIGRUNTIME const char *
	SWIG_UnpackDataName(const char c, void ptr, size_t sz, const char *name) {
	if (*c != '_') {
	if (strcmp(c,"NULL") == 0) {
	memset(ptr,0,sz);
	return name;
	} else {
	return 0;
	}
	}
	return SWIG_UnpackData(++c,ptr,sz);
	}

	#ifdef __cplusplus
	}
	#endif