1 /* ----------------------------------------------------------------------------
2 * This file was automatically generated by SWIG (http://www.swig.org).
5 * This file is not intended to be easily readable and contains a number of
6 * coding conventions designed to improve portability and efficiency. Do not make
7 * changes to this file unless you know what you are doing--modify the SWIG
8 * interface file instead.
9 * ----------------------------------------------------------------------------- */
12 #define SWIG_CASTRANK_MODE
13 /* -----------------------------------------------------------------------------
14 * This section contains generic SWIG labels for method/variable
15 * declarations/attributes, and other compiler dependent labels.
16 * ----------------------------------------------------------------------------- */
18 /* template workaround for compilers that cannot correctly implement the C++ standard */
19 #ifndef SWIGTEMPLATEDISAMBIGUATOR
20 # if defined(__SUNPRO_CC) && (__SUNPRO_CC <= 0x560)
21 # define SWIGTEMPLATEDISAMBIGUATOR template
22 # elif defined(__HP_aCC)
23 /* Needed even with `aCC -AA' when `aCC -V' reports HP ANSI C++ B3910B A.03.55 */
24 /* If we find a maximum version that requires this, the test would be __HP_aCC <= 35500 for A.03.55 */
25 # define SWIGTEMPLATEDISAMBIGUATOR template
27 # define SWIGTEMPLATEDISAMBIGUATOR
31 /* inline attribute */
33 # if defined(__cplusplus) || (defined(__GNUC__) && !defined(__STRICT_ANSI__))
34 # define SWIGINLINE inline
40 /* attribute recognised by some compilers to avoid 'unused' warnings */
42 # if defined(__GNUC__)
43 # if !(defined(__cplusplus)) || (__GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 4))
44 # define SWIGUNUSED __attribute__ ((__unused__))
49 # define SWIGUNUSED __attribute__ ((__unused__))
55 #ifndef SWIGUNUSEDPARM
57 # define SWIGUNUSEDPARM(p)
59 # define SWIGUNUSEDPARM(p) p SWIGUNUSED
63 /* internal SWIG method */
65 # define SWIGINTERN static SWIGUNUSED
68 /* internal inline SWIG method */
69 #ifndef SWIGINTERNINLINE
70 # define SWIGINTERNINLINE SWIGINTERN SWIGINLINE
73 /* exporting methods */
74 #if (__GNUC__ >= 4) || (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)
75 # ifndef GCC_HASCLASSVISIBILITY
76 # define GCC_HASCLASSVISIBILITY
81 # if defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__)
82 # if defined(STATIC_LINKED)
85 # define SWIGEXPORT __declspec(dllexport)
88 # if defined(__GNUC__) && defined(GCC_HASCLASSVISIBILITY)
89 # define SWIGEXPORT __attribute__ ((visibility("default")))
96 /* calling conventions for Windows */
98 # if defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__)
99 # define SWIGSTDCALL __stdcall
105 /* Deal with Microsoft's attempt at deprecating C standard runtime functions */
106 #if !defined(SWIG_NO_CRT_SECURE_NO_DEPRECATE) && defined(_MSC_VER) && !defined(_CRT_SECURE_NO_DEPRECATE)
107 # define _CRT_SECURE_NO_DEPRECATE
110 /* Deal with Microsoft's attempt at deprecating methods in the standard C++ library */
111 #if !defined(SWIG_NO_SCL_SECURE_NO_DEPRECATE) && defined(_MSC_VER) && !defined(_SCL_SECURE_NO_DEPRECATE)
112 # define _SCL_SECURE_NO_DEPRECATE
116 /* -----------------------------------------------------------------------------
119 * This file contains generic CAPI SWIG runtime support for pointer
121 * ----------------------------------------------------------------------------- */
123 /* This should only be incremented when either the layout of swig_type_info changes,
124 or for whatever reason, the runtime changes incompatibly */
125 #define SWIG_RUNTIME_VERSION "4"
127 /* define SWIG_TYPE_TABLE_NAME as "SWIG_TYPE_TABLE" */
128 #ifdef SWIG_TYPE_TABLE
129 # define SWIG_QUOTE_STRING(x) #x
130 # define SWIG_EXPAND_AND_QUOTE_STRING(x) SWIG_QUOTE_STRING(x)
131 # define SWIG_TYPE_TABLE_NAME SWIG_EXPAND_AND_QUOTE_STRING(SWIG_TYPE_TABLE)
133 # define SWIG_TYPE_TABLE_NAME
137 You can use the SWIGRUNTIME and SWIGRUNTIMEINLINE macros for
138 creating a static or dynamic library from the swig runtime code.
139 In 99.9% of the cases, swig just needs to declare them as 'static'.
141 But only do this if is strictly necessary, ie, if you have problems
142 with your compiler or so.
146 # define SWIGRUNTIME SWIGINTERN
149 #ifndef SWIGRUNTIMEINLINE
150 # define SWIGRUNTIMEINLINE SWIGRUNTIME SWIGINLINE
153 /* Generic buffer size */
154 #ifndef SWIG_BUFFER_SIZE
155 # define SWIG_BUFFER_SIZE 1024
158 /* Flags for pointer conversions */
159 #define SWIG_POINTER_DISOWN 0x1
160 #define SWIG_CAST_NEW_MEMORY 0x2
162 /* Flags for new pointer objects */
163 #define SWIG_POINTER_OWN 0x1
167 Flags/methods for returning states.
169 The swig conversion methods, as ConvertPtr, return and integer
170 that tells if the conversion was successful or not. And if not,
171 an error code can be returned (see swigerrors.swg for the codes).
173 Use the following macros/flags to set or process the returning
176 In old swig versions, you usually write code as:
178 if (SWIG_ConvertPtr(obj,vptr,ty.flags) != -1) {
184 Now you can be more explicit as:
186 int res = SWIG_ConvertPtr(obj,vptr,ty.flags);
187 if (SWIG_IsOK(res)) {
193 that seems to be the same, but now you can also do
196 int res = SWIG_ConvertPtr(obj,(void **)(&ptr),ty.flags);
197 if (SWIG_IsOK(res)) {
199 if (SWIG_IsNewObj(res) {
209 I.e., now SWIG_ConvertPtr can return new objects and you can
210 identify the case and take care of the deallocation. Of course that
211 requires also to SWIG_ConvertPtr to return new result values, as
213 int SWIG_ConvertPtr(obj, ptr,...) {
215 if (<need new object>) {
216 *ptr = <ptr to new allocated object>;
219 *ptr = <ptr to old object>;
227 Of course, returning the plain '0(success)/-1(fail)' still works, but you can be
228 more explicit by returning SWIG_BADOBJ, SWIG_ERROR or any of the
231 Finally, if the SWIG_CASTRANK_MODE is enabled, the result code
232 allows to return the 'cast rank', for example, if you have this
239 food(1) // cast rank '1' (1 -> 1.0)
240 fooi(1) // cast rank '0'
242 just use the SWIG_AddCast()/SWIG_CheckState()
247 #define SWIG_ERROR (-1)
248 #define SWIG_IsOK(r) (r >= 0)
249 #define SWIG_ArgError(r) ((r != SWIG_ERROR) ? r : SWIG_TypeError)
251 /* The CastRankLimit says how many bits are used for the cast rank */
252 #define SWIG_CASTRANKLIMIT (1 << 8)
253 /* The NewMask denotes the object was created (using new/malloc) */
254 #define SWIG_NEWOBJMASK (SWIG_CASTRANKLIMIT << 1)
255 /* The TmpMask is for in/out typemaps that use temporal objects */
256 #define SWIG_TMPOBJMASK (SWIG_NEWOBJMASK << 1)
257 /* Simple returning values */
258 #define SWIG_BADOBJ (SWIG_ERROR)
259 #define SWIG_OLDOBJ (SWIG_OK)
260 #define SWIG_NEWOBJ (SWIG_OK | SWIG_NEWOBJMASK)
261 #define SWIG_TMPOBJ (SWIG_OK | SWIG_TMPOBJMASK)
262 /* Check, add and del mask methods */
263 #define SWIG_AddNewMask(r) (SWIG_IsOK(r) ? (r | SWIG_NEWOBJMASK) : r)
264 #define SWIG_DelNewMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_NEWOBJMASK) : r)
265 #define SWIG_IsNewObj(r) (SWIG_IsOK(r) && (r & SWIG_NEWOBJMASK))
266 #define SWIG_AddTmpMask(r) (SWIG_IsOK(r) ? (r | SWIG_TMPOBJMASK) : r)
267 #define SWIG_DelTmpMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_TMPOBJMASK) : r)
268 #define SWIG_IsTmpObj(r) (SWIG_IsOK(r) && (r & SWIG_TMPOBJMASK))
272 #if defined(SWIG_CASTRANK_MODE)
273 # ifndef SWIG_TypeRank
274 # define SWIG_TypeRank unsigned long
276 # ifndef SWIG_MAXCASTRANK /* Default cast allowed */
277 # define SWIG_MAXCASTRANK (2)
279 # define SWIG_CASTRANKMASK ((SWIG_CASTRANKLIMIT) -1)
280 # define SWIG_CastRank(r) (r & SWIG_CASTRANKMASK)
281 SWIGINTERNINLINE int SWIG_AddCast(int r) {
282 return SWIG_IsOK(r) ? ((SWIG_CastRank(r) < SWIG_MAXCASTRANK) ? (r + 1) : SWIG_ERROR) : r;
284 SWIGINTERNINLINE int SWIG_CheckState(int r) {
285 return SWIG_IsOK(r) ? SWIG_CastRank(r) + 1 : 0;
287 #else /* no cast-rank mode */
288 # define SWIG_AddCast
289 # define SWIG_CheckState(r) (SWIG_IsOK(r) ? 1 : 0)
301 typedef void *(*swig_converter_func)(void *, int *);
302 typedef struct swig_type_info *(*swig_dycast_func)(void **);
304 /* Structure to store information on one type */
305 typedef struct swig_type_info {
306 const char *name; /* mangled name of this type */
307 const char *str; /* human readable name of this type */
308 swig_dycast_func dcast; /* dynamic cast function down a hierarchy */
309 struct swig_cast_info *cast; /* linked list of types that can cast into this type */
310 void *clientdata; /* language specific type data */
311 int owndata; /* flag if the structure owns the clientdata */
314 /* Structure to store a type and conversion function used for casting */
315 typedef struct swig_cast_info {
316 swig_type_info *type; /* pointer to type that is equivalent to this type */
317 swig_converter_func converter; /* function to cast the void pointers */
318 struct swig_cast_info *next; /* pointer to next cast in linked list */
319 struct swig_cast_info *prev; /* pointer to the previous cast */
322 /* Structure used to store module information
323 * Each module generates one structure like this, and the runtime collects
324 * all of these structures and stores them in a circularly linked list.*/
325 typedef struct swig_module_info {
326 swig_type_info **types; /* Array of pointers to swig_type_info structures that are in this module */
327 size_t size; /* Number of types in this module */
328 struct swig_module_info *next; /* Pointer to next element in circularly linked list */
329 swig_type_info **type_initial; /* Array of initially generated type structures */
330 swig_cast_info **cast_initial; /* Array of initially generated casting structures */
331 void *clientdata; /* Language specific module data */
335 Compare two type names skipping the space characters, therefore
336 "char*" == "char *" and "Class<int>" == "Class<int >", etc.
338 Return 0 when the two name types are equivalent, as in
339 strncmp, but skipping ' '.
342 SWIG_TypeNameComp(const char *f1, const char *l1,
343 const char *f2, const char *l2) {
344 for (;(f1 != l1) && (f2 != l2); ++f1, ++f2) {
345 while ((*f1 == ' ') && (f1 != l1)) ++f1;
346 while ((*f2 == ' ') && (f2 != l2)) ++f2;
347 if (*f1 != *f2) return (*f1 > *f2) ? 1 : -1;
349 return (int)((l1 - f1) - (l2 - f2));
353 Check type equivalence in a name list like <name1>|<name2>|...
354 Return 0 if not equal, 1 if equal
357 SWIG_TypeEquiv(const char *nb, const char *tb) {
359 const char* te = tb + strlen(tb);
361 while (!equiv && *ne) {
362 for (nb = ne; *ne; ++ne) {
363 if (*ne == '|') break;
365 equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
372 Check type equivalence in a name list like <name1>|<name2>|...
373 Return 0 if equal, -1 if nb < tb, 1 if nb > tb
376 SWIG_TypeCompare(const char *nb, const char *tb) {
378 const char* te = tb + strlen(tb);
380 while (!equiv && *ne) {
381 for (nb = ne; *ne; ++ne) {
382 if (*ne == '|') break;
384 equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0;
391 /* think of this as a c++ template<> or a scheme macro */
392 #define SWIG_TypeCheck_Template(comparison, ty) \
394 swig_cast_info *iter = ty->cast; \
397 if (iter == ty->cast) return iter; \
398 /* Move iter to the top of the linked list */ \
399 iter->prev->next = iter->next; \
401 iter->next->prev = iter->prev; \
402 iter->next = ty->cast; \
404 if (ty->cast) ty->cast->prev = iter; \
416 SWIGRUNTIME swig_cast_info *
417 SWIG_TypeCheck(const char *c, swig_type_info *ty) {
418 SWIG_TypeCheck_Template(strcmp(iter->type->name, c) == 0, ty);
421 /* Same as previous function, except strcmp is replaced with a pointer comparison */
422 SWIGRUNTIME swig_cast_info *
423 SWIG_TypeCheckStruct(swig_type_info *from, swig_type_info *into) {
424 SWIG_TypeCheck_Template(iter->type == from, into);
428 Cast a pointer up an inheritance hierarchy
430 SWIGRUNTIMEINLINE void *
431 SWIG_TypeCast(swig_cast_info *ty, void *ptr, int *newmemory) {
432 return ((!ty) || (!ty->converter)) ? ptr : (*ty->converter)(ptr, newmemory);
436 Dynamic pointer casting. Down an inheritance hierarchy
438 SWIGRUNTIME swig_type_info *
439 SWIG_TypeDynamicCast(swig_type_info *ty, void **ptr) {
440 swig_type_info *lastty = ty;
441 if (!ty || !ty->dcast) return ty;
442 while (ty && (ty->dcast)) {
443 ty = (*ty->dcast)(ptr);
450 Return the name associated with this type
452 SWIGRUNTIMEINLINE const char *
453 SWIG_TypeName(const swig_type_info *ty) {
458 Return the pretty name associated with this type,
459 that is an unmangled type name in a form presentable to the user.
461 SWIGRUNTIME const char *
462 SWIG_TypePrettyName(const swig_type_info *type) {
463 /* The "str" field contains the equivalent pretty names of the
464 type, separated by vertical-bar characters. We choose
465 to print the last name, as it is often (?) the most
467 if (!type) return NULL;
468 if (type->str != NULL) {
469 const char *last_name = type->str;
471 for (s = type->str; *s; s++)
472 if (*s == '|') last_name = s+1;
480 Set the clientdata field for a type
483 SWIG_TypeClientData(swig_type_info *ti, void *clientdata) {
484 swig_cast_info *cast = ti->cast;
485 /* if (ti->clientdata == clientdata) return; */
486 ti->clientdata = clientdata;
489 if (!cast->converter) {
490 swig_type_info *tc = cast->type;
491 if (!tc->clientdata) {
492 SWIG_TypeClientData(tc, clientdata);
499 SWIG_TypeNewClientData(swig_type_info *ti, void *clientdata) {
500 SWIG_TypeClientData(ti, clientdata);
505 Search for a swig_type_info structure only by mangled name
506 Search is a O(log #types)
508 We start searching at module start, and finish searching when start == end.
509 Note: if start == end at the beginning of the function, we go all the way around
512 SWIGRUNTIME swig_type_info *
513 SWIG_MangledTypeQueryModule(swig_module_info *start,
514 swig_module_info *end,
516 swig_module_info *iter = start;
519 register size_t l = 0;
520 register size_t r = iter->size - 1;
522 /* since l+r >= 0, we can (>> 1) instead (/ 2) */
523 register size_t i = (l + r) >> 1;
524 const char *iname = iter->types[i]->name;
526 register int compare = strcmp(name, iname);
528 return iter->types[i];
529 } else if (compare < 0) {
535 } else if (compare > 0) {
539 break; /* should never happen */
544 } while (iter != end);
549 Search for a swig_type_info structure for either a mangled name or a human readable name.
550 It first searches the mangled names of the types, which is a O(log #types)
551 If a type is not found it then searches the human readable names, which is O(#types).
553 We start searching at module start, and finish searching when start == end.
554 Note: if start == end at the beginning of the function, we go all the way around
557 SWIGRUNTIME swig_type_info *
558 SWIG_TypeQueryModule(swig_module_info *start,
559 swig_module_info *end,
561 /* STEP 1: Search the name field using binary search */
562 swig_type_info *ret = SWIG_MangledTypeQueryModule(start, end, name);
566 /* STEP 2: If the type hasn't been found, do a complete search
567 of the str field (the human readable name) */
568 swig_module_info *iter = start;
570 register size_t i = 0;
571 for (; i < iter->size; ++i) {
572 if (iter->types[i]->str && (SWIG_TypeEquiv(iter->types[i]->str, name)))
573 return iter->types[i];
576 } while (iter != end);
579 /* neither found a match */
584 Pack binary data into a string
587 SWIG_PackData(char *c, void *ptr, size_t sz) {
588 static const char hex[17] = "0123456789abcdef";
589 register const unsigned char *u = (unsigned char *) ptr;
590 register const unsigned char *eu = u + sz;
591 for (; u != eu; ++u) {
592 register unsigned char uu = *u;
593 *(c++) = hex[(uu & 0xf0) >> 4];
594 *(c++) = hex[uu & 0xf];
600 Unpack binary data from a string
602 SWIGRUNTIME const char *
603 SWIG_UnpackData(const char *c, void *ptr, size_t sz) {
604 register unsigned char *u = (unsigned char *) ptr;
605 register const unsigned char *eu = u + sz;
606 for (; u != eu; ++u) {
607 register char d = *(c++);
608 register unsigned char uu;
609 if ((d >= '0') && (d <= '9'))
610 uu = ((d - '0') << 4);
611 else if ((d >= 'a') && (d <= 'f'))
612 uu = ((d - ('a'-10)) << 4);
616 if ((d >= '0') && (d <= '9'))
618 else if ((d >= 'a') && (d <= 'f'))
619 uu |= (d - ('a'-10));
628 Pack 'void *' into a string buffer.
631 SWIG_PackVoidPtr(char *buff, void *ptr, const char *name, size_t bsz) {
633 if ((2*sizeof(void *) + 2) > bsz) return 0;
635 r = SWIG_PackData(r,&ptr,sizeof(void *));
636 if (strlen(name) + 1 > (bsz - (r - buff))) return 0;
641 SWIGRUNTIME const char *
642 SWIG_UnpackVoidPtr(const char *c, void **ptr, const char *name) {
644 if (strcmp(c,"NULL") == 0) {
651 return SWIG_UnpackData(++c,ptr,sizeof(void *));
655 SWIG_PackDataName(char *buff, void *ptr, size_t sz, const char *name, size_t bsz) {
657 size_t lname = (name ? strlen(name) : 0);
658 if ((2*sz + 2 + lname) > bsz) return 0;
660 r = SWIG_PackData(r,ptr,sz);
662 strncpy(r,name,lname+1);
669 SWIGRUNTIME const char *
670 SWIG_UnpackDataName(const char *c, void *ptr, size_t sz, const char *name) {
672 if (strcmp(c,"NULL") == 0) {
679 return SWIG_UnpackData(++c,ptr,sz);
687 #define SWIG_UnknownError -1
688 #define SWIG_IOError -2
689 #define SWIG_RuntimeError -3
690 #define SWIG_IndexError -4
691 #define SWIG_TypeError -5
692 #define SWIG_DivisionByZero -6
693 #define SWIG_OverflowError -7
694 #define SWIG_SyntaxError -8
695 #define SWIG_ValueError -9
696 #define SWIG_SystemError -10
697 #define SWIG_AttributeError -11
698 #define SWIG_MemoryError -12
699 #define SWIG_NullReferenceError -13
704 /* Needed on some windows machines---since MS plays funny games with the header files under C++ */
713 /* Add in functionality missing in older versions of Perl. Much of this is based on Devel-PPPort on cpan. */
715 /* Add PERL_REVISION, PERL_VERSION, PERL_SUBVERSION if missing */
716 #ifndef PERL_REVISION
717 # if !defined(__PATCHLEVEL_H_INCLUDED__) && !(defined(PATCHLEVEL) && defined(SUBVERSION))
718 # define PERL_PATCHLEVEL_H_IMPLICIT
719 # include <patchlevel.h>
721 # if !(defined(PERL_VERSION) || (defined(SUBVERSION) && defined(PATCHLEVEL)))
722 # include <could_not_find_Perl_patchlevel.h>
724 # ifndef PERL_REVISION
725 # define PERL_REVISION (5)
726 # define PERL_VERSION PATCHLEVEL
727 # define PERL_SUBVERSION SUBVERSION
731 #if defined(WIN32) && defined(PERL_OBJECT) && !defined(PerlIO_exportFILE)
732 #define PerlIO_exportFILE(fh,fl) (FILE*)(fh)
736 # define SvIOK_UV(sv) (SvIOK(sv) && (SvUVX(sv) == SvIVX(sv)))
740 # define SvUOK(sv) SvIOK_UV(sv)
743 #if ((PERL_VERSION < 4) || ((PERL_VERSION == 4) && (PERL_SUBVERSION <= 5)))
744 # define PL_sv_undef sv_undef
746 # define PL_errgv errgv
747 # define PL_sv_no sv_no
748 # define PL_sv_yes sv_yes
749 # define PL_markstack_ptr markstack_ptr
754 # define IVSIZE LONGSIZE
756 # define IVSIZE 4 /* A bold guess, but the best we can make. */
761 # if (IVSIZE == PTRSIZE) && (UVSIZE == PTRSIZE)
763 # define INT2PTR(any,d) (any)(d)
765 # if PTRSIZE == LONGSIZE
766 # define PTRV unsigned long
768 # define PTRV unsigned
770 # define INT2PTR(any,d) (any)(PTRV)(d)
773 # define NUM2PTR(any,d) (any)(PTRV)(d)
774 # define PTR2IV(p) INT2PTR(IV,p)
775 # define PTR2UV(p) INT2PTR(UV,p)
776 # define PTR2NV(p) NUM2PTR(NV,p)
778 # if PTRSIZE == LONGSIZE
779 # define PTR2ul(p) (unsigned long)(p)
781 # define PTR2ul(p) INT2PTR(unsigned long,p)
783 #endif /* !INT2PTR */
786 # define SvPV_nolen(x) SvPV(x,PL_na)
790 # define get_sv perl_get_sv
794 # define ERRSV get_sv("@",FALSE)
806 /* -----------------------------------------------------------------------------
808 * ----------------------------------------------------------------------------- */
810 SWIGINTERN const char*
811 SWIG_Perl_ErrorType(int code) {
812 const char* type = 0;
814 case SWIG_MemoryError:
815 type = "MemoryError";
820 case SWIG_RuntimeError:
821 type = "RuntimeError";
823 case SWIG_IndexError:
829 case SWIG_DivisionByZero:
830 type = "ZeroDivisionError";
832 case SWIG_OverflowError:
833 type = "OverflowError";
835 case SWIG_SyntaxError:
836 type = "SyntaxError";
838 case SWIG_ValueError:
841 case SWIG_SystemError:
842 type = "SystemError";
844 case SWIG_AttributeError:
845 type = "AttributeError";
848 type = "RuntimeError";
856 /* -----------------------------------------------------------------------------
859 * This file contains the runtime support for Perl modules
860 * and includes code for managing global variables and pointer
862 * ----------------------------------------------------------------------------- */
865 #define SWIG_PERL_OBJECT_DECL CPerlObj *SWIGUNUSEDPARM(pPerl),
866 #define SWIG_PERL_OBJECT_CALL pPerl,
868 #define SWIG_PERL_OBJECT_DECL
869 #define SWIG_PERL_OBJECT_CALL
872 /* Common SWIG API */
874 /* for raw pointers */
875 #define SWIG_ConvertPtr(obj, pp, type, flags) SWIG_Perl_ConvertPtr(SWIG_PERL_OBJECT_CALL obj, pp, type, flags)
876 #define SWIG_NewPointerObj(p, type, flags) SWIG_Perl_NewPointerObj(SWIG_PERL_OBJECT_CALL p, type, flags)
878 /* for raw packed data */
879 #define SWIG_ConvertPacked(obj, p, s, type) SWIG_Perl_ConvertPacked(SWIG_PERL_OBJECT_CALL obj, p, s, type)
880 #define SWIG_NewPackedObj(p, s, type) SWIG_Perl_NewPackedObj(SWIG_PERL_OBJECT_CALL p, s, type)
882 /* for class or struct pointers */
883 #define SWIG_ConvertInstance(obj, pptr, type, flags) SWIG_ConvertPtr(obj, pptr, type, flags)
884 #define SWIG_NewInstanceObj(ptr, type, flags) SWIG_NewPointerObj(ptr, type, flags)
886 /* for C or C++ function pointers */
887 #define SWIG_ConvertFunctionPtr(obj, pptr, type) SWIG_ConvertPtr(obj, pptr, type, 0)
888 #define SWIG_NewFunctionPtrObj(ptr, type) SWIG_NewPointerObj(ptr, type, 0)
890 /* for C++ member pointers, ie, member methods */
891 #define SWIG_ConvertMember(obj, ptr, sz, ty) SWIG_ConvertPacked(obj, ptr, sz, ty)
892 #define SWIG_NewMemberObj(ptr, sz, type) SWIG_NewPackedObj(ptr, sz, type)
897 #define SWIG_GetModule(clientdata) SWIG_Perl_GetModule()
898 #define SWIG_SetModule(clientdata, pointer) SWIG_Perl_SetModule(pointer)
901 /* Error manipulation */
903 #define SWIG_ErrorType(code) SWIG_Perl_ErrorType(code)
904 #define SWIG_Error(code, msg) sv_setpvf(GvSV(PL_errgv),"%s %s\n", SWIG_ErrorType(code), msg)
905 #define SWIG_fail goto fail
907 /* Perl-specific SWIG API */
909 #define SWIG_MakePtr(sv, ptr, type, flags) SWIG_Perl_MakePtr(SWIG_PERL_OBJECT_CALL sv, ptr, type, flags)
910 #define SWIG_MakePackedObj(sv, p, s, type) SWIG_Perl_MakePackedObj(SWIG_PERL_OBJECT_CALL sv, p, s, type)
911 #define SWIG_SetError(str) SWIG_Error(SWIG_RuntimeError, str)
914 #define SWIG_PERL_DECL_ARGS_1(arg1) (SWIG_PERL_OBJECT_DECL arg1)
915 #define SWIG_PERL_CALL_ARGS_1(arg1) (SWIG_PERL_OBJECT_CALL arg1)
916 #define SWIG_PERL_DECL_ARGS_2(arg1, arg2) (SWIG_PERL_OBJECT_DECL arg1, arg2)
917 #define SWIG_PERL_CALL_ARGS_2(arg1, arg2) (SWIG_PERL_OBJECT_CALL arg1, arg2)
919 /* -----------------------------------------------------------------------------
920 * pointers/data manipulation
921 * ----------------------------------------------------------------------------- */
923 /* For backward compatibility only */
924 #define SWIG_POINTER_EXCEPTION 0
930 #define SWIG_OWNER SWIG_POINTER_OWN
931 #define SWIG_SHADOW SWIG_OWNER << 1
933 #define SWIG_MAYBE_PERL_OBJECT SWIG_PERL_OBJECT_DECL
935 /* SWIG Perl macros */
937 /* Macro to declare an XS function */
939 # define XSPROTO(name) void name(pTHX_ CV* cv)
942 /* Macro to call an XS function */
944 # define SWIG_CALLXS(_name) _name(cv,pPerl)
946 # ifndef MULTIPLICITY
947 # define SWIG_CALLXS(_name) _name(cv)
949 # define SWIG_CALLXS(_name) _name(PERL_GET_THX, cv)
954 #define MAGIC_PPERL CPerlObj *pPerl = (CPerlObj *) this;
959 typedef int (CPerlObj::*SwigMagicFunc)(SV *, MAGIC *);
964 #define SWIG_MAGIC(a,b) (SV *a, MAGIC *b)
965 #define SWIGCLASS_STATIC
967 #else /* PERL_OBJECT */
970 #define SWIGCLASS_STATIC static SWIGUNUSED
973 #define SWIG_MAGIC(a,b) (SV *a, MAGIC *b)
978 typedef int (*SwigMagicFunc)(SV *, MAGIC *);
983 #else /* MULTIPLICITY */
985 #define SWIG_MAGIC(a,b) (struct interpreter *interp, SV *a, MAGIC *b)
990 typedef int (*SwigMagicFunc)(struct interpreter *, SV *, MAGIC *);
995 #endif /* MULTIPLICITY */
996 #endif /* PERL_OBJECT */
998 /* Workaround for bug in perl 5.6.x croak and earlier */
999 #if (PERL_VERSION < 8)
1001 # define SWIG_croak_null() SWIG_Perl_croak_null(pPerl)
1002 static void SWIG_Perl_croak_null(CPerlObj *pPerl)
1004 static void SWIG_croak_null()
1008 # if (PERL_VERSION < 6)
1011 if (SvOK(err) && !SvROK(err)) croak("%_", err);
1016 # define SWIG_croak_null() croak(Nullch)
1021 Define how strict is the cast between strings and integers/doubles
1022 when overloading between these types occurs.
1024 The default is making it as strict as possible by using SWIG_AddCast
1027 You can use -DSWIG_PERL_NO_STRICT_STR2NUM at compilation time to
1028 disable the SWIG_AddCast, making the casting between string and
1029 numbers less strict.
1031 In the end, we try to solve the overloading between strings and
1032 numerical types in the more natural way, but if you can avoid it,
1033 well, avoid it using %rename, for example.
1035 #ifndef SWIG_PERL_NO_STRICT_STR2NUM
1036 # ifndef SWIG_PERL_STRICT_STR2NUM
1037 # define SWIG_PERL_STRICT_STR2NUM
1040 #ifdef SWIG_PERL_STRICT_STR2NUM
1041 /* string takes precedence */
1042 #define SWIG_Str2NumCast(x) SWIG_AddCast(x)
1044 /* number takes precedence */
1045 #define SWIG_Str2NumCast(x) x
1052 SWIGRUNTIME const char *
1053 SWIG_Perl_TypeProxyName(const swig_type_info *type) {
1054 if (!type) return NULL;
1055 if (type->clientdata != NULL) {
1056 return (const char*) type->clientdata;
1063 SWIGRUNTIME swig_cast_info *
1064 SWIG_TypeProxyCheck(const char *c, swig_type_info *ty) {
1065 SWIG_TypeCheck_Template(( (!iter->type->clientdata && (strcmp(iter->type->name, c) == 0))
1066 || (iter->type->clientdata && (strcmp((char*)iter->type->clientdata, c) == 0))), ty);
1070 /* Function for getting a pointer value */
1073 SWIG_Perl_ConvertPtr(SWIG_MAYBE_PERL_OBJECT SV *sv, void **ptr, swig_type_info *_t, int flags) {
1075 void *voidptr = (void *)0;
1077 /* If magical, apply more magic */
1081 /* Check to see if this is an object */
1082 if (sv_isobject(sv)) {
1084 tsv = (SV*) SvRV(sv);
1085 if ((SvTYPE(tsv) == SVt_PVHV)) {
1087 if (SvMAGICAL(tsv)) {
1088 mg = mg_find(tsv,'P');
1091 if (sv_isobject(sv)) {
1092 tsv = (SV*)SvRV(sv);
1102 voidptr = INT2PTR(void *,tmp);
1103 } else if (! SvOK(sv)) { /* Check for undef */
1104 *(ptr) = (void *) 0;
1106 } else if (SvTYPE(sv) == SVt_RV) { /* Check for NULL pointer */
1108 *(ptr) = (void *) 0;
1113 } else { /* Don't know what it is */
1117 /* Now see if the types match */
1118 char *_c = HvNAME(SvSTASH(SvRV(sv)));
1119 tc = SWIG_TypeProxyCheck(_c,_t);
1125 *ptr = SWIG_TypeCast(tc,voidptr,&newmemory);
1126 assert(!newmemory); /* newmemory handling not yet implemented */
1133 * DISOWN implementation: we need a perl guru to check this one.
1135 if (tsv && (flags & SWIG_POINTER_DISOWN)) {
1137 * almost copy paste code from below SWIG_POINTER_OWN setting
1140 HV *stash = SvSTASH(SvRV(obj));
1141 GV *gv = *(GV**) hv_fetch(stash, "OWNER", 5, TRUE);
1145 * To set ownership (see below), a newSViv(1) entry is added.
1146 * Hence, to remove ownership, we delete the entry.
1148 if (hv_exists_ent(hv, obj, 0)) {
1149 hv_delete_ent(hv, obj, 0, 0);
1157 SWIG_Perl_MakePtr(SWIG_MAYBE_PERL_OBJECT SV *sv, void *ptr, swig_type_info *t, int flags) {
1158 if (ptr && (flags & SWIG_SHADOW)) {
1163 sv_setref_pv(obj, (char *) SWIG_Perl_TypeProxyName(t), ptr);
1164 stash=SvSTASH(SvRV(obj));
1165 if (flags & SWIG_POINTER_OWN) {
1167 GV *gv=*(GV**)hv_fetch(stash, "OWNER", 5, TRUE);
1169 gv_init(gv, stash, "OWNER", 5, FALSE);
1171 hv_store_ent(hv, obj, newSViv(1), 0);
1173 sv_magic((SV *)hash, (SV *)obj, 'P', Nullch, 0);
1175 self=newRV_noinc((SV *)hash);
1177 SvREFCNT_dec((SV *)self);
1178 sv_bless(sv, stash);
1181 sv_setref_pv(sv, (char *) SWIG_Perl_TypeProxyName(t), ptr);
1185 SWIGRUNTIMEINLINE SV *
1186 SWIG_Perl_NewPointerObj(SWIG_MAYBE_PERL_OBJECT void *ptr, swig_type_info *t, int flags) {
1187 SV *result = sv_newmortal();
1188 SWIG_MakePtr(result, ptr, t, flags);
1193 SWIG_Perl_MakePackedObj(SWIG_MAYBE_PERL_OBJECT SV *sv, void *ptr, int sz, swig_type_info *type) {
1196 if ((2*sz + 1 + strlen(SWIG_Perl_TypeProxyName(type))) > 1000) return;
1198 r = SWIG_PackData(r,ptr,sz);
1199 strcpy(r,SWIG_Perl_TypeProxyName(type));
1200 sv_setpv(sv, result);
1204 SWIG_Perl_NewPackedObj(SWIG_MAYBE_PERL_OBJECT void *ptr, int sz, swig_type_info *type) {
1205 SV *result = sv_newmortal();
1206 SWIG_Perl_MakePackedObj(result, ptr, sz, type);
1210 /* Convert a packed value value */
1212 SWIG_Perl_ConvertPacked(SWIG_MAYBE_PERL_OBJECT SV *obj, void *ptr, int sz, swig_type_info *ty) {
1216 if ((!obj) || (!SvOK(obj))) return SWIG_ERROR;
1217 c = SvPV_nolen(obj);
1218 /* Pointer values must start with leading underscore */
1219 if (*c != '_') return SWIG_ERROR;
1221 c = SWIG_UnpackData(c,ptr,sz);
1223 tc = SWIG_TypeCheck(c,ty);
1224 if (!tc) return SWIG_ERROR;
1230 /* Macros for low-level exception handling */
1231 #define SWIG_croak(x) { SWIG_Error(SWIG_RuntimeError, x); SWIG_fail; }
1234 typedef XSPROTO(SwigPerlWrapper);
1235 typedef SwigPerlWrapper *SwigPerlWrapperPtr;
1237 /* Structure for command table */
1240 SwigPerlWrapperPtr wrapper;
1241 } swig_command_info;
1243 /* Information for constant table */
1246 #define SWIG_FLOAT 2
1247 #define SWIG_STRING 3
1248 #define SWIG_POINTER 4
1249 #define SWIG_BINARY 5
1251 /* Constant information structure */
1252 typedef struct swig_constant_info {
1258 swig_type_info **ptype;
1259 } swig_constant_info;
1262 /* Structure for variable table */
1267 swig_type_info **type;
1268 } swig_variable_info;
1270 /* Magic variable code */
1272 #define swig_create_magic(s,a,b,c) _swig_create_magic(s,a,b,c)
1273 #ifndef MULTIPLICITY
1274 SWIGRUNTIME void _swig_create_magic(SV *sv, char *name, int (*set)(SV *, MAGIC *), int (*get)(SV *,MAGIC *))
1276 SWIGRUNTIME void _swig_create_magic(SV *sv, char *name, int (*set)(struct interpreter*, SV *, MAGIC *), int (*get)(struct interpreter*, SV *,MAGIC *))
1279 # define swig_create_magic(s,a,b,c) _swig_create_magic(pPerl,s,a,b,c)
1280 SWIGRUNTIME void _swig_create_magic(CPerlObj *pPerl, SV *sv, const char *name, int (CPerlObj::*set)(SV *, MAGIC *), int (CPerlObj::*get)(SV *, MAGIC *))
1284 sv_magic(sv,sv,'U',(char *) name,strlen(name));
1285 mg = mg_find(sv,'U');
1286 mg->mg_virtual = (MGVTBL *) malloc(sizeof(MGVTBL));
1287 mg->mg_virtual->svt_get = (SwigMagicFunc) get;
1288 mg->mg_virtual->svt_set = (SwigMagicFunc) set;
1289 mg->mg_virtual->svt_len = 0;
1290 mg->mg_virtual->svt_clear = 0;
1291 mg->mg_virtual->svt_free = 0;
1295 SWIGRUNTIME swig_module_info *
1296 SWIG_Perl_GetModule(void) {
1297 static void *type_pointer = (void *)0;
1300 /* first check if pointer already created */
1301 if (!type_pointer) {
1302 pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, FALSE | GV_ADDMULTI);
1303 if (pointer && SvOK(pointer)) {
1304 type_pointer = INT2PTR(swig_type_info **, SvIV(pointer));
1308 return (swig_module_info *) type_pointer;
1312 SWIG_Perl_SetModule(swig_module_info *module) {
1315 /* create a new pointer */
1316 pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, TRUE | GV_ADDMULTI);
1317 sv_setiv(pointer, PTR2IV(module));
1324 /* Workaround perl5 global namespace pollution. Note that undefining library
1325 * functions like fopen will not solve the problem on all platforms as fopen
1326 * might be a macro on Windows but not necessarily on other operating systems. */
1420 #define SWIG_exception_fail(code, msg) do { SWIG_Error(code, msg); SWIG_fail; } while(0)
1422 #define SWIG_contract_assert(expr, msg) if (!(expr)) { SWIG_Error(SWIG_RuntimeError, msg); SWIG_fail; } else
1426 #define SWIG_exception(code, msg) do { SWIG_Error(code, msg); SWIG_fail;; } while(0)
1429 /* -------- TYPES TABLE (BEGIN) -------- */
1431 #define SWIGTYPE_p_Device swig_types[0]
1432 #define SWIGTYPE_p_Xfer swig_types[1]
1433 #define SWIGTYPE_p_XferElement swig_types[2]
1434 #define SWIGTYPE_p_a_STRMAX__char swig_types[3]
1435 #define SWIGTYPE_p_amglue_Source swig_types[4]
1436 #define SWIGTYPE_p_char swig_types[5]
1437 #define SWIGTYPE_p_double swig_types[6]
1438 #define SWIGTYPE_p_float swig_types[7]
1439 #define SWIGTYPE_p_guint32 swig_types[8]
1440 #define SWIGTYPE_p_guint64 swig_types[9]
1441 #define SWIGTYPE_p_int swig_types[10]
1442 #define SWIGTYPE_p_p_XferElement swig_types[11]
1443 #define SWIGTYPE_p_queue_fd_t swig_types[12]
1444 #define SWIGTYPE_p_unsigned_char swig_types[13]
1445 static swig_type_info *swig_types[15];
1446 static swig_module_info swig_module = {swig_types, 14, 0, 0, 0, 0};
1447 #define SWIG_TypeQuery(name) SWIG_TypeQueryModule(&swig_module, &swig_module, name)
1448 #define SWIG_MangledTypeQuery(name) SWIG_MangledTypeQueryModule(&swig_module, &swig_module, name)
1450 /* -------- TYPES TABLE (END) -------- */
1452 #define SWIG_init boot_Amanda__Xfer
1454 #define SWIG_name "Amanda::Xferc::boot_Amanda__Xfer"
1455 #define SWIG_prefix "Amanda::Xferc::"
1457 #define SWIGVERSION 0x010335
1458 #define SWIG_VERSION SWIGVERSION
1461 #define SWIG_as_voidptr(a) (void *)((const void *)(a))
1462 #define SWIG_as_voidptrptr(a) ((void)SWIG_as_voidptr(*a),(void**)(a))
1469 #ifndef MULTIPLICITY
1470 SWIGEXPORT void SWIG_init (CV* cv);
1472 SWIGEXPORT void SWIG_init (pTHXo_ CV* cv);
1475 SWIGEXPORT void SWIG_init (CV *cv, CPerlObj *);
1488 #include "glib-util.h"
1492 SWIGINTERNINLINE SV *
1493 SWIG_From_long SWIG_PERL_DECL_ARGS_1(long value)
1495 SV *obj = sv_newmortal();
1496 sv_setiv(obj, (IV) value);
1501 SWIGINTERNINLINE SV *
1502 SWIG_From_int SWIG_PERL_DECL_ARGS_1(int value)
1504 return SWIG_From_long SWIG_PERL_CALL_ARGS_1(value);
1508 /* Return a new SV with refcount 1 representing the given C object
1509 * with the given class.
1511 * @param c_obj: the object to represent
1512 * @param perl_class: the perl with which to bless and tie the SV
1517 const char *perl_class)
1521 /* Make an SV that contains a pointer to the object, and bless it
1522 * with the appropriate class. */
1523 sv_setref_pv(sv, perl_class, c_obj);
1528 /* Return a new SV representing a transfer.
1530 * @param xfer: the transfer to represent
1536 if (!xfer) return &PL_sv_undef;
1539 return new_sv_for_c_obj(xfer, "Amanda::Xfer::Xfer");
1542 /* Return a new SV representing a transfer element.
1544 * @param xe: the transfer element to represent
1547 new_sv_for_xfer_element(
1550 const char *perl_class;
1552 if (!xe) return &PL_sv_undef;
1554 perl_class = XFER_ELEMENT_GET_CLASS(xe)->perl_class;
1555 if (!perl_class) die("Attempt to wrap an XferElementClass with no perl class!");
1557 return new_sv_for_c_obj(xe, perl_class);
1560 /* Return the C object buried in an SV, asserting that the perl SV is
1561 * derived from derived_from. Returns NULL for undefined perl values.
1563 * This function is based on SWIG's SWIG_Perl_ConvertPtr. The INT2PTR
1564 * situation certainly looks strange, but is documented in perlxs.
1566 * @param sv: the SV to convert
1567 * @param derived_from: perl class from which the SV should be derived
1568 * @return: underlying pointer
1573 const char *derived_from)
1578 if (!sv) return NULL;
1579 if (!SvOK(sv)) return NULL;
1581 /* Peel back the layers. The sv should be a blessed reference to a PV,
1582 * and we check the class against derived_from to ensure we have the right
1584 if (!sv_isobject(sv) || !sv_derived_from(sv, derived_from)) {
1585 croak("Value is not an object of type %s", derived_from);
1589 referent = (SV *)SvRV(sv);
1590 tmp = SvIV(referent);
1591 return INT2PTR(gpointer, tmp);
1594 /* Convert an SV to an Xfer. The Xfer's reference count is not
1595 * incremented -- this is a "borrowed" reference.
1597 * @param sv: the perl value
1598 * @returns: pointer to the corresponding transfer, or NULL
1604 return (Xfer *)c_obj_from_sv(sv, "Amanda::Xfer::Xfer");
1607 /* Convert an SV to an XferElement. The element's reference count is
1608 * not incremented -- this is a "borrowed" reference.
1610 * @param sv: the perl value
1611 * @returns: pointer to the corresponding transfer element, or NULL.
1613 static XferElement *
1614 xfer_element_from_sv(
1617 return (XferElement *)c_obj_from_sv(sv, "Amanda::Xfer::Element");
1620 /* Given an XMsg, return a hashref representing the message as a pure-perl
1621 * object. The object is new, has refcount 1, and is totally independent of
1622 * the underlying XMsg.
1624 * Reflecting the XMsg directly into Perl avoids the need to reference-count
1625 * the XMsg objects themselves, which can simply be freed after a callback
1626 * completes. The overhead of creating a hash is likely equivalent to or
1627 * less than the overhead that would be consumed with SWIG's swig_$field_get
1628 * accessors, assuming that perl code examines most of the fields in a message.
1630 * @param msg: the message to represent
1631 * @returns: a perl SV
1637 static HV *amanda_xfer_msg_stash = NULL;
1639 SV *rv = newRV_noinc((SV *)hash);
1641 /* bless the rv as an Amanda::Xfer::Msg object */
1642 if (!amanda_xfer_msg_stash) {
1643 amanda_xfer_msg_stash = gv_stashpv("Amanda::Xfer::Msg", GV_ADD);
1645 sv_bless(rv, amanda_xfer_msg_stash);
1647 /* TODO: consider optimizing by precomputing the hash values of
1651 hv_store(hash, "elt", 3, new_sv_for_xfer_element(msg->elt), 0);
1654 hv_store(hash, "type", 4, newSViv(msg->type), 0);
1657 hv_store(hash, "version", 7, newSViv(msg->version), 0);
1661 hv_store(hash, "message", 7, newSVpv(msg->message, 0), 0);
1668 #if !defined(SWIG_NO_LLONG_MAX)
1669 # if !defined(LLONG_MAX) && defined(__GNUC__) && defined (__LONG_LONG_MAX__)
1670 # define LLONG_MAX __LONG_LONG_MAX__
1671 # define LLONG_MIN (-LLONG_MAX - 1LL)
1672 # define ULLONG_MAX (LLONG_MAX * 2ULL + 1ULL)
1678 SWIG_AsVal_double SWIG_PERL_DECL_ARGS_2(SV *obj, double *val)
1681 if (val) *val = SvNV(obj);
1683 } else if (SvIOK(obj)) {
1684 if (val) *val = (double) SvIV(obj);
1685 return SWIG_AddCast(SWIG_OK);
1687 const char *nptr = SvPV_nolen(obj);
1690 double v = strtod(nptr, &endptr);
1691 if (errno == ERANGE) {
1693 return SWIG_OverflowError;
1695 if (*endptr == '\0') {
1697 return SWIG_Str2NumCast(SWIG_OK);
1702 return SWIG_TypeError;
1712 SWIGINTERNINLINE int
1713 SWIG_CanCastAsInteger(double *d, double min, double max) {
1715 if ((min <= x && x <= max)) {
1716 double fx = floor(x);
1717 double cx = ceil(x);
1718 double rd = ((x - fx) < 0.5) ? fx : cx; /* simple rint */
1719 if ((errno == EDOM) || (errno == ERANGE)) {
1722 double summ, reps, diff;
1725 } else if (rd > x) {
1732 if (reps < 8*DBL_EPSILON) {
1743 SWIG_AsVal_unsigned_SS_long SWIG_PERL_DECL_ARGS_2(SV *obj, unsigned long *val)
1746 if (val) *val = SvUV(obj);
1748 } else if (SvIOK(obj)) {
1754 return SWIG_OverflowError;
1758 const char *nptr = SvPV_nolen(obj);
1763 v = strtoul(nptr, &endptr,0);
1764 if (errno == ERANGE) {
1766 return SWIG_OverflowError;
1768 if (*endptr == '\0') {
1770 return SWIG_Str2NumCast(SWIG_OK);
1776 int res = SWIG_AddCast(SWIG_AsVal_double SWIG_PERL_CALL_ARGS_2(obj,&d));
1777 if (SWIG_IsOK(res) && SWIG_CanCastAsInteger(&d, 0, ULONG_MAX)) {
1778 if (val) *val = (unsigned long)(d);
1783 return SWIG_TypeError;
1788 SWIG_AsVal_unsigned_SS_int SWIG_PERL_DECL_ARGS_2(SV * obj, unsigned int *val)
1791 int res = SWIG_AsVal_unsigned_SS_long SWIG_PERL_CALL_ARGS_2(obj, &v);
1792 if (SWIG_IsOK(res)) {
1793 if ((v > UINT_MAX)) {
1794 return SWIG_OverflowError;
1796 if (val) *val = (unsigned int)(v);
1803 SWIGINTERNINLINE SV *
1804 SWIG_FromCharPtrAndSize(const char* carray, size_t size)
1806 SV *obj = sv_newmortal();
1808 sv_setpvn(obj, carray, size);
1810 sv_setsv(obj, &PL_sv_undef);
1816 SWIGINTERNINLINE SV *
1817 SWIG_FromCharPtr(const char *cptr)
1819 return SWIG_FromCharPtrAndSize(cptr, (cptr ? strlen(cptr) : 0));
1823 /* SWIG wants to treat this as a function */
1824 #define xfer_get_status(xfer) ((xfer)->status)
1827 SWIGINTERNINLINE int
1828 SWIG_AsVal_size_t SWIG_PERL_DECL_ARGS_2(SV * obj, size_t *val)
1831 int res = SWIG_AsVal_unsigned_SS_long SWIG_PERL_CALL_ARGS_2(obj, val ? &v : 0);
1832 if (SWIG_IsOK(res) && val) *val = (size_t)(v);
1838 SWIG_AsVal_long SWIG_PERL_DECL_ARGS_2(SV *obj, long* val)
1841 if (val) *val = SvIV(obj);
1845 const char *nptr = SvPV_nolen(obj);
1850 v = strtol(nptr, &endptr,0);
1851 if (errno == ERANGE) {
1853 return SWIG_OverflowError;
1855 if (*endptr == '\0') {
1857 return SWIG_Str2NumCast(SWIG_OK);
1863 int res = SWIG_AddCast(SWIG_AsVal_double SWIG_PERL_CALL_ARGS_2(obj,&d));
1864 if (SWIG_IsOK(res) && SWIG_CanCastAsInteger(&d, LONG_MIN, LONG_MAX)) {
1865 if (val) *val = (long)(d);
1870 return SWIG_TypeError;
1875 SWIG_AsVal_int SWIG_PERL_DECL_ARGS_2(SV * obj, int *val)
1878 int res = SWIG_AsVal_long SWIG_PERL_CALL_ARGS_2(obj, &v);
1879 if (SWIG_IsOK(res)) {
1880 if ((v < INT_MIN || v > INT_MAX)) {
1881 return SWIG_OverflowError;
1883 if (val) *val = (int)(v);
1891 SWIG_AsVal_unsigned_SS_char SWIG_PERL_DECL_ARGS_2(SV * obj, unsigned char *val)
1894 int res = SWIG_AsVal_unsigned_SS_long SWIG_PERL_CALL_ARGS_2(obj, &v);
1895 if (SWIG_IsOK(res)) {
1896 if ((v > UCHAR_MAX)) {
1897 return SWIG_OverflowError;
1899 if (val) *val = (unsigned char)(v);
1907 xmsgsource_perl_callback(
1913 amglue_Source *src = (amglue_Source *)data;
1916 g_assert(src->callback_sv != NULL);
1921 /* create a new SV pointing to 'src', and increase its refcount
1922 * accordingly. The SV is mortal, so FREETMPS will decrease the
1923 * refcount, unless the callee keeps a copy of it somewhere */
1924 amglue_source_ref(src);
1925 src_sv = SWIG_NewPointerObj(src, SWIGTYPE_p_amglue_Source,
1926 SWIG_OWNER | SWIG_SHADOW);
1930 XPUSHs(sv_2mortal(new_sv_for_xmsg(msg)));
1931 XPUSHs(sv_2mortal(new_sv_for_xfer(xfer)));
1934 call_sv(src->callback_sv, G_EVAL|G_DISCARD);
1939 /* these may have been freed, so don't use them after this point */
1943 /* check for an uncaught 'die'. If we don't do this, then Perl will longjmp()
1944 * over the GMainLoop mechanics, leaving GMainLoop in an inconsistent (locked)
1946 if (SvTRUE(ERRSV)) {
1947 /* We handle this just the way the default 'die' handler in Amanda::Debug
1948 * does, but since Amanda's debug support may not yet be running, we back
1949 * it up with an exit() */
1950 g_critical("%s", SvPV_nolen(ERRSV));
1959 xfer_get_amglue_source(
1962 return amglue_source_get(xfer_get_source(xfer),
1963 (GSourceFunc)xmsgsource_perl_callback);
1971 #define MAGIC_CLASS _wrap_Amanda::Xfer_var::
1972 class _wrap_Amanda::Xfer_var : public CPerlObj {
1977 SWIGCLASS_STATIC int swig_magic_readonly(pTHX_ SV *SWIGUNUSEDPARM(sv), MAGIC *SWIGUNUSEDPARM(mg)) {
1979 croak("Value is read-only.");
1995 XS(_wrap_xfer_new) {
1997 XferElement **arg1 = (XferElement **) 0 ;
2003 if ((items < 1) || (items > 1)) {
2004 SWIG_croak("Usage: xfer_new(elementlist,nelements);");
2010 /* check that it's an arrayref */
2011 if (!SvROK(ST(0)) || SvTYPE(SvRV(ST(0))) != SVt_PVAV) {
2012 SWIG_exception(SWIG_TypeError, "Expected an arrayref");
2014 av = (AV *)SvRV(ST(0));
2016 /* allocate memory for arg1 */
2017 arg2 = av_len(av)+1; /* av_len(av) is like $#av */
2018 arg1 = g_new(XferElement *, arg2);
2020 /* extract the underlying XferElement objects and add pointers to
2021 * them, "borrowing" the caller's references for the moment. */
2022 for (i = 0; i < arg2; i++) {
2023 SV **sv = av_fetch(av, i, 0);
2024 XferElement *elt = sv? xfer_element_from_sv(*sv):NULL;
2027 SWIG_exception(SWIG_TypeError, "Expected an arrayref of Amanda::Xfer::Element objects");
2032 result = (Xfer *)xfer_new(arg1,arg2);
2034 ST(argvi) = sv_2mortal(new_sv_for_xfer(result));
2038 /* free the element vector allocated in the (in) typemap */
2047 /* free the element vector allocated in the (in) typemap */
2055 XS(_wrap_xfer_unref) {
2057 Xfer *arg1 = (Xfer *) 0 ;
2061 if ((items < 1) || (items > 1)) {
2062 SWIG_croak("Usage: xfer_unref(Xfer *);");
2065 arg1 = xfer_from_sv(ST(0));
2078 XS(_wrap_xfer_get_status) {
2080 Xfer *arg1 = (Xfer *) 0 ;
2085 if ((items < 1) || (items > 1)) {
2086 SWIG_croak("Usage: xfer_get_status(xfer);");
2089 arg1 = xfer_from_sv(ST(0));
2091 result = (xfer_status)xfer_get_status(arg1);
2093 ST(argvi) = sv_2mortal(amglue_newSVi64(result));
2105 XS(_wrap_xfer_repr) {
2107 Xfer *arg1 = (Xfer *) 0 ;
2112 if ((items < 1) || (items > 1)) {
2113 SWIG_croak("Usage: xfer_repr(xfer);");
2116 arg1 = xfer_from_sv(ST(0));
2118 result = (char *)xfer_repr(arg1);
2119 ST(argvi) = SWIG_FromCharPtr((const char *)result); argvi++ ;
2129 XS(_wrap_xfer_start) {
2131 Xfer *arg1 = (Xfer *) 0 ;
2135 if ((items < 1) || (items > 1)) {
2136 SWIG_croak("Usage: xfer_start(xfer);");
2139 arg1 = xfer_from_sv(ST(0));
2152 XS(_wrap_xfer_cancel) {
2154 Xfer *arg1 = (Xfer *) 0 ;
2158 if ((items < 1) || (items > 1)) {
2159 SWIG_croak("Usage: xfer_cancel(xfer);");
2162 arg1 = xfer_from_sv(ST(0));
2175 XS(_wrap_xfer_element_unref) {
2177 XferElement *arg1 = (XferElement *) 0 ;
2181 if ((items < 1) || (items > 1)) {
2182 SWIG_croak("Usage: xfer_element_unref(elt);");
2185 arg1 = xfer_element_from_sv(ST(0));
2187 xfer_element_unref(arg1);
2198 XS(_wrap_xfer_element_repr) {
2200 XferElement *arg1 = (XferElement *) 0 ;
2205 if ((items < 1) || (items > 1)) {
2206 SWIG_croak("Usage: xfer_element_repr(elt);");
2209 arg1 = xfer_element_from_sv(ST(0));
2211 result = (char *)xfer_element_repr(arg1);
2212 ST(argvi) = SWIG_FromCharPtr((const char *)result); argvi++ ;
2222 XS(_wrap_xfer_source_device) {
2224 Device *arg1 = (Device *) 0 ;
2225 XferElement *result = 0 ;
2231 if ((items < 1) || (items > 1)) {
2232 SWIG_croak("Usage: xfer_source_device(device);");
2234 res1 = SWIG_ConvertPtr(ST(0), &argp1,SWIGTYPE_p_Device, 0 | 0 );
2235 if (!SWIG_IsOK(res1)) {
2236 SWIG_exception_fail(SWIG_ArgError(res1), "in method '" "xfer_source_device" "', argument " "1"" of type '" "Device *""'");
2238 arg1 = (Device *)(argp1);
2239 result = (XferElement *)xfer_source_device(arg1);
2241 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2246 xfer_element_unref(result);
2256 XS(_wrap_xfer_source_random) {
2260 XferElement *result = 0 ;
2264 if ((items < 2) || (items > 2)) {
2265 SWIG_croak("Usage: xfer_source_random(length,seed);");
2268 arg1 = amglue_SvU64(ST(0));
2271 arg2 = amglue_SvU32(ST(1));
2273 result = (XferElement *)xfer_source_random(arg1,arg2);
2275 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2279 xfer_element_unref(result);
2288 XS(_wrap_xfer_source_pattern) {
2291 void *arg2 = (void *) 0 ;
2293 XferElement *result = 0 ;
2297 if ((items < 2) || (items > 2)) {
2298 SWIG_croak("Usage: xfer_source_pattern(length,pattern,pattern_length);");
2301 arg1 = amglue_SvU64(ST(0));
2307 pat = SvPV(ST(1), len);
2308 arg2 = g_memdup(pat, len);
2311 result = (XferElement *)xfer_source_pattern(arg1,arg2,arg3);
2313 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2323 XS(_wrap_xfer_source_fd) {
2326 XferElement *result = 0 ;
2330 if ((items < 1) || (items > 1)) {
2331 SWIG_croak("Usage: xfer_source_fd(fd);");
2334 if (sizeof(signed int) == 1) {
2335 arg1 = amglue_SvI8(ST(0));
2336 } else if (sizeof(signed int) == 2) {
2337 arg1 = amglue_SvI16(ST(0));
2338 } else if (sizeof(signed int) == 4) {
2339 arg1 = amglue_SvI32(ST(0));
2340 } else if (sizeof(signed int) == 8) {
2341 arg1 = amglue_SvI64(ST(0));
2343 g_critical("Unexpected signed int >64 bits?"); /* should be optimized out unless sizeof(signed int) > 8 */
2346 result = (XferElement *)xfer_source_fd(arg1);
2348 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2353 xfer_element_unref(result);
2363 XS(_wrap_xfer_filter_xor) {
2365 unsigned char arg1 ;
2366 XferElement *result = 0 ;
2367 unsigned char val1 ;
2372 if ((items < 1) || (items > 1)) {
2373 SWIG_croak("Usage: xfer_filter_xor(xor_key);");
2375 ecode1 = SWIG_AsVal_unsigned_SS_char SWIG_PERL_CALL_ARGS_2(ST(0), &val1);
2376 if (!SWIG_IsOK(ecode1)) {
2377 SWIG_exception_fail(SWIG_ArgError(ecode1), "in method '" "xfer_filter_xor" "', argument " "1"" of type '" "unsigned char""'");
2379 arg1 = (unsigned char)(val1);
2380 result = (XferElement *)xfer_filter_xor(arg1);
2382 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2387 xfer_element_unref(result);
2397 XS(_wrap_xfer_dest_device) {
2399 Device *arg1 = (Device *) 0 ;
2401 XferElement *result = 0 ;
2407 if ((items < 2) || (items > 2)) {
2408 SWIG_croak("Usage: xfer_dest_device(device,max_memory);");
2410 res1 = SWIG_ConvertPtr(ST(0), &argp1,SWIGTYPE_p_Device, 0 | 0 );
2411 if (!SWIG_IsOK(res1)) {
2412 SWIG_exception_fail(SWIG_ArgError(res1), "in method '" "xfer_dest_device" "', argument " "1"" of type '" "Device *""'");
2414 arg1 = (Device *)(argp1);
2416 if (sizeof(size_t) == 1) {
2417 arg2 = amglue_SvU8(ST(1));
2418 } else if (sizeof(size_t) == 2) {
2419 arg2 = amglue_SvU16(ST(1));
2420 } else if (sizeof(size_t) == 4) {
2421 arg2 = amglue_SvU32(ST(1));
2422 } else if (sizeof(size_t) == 8) {
2423 arg2 = amglue_SvU64(ST(1));
2425 croak("Unexpected size_t >64 bits?"); /* should be optimized out unless sizeof(size_t) > 8 */
2428 result = (XferElement *)xfer_dest_device(arg1,arg2);
2430 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2436 xfer_element_unref(result);
2447 XS(_wrap_xfer_dest_null) {
2450 XferElement *result = 0 ;
2454 if ((items < 1) || (items > 1)) {
2455 SWIG_croak("Usage: xfer_dest_null(prng_seed);");
2458 arg1 = amglue_SvU32(ST(0));
2460 result = (XferElement *)xfer_dest_null(arg1);
2462 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2466 xfer_element_unref(result);
2475 XS(_wrap_xfer_dest_fd) {
2478 XferElement *result = 0 ;
2482 if ((items < 1) || (items > 1)) {
2483 SWIG_croak("Usage: xfer_dest_fd(fd);");
2486 if (sizeof(signed int) == 1) {
2487 arg1 = amglue_SvI8(ST(0));
2488 } else if (sizeof(signed int) == 2) {
2489 arg1 = amglue_SvI16(ST(0));
2490 } else if (sizeof(signed int) == 4) {
2491 arg1 = amglue_SvI32(ST(0));
2492 } else if (sizeof(signed int) == 8) {
2493 arg1 = amglue_SvI64(ST(0));
2495 g_critical("Unexpected signed int >64 bits?"); /* should be optimized out unless sizeof(signed int) > 8 */
2498 result = (XferElement *)xfer_dest_fd(arg1);
2500 ST(argvi) = sv_2mortal(new_sv_for_xfer_element(result));
2505 xfer_element_unref(result);
2515 XS(_wrap_xfer_get_amglue_source) {
2517 Xfer *arg1 = (Xfer *) 0 ;
2518 amglue_Source *result = 0 ;
2522 if ((items < 1) || (items > 1)) {
2523 SWIG_croak("Usage: xfer_get_amglue_source(xfer);");
2526 arg1 = xfer_from_sv(ST(0));
2528 result = (amglue_Source *)xfer_get_amglue_source(arg1);
2529 ST(argvi) = SWIG_NewPointerObj(SWIG_as_voidptr(result), SWIGTYPE_p_amglue_Source, SWIG_OWNER | SWIG_SHADOW); argvi++ ;
2540 /* -------- TYPE CONVERSION AND EQUIVALENCE RULES (BEGIN) -------- */
2542 static swig_type_info _swigt__p_Device = {"_p_Device", "struct Device *|Device *", 0, 0, (void*)"Amanda::Device::Device", 0};
2543 static swig_type_info _swigt__p_Xfer = {"_p_Xfer", "Xfer *", 0, 0, (void*)0, 0};
2544 static swig_type_info _swigt__p_XferElement = {"_p_XferElement", "XferElement *", 0, 0, (void*)0, 0};
2545 static swig_type_info _swigt__p_a_STRMAX__char = {"_p_a_STRMAX__char", "char (*)[STRMAX]|string_t *", 0, 0, (void*)0, 0};
2546 static swig_type_info _swigt__p_amglue_Source = {"_p_amglue_Source", "struct amglue_Source *|amglue_Source *", 0, 0, (void*)"Amanda::MainLoop::Source", 0};
2547 static swig_type_info _swigt__p_char = {"_p_char", "gchar *|char *", 0, 0, (void*)0, 0};
2548 static swig_type_info _swigt__p_double = {"_p_double", "double *|gdouble *", 0, 0, (void*)0, 0};
2549 static swig_type_info _swigt__p_float = {"_p_float", "float *|gfloat *", 0, 0, (void*)0, 0};
2550 static swig_type_info _swigt__p_guint32 = {"_p_guint32", "guint32 *", 0, 0, (void*)0, 0};
2551 static swig_type_info _swigt__p_guint64 = {"_p_guint64", "guint64 *", 0, 0, (void*)0, 0};
2552 static swig_type_info _swigt__p_int = {"_p_int", "SizeAccuracy *|xmsg_type *|int *|DeviceAccessMode *|MediaAccessMode *|ConcurrencyParadigm *|filetype_t *|gboolean *|GIOCondition *|PropertySource *|DeviceStatusFlags *|PropertyAccessFlags *|PropertyPhaseFlags *|xfer_status *|PropertySurety *|StreamingRequirement *", 0, 0, (void*)0, 0};
2553 static swig_type_info _swigt__p_p_XferElement = {"_p_p_XferElement", "XferElement **", 0, 0, (void*)0, 0};
2554 static swig_type_info _swigt__p_queue_fd_t = {"_p_queue_fd_t", "struct queue_fd_t *|queue_fd_t *", 0, 0, (void*)"Amanda::Device::queue_fd_t", 0};
2555 static swig_type_info _swigt__p_unsigned_char = {"_p_unsigned_char", "guchar *|unsigned char *", 0, 0, (void*)0, 0};
2557 static swig_type_info *swig_type_initial[] = {
2560 &_swigt__p_XferElement,
2561 &_swigt__p_a_STRMAX__char,
2562 &_swigt__p_amglue_Source,
2569 &_swigt__p_p_XferElement,
2570 &_swigt__p_queue_fd_t,
2571 &_swigt__p_unsigned_char,
2574 static swig_cast_info _swigc__p_Device[] = { {&_swigt__p_Device, 0, 0, 0},{0, 0, 0, 0}};
2575 static swig_cast_info _swigc__p_Xfer[] = { {&_swigt__p_Xfer, 0, 0, 0},{0, 0, 0, 0}};
2576 static swig_cast_info _swigc__p_XferElement[] = { {&_swigt__p_XferElement, 0, 0, 0},{0, 0, 0, 0}};
2577 static swig_cast_info _swigc__p_a_STRMAX__char[] = { {&_swigt__p_a_STRMAX__char, 0, 0, 0},{0, 0, 0, 0}};
2578 static swig_cast_info _swigc__p_amglue_Source[] = { {&_swigt__p_amglue_Source, 0, 0, 0},{0, 0, 0, 0}};
2579 static swig_cast_info _swigc__p_char[] = { {&_swigt__p_char, 0, 0, 0},{0, 0, 0, 0}};
2580 static swig_cast_info _swigc__p_double[] = { {&_swigt__p_double, 0, 0, 0},{0, 0, 0, 0}};
2581 static swig_cast_info _swigc__p_float[] = { {&_swigt__p_float, 0, 0, 0},{0, 0, 0, 0}};
2582 static swig_cast_info _swigc__p_guint32[] = { {&_swigt__p_guint32, 0, 0, 0},{0, 0, 0, 0}};
2583 static swig_cast_info _swigc__p_guint64[] = { {&_swigt__p_guint64, 0, 0, 0},{0, 0, 0, 0}};
2584 static swig_cast_info _swigc__p_int[] = { {&_swigt__p_int, 0, 0, 0},{0, 0, 0, 0}};
2585 static swig_cast_info _swigc__p_p_XferElement[] = { {&_swigt__p_p_XferElement, 0, 0, 0},{0, 0, 0, 0}};
2586 static swig_cast_info _swigc__p_queue_fd_t[] = { {&_swigt__p_queue_fd_t, 0, 0, 0},{0, 0, 0, 0}};
2587 static swig_cast_info _swigc__p_unsigned_char[] = { {&_swigt__p_unsigned_char, 0, 0, 0},{0, 0, 0, 0}};
2589 static swig_cast_info *swig_cast_initial[] = {
2592 _swigc__p_XferElement,
2593 _swigc__p_a_STRMAX__char,
2594 _swigc__p_amglue_Source,
2601 _swigc__p_p_XferElement,
2602 _swigc__p_queue_fd_t,
2603 _swigc__p_unsigned_char,
2607 /* -------- TYPE CONVERSION AND EQUIVALENCE RULES (END) -------- */
2609 static swig_constant_info swig_constants[] = {
2615 static swig_variable_info swig_variables[] = {
2618 static swig_command_info swig_commands[] = {
2619 {"Amanda::Xferc::xfer_new", _wrap_xfer_new},
2620 {"Amanda::Xferc::xfer_unref", _wrap_xfer_unref},
2621 {"Amanda::Xferc::xfer_get_status", _wrap_xfer_get_status},
2622 {"Amanda::Xferc::xfer_repr", _wrap_xfer_repr},
2623 {"Amanda::Xferc::xfer_start", _wrap_xfer_start},
2624 {"Amanda::Xferc::xfer_cancel", _wrap_xfer_cancel},
2625 {"Amanda::Xferc::xfer_element_unref", _wrap_xfer_element_unref},
2626 {"Amanda::Xferc::xfer_element_repr", _wrap_xfer_element_repr},
2627 {"Amanda::Xferc::xfer_source_device", _wrap_xfer_source_device},
2628 {"Amanda::Xferc::xfer_source_random", _wrap_xfer_source_random},
2629 {"Amanda::Xferc::xfer_source_pattern", _wrap_xfer_source_pattern},
2630 {"Amanda::Xferc::xfer_source_fd", _wrap_xfer_source_fd},
2631 {"Amanda::Xferc::xfer_filter_xor", _wrap_xfer_filter_xor},
2632 {"Amanda::Xferc::xfer_dest_device", _wrap_xfer_dest_device},
2633 {"Amanda::Xferc::xfer_dest_null", _wrap_xfer_dest_null},
2634 {"Amanda::Xferc::xfer_dest_fd", _wrap_xfer_dest_fd},
2635 {"Amanda::Xferc::xfer_get_amglue_source", _wrap_xfer_get_amglue_source},
2638 /* -----------------------------------------------------------------------------
2639 * Type initialization:
2640 * This problem is tough by the requirement that no dynamic
2641 * memory is used. Also, since swig_type_info structures store pointers to
2642 * swig_cast_info structures and swig_cast_info structures store pointers back
2643 * to swig_type_info structures, we need some lookup code at initialization.
2644 * The idea is that swig generates all the structures that are needed.
2645 * The runtime then collects these partially filled structures.
2646 * The SWIG_InitializeModule function takes these initial arrays out of
2647 * swig_module, and does all the lookup, filling in the swig_module.types
2648 * array with the correct data and linking the correct swig_cast_info
2649 * structures together.
2651 * The generated swig_type_info structures are assigned staticly to an initial
2652 * array. We just loop through that array, and handle each type individually.
2653 * First we lookup if this type has been already loaded, and if so, use the
2654 * loaded structure instead of the generated one. Then we have to fill in the
2655 * cast linked list. The cast data is initially stored in something like a
2656 * two-dimensional array. Each row corresponds to a type (there are the same
2657 * number of rows as there are in the swig_type_initial array). Each entry in
2658 * a column is one of the swig_cast_info structures for that type.
2659 * The cast_initial array is actually an array of arrays, because each row has
2660 * a variable number of columns. So to actually build the cast linked list,
2661 * we find the array of casts associated with the type, and loop through it
2662 * adding the casts to the list. The one last trick we need to do is making
2663 * sure the type pointer in the swig_cast_info struct is correct.
2665 * First off, we lookup the cast->type name to see if it is already loaded.
2666 * There are three cases to handle:
2667 * 1) If the cast->type has already been loaded AND the type we are adding
2668 * casting info to has not been loaded (it is in this module), THEN we
2669 * replace the cast->type pointer with the type pointer that has already
2671 * 2) If BOTH types (the one we are adding casting info to, and the
2672 * cast->type) are loaded, THEN the cast info has already been loaded by
2673 * the previous module so we just ignore it.
2674 * 3) Finally, if cast->type has not already been loaded, then we add that
2675 * swig_cast_info to the linked list (because the cast->type) pointer will
2677 * ----------------------------------------------------------------------------- */
2687 #define SWIGRUNTIME_DEBUG
2692 SWIG_InitializeModule(void *clientdata) {
2694 swig_module_info *module_head, *iter;
2697 clientdata = clientdata;
2699 /* check to see if the circular list has been setup, if not, set it up */
2700 if (swig_module.next==0) {
2701 /* Initialize the swig_module */
2702 swig_module.type_initial = swig_type_initial;
2703 swig_module.cast_initial = swig_cast_initial;
2704 swig_module.next = &swig_module;
2710 /* Try and load any already created modules */
2711 module_head = SWIG_GetModule(clientdata);
2713 /* This is the first module loaded for this interpreter */
2714 /* so set the swig module into the interpreter */
2715 SWIG_SetModule(clientdata, &swig_module);
2716 module_head = &swig_module;
2718 /* the interpreter has loaded a SWIG module, but has it loaded this one? */
2722 if (iter==&swig_module) {
2727 } while (iter!= module_head);
2729 /* if the is found in the list, then all is done and we may leave */
2731 /* otherwise we must add out module into the list */
2732 swig_module.next = module_head->next;
2733 module_head->next = &swig_module;
2736 /* When multiple interpeters are used, a module could have already been initialized in
2737 a different interpreter, but not yet have a pointer in this interpreter.
2738 In this case, we do not want to continue adding types... everything should be
2740 if (init == 0) return;
2742 /* Now work on filling in swig_module.types */
2743 #ifdef SWIGRUNTIME_DEBUG
2744 printf("SWIG_InitializeModule: size %d\n", swig_module.size);
2746 for (i = 0; i < swig_module.size; ++i) {
2747 swig_type_info *type = 0;
2748 swig_type_info *ret;
2749 swig_cast_info *cast;
2751 #ifdef SWIGRUNTIME_DEBUG
2752 printf("SWIG_InitializeModule: type %d %s\n", i, swig_module.type_initial[i]->name);
2755 /* if there is another module already loaded */
2756 if (swig_module.next != &swig_module) {
2757 type = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, swig_module.type_initial[i]->name);
2760 /* Overwrite clientdata field */
2761 #ifdef SWIGRUNTIME_DEBUG
2762 printf("SWIG_InitializeModule: found type %s\n", type->name);
2764 if (swig_module.type_initial[i]->clientdata) {
2765 type->clientdata = swig_module.type_initial[i]->clientdata;
2766 #ifdef SWIGRUNTIME_DEBUG
2767 printf("SWIG_InitializeModule: found and overwrite type %s \n", type->name);
2771 type = swig_module.type_initial[i];
2774 /* Insert casting types */
2775 cast = swig_module.cast_initial[i];
2776 while (cast->type) {
2777 /* Don't need to add information already in the list */
2779 #ifdef SWIGRUNTIME_DEBUG
2780 printf("SWIG_InitializeModule: look cast %s\n", cast->type->name);
2782 if (swig_module.next != &swig_module) {
2783 ret = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, cast->type->name);
2784 #ifdef SWIGRUNTIME_DEBUG
2785 if (ret) printf("SWIG_InitializeModule: found cast %s\n", ret->name);
2789 if (type == swig_module.type_initial[i]) {
2790 #ifdef SWIGRUNTIME_DEBUG
2791 printf("SWIG_InitializeModule: skip old type %s\n", ret->name);
2796 /* Check for casting already in the list */
2797 swig_cast_info *ocast = SWIG_TypeCheck(ret->name, type);
2798 #ifdef SWIGRUNTIME_DEBUG
2799 if (ocast) printf("SWIG_InitializeModule: skip old cast %s\n", ret->name);
2801 if (!ocast) ret = 0;
2806 #ifdef SWIGRUNTIME_DEBUG
2807 printf("SWIG_InitializeModule: adding cast %s\n", cast->type->name);
2810 type->cast->prev = cast;
2811 cast->next = type->cast;
2817 /* Set entry in modules->types array equal to the type */
2818 swig_module.types[i] = type;
2820 swig_module.types[i] = 0;
2822 #ifdef SWIGRUNTIME_DEBUG
2823 printf("**** SWIG_InitializeModule: Cast List ******\n");
2824 for (i = 0; i < swig_module.size; ++i) {
2826 swig_cast_info *cast = swig_module.cast_initial[i];
2827 printf("SWIG_InitializeModule: type %d %s\n", i, swig_module.type_initial[i]->name);
2828 while (cast->type) {
2829 printf("SWIG_InitializeModule: cast type %s\n", cast->type->name);
2833 printf("---- Total casts: %d\n",j);
2835 printf("**** SWIG_InitializeModule: Cast List ******\n");
2839 /* This function will propagate the clientdata field of type to
2840 * any new swig_type_info structures that have been added into the list
2841 * of equivalent types. It is like calling
2842 * SWIG_TypeClientData(type, clientdata) a second time.
2845 SWIG_PropagateClientData(void) {
2847 swig_cast_info *equiv;
2848 static int init_run = 0;
2850 if (init_run) return;
2853 for (i = 0; i < swig_module.size; i++) {
2854 if (swig_module.types[i]->clientdata) {
2855 equiv = swig_module.types[i]->cast;
2857 if (!equiv->converter) {
2858 if (equiv->type && !equiv->type->clientdata)
2859 SWIG_TypeClientData(equiv->type, swig_module.types[i]->clientdata);
2861 equiv = equiv->next;
2885 SWIG_InitializeModule(0);
2887 /* Install commands */
2888 for (i = 0; swig_commands[i].name; i++) {
2889 newXS((char*) swig_commands[i].name,swig_commands[i].wrapper, (char*)__FILE__);
2892 /* Install variables */
2893 for (i = 0; swig_variables[i].name; i++) {
2895 sv = get_sv((char*) swig_variables[i].name, TRUE | 0x2 | GV_ADDMULTI);
2896 if (swig_variables[i].type) {
2897 SWIG_MakePtr(sv,(void *)1, *swig_variables[i].type,0);
2899 sv_setiv(sv,(IV) 0);
2901 swig_create_magic(sv, (char *) swig_variables[i].name, swig_variables[i].set, swig_variables[i].get);
2904 /* Install constant */
2905 for (i = 0; swig_constants[i].type; i++) {
2907 sv = get_sv((char*)swig_constants[i].name, TRUE | 0x2 | GV_ADDMULTI);
2908 switch(swig_constants[i].type) {
2910 sv_setiv(sv, (IV) swig_constants[i].lvalue);
2913 sv_setnv(sv, (double) swig_constants[i].dvalue);
2916 sv_setpv(sv, (char *) swig_constants[i].pvalue);
2919 SWIG_MakePtr(sv, swig_constants[i].pvalue, *(swig_constants[i].ptype),0);
2922 SWIG_MakePackedObj(sv, swig_constants[i].pvalue, swig_constants[i].lvalue, *(swig_constants[i].ptype));
2931 /* We need GType and GThread initialized to use xfers */
2934 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2935 SV *sv = get_sv((char*) SWIG_prefix "XFER_INIT", TRUE | 0x2 | GV_ADDMULTI);
2936 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XFER_INIT)));
2938 } while(0) /*@SWIG@*/;
2939 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2940 SV *sv = get_sv((char*) SWIG_prefix "XFER_START", TRUE | 0x2 | GV_ADDMULTI);
2941 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XFER_START)));
2943 } while(0) /*@SWIG@*/;
2944 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2945 SV *sv = get_sv((char*) SWIG_prefix "XFER_RUNNING", TRUE | 0x2 | GV_ADDMULTI);
2946 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XFER_RUNNING)));
2948 } while(0) /*@SWIG@*/;
2949 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2950 SV *sv = get_sv((char*) SWIG_prefix "XFER_DONE", TRUE | 0x2 | GV_ADDMULTI);
2951 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XFER_DONE)));
2953 } while(0) /*@SWIG@*/;
2954 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2955 SV *sv = get_sv((char*) SWIG_prefix "XMSG_INFO", TRUE | 0x2 | GV_ADDMULTI);
2956 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XMSG_INFO)));
2958 } while(0) /*@SWIG@*/;
2959 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2960 SV *sv = get_sv((char*) SWIG_prefix "XMSG_ERROR", TRUE | 0x2 | GV_ADDMULTI);
2961 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XMSG_ERROR)));
2963 } while(0) /*@SWIG@*/;
2964 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2965 SV *sv = get_sv((char*) SWIG_prefix "XMSG_DONE", TRUE | 0x2 | GV_ADDMULTI);
2966 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XMSG_DONE)));
2968 } while(0) /*@SWIG@*/;
2969 /*@SWIG:/usr/share/swig/1.3.35/perl5/perltypemaps.swg,64,%set_constant@*/ do {
2970 SV *sv = get_sv((char*) SWIG_prefix "XMSG_CANCEL", TRUE | 0x2 | GV_ADDMULTI);
2971 sv_setsv(sv, SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(XMSG_CANCEL)));
2973 } while(0) /*@SWIG@*/;