File Coverage

itex2MML_perl.c

Criterion	Covered	Total	%
statement	125	618	20.2
branch	51	498	10.2
condition			n/a
subroutine			n/a
pod			n/a
total	176	1116	15.7

line	stmt	bran	code
1			/* ----------------------------------------------------------------------------
2			* This file was automatically generated by SWIG (http://www.swig.org).
3			* Version 3.0.12
4			*
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			* ----------------------------------------------------------------------------- */
10
11
12			#ifndef SWIGPERL
13			#define SWIGPERL
14			#endif
15
16			#define SWIG_CASTRANK_MODE
17
18			/* -----------------------------------------------------------------------------
19			* This section contains generic SWIG labels for method/variable
20			* declarations/attributes, and other compiler dependent labels.
21			* ----------------------------------------------------------------------------- */
22
23			/* template workaround for compilers that cannot correctly implement the C++ standard */
24			#ifndef SWIGTEMPLATEDISAMBIGUATOR
25			# if defined(__SUNPRO_CC) && (__SUNPRO_CC <= 0x560)
26			# define SWIGTEMPLATEDISAMBIGUATOR template
27			# elif defined(__HP_aCC)
28			/* Needed even with `aCC -AA' when `aCC -V' reports HP ANSI C++ B3910B A.03.55 */
29			/* If we find a maximum version that requires this, the test would be __HP_aCC <= 35500 for A.03.55 */
30			# define SWIGTEMPLATEDISAMBIGUATOR template
31			# else
32			# define SWIGTEMPLATEDISAMBIGUATOR
33			# endif
34			#endif
35
36			/* inline attribute */
37			#ifndef SWIGINLINE
38			# if defined(__cplusplus) \|\| (defined(__GNUC__) && !defined(__STRICT_ANSI__))
39			# define SWIGINLINE inline
40			# else
41			# define SWIGINLINE
42			# endif
43			#endif
44
45			/* attribute recognised by some compilers to avoid 'unused' warnings */
46			#ifndef SWIGUNUSED
47			# if defined(__GNUC__)
48			# if !(defined(__cplusplus)) \|\| (__GNUC__ > 3 \|\| (__GNUC__ == 3 && __GNUC_MINOR__ >= 4))
49			# define SWIGUNUSED __attribute__ ((__unused__))
50			# else
51			# define SWIGUNUSED
52			# endif
53			# elif defined(__ICC)
54			# define SWIGUNUSED __attribute__ ((__unused__))
55			# else
56			# define SWIGUNUSED
57			# endif
58			#endif
59
60			#ifndef SWIG_MSC_UNSUPPRESS_4505
61			# if defined(_MSC_VER)
62			# pragma warning(disable : 4505) /* unreferenced local function has been removed */
63			# endif
64			#endif
65
66			#ifndef SWIGUNUSEDPARM
67			# ifdef __cplusplus
68			# define SWIGUNUSEDPARM(p)
69			# else
70			# define SWIGUNUSEDPARM(p) p SWIGUNUSED
71			# endif
72			#endif
73
74			/* internal SWIG method */
75			#ifndef SWIGINTERN
76			# define SWIGINTERN static SWIGUNUSED
77			#endif
78
79			/* internal inline SWIG method */
80			#ifndef SWIGINTERNINLINE
81			# define SWIGINTERNINLINE SWIGINTERN SWIGINLINE
82			#endif
83
84			/* exporting methods */
85			#if defined(__GNUC__)
86			# if (__GNUC__ >= 4) \|\| (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)
87			# ifndef GCC_HASCLASSVISIBILITY
88			# define GCC_HASCLASSVISIBILITY
89			# endif
90			# endif
91			#endif
92
93			#ifndef SWIGEXPORT
94			# if defined(_WIN32) \|\| defined(__WIN32__) \|\| defined(__CYGWIN__)
95			# if defined(STATIC_LINKED)
96			# define SWIGEXPORT
97			# else
98			# define SWIGEXPORT __declspec(dllexport)
99			# endif
100			# else
101			# if defined(__GNUC__) && defined(GCC_HASCLASSVISIBILITY)
102			# define SWIGEXPORT __attribute__ ((visibility("default")))
103			# else
104			# define SWIGEXPORT
105			# endif
106			# endif
107			#endif
108
109			/* calling conventions for Windows */
110			#ifndef SWIGSTDCALL
111			# if defined(_WIN32) \|\| defined(__WIN32__) \|\| defined(__CYGWIN__)
112			# define SWIGSTDCALL __stdcall
113			# else
114			# define SWIGSTDCALL
115			# endif
116			#endif
117
118			/* Deal with Microsoft's attempt at deprecating C standard runtime functions */
119			#if !defined(SWIG_NO_CRT_SECURE_NO_DEPRECATE) && defined(_MSC_VER) && !defined(_CRT_SECURE_NO_DEPRECATE)
120			# define _CRT_SECURE_NO_DEPRECATE
121			#endif
122
123			/* Deal with Microsoft's attempt at deprecating methods in the standard C++ library */
124			#if !defined(SWIG_NO_SCL_SECURE_NO_DEPRECATE) && defined(_MSC_VER) && !defined(_SCL_SECURE_NO_DEPRECATE)
125			# define _SCL_SECURE_NO_DEPRECATE
126			#endif
127
128			/* Deal with Apple's deprecated 'AssertMacros.h' from Carbon-framework */
129			#if defined(__APPLE__) && !defined(__ASSERT_MACROS_DEFINE_VERSIONS_WITHOUT_UNDERSCORES)
130			# define __ASSERT_MACROS_DEFINE_VERSIONS_WITHOUT_UNDERSCORES 0
131			#endif
132
133			/* Intel's compiler complains if a variable which was never initialised is
134			* cast to void, which is a common idiom which we use to indicate that we
135			* are aware a variable isn't used. So we just silence that warning.
136			* See: https://github.com/swig/swig/issues/192 for more discussion.
137			*/
138			#ifdef __INTEL_COMPILER
139			# pragma warning disable 592
140			#endif
141
142			/* -----------------------------------------------------------------------------
143			* swigrun.swg
144			*
145			* This file contains generic C API SWIG runtime support for pointer
146			* type checking.
147			* ----------------------------------------------------------------------------- */
148
149			/* This should only be incremented when either the layout of swig_type_info changes,
150			or for whatever reason, the runtime changes incompatibly */
151			#define SWIG_RUNTIME_VERSION "4"
152
153			/* define SWIG_TYPE_TABLE_NAME as "SWIG_TYPE_TABLE" */
154			#ifdef SWIG_TYPE_TABLE
155			# define SWIG_QUOTE_STRING(x) #x
156			# define SWIG_EXPAND_AND_QUOTE_STRING(x) SWIG_QUOTE_STRING(x)
157			# define SWIG_TYPE_TABLE_NAME SWIG_EXPAND_AND_QUOTE_STRING(SWIG_TYPE_TABLE)
158			#else
159			# define SWIG_TYPE_TABLE_NAME
160			#endif
161
162			/*
163			You can use the SWIGRUNTIME and SWIGRUNTIMEINLINE macros for
164			creating a static or dynamic library from the SWIG runtime code.
165			In 99.9% of the cases, SWIG just needs to declare them as 'static'.
166
167			But only do this if strictly necessary, ie, if you have problems
168			with your compiler or suchlike.
169			*/
170
171			#ifndef SWIGRUNTIME
172			# define SWIGRUNTIME SWIGINTERN
173			#endif
174
175			#ifndef SWIGRUNTIMEINLINE
176			# define SWIGRUNTIMEINLINE SWIGRUNTIME SWIGINLINE
177			#endif
178
179			/* Generic buffer size */
180			#ifndef SWIG_BUFFER_SIZE
181			# define SWIG_BUFFER_SIZE 1024
182			#endif
183
184			/* Flags for pointer conversions */
185			#define SWIG_POINTER_DISOWN 0x1
186			#define SWIG_CAST_NEW_MEMORY 0x2
187
188			/* Flags for new pointer objects */
189			#define SWIG_POINTER_OWN 0x1
190
191
192			/*
193			Flags/methods for returning states.
194
195			The SWIG conversion methods, as ConvertPtr, return an integer
196			that tells if the conversion was successful or not. And if not,
197			an error code can be returned (see swigerrors.swg for the codes).
198
199			Use the following macros/flags to set or process the returning
200			states.
201
202			In old versions of SWIG, code such as the following was usually written:
203
204			if (SWIG_ConvertPtr(obj,vptr,ty.flags) != -1) {
205			// success code
206			} else {
207			//fail code
208			}
209
210			Now you can be more explicit:
211
212			int res = SWIG_ConvertPtr(obj,vptr,ty.flags);
213			if (SWIG_IsOK(res)) {
214			// success code
215			} else {
216			// fail code
217			}
218
219			which is the same really, but now you can also do
220
221			Type *ptr;
222			int res = SWIG_ConvertPtr(obj,(void **)(&ptr),ty.flags);
223			if (SWIG_IsOK(res)) {
224			// success code
225			if (SWIG_IsNewObj(res) {
226			...
227			delete *ptr;
228			} else {
229			...
230			}
231			} else {
232			// fail code
233			}
234
235			I.e., now SWIG_ConvertPtr can return new objects and you can
236			identify the case and take care of the deallocation. Of course that
237			also requires SWIG_ConvertPtr to return new result values, such as
238
239			int SWIG_ConvertPtr(obj, ptr,...) {
240			if () {
241			if () {
242			*ptr = ;
243			return SWIG_NEWOBJ;
244			} else {
245			*ptr = ;
246			return SWIG_OLDOBJ;
247			}
248			} else {
249			return SWIG_BADOBJ;
250			}
251			}
252
253			Of course, returning the plain '0(success)/-1(fail)' still works, but you can be
254			more explicit by returning SWIG_BADOBJ, SWIG_ERROR or any of the
255			SWIG errors code.
256
257			Finally, if the SWIG_CASTRANK_MODE is enabled, the result code
258			allows to return the 'cast rank', for example, if you have this
259
260			int food(double)
261			int fooi(int);
262
263			and you call
264
265			food(1) // cast rank '1' (1 -> 1.0)
266			fooi(1) // cast rank '0'
267
268			just use the SWIG_AddCast()/SWIG_CheckState()
269			*/
270
271			#define SWIG_OK (0)
272			#define SWIG_ERROR (-1)
273			#define SWIG_IsOK(r) (r >= 0)
274			#define SWIG_ArgError(r) ((r != SWIG_ERROR) ? r : SWIG_TypeError)
275
276			/* The CastRankLimit says how many bits are used for the cast rank */
277			#define SWIG_CASTRANKLIMIT (1 << 8)
278			/* The NewMask denotes the object was created (using new/malloc) */
279			#define SWIG_NEWOBJMASK (SWIG_CASTRANKLIMIT << 1)
280			/* The TmpMask is for in/out typemaps that use temporal objects */
281			#define SWIG_TMPOBJMASK (SWIG_NEWOBJMASK << 1)
282			/* Simple returning values */
283			#define SWIG_BADOBJ (SWIG_ERROR)
284			#define SWIG_OLDOBJ (SWIG_OK)
285			#define SWIG_NEWOBJ (SWIG_OK \| SWIG_NEWOBJMASK)
286			#define SWIG_TMPOBJ (SWIG_OK \| SWIG_TMPOBJMASK)
287			/* Check, add and del mask methods */
288			#define SWIG_AddNewMask(r) (SWIG_IsOK(r) ? (r \| SWIG_NEWOBJMASK) : r)
289			#define SWIG_DelNewMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_NEWOBJMASK) : r)
290			#define SWIG_IsNewObj(r) (SWIG_IsOK(r) && (r & SWIG_NEWOBJMASK))
291			#define SWIG_AddTmpMask(r) (SWIG_IsOK(r) ? (r \| SWIG_TMPOBJMASK) : r)
292			#define SWIG_DelTmpMask(r) (SWIG_IsOK(r) ? (r & ~SWIG_TMPOBJMASK) : r)
293			#define SWIG_IsTmpObj(r) (SWIG_IsOK(r) && (r & SWIG_TMPOBJMASK))
294
295			/* Cast-Rank Mode */
296			#if defined(SWIG_CASTRANK_MODE)
297			# ifndef SWIG_TypeRank
298			# define SWIG_TypeRank unsigned long
299			# endif
300			# ifndef SWIG_MAXCASTRANK /* Default cast allowed */
301			# define SWIG_MAXCASTRANK (2)
302			# endif
303			# define SWIG_CASTRANKMASK ((SWIG_CASTRANKLIMIT) -1)
304			# define SWIG_CastRank(r) (r & SWIG_CASTRANKMASK)
305	0		SWIGINTERNINLINE int SWIG_AddCast(int r) {
306	0	0	return SWIG_IsOK(r) ? ((SWIG_CastRank(r) < SWIG_MAXCASTRANK) ? (r + 1) : SWIG_ERROR) : r;
		0
307			}
308			SWIGINTERNINLINE int SWIG_CheckState(int r) {
309			return SWIG_IsOK(r) ? SWIG_CastRank(r) + 1 : 0;
310			}
311			#else /* no cast-rank mode */
312			# define SWIG_AddCast(r) (r)
313			# define SWIG_CheckState(r) (SWIG_IsOK(r) ? 1 : 0)
314			#endif
315
316
317			#include
318
319			#ifdef __cplusplus
320			extern "C" {
321			#endif
322
323			typedef void (swig_converter_func)(void , int );
324			typedef struct swig_type_info (swig_dycast_func)(void **);
325
326			/* Structure to store information on one type */
327			typedef struct swig_type_info {
328			const char name; / mangled name of this type */
329			const char str; / human readable name of this type */
330			swig_dycast_func dcast; /* dynamic cast function down a hierarchy */
331			struct swig_cast_info cast; / linked list of types that can cast into this type */
332			void clientdata; / language specific type data */
333			int owndata; /* flag if the structure owns the clientdata */
334			} swig_type_info;
335
336			/* Structure to store a type and conversion function used for casting */
337			typedef struct swig_cast_info {
338			swig_type_info type; / pointer to type that is equivalent to this type */
339			swig_converter_func converter; /* function to cast the void pointers */
340			struct swig_cast_info next; / pointer to next cast in linked list */
341			struct swig_cast_info prev; / pointer to the previous cast */
342			} swig_cast_info;
343
344			/* Structure used to store module information
345			* Each module generates one structure like this, and the runtime collects
346			* all of these structures and stores them in a circularly linked list.*/
347			typedef struct swig_module_info {
348			swig_type_info *types; / Array of pointers to swig_type_info structures that are in this module */
349			size_t size; /* Number of types in this module */
350			struct swig_module_info next; / Pointer to next element in circularly linked list */
351			swig_type_info *type_initial; / Array of initially generated type structures */
352			swig_cast_info *cast_initial; / Array of initially generated casting structures */
353			void clientdata; / Language specific module data */
354			} swig_module_info;
355
356			/*
357			Compare two type names skipping the space characters, therefore
358			"char" == "char " and "Class" == "Class", etc.
359
360			Return 0 when the two name types are equivalent, as in
361			strncmp, but skipping ' '.
362			*/
363			SWIGRUNTIME int
364	0		SWIG_TypeNameComp(const char f1, const char l1,
365			const char f2, const char l2) {
366	0	0	for (;(f1 != l1) && (f2 != l2); ++f1, ++f2) {
		0
367	0	0	while ((*f1 == ' ') && (f1 != l1)) ++f1;
		0
368	0	0	while ((*f2 == ' ') && (f2 != l2)) ++f2;
		0
369	0	0	if (f1 != f2) return (f1 > f2) ? 1 : -1;
		0
370			}
371	0		return (int)((l1 - f1) - (l2 - f2));
372			}
373
374			/*
375			Check type equivalence in a name list like \|\|...
376			Return 0 if equal, -1 if nb < tb, 1 if nb > tb
377			*/
378			SWIGRUNTIME int
379	0		SWIG_TypeCmp(const char nb, const char tb) {
380	0		int equiv = 1;
381	0		const char* te = tb + strlen(tb);
382	0		const char* ne = nb;
383	0	0	while (equiv != 0 && *ne) {
		0
384	0	0	for (nb = ne; *ne; ++ne) {
385	0	0	if (*ne == '\|') break;
386			}
387	0		equiv = SWIG_TypeNameComp(nb, ne, tb, te);
388	0	0	if (*ne) ++ne;
389			}
390	0		return equiv;
391			}
392
393			/*
394			Check type equivalence in a name list like \|\|...
395			Return 0 if not equal, 1 if equal
396			*/
397			SWIGRUNTIME int
398	0		SWIG_TypeEquiv(const char nb, const char tb) {
399	0		return SWIG_TypeCmp(nb, tb) == 0 ? 1 : 0;
400			}
401
402			/*
403			Check the typename
404			*/
405			SWIGRUNTIME swig_cast_info *
406	0		SWIG_TypeCheck(const char c, swig_type_info ty) {
407	0	0	if (ty) {
408	0		swig_cast_info *iter = ty->cast;
409	0	0	while (iter) {
410	0	0	if (strcmp(iter->type->name, c) == 0) {
411	0	0	if (iter == ty->cast)
412	0		return iter;
413			/* Move iter to the top of the linked list */
414	0		iter->prev->next = iter->next;
415	0	0	if (iter->next)
416	0		iter->next->prev = iter->prev;
417	0		iter->next = ty->cast;
418	0		iter->prev = 0;
419	0	0	if (ty->cast) ty->cast->prev = iter;
420	0		ty->cast = iter;
421	0		return iter;
422			}
423	0		iter = iter->next;
424			}
425			}
426	0		return 0;
427			}
428
429			/*
430			Identical to SWIG_TypeCheck, except strcmp is replaced with a pointer comparison
431			*/
432			SWIGRUNTIME swig_cast_info *
433	0		SWIG_TypeCheckStruct(swig_type_info from, swig_type_info ty) {
434	0	0	if (ty) {
435	0		swig_cast_info *iter = ty->cast;
436	0	0	while (iter) {
437	0	0	if (iter->type == from) {
438	0	0	if (iter == ty->cast)
439	0		return iter;
440			/* Move iter to the top of the linked list */
441	0		iter->prev->next = iter->next;
442	0	0	if (iter->next)
443	0		iter->next->prev = iter->prev;
444	0		iter->next = ty->cast;
445	0		iter->prev = 0;
446	0	0	if (ty->cast) ty->cast->prev = iter;
447	0		ty->cast = iter;
448	0		return iter;
449			}
450	0		iter = iter->next;
451			}
452			}
453	0		return 0;
454			}
455
456			/*
457			Cast a pointer up an inheritance hierarchy
458			*/
459			SWIGRUNTIMEINLINE void *
460	0		SWIG_TypeCast(swig_cast_info ty, void ptr, int *newmemory) {
461	0	0	return ((!ty) \|\| (!ty->converter)) ? ptr : (*ty->converter)(ptr, newmemory);
		0
462			}
463
464			/*
465			Dynamic pointer casting. Down an inheritance hierarchy
466			*/
467			SWIGRUNTIME swig_type_info *
468	0		SWIG_TypeDynamicCast(swig_type_info ty, void *ptr) {
469	0		swig_type_info *lastty = ty;
470	0	0	if (!ty \|\| !ty->dcast) return ty;
		0
471	0	0	while (ty && (ty->dcast)) {
		0
472	0		ty = (*ty->dcast)(ptr);
473	0	0	if (ty) lastty = ty;
474			}
475	0		return lastty;
476			}
477
478			/*
479			Return the name associated with this type
480			*/
481			SWIGRUNTIMEINLINE const char *
482			SWIG_TypeName(const swig_type_info *ty) {
483			return ty->name;
484			}
485
486			/*
487			Return the pretty name associated with this type,
488			that is an unmangled type name in a form presentable to the user.
489			*/
490			SWIGRUNTIME const char *
491	0		SWIG_TypePrettyName(const swig_type_info *type) {
492			/* The "str" field contains the equivalent pretty names of the
493			type, separated by vertical-bar characters. We choose
494			to print the last name, as it is often (?) the most
495			specific. */
496	0	0	if (!type) return NULL;
497	0	0	if (type->str != NULL) {
498	0		const char *last_name = type->str;
499			const char *s;
500	0	0	for (s = type->str; *s; s++)
501	0	0	if (*s == '\|') last_name = s+1;
502	0		return last_name;
503			}
504			else
505	0		return type->name;
506			}
507
508			/*
509			Set the clientdata field for a type
510			*/
511			SWIGRUNTIME void
512	0		SWIG_TypeClientData(swig_type_info ti, void clientdata) {
513	0		swig_cast_info *cast = ti->cast;
514			/* if (ti->clientdata == clientdata) return; */
515	0		ti->clientdata = clientdata;
516
517	0	0	while (cast) {
518	0	0	if (!cast->converter) {
519	0		swig_type_info *tc = cast->type;
520	0	0	if (!tc->clientdata) {
521	0		SWIG_TypeClientData(tc, clientdata);
522			}
523			}
524	0		cast = cast->next;
525			}
526	0		}
527			SWIGRUNTIME void
528	0		SWIG_TypeNewClientData(swig_type_info ti, void clientdata) {
529	0		SWIG_TypeClientData(ti, clientdata);
530	0		ti->owndata = 1;
531	0		}
532
533			/*
534			Search for a swig_type_info structure only by mangled name
535			Search is a O(log #types)
536
537			We start searching at module start, and finish searching when start == end.
538			Note: if start == end at the beginning of the function, we go all the way around
539			the circular list.
540			*/
541			SWIGRUNTIME swig_type_info *
542	0		SWIG_MangledTypeQueryModule(swig_module_info *start,
543			swig_module_info *end,
544			const char *name) {
545	0		swig_module_info *iter = start;
546			do {
547	0	0	if (iter->size) {
548	0		size_t l = 0;
549	0		size_t r = iter->size - 1;
550			do {
551			/* since l+r >= 0, we can (>> 1) instead (/ 2) */
552	0		size_t i = (l + r) >> 1;
553	0		const char *iname = iter->types[i]->name;
554	0	0	if (iname) {
555	0		int compare = strcmp(name, iname);
556	0	0	if (compare == 0) {
557	0		return iter->types[i];
558	0	0	} else if (compare < 0) {
559	0	0	if (i) {
560	0		r = i - 1;
561			} else {
562	0		break;
563			}
564	0	0	} else if (compare > 0) {
565	0		l = i + 1;
566			}
567			} else {
568	0		break; /* should never happen */
569			}
570	0	0	} while (l <= r);
571			}
572	0		iter = iter->next;
573	0	0	} while (iter != end);
574	0		return 0;
575			}
576
577			/*
578			Search for a swig_type_info structure for either a mangled name or a human readable name.
579			It first searches the mangled names of the types, which is a O(log #types)
580			If a type is not found it then searches the human readable names, which is O(#types).
581
582			We start searching at module start, and finish searching when start == end.
583			Note: if start == end at the beginning of the function, we go all the way around
584			the circular list.
585			*/
586			SWIGRUNTIME swig_type_info *
587	0		SWIG_TypeQueryModule(swig_module_info *start,
588			swig_module_info *end,
589			const char *name) {
590			/* STEP 1: Search the name field using binary search */
591	0		swig_type_info *ret = SWIG_MangledTypeQueryModule(start, end, name);
592	0	0	if (ret) {
593	0		return ret;
594			} else {
595			/* STEP 2: If the type hasn't been found, do a complete search
596			of the str field (the human readable name) */
597	0		swig_module_info *iter = start;
598			do {
599	0		size_t i = 0;
600	0	0	for (; i < iter->size; ++i) {
601	0	0	if (iter->types[i]->str && (SWIG_TypeEquiv(iter->types[i]->str, name)))
		0
602	0		return iter->types[i];
603			}
604	0		iter = iter->next;
605	0	0	} while (iter != end);
606			}
607
608			/* neither found a match */
609	0		return 0;
610			}
611
612			/*
613			Pack binary data into a string
614			*/
615			SWIGRUNTIME char *
616	0		SWIG_PackData(char c, void ptr, size_t sz) {
617			static const char hex[17] = "0123456789abcdef";
618	0		const unsigned char u = (unsigned char ) ptr;
619	0		const unsigned char *eu = u + sz;
620	0	0	for (; u != eu; ++u) {
621	0		unsigned char uu = *u;
622	0		*(c++) = hex[(uu & 0xf0) >> 4];
623	0		*(c++) = hex[uu & 0xf];
624			}
625	0		return c;
626			}
627
628			/*
629			Unpack binary data from a string
630			*/
631			SWIGRUNTIME const char *
632	0		SWIG_UnpackData(const char c, void ptr, size_t sz) {
633	0		unsigned char u = (unsigned char ) ptr;
634	0		const unsigned char *eu = u + sz;
635	0	0	for (; u != eu; ++u) {
636	0		char d = *(c++);
637			unsigned char uu;
638	0	0	if ((d >= '0') && (d <= '9'))
		0
639	0		uu = (unsigned char)((d - '0') << 4);
640	0	0	else if ((d >= 'a') && (d <= 'f'))
		0
641	0		uu = (unsigned char)((d - ('a'-10)) << 4);
642			else
643	0		return (char *) 0;
644	0		d = *(c++);
645	0	0	if ((d >= '0') && (d <= '9'))
		0
646	0		uu \|= (unsigned char)(d - '0');
647	0	0	else if ((d >= 'a') && (d <= 'f'))
		0
648	0		uu \|= (unsigned char)(d - ('a'-10));
649			else
650	0		return (char *) 0;
651	0		*u = uu;
652			}
653	0		return c;
654			}
655
656			/*
657			Pack 'void *' into a string buffer.
658			*/
659			SWIGRUNTIME char *
660	0		SWIG_PackVoidPtr(char buff, void ptr, const char *name, size_t bsz) {
661	0		char *r = buff;
662	0	0	if ((2sizeof(void ) + 2) > bsz) return 0;
663	0		*(r++) = '_';
664	0		r = SWIG_PackData(r,&ptr,sizeof(void *));
665	0	0	if (strlen(name) + 1 > (bsz - (r - buff))) return 0;
666	0		strcpy(r,name);
667	0		return buff;
668			}
669
670			SWIGRUNTIME const char *
671	0		SWIG_UnpackVoidPtr(const char c, void ptr, const char name) {
672	0	0	if (*c != '_') {
673	0	0	if (strcmp(c,"NULL") == 0) {
674	0		ptr = (void ) 0;
675	0		return name;
676			} else {
677	0		return 0;
678			}
679			}
680	0		return SWIG_UnpackData(++c,ptr,sizeof(void *));
681			}
682
683			SWIGRUNTIME char *
684	0		SWIG_PackDataName(char buff, void ptr, size_t sz, const char *name, size_t bsz) {
685	0		char *r = buff;
686	0	0	size_t lname = (name ? strlen(name) : 0);
687	0	0	if ((2*sz + 2 + lname) > bsz) return 0;
688	0		*(r++) = '_';
689	0		r = SWIG_PackData(r,ptr,sz);
690	0	0	if (lname) {
691	0		strncpy(r,name,lname+1);
692			} else {
693	0		*r = 0;
694			}
695	0		return buff;
696			}
697
698			SWIGRUNTIME const char *
699	0		SWIG_UnpackDataName(const char c, void ptr, size_t sz, const char *name) {
700	0	0	if (*c != '_') {
701	0	0	if (strcmp(c,"NULL") == 0) {
702	0		memset(ptr,0,sz);
703	0		return name;
704			} else {
705	0		return 0;
706			}
707			}
708	0		return SWIG_UnpackData(++c,ptr,sz);
709			}
710
711			#ifdef __cplusplus
712			}
713			#endif
714
715			/* Errors in SWIG */
716			#define SWIG_UnknownError -1
717			#define SWIG_IOError -2
718			#define SWIG_RuntimeError -3
719			#define SWIG_IndexError -4
720			#define SWIG_TypeError -5
721			#define SWIG_DivisionByZero -6
722			#define SWIG_OverflowError -7
723			#define SWIG_SyntaxError -8
724			#define SWIG_ValueError -9
725			#define SWIG_SystemError -10
726			#define SWIG_AttributeError -11
727			#define SWIG_MemoryError -12
728			#define SWIG_NullReferenceError -13
729
730
731
732			#ifdef __cplusplus
733			/* Needed on some windows machines---since MS plays funny games with the header files under C++ */
734			#include
735			#include
736			extern "C" {
737			#endif
738			#include "EXTERN.h"
739			#include "perl.h"
740			#include "XSUB.h"
741
742			/* Add in functionality missing in older versions of Perl. Much of this is based on Devel-PPPort on cpan. */
743
744			/* Add PERL_REVISION, PERL_VERSION, PERL_SUBVERSION if missing */
745			#ifndef PERL_REVISION
746			# if !defined(__PATCHLEVEL_H_INCLUDED__) && !(defined(PATCHLEVEL) && defined(SUBVERSION))
747			# define PERL_PATCHLEVEL_H_IMPLICIT
748			# include
749			# endif
750			# if !(defined(PERL_VERSION) \|\| (defined(SUBVERSION) && defined(PATCHLEVEL)))
751			# include
752			# endif
753			# ifndef PERL_REVISION
754			# define PERL_REVISION (5)
755			# define PERL_VERSION PATCHLEVEL
756			# define PERL_SUBVERSION SUBVERSION
757			# endif
758			#endif
759
760			#if defined(WIN32) && defined(PERL_OBJECT) && !defined(PerlIO_exportFILE)
761			#define PerlIO_exportFILE(fh,fl) (FILE*)(fh)
762			#endif
763
764			#ifndef SvIOK_UV
765			# define SvIOK_UV(sv) (SvIOK(sv) && (SvUVX(sv) == SvIVX(sv)))
766			#endif
767
768			#ifndef SvUOK
769			# define SvUOK(sv) SvIOK_UV(sv)
770			#endif
771
772			#if ((PERL_VERSION < 4) \|\| ((PERL_VERSION == 4) && (PERL_SUBVERSION <= 5)))
773			# define PL_sv_undef sv_undef
774			# define PL_na na
775			# define PL_errgv errgv
776			# define PL_sv_no sv_no
777			# define PL_sv_yes sv_yes
778			# define PL_markstack_ptr markstack_ptr
779			#endif
780
781			#ifndef IVSIZE
782			# ifdef LONGSIZE
783			# define IVSIZE LONGSIZE
784			# else
785			# define IVSIZE 4 /* A bold guess, but the best we can make. */
786			# endif
787			#endif
788
789			#ifndef INT2PTR
790			# if (IVSIZE == PTRSIZE) && (UVSIZE == PTRSIZE)
791			# define PTRV UV
792			# define INT2PTR(any,d) (any)(d)
793			# else
794			# if PTRSIZE == LONGSIZE
795			# define PTRV unsigned long
796			# else
797			# define PTRV unsigned
798			# endif
799			# define INT2PTR(any,d) (any)(PTRV)(d)
800			# endif
801
802			# define NUM2PTR(any,d) (any)(PTRV)(d)
803			# define PTR2IV(p) INT2PTR(IV,p)
804			# define PTR2UV(p) INT2PTR(UV,p)
805			# define PTR2NV(p) NUM2PTR(NV,p)
806
807			# if PTRSIZE == LONGSIZE
808			# define PTR2ul(p) (unsigned long)(p)
809			# else
810			# define PTR2ul(p) INT2PTR(unsigned long,p)
811			# endif
812			#endif /* !INT2PTR */
813
814			#ifndef SvPV_nolen
815			# define SvPV_nolen(x) SvPV(x,PL_na)
816			#endif
817
818			#ifndef get_sv
819			# define get_sv perl_get_sv
820			#endif
821
822			#ifndef ERRSV
823			# define ERRSV get_sv("@",FALSE)
824			#endif
825
826			#ifndef pTHX_
827			#define pTHX_
828			#endif
829
830			#include
831			#ifdef __cplusplus
832			}
833			#endif
834
835			/* -----------------------------------------------------------------------------
836			* error manipulation
837			* ----------------------------------------------------------------------------- */
838
839			SWIGINTERN const char*
840	0		SWIG_Perl_ErrorType(int code) {
841	0		switch(code) {
842			case SWIG_MemoryError:
843	0		return "MemoryError";
844			case SWIG_IOError:
845	0		return "IOError";
846			case SWIG_RuntimeError:
847	0		return "RuntimeError";
848			case SWIG_IndexError:
849	0		return "IndexError";
850			case SWIG_TypeError:
851	0		return "TypeError";
852			case SWIG_DivisionByZero:
853	0		return "ZeroDivisionError";
854			case SWIG_OverflowError:
855	0		return "OverflowError";
856			case SWIG_SyntaxError:
857	0		return "SyntaxError";
858			case SWIG_ValueError:
859	0		return "ValueError";
860			case SWIG_SystemError:
861	0		return "SystemError";
862			case SWIG_AttributeError:
863	0		return "AttributeError";
864			default:
865	0		return "RuntimeError";
866			}
867			}
868
869
870			/* -----------------------------------------------------------------------------
871			* perlrun.swg
872			*
873			* This file contains the runtime support for Perl modules
874			* and includes code for managing global variables and pointer
875			* type checking.
876			* ----------------------------------------------------------------------------- */
877
878			#ifdef PERL_OBJECT
879			#define SWIG_PERL_OBJECT_DECL CPerlObj *SWIGUNUSEDPARM(pPerl),
880			#define SWIG_PERL_OBJECT_CALL pPerl,
881			#else
882			#define SWIG_PERL_OBJECT_DECL
883			#define SWIG_PERL_OBJECT_CALL
884			#endif
885
886			/* Common SWIG API */
887
888			/* for raw pointers */
889			#define SWIG_ConvertPtr(obj, pp, type, flags) SWIG_Perl_ConvertPtr(SWIG_PERL_OBJECT_CALL obj, pp, type, flags)
890			#define SWIG_ConvertPtrAndOwn(obj, pp, type, flags,own) SWIG_Perl_ConvertPtrAndOwn(SWIG_PERL_OBJECT_CALL obj, pp, type, flags, own)
891			#define SWIG_NewPointerObj(p, type, flags) SWIG_Perl_NewPointerObj(SWIG_PERL_OBJECT_CALL p, type, flags)
892			#define swig_owntype int
893
894			/* for raw packed data */
895			#define SWIG_ConvertPacked(obj, p, s, type) SWIG_Perl_ConvertPacked(SWIG_PERL_OBJECT_CALL obj, p, s, type)
896			#define SWIG_NewPackedObj(p, s, type) SWIG_Perl_NewPackedObj(SWIG_PERL_OBJECT_CALL p, s, type)
897
898			/* for class or struct pointers */
899			#define SWIG_ConvertInstance(obj, pptr, type, flags) SWIG_ConvertPtr(obj, pptr, type, flags)
900			#define SWIG_NewInstanceObj(ptr, type, flags) SWIG_NewPointerObj(ptr, type, flags)
901
902			/* for C or C++ function pointers */
903			#define SWIG_ConvertFunctionPtr(obj, pptr, type) SWIG_ConvertPtr(obj, pptr, type, 0)
904			#define SWIG_NewFunctionPtrObj(ptr, type) SWIG_NewPointerObj(ptr, type, 0)
905
906			/* for C++ member pointers, ie, member methods */
907			#define SWIG_ConvertMember(obj, ptr, sz, ty) SWIG_ConvertPacked(obj, ptr, sz, ty)
908			#define SWIG_NewMemberObj(ptr, sz, type) SWIG_NewPackedObj(ptr, sz, type)
909
910
911			/* Runtime API */
912
913			#define SWIG_GetModule(clientdata) SWIG_Perl_GetModule(clientdata)
914			#define SWIG_SetModule(clientdata, pointer) SWIG_Perl_SetModule(pointer)
915
916
917			/* Error manipulation */
918
919			#define SWIG_ErrorType(code) SWIG_Perl_ErrorType(code)
920			#define SWIG_Error(code, msg) sv_setpvf(get_sv("@", GV_ADD), "%s %s", SWIG_ErrorType(code), msg)
921			#define SWIG_fail goto fail
922
923			/* Perl-specific SWIG API */
924
925			#define SWIG_MakePtr(sv, ptr, type, flags) SWIG_Perl_MakePtr(SWIG_PERL_OBJECT_CALL sv, ptr, type, flags)
926			#define SWIG_MakePackedObj(sv, p, s, type) SWIG_Perl_MakePackedObj(SWIG_PERL_OBJECT_CALL sv, p, s, type)
927			#define SWIG_SetError(str) SWIG_Error(SWIG_RuntimeError, str)
928
929
930			#define SWIG_PERL_DECL_ARGS_1(arg1) (SWIG_PERL_OBJECT_DECL arg1)
931			#define SWIG_PERL_CALL_ARGS_1(arg1) (SWIG_PERL_OBJECT_CALL arg1)
932			#define SWIG_PERL_DECL_ARGS_2(arg1, arg2) (SWIG_PERL_OBJECT_DECL arg1, arg2)
933			#define SWIG_PERL_CALL_ARGS_2(arg1, arg2) (SWIG_PERL_OBJECT_CALL arg1, arg2)
934
935			/* -----------------------------------------------------------------------------
936			* pointers/data manipulation
937			* ----------------------------------------------------------------------------- */
938
939			/* For backward compatibility only */
940			#define SWIG_POINTER_EXCEPTION 0
941
942			#ifdef __cplusplus
943			extern "C" {
944			#endif
945
946			#define SWIG_OWNER SWIG_POINTER_OWN
947			#define SWIG_SHADOW SWIG_OWNER << 1
948
949			#define SWIG_MAYBE_PERL_OBJECT SWIG_PERL_OBJECT_DECL
950
951			/* SWIG Perl macros */
952
953			/* Macro to declare an XS function */
954			#ifndef XSPROTO
955			# define XSPROTO(name) void name(pTHX_ CV* cv)
956			#endif
957
958			/* Macro to call an XS function */
959			#ifdef PERL_OBJECT
960			# define SWIG_CALLXS(_name) _name(cv,pPerl)
961			#else
962			# ifndef MULTIPLICITY
963			# define SWIG_CALLXS(_name) _name(cv)
964			# else
965			# define SWIG_CALLXS(_name) _name(PERL_GET_THX, cv)
966			# endif
967			#endif
968
969			#ifdef PERL_OBJECT
970			#define MAGIC_PPERL CPerlObj pPerl = (CPerlObj ) this;
971
972			#ifdef __cplusplus
973			extern "C" {
974			#endif
975			typedef int (CPerlObj::SwigMagicFunc)(SV , MAGIC *);
976			#ifdef __cplusplus
977			}
978			#endif
979
980			#define SWIG_MAGIC(a,b) (SV a, MAGIC b)
981			#define SWIGCLASS_STATIC
982
983			#else /* PERL_OBJECT */
984
985			#define MAGIC_PPERL
986			#define SWIGCLASS_STATIC static SWIGUNUSED
987
988			#ifndef MULTIPLICITY
989			#define SWIG_MAGIC(a,b) (SV a, MAGIC b)
990
991			#ifdef __cplusplus
992			extern "C" {
993			#endif
994			typedef int (SwigMagicFunc)(SV , MAGIC *);
995			#ifdef __cplusplus
996			}
997			#endif
998
999			#else /* MULTIPLICITY */
1000
1001			#define SWIG_MAGIC(a,b) (struct interpreter interp, SV a, MAGIC *b)
1002
1003			#ifdef __cplusplus
1004			extern "C" {
1005			#endif
1006			typedef int (SwigMagicFunc)(struct interpreter , SV , MAGIC );
1007			#ifdef __cplusplus
1008			}
1009			#endif
1010
1011			#endif /* MULTIPLICITY */
1012			#endif /* PERL_OBJECT */
1013
1014			# ifdef PERL_OBJECT
1015			# define SWIG_croak_null() SWIG_Perl_croak_null(pPerl)
1016			static void SWIGUNUSED SWIG_Perl_croak_null(CPerlObj *pPerl)
1017			# else
1018	0		static void SWIGUNUSED SWIG_croak_null()
1019			# endif
1020			{
1021	0		SV *err = get_sv("@", GV_ADD);
1022			# if (PERL_VERSION < 6)
1023			croak("%_", err);
1024			# else
1025	0	0	if (sv_isobject(err))
1026	0		croak(0);
1027			else
1028	0	0	croak("%s", SvPV_nolen(err));
1029			# endif
1030			}
1031
1032
1033			/*
1034			Define how strict is the cast between strings and integers/doubles
1035			when overloading between these types occurs.
1036
1037			The default is making it as strict as possible by using SWIG_AddCast
1038			when needed.
1039
1040			You can use -DSWIG_PERL_NO_STRICT_STR2NUM at compilation time to
1041			disable the SWIG_AddCast, making the casting between string and
1042			numbers less strict.
1043
1044			In the end, we try to solve the overloading between strings and
1045			numerical types in the more natural way, but if you can avoid it,
1046			well, avoid it using %rename, for example.
1047			*/
1048			#ifndef SWIG_PERL_NO_STRICT_STR2NUM
1049			# ifndef SWIG_PERL_STRICT_STR2NUM
1050			# define SWIG_PERL_STRICT_STR2NUM
1051			# endif
1052			#endif
1053			#ifdef SWIG_PERL_STRICT_STR2NUM
1054			/* string takes precedence */
1055			#define SWIG_Str2NumCast(x) SWIG_AddCast(x)
1056			#else
1057			/* number takes precedence */
1058			#define SWIG_Str2NumCast(x) x
1059			#endif
1060
1061
1062
1063			#include
1064
1065			SWIGRUNTIME const char *
1066	0		SWIG_Perl_TypeProxyName(const swig_type_info *type) {
1067	0	0	if (!type) return NULL;
1068	0	0	if (type->clientdata != NULL) {
1069	0		return (const char*) type->clientdata;
1070			}
1071			else {
1072	0		return type->name;
1073			}
1074			}
1075
1076			/* Identical to SWIG_TypeCheck, except for strcmp comparison */
1077			SWIGRUNTIME swig_cast_info *
1078	0		SWIG_TypeProxyCheck(const char c, swig_type_info ty) {
1079	0	0	if (ty) {
1080	0		swig_cast_info *iter = ty->cast;
1081	0	0	while (iter) {
1082	0	0	if (strcmp(SWIG_Perl_TypeProxyName(iter->type), c) == 0) {
1083	0	0	if (iter == ty->cast)
1084	0		return iter;
1085			/* Move iter to the top of the linked list */
1086	0		iter->prev->next = iter->next;
1087	0	0	if (iter->next)
1088	0		iter->next->prev = iter->prev;
1089	0		iter->next = ty->cast;
1090	0		iter->prev = 0;
1091	0	0	if (ty->cast) ty->cast->prev = iter;
1092	0		ty->cast = iter;
1093	0		return iter;
1094			}
1095	0		iter = iter->next;
1096			}
1097			}
1098	0		return 0;
1099			}
1100
1101			/* Function for getting a pointer value */
1102
1103			SWIGRUNTIME int
1104	0		SWIG_Perl_ConvertPtrAndOwn(SWIG_MAYBE_PERL_OBJECT SV sv, void ptr, swig_type_info _t, int flags, int *own) {
1105			swig_cast_info *tc;
1106	0		void voidptr = (void )0;
1107	0		SV *tsv = 0;
1108
1109	0	0	if (own)
1110	0		*own = 0;
1111
1112			/* If magical, apply more magic */
1113	0	0	if (SvGMAGICAL(sv))
1114	0		mg_get(sv);
1115
1116			/* Check to see if this is an object */
1117	0	0	if (sv_isobject(sv)) {
1118	0		IV tmp = 0;
1119	0		tsv = (SV*) SvRV(sv);
1120	0	0	if ((SvTYPE(tsv) == SVt_PVHV)) {
1121			MAGIC *mg;
1122	0	0	if (SvMAGICAL(tsv)) {
1123	0		mg = mg_find(tsv,'P');
1124	0	0	if (mg) {
1125	0		sv = mg->mg_obj;
1126	0	0	if (sv_isobject(sv)) {
1127	0		tsv = (SV*)SvRV(sv);
1128	0	0	tmp = SvIV(tsv);
1129			}
1130			}
1131			} else {
1132	0		return SWIG_ERROR;
1133			}
1134			} else {
1135	0	0	tmp = SvIV(tsv);
1136			}
1137	0		voidptr = INT2PTR(void *,tmp);
1138	0	0	} else if (! SvOK(sv)) { /* Check for undef */
		0
		0
1139	0		(ptr) = (void ) 0;
1140	0		return SWIG_OK;
1141	0	0	} else if (SvTYPE(sv) == SVt_RV) { /* Check for NULL pointer */
1142	0	0	if (!SvROK(sv)) {
1143			/* In Perl 5.12 and later, SVt_RV == SVt_IV, so sv could be a valid integer value. */
1144	0	0	if (SvIOK(sv)) {
1145	0		return SWIG_ERROR;
1146			} else {
1147			/* NULL pointer (reference to undef). */
1148	0		(ptr) = (void ) 0;
1149	0		return SWIG_OK;
1150			}
1151			} else {
1152	0		return SWIG_ERROR;
1153			}
1154			} else { /* Don't know what it is */
1155	0		return SWIG_ERROR;
1156			}
1157	0	0	if (_t) {
1158			/* Now see if the types match */
1159	0	0	char *_c = HvNAME(SvSTASH(SvRV(sv)));
		0
		0
		0
		0
		0
1160	0		tc = SWIG_TypeProxyCheck(_c,_t);
1161			#ifdef SWIG_DIRECTORS
1162			if (!tc && !sv_derived_from(sv,SWIG_Perl_TypeProxyName(_t))) {
1163			#else
1164	0	0	if (!tc) {
1165			#endif
1166	0		return SWIG_ERROR;
1167			}
1168			{
1169	0		int newmemory = 0;
1170	0		*ptr = SWIG_TypeCast(tc,voidptr,&newmemory);
1171	0	0	if (newmemory == SWIG_CAST_NEW_MEMORY) {
1172			assert(own); /* badly formed typemap which will lead to a memory leak - it must set and use own to delete ptr /
1173	0	0	if (own)
1174	0		own = own \| SWIG_CAST_NEW_MEMORY;
1175			}
1176			}
1177			} else {
1178	0		*ptr = voidptr;
1179			}
1180
1181			/*
1182			* DISOWN implementation: we need a perl guru to check this one.
1183			*/
1184	0	0	if (tsv && (flags & SWIG_POINTER_DISOWN)) {
		0
1185			/*
1186			* almost copy paste code from below SWIG_POINTER_OWN setting
1187			*/
1188	0		SV *obj = sv;
1189	0		HV *stash = SvSTASH(SvRV(obj));
1190	0		GV gv = (GV**)hv_fetch(stash, "OWNER", 5, TRUE);
1191	0	0	if (isGV(gv)) {
1192	0	0	HV *hv = GvHVn(gv);
1193			/*
1194			* To set ownership (see below), a newSViv(1) entry is added.
1195			* Hence, to remove ownership, we delete the entry.
1196			*/
1197	0	0	if (hv_exists_ent(hv, obj, 0)) {
1198	0		hv_delete_ent(hv, obj, 0, 0);
1199			}
1200			}
1201			}
1202	0		return SWIG_OK;
1203			}
1204
1205			SWIGRUNTIME int
1206	0		SWIG_Perl_ConvertPtr(SWIG_MAYBE_PERL_OBJECT SV sv, void ptr, swig_type_info _t, int flags) {
1207	0		return SWIG_Perl_ConvertPtrAndOwn(sv, ptr, _t, flags, 0);
1208			}
1209
1210			SWIGRUNTIME void
1211	0		SWIG_Perl_MakePtr(SWIG_MAYBE_PERL_OBJECT SV sv, void ptr, swig_type_info *t, int flags) {
1212	0	0	if (ptr && (flags & (SWIG_SHADOW \| SWIG_POINTER_OWN))) {
		0
1213			SV *self;
1214	0		SV *obj=newSV(0);
1215	0		HV *hash=newHV();
1216			HV *stash;
1217	0		sv_setref_pv(obj, SWIG_Perl_TypeProxyName(t), ptr);
1218	0		stash=SvSTASH(SvRV(obj));
1219	0	0	if (flags & SWIG_POINTER_OWN) {
1220			HV *hv;
1221	0		GV gv = (GV**)hv_fetch(stash, "OWNER", 5, TRUE);
1222	0	0	if (!isGV(gv))
1223	0		gv_init(gv, stash, "OWNER", 5, FALSE);
1224	0	0	hv=GvHVn(gv);
1225	0		hv_store_ent(hv, obj, newSViv(1), 0);
1226			}
1227	0		sv_magic((SV )hash, (SV )obj, 'P', Nullch, 0);
1228	0		SvREFCNT_dec(obj);
1229	0		self=newRV_noinc((SV *)hash);
1230	0		sv_setsv(sv, self);
1231	0		SvREFCNT_dec((SV *)self);
1232	0		sv_bless(sv, stash);
1233			}
1234			else {
1235	0		sv_setref_pv(sv, SWIG_Perl_TypeProxyName(t), ptr);
1236			}
1237	0		}
1238
1239			SWIGRUNTIMEINLINE SV *
1240			SWIG_Perl_NewPointerObj(SWIG_MAYBE_PERL_OBJECT void ptr, swig_type_info t, int flags) {
1241			SV *result = sv_newmortal();
1242			SWIG_MakePtr(result, ptr, t, flags);
1243			return result;
1244			}
1245
1246			SWIGRUNTIME void
1247	0		SWIG_Perl_MakePackedObj(SWIG_MAYBE_PERL_OBJECT SV sv, void ptr, int sz, swig_type_info *type) {
1248			char result[1024];
1249	0		char *r = result;
1250	0	0	if ((2*sz + 1 + strlen(SWIG_Perl_TypeProxyName(type))) > 1000) return;
1251	0		*(r++) = '_';
1252	0		r = SWIG_PackData(r,ptr,sz);
1253	0		strcpy(r,SWIG_Perl_TypeProxyName(type));
1254	0		sv_setpv(sv, result);
1255			}
1256
1257			SWIGRUNTIME SV *
1258	0		SWIG_Perl_NewPackedObj(SWIG_MAYBE_PERL_OBJECT void ptr, int sz, swig_type_info type) {
1259	0		SV *result = sv_newmortal();
1260	0		SWIG_Perl_MakePackedObj(result, ptr, sz, type);
1261	0		return result;
1262			}
1263
1264			/* Convert a packed value value */
1265			SWIGRUNTIME int
1266	0		SWIG_Perl_ConvertPacked(SWIG_MAYBE_PERL_OBJECT SV obj, void ptr, int sz, swig_type_info *ty) {
1267			swig_cast_info *tc;
1268	0		const char *c = 0;
1269
1270	0	0	if ((!obj) \|\| (!SvOK(obj))) return SWIG_ERROR;
		0
		0
		0
1271	0	0	c = SvPV_nolen(obj);
1272			/* Pointer values must start with leading underscore */
1273	0	0	if (*c != '_') return SWIG_ERROR;
1274	0		c++;
1275	0		c = SWIG_UnpackData(c,ptr,sz);
1276	0	0	if (ty) {
1277	0		tc = SWIG_TypeCheck(c,ty);
1278	0	0	if (!tc) return SWIG_ERROR;
1279			}
1280	0		return SWIG_OK;
1281			}
1282
1283
1284			/* Macros for low-level exception handling */
1285			#define SWIG_croak(x) { SWIG_Error(SWIG_RuntimeError, x); SWIG_fail; }
1286
1287
1288			typedef XSPROTO(SwigPerlWrapper);
1289			typedef SwigPerlWrapper *SwigPerlWrapperPtr;
1290
1291			/* Structure for command table */
1292			typedef struct {
1293			const char *name;
1294			SwigPerlWrapperPtr wrapper;
1295			} swig_command_info;
1296
1297			/* Information for constant table */
1298
1299			#define SWIG_INT 1
1300			#define SWIG_FLOAT 2
1301			#define SWIG_STRING 3
1302			#define SWIG_POINTER 4
1303			#define SWIG_BINARY 5
1304
1305			/* Constant information structure */
1306			typedef struct swig_constant_info {
1307			int type;
1308			const char *name;
1309			long lvalue;
1310			double dvalue;
1311			void *pvalue;
1312			swig_type_info **ptype;
1313			} swig_constant_info;
1314
1315
1316			/* Structure for variable table */
1317			typedef struct {
1318			const char *name;
1319			SwigMagicFunc set;
1320			SwigMagicFunc get;
1321			swig_type_info **type;
1322			} swig_variable_info;
1323
1324			/* Magic variable code */
1325			#ifndef PERL_OBJECT
1326			# ifdef __cplusplus
1327			# define swig_create_magic(s,a,b,c) _swig_create_magic(s,const_cast(a),b,c)
1328			# else
1329			# define swig_create_magic(s,a,b,c) _swig_create_magic(s,(char*)(a),b,c)
1330			# endif
1331			# ifndef MULTIPLICITY
1332	0		SWIGRUNTIME void _swig_create_magic(SV sv, char name, int (set)(SV , MAGIC ), int (get)(SV ,MAGIC ))
1333			# else
1334			SWIGRUNTIME void _swig_create_magic(SV sv, char name, int (set)(struct interpreter, SV , MAGIC ), int (get)(struct interpreter, SV ,MAGIC ))
1335			# endif
1336			#else
1337			# define swig_create_magic(s,a,b,c) _swig_create_magic(pPerl,s,a,b,c)
1338			SWIGRUNTIME void _swig_create_magic(CPerlObj pPerl, SV sv, const char name, int (CPerlObj::set)(SV , MAGIC ), int (CPerlObj::get)(SV , MAGIC *))
1339			#endif
1340			{
1341			MAGIC *mg;
1342	0		sv_magic(sv,sv,'U',name,strlen(name));
1343	0		mg = mg_find(sv,'U');
1344	0		mg->mg_virtual = (MGVTBL *) malloc(sizeof(MGVTBL));
1345	0		mg->mg_virtual->svt_get = (SwigMagicFunc) get;
1346	0		mg->mg_virtual->svt_set = (SwigMagicFunc) set;
1347	0		mg->mg_virtual->svt_len = 0;
1348	0		mg->mg_virtual->svt_clear = 0;
1349	0		mg->mg_virtual->svt_free = 0;
1350	0		}
1351
1352
1353			SWIGRUNTIME swig_module_info *
1354	1		SWIG_Perl_GetModule(void *SWIGUNUSEDPARM(clientdata)) {
1355			static void type_pointer = (void )0;
1356			SV *pointer;
1357
1358			/* first check if pointer already created */
1359	1	50	if (!type_pointer) {
1360	1		pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, FALSE \| GV_ADDMULTI);
1361	1	50	if (pointer && SvOK(pointer)) {
		50
		50
		50
1362	0	0	type_pointer = INT2PTR(swig_type_info **, SvIV(pointer));
1363			}
1364			}
1365
1366	1		return (swig_module_info *) type_pointer;
1367			}
1368
1369			SWIGRUNTIME void
1370	1		SWIG_Perl_SetModule(swig_module_info *module) {
1371			SV *pointer;
1372
1373			/* create a new pointer */
1374	1		pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, TRUE \| GV_ADDMULTI);
1375	1		sv_setiv(pointer, PTR2IV(module));
1376	1		}
1377
1378			#ifdef __cplusplus
1379			}
1380			#endif
1381
1382			/* Workaround perl5 global namespace pollution. Note that undefining library
1383			* functions like fopen will not solve the problem on all platforms as fopen
1384			* might be a macro on Windows but not necessarily on other operating systems. */
1385			#ifdef do_open
1386			#undef do_open
1387			#endif
1388			#ifdef do_close
1389			#undef do_close
1390			#endif
1391			#ifdef do_exec
1392			#undef do_exec
1393			#endif
1394			#ifdef scalar
1395			#undef scalar
1396			#endif
1397			#ifdef list
1398			#undef list
1399			#endif
1400			#ifdef apply
1401			#undef apply
1402			#endif
1403			#ifdef convert
1404			#undef convert
1405			#endif
1406			#ifdef Error
1407			#undef Error
1408			#endif
1409			#ifdef form
1410			#undef form
1411			#endif
1412			#ifdef vform
1413			#undef vform
1414			#endif
1415			#ifdef LABEL
1416			#undef LABEL
1417			#endif
1418			#ifdef METHOD
1419			#undef METHOD
1420			#endif
1421			#ifdef Move
1422			#undef Move
1423			#endif
1424			#ifdef yylex
1425			#undef yylex
1426			#endif
1427			#ifdef yyparse
1428			#undef yyparse
1429			#endif
1430			#ifdef yyerror
1431			#undef yyerror
1432			#endif
1433			#ifdef invert
1434			#undef invert
1435			#endif
1436			#ifdef ref
1437			#undef ref
1438			#endif
1439			#ifdef read
1440			#undef read
1441			#endif
1442			#ifdef write
1443			#undef write
1444			#endif
1445			#ifdef eof
1446			#undef eof
1447			#endif
1448			#ifdef close
1449			#undef close
1450			#endif
1451			#ifdef rewind
1452			#undef rewind
1453			#endif
1454			#ifdef free
1455			#undef free
1456			#endif
1457			#ifdef malloc
1458			#undef malloc
1459			#endif
1460			#ifdef calloc
1461			#undef calloc
1462			#endif
1463			#ifdef Stat
1464			#undef Stat
1465			#endif
1466			#ifdef check
1467			#undef check
1468			#endif
1469			#ifdef seekdir
1470			#undef seekdir
1471			#endif
1472			#ifdef open
1473			#undef open
1474			#endif
1475			#ifdef readdir
1476			#undef readdir
1477			#endif
1478			#ifdef bind
1479			#undef bind
1480			#endif
1481			#ifdef access
1482			#undef access
1483			#endif
1484			#ifdef stat
1485			#undef stat
1486			#endif
1487			#ifdef seed
1488			#undef seed
1489			#endif
1490
1491			#ifdef bool
1492			/* Leave if macro is from C99 stdbool.h */
1493			#ifndef __bool_true_false_are_defined
1494			#undef bool
1495			#endif
1496			#endif
1497
1498
1499
1500
1501			#define SWIG_exception_fail(code, msg) do { SWIG_Error(code, msg); SWIG_fail; } while(0)
1502
1503			#define SWIG_contract_assert(expr, msg) if (!(expr)) { SWIG_Error(SWIG_RuntimeError, msg); SWIG_fail; } else
1504
1505
1506
1507			/* -------- TYPES TABLE (BEGIN) -------- */
1508
1509			#define SWIGTYPE_p_char swig_types[0]
1510			static swig_type_info *swig_types[2];
1511			static swig_module_info swig_module = {swig_types, 1, 0, 0, 0, 0};
1512			#define SWIG_TypeQuery(name) SWIG_TypeQueryModule(&swig_module, &swig_module, name)
1513			#define SWIG_MangledTypeQuery(name) SWIG_MangledTypeQueryModule(&swig_module, &swig_module, name)
1514
1515			/* -------- TYPES TABLE (END) -------- */
1516
1517			#define SWIG_init boot_MathML__itex2MML
1518
1519			#define SWIG_name "MathML::itex2MMLc::boot_MathML__itex2MML"
1520			#define SWIG_prefix "MathML::itex2MMLc::"
1521
1522			#define SWIGVERSION 0x030012
1523			#define SWIG_VERSION SWIGVERSION
1524
1525
1526			#define SWIG_as_voidptr(a) (void )((const void )(a))
1527			#define SWIG_as_voidptrptr(a) ((void)SWIG_as_voidptr(a),(void*)(a))
1528
1529
1530			#ifdef __cplusplus
1531			extern "C"
1532			#endif
1533			#ifndef PERL_OBJECT
1534			#ifndef MULTIPLICITY
1535			SWIGEXPORT void SWIG_init (CV* cv);
1536			#else
1537			SWIGEXPORT void SWIG_init (pTHXo_ CV* cv);
1538			#endif
1539			#else
1540			SWIGEXPORT void SWIG_init (CV cv, CPerlObj );
1541			#endif
1542
1543
1544			#include "itex2MML.h"
1545			extern const char * itex2MML_output ();
1546
1547
1548			SWIGINTERN swig_type_info*
1549	0		SWIG_pchar_descriptor(void)
1550			{
1551			static int init = 0;
1552			static swig_type_info* info = 0;
1553	0	0	if (!init) {
1554	0		info = SWIG_TypeQuery("_p_char");
1555	0		init = 1;
1556			}
1557	0		return info;
1558			}
1559
1560
1561			SWIGINTERN int
1562	4		SWIG_AsCharPtrAndSize(SV obj, char* cptr, size_t* psize, int *alloc)
1563			{
1564	4	50	if (SvMAGICAL(obj)) {
1565	0		SV *tmp = sv_newmortal();
1566	0	0	SvSetSV(tmp, obj);
1567	0		obj = tmp;
1568			}
1569	4	50	if (SvPOK(obj)) {
1570	4		STRLEN len = 0;
1571	4	50	char *cstr = SvPV(obj, len);
1572	4		size_t size = len + 1;
1573	4	50	if (cptr) {
1574	4	50	if (alloc) {
1575	4	50	if (*alloc == SWIG_NEWOBJ) {
1576	0		cptr = (char )memcpy(malloc((size)sizeof(char)), cstr, sizeof(char)(size));
1577			} else {
1578	4		*cptr = cstr;
1579	4		*alloc = SWIG_OLDOBJ;
1580			}
1581			}
1582			}
1583	4	50	if (psize) *psize = size;
1584	4		return SWIG_OK;
1585			} else {
1586	0		swig_type_info* pchar_descriptor = SWIG_pchar_descriptor();
1587	0	0	if (pchar_descriptor) {
1588	0		char* vptr = 0;
1589	0	0	if (SWIG_ConvertPtr(obj, (void**)&vptr, pchar_descriptor, 0) == SWIG_OK) {
1590	0	0	if (cptr) *cptr = vptr;
1591	0	0	if (psize) *psize = vptr ? (strlen(vptr) + 1) : 0;
		0
1592	0	0	if (alloc) *alloc = SWIG_OLDOBJ;
1593	0		return SWIG_OK;
1594			}
1595			}
1596			}
1597	0		return SWIG_TypeError;
1598			}
1599
1600
1601
1602
1603
1604			#include
1605			#if !defined(SWIG_NO_LLONG_MAX)
1606			# if !defined(LLONG_MAX) && defined(__GNUC__) && defined (__LONG_LONG_MAX__)
1607			# define LLONG_MAX __LONG_LONG_MAX__
1608			# define LLONG_MIN (-LLONG_MAX - 1LL)
1609			# define ULLONG_MAX (LLONG_MAX * 2ULL + 1ULL)
1610			# endif
1611			#endif
1612
1613
1614			#include
1615			#ifdef _MSC_VER
1616			# ifndef strtoull
1617			# define strtoull _strtoui64
1618			# endif
1619			# ifndef strtoll
1620			# define strtoll _strtoi64
1621			# endif
1622			#endif
1623
1624
1625			SWIGINTERN int
1626	0		SWIG_AsVal_double SWIG_PERL_DECL_ARGS_2(SV obj, double val)
1627			{
1628	0	0	if (SvNIOK(obj)) {
1629	0	0	if (val) *val = SvNV(obj);
		0
1630	0		return SWIG_OK;
1631	0	0	} else if (SvIOK(obj)) {
1632	0	0	if (val) *val = (double) SvIV(obj);
		0
1633	0		return SWIG_AddCast(SWIG_OK);
1634			} else {
1635	0	0	const char *nptr = SvPV_nolen(obj);
1636	0	0	if (nptr) {
1637			char *endptr;
1638			double v;
1639	0		errno = 0;
1640	0		v = strtod(nptr, &endptr);
1641	0	0	if (errno == ERANGE) {
1642	0		errno = 0;
1643	0		return SWIG_OverflowError;
1644			} else {
1645	0	0	if (*endptr == '\0') {
1646	0	0	if (val) *val = v;
1647	0		return SWIG_Str2NumCast(SWIG_OK);
1648			}
1649			}
1650			}
1651			}
1652	0		return SWIG_TypeError;
1653			}
1654
1655
1656			#include
1657
1658
1659			#include
1660
1661
1662			SWIGINTERNINLINE int
1663	0		SWIG_CanCastAsInteger(double *d, double min, double max) {
1664	0		double x = *d;
1665	0	0	if ((min <= x && x <= max)) {
		0
1666	0		double fx = floor(x);
1667	0		double cx = ceil(x);
1668	0	0	double rd = ((x - fx) < 0.5) ? fx : cx; /* simple rint */
1669	0	0	if ((errno == EDOM) \|\| (errno == ERANGE)) {
		0
1670	0		errno = 0;
1671			} else {
1672			double summ, reps, diff;
1673	0	0	if (rd < x) {
1674	0		diff = x - rd;
1675	0	0	} else if (rd > x) {
1676	0		diff = rd - x;
1677			} else {
1678	0		return 1;
1679			}
1680	0		summ = rd + x;
1681	0		reps = diff/summ;
1682	0	0	if (reps < 8*DBL_EPSILON) {
1683	0		*d = rd;
1684	0		return 1;
1685			}
1686			}
1687			}
1688	0		return 0;
1689			}
1690
1691
1692			SWIGINTERN int
1693	4		SWIG_AsVal_unsigned_SS_long SWIG_PERL_DECL_ARGS_2(SV obj, unsigned long val)
1694			{
1695	4	50	if (SvUOK(obj)) {
1696	0	0	UV v = SvUV(obj);
1697			if (UVSIZE <= sizeof(*val) \|\| v <= ULONG_MAX) {
1698	0	0	if (val) *val = v;
1699	0		return SWIG_OK;
1700			}
1701			return SWIG_OverflowError;
1702	4	50	} else if (SvIOK(obj)) {
1703	4	50	IV v = SvIV(obj);
1704	4	50	if (v >= 0 && (IVSIZE <= sizeof(*val) \|\| v <= ULONG_MAX)) {
1705	4	50	if (val) *val = v;
1706	4		return SWIG_OK;
1707			}
1708	0		return SWIG_OverflowError;
1709			} else {
1710	0		int dispatch = 0;
1711	0	0	const char *nptr = SvPV_nolen(obj);
1712	0	0	if (nptr) {
1713			char *endptr;
1714			unsigned long v;
1715	0		errno = 0;
1716	0		v = strtoul(nptr, &endptr,0);
1717	0	0	if (errno == ERANGE) {
1718	0		errno = 0;
1719	0		return SWIG_OverflowError;
1720			} else {
1721	0	0	if (*endptr == '\0') {
1722	0	0	if (val) *val = v;
1723	0		return SWIG_Str2NumCast(SWIG_OK);
1724			}
1725			}
1726			}
1727	0	0	if (!dispatch) {
1728			double d;
1729	0		int res = SWIG_AddCast(SWIG_AsVal_double SWIG_PERL_CALL_ARGS_2(obj,&d));
1730	0	0	if (SWIG_IsOK(res) && SWIG_CanCastAsInteger(&d, 0, ULONG_MAX)) {
		0
1731	0	0	if (val) *val = (unsigned long)(d);
1732	0		return res;
1733			}
1734			}
1735			}
1736	0		return SWIG_TypeError;
1737			}
1738
1739
1740			#if defined(LLONG_MAX) && !defined(SWIG_LONG_LONG_AVAILABLE)
1741			# define SWIG_LONG_LONG_AVAILABLE
1742			#endif
1743
1744
1745			#ifdef SWIG_LONG_LONG_AVAILABLE
1746			SWIGINTERN int
1747	0		SWIG_AsVal_unsigned_SS_long_SS_long SWIG_PERL_DECL_ARGS_2(SV obj, unsigned long long val)
1748			{
1749	0	0	if (SvUOK(obj)) {
1750			/* pretty sure this should be conditional on
1751			* (UVSIZE <= sizeof(val) \|\| v <= ULLONG_MAX) /
1752	0	0	if (val) *val = SvUV(obj);
		0
1753	0		return SWIG_OK;
1754	0	0	} else if (SvIOK(obj)) {
1755	0	0	IV v = SvIV(obj);
1756	0	0	if (v >= 0 && (IVSIZE <= sizeof(*val) \|\| v <= ULLONG_MAX)) {
1757	0	0	if (val) *val = v;
1758	0		return SWIG_OK;
1759			} else {
1760	0		return SWIG_OverflowError;
1761			}
1762			} else {
1763	0		int dispatch = 0;
1764	0	0	const char *nptr = SvPV_nolen(obj);
1765	0	0	if (nptr) {
1766			char *endptr;
1767			unsigned long long v;
1768	0		errno = 0;
1769	0		v = strtoull(nptr, &endptr,0);
1770	0	0	if (errno == ERANGE) {
1771	0		errno = 0;
1772	0		return SWIG_OverflowError;
1773			} else {
1774	0	0	if (*endptr == '\0') {
1775	0	0	if (val) *val = v;
1776	0		return SWIG_Str2NumCast(SWIG_OK);
1777			}
1778			}
1779			}
1780	0	0	if (!dispatch) {
1781	0		const double mant_max = 1LL << DBL_MANT_DIG;
1782			double d;
1783	0		int res = SWIG_AddCast(SWIG_AsVal_double SWIG_PERL_CALL_ARGS_2(obj,&d));
1784	0	0	if (SWIG_IsOK(res) && SWIG_CanCastAsInteger(&d, 0, mant_max)) {
		0
1785	0	0	if (val) *val = (unsigned long long)(d);
1786	0		return res;
1787			}
1788			}
1789			}
1790	0		return SWIG_TypeError;
1791			}
1792			#endif
1793
1794
1795			SWIGINTERNINLINE int
1796	4		SWIG_AsVal_size_t SWIG_PERL_DECL_ARGS_2(SV * obj, size_t *val)
1797			{
1798	4		int res = SWIG_TypeError;
1799			#ifdef SWIG_LONG_LONG_AVAILABLE
1800			if (sizeof(size_t) <= sizeof(unsigned long)) {
1801			#endif
1802			unsigned long v;
1803	4	50	res = SWIG_AsVal_unsigned_SS_long SWIG_PERL_CALL_ARGS_2(obj, val ? &v : 0);
1804	4	50	if (SWIG_IsOK(res) && val) *val = (size_t)(v);
		50
1805			#ifdef SWIG_LONG_LONG_AVAILABLE
1806			} else if (sizeof(size_t) <= sizeof(unsigned long long)) {
1807			unsigned long long v;
1808			res = SWIG_AsVal_unsigned_SS_long_SS_long SWIG_PERL_CALL_ARGS_2(obj, val ? &v : 0);
1809			if (SWIG_IsOK(res) && val) *val = (size_t)(v);
1810			}
1811			#endif
1812	4		return res;
1813			}
1814
1815
1816			SWIGINTERNINLINE SV *
1817	8		SWIG_From_long SWIG_PERL_DECL_ARGS_1(long value)
1818			{
1819			SV *sv;
1820			if (IVSIZE >= sizeof(value) \|\| (value >= IV_MIN && value <= IV_MAX))
1821	4		sv = newSViv(value);
1822			else
1823			sv = newSVpvf("%ld", value);
1824	4		return sv_2mortal(sv);
1825			}
1826
1827
1828			SWIGINTERNINLINE SV *
1829	4		SWIG_From_int SWIG_PERL_DECL_ARGS_1(int value)
1830			{
1831	4		return SWIG_From_long SWIG_PERL_CALL_ARGS_1(value);
1832			}
1833
1834
1835			SWIGINTERNINLINE SV *
1836	4		SWIG_FromCharPtrAndSize(const char* carray, size_t size)
1837			{
1838	4		SV *obj = sv_newmortal();
1839	4	50	if (carray) {
1840	4		sv_setpvn(obj, carray, size);
1841			} else {
1842	0		sv_setsv(obj, &PL_sv_undef);
1843			}
1844	4		return obj;
1845			}
1846
1847
1848			SWIGINTERNINLINE SV *
1849	4		SWIG_FromCharPtr(const char *cptr)
1850			{
1851	4	50	return SWIG_FromCharPtrAndSize(cptr, (cptr ? strlen(cptr) : 0));
1852			}
1853
1854			#ifdef __cplusplus
1855			extern "C" {
1856			#endif
1857
1858			#ifdef PERL_OBJECT
1859			#define MAGIC_CLASS _wrap_MathML__itex2MML_var::
1860			class _wrap_MathML__itex2MML_var : public CPerlObj {
1861			public:
1862			#else
1863			#define MAGIC_CLASS
1864			#endif
1865	0		SWIGCLASS_STATIC int swig_magic_readonly(pTHX_ SV SWIGUNUSEDPARM(sv), MAGIC SWIGUNUSEDPARM(mg)) {
1866			MAGIC_PPERL
1867	0		croak("Value is read-only.");
1868			return 0;
1869			}
1870
1871
1872			#ifdef PERL_OBJECT
1873			};
1874			#endif
1875
1876			#ifdef __cplusplus
1877			}
1878			#endif
1879
1880			#ifdef __cplusplus
1881			extern "C" {
1882			#endif
1883	3		XS(_wrap_itex2MML_filter) {
1884			{
1885	3		char arg1 = (char ) 0 ;
1886			size_t arg2 ;
1887			int res1 ;
1888	3		char *buf1 = 0 ;
1889	3		int alloc1 = 0 ;
1890			size_t val2 ;
1891	3		int ecode2 = 0 ;
1892	3		int argvi = 0;
1893			int result;
1894	3		dXSARGS;
1895
1896	3	50	if ((items < 2) \|\| (items > 2)) {
		50
1897	0		SWIG_croak("Usage: itex2MML_filter(buffer,length);");
1898			}
1899	3		res1 = SWIG_AsCharPtrAndSize(ST(0), &buf1, NULL, &alloc1);
1900	3	50	if (!SWIG_IsOK(res1)) {
1901	0	0	SWIG_exception_fail(SWIG_ArgError(res1), "in method '" "itex2MML_filter" "', argument " "1"" of type '" "char const *""'");
1902			}
1903	3		arg1 = (char *)(buf1);
1904	3		ecode2 = SWIG_AsVal_size_t SWIG_PERL_CALL_ARGS_2(ST(1), &val2);
1905	3	50	if (!SWIG_IsOK(ecode2)) {
1906	0	0	SWIG_exception_fail(SWIG_ArgError(ecode2), "in method '" "itex2MML_filter" "', argument " "2"" of type '" "size_t""'");
1907			}
1908	3		arg2 = (size_t)(val2);
1909	3		result = (int)itex2MML_filter((char const *)arg1,arg2);
1910	3		ST(argvi) = SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(result)); argvi++ ;
1911	3	50	if (alloc1 == SWIG_NEWOBJ) free((char*)buf1);
1912
1913	3		XSRETURN(argvi);
1914			fail:
1915	0	0	if (alloc1 == SWIG_NEWOBJ) free((char*)buf1);
1916
1917	0		SWIG_croak_null();
1918			}
1919			}
1920
1921
1922	1		XS(_wrap_itex2MML_html_filter) {
1923			{
1924	1		char arg1 = (char ) 0 ;
1925			size_t arg2 ;
1926			int res1 ;
1927	1		char *buf1 = 0 ;
1928	1		int alloc1 = 0 ;
1929			size_t val2 ;
1930	1		int ecode2 = 0 ;
1931	1		int argvi = 0;
1932			int result;
1933	1		dXSARGS;
1934
1935	1	50	if ((items < 2) \|\| (items > 2)) {
		50
1936	0		SWIG_croak("Usage: itex2MML_html_filter(buffer,length);");
1937			}
1938	1		res1 = SWIG_AsCharPtrAndSize(ST(0), &buf1, NULL, &alloc1);
1939	1	50	if (!SWIG_IsOK(res1)) {
1940	0	0	SWIG_exception_fail(SWIG_ArgError(res1), "in method '" "itex2MML_html_filter" "', argument " "1"" of type '" "char const *""'");
1941			}
1942	1		arg1 = (char *)(buf1);
1943	1		ecode2 = SWIG_AsVal_size_t SWIG_PERL_CALL_ARGS_2(ST(1), &val2);
1944	1	50	if (!SWIG_IsOK(ecode2)) {
1945	0	0	SWIG_exception_fail(SWIG_ArgError(ecode2), "in method '" "itex2MML_html_filter" "', argument " "2"" of type '" "size_t""'");
1946			}
1947	1		arg2 = (size_t)(val2);
1948	1		result = (int)itex2MML_html_filter((char const *)arg1,arg2);
1949	1		ST(argvi) = SWIG_From_int SWIG_PERL_CALL_ARGS_1((int)(result)); argvi++ ;
1950	1	50	if (alloc1 == SWIG_NEWOBJ) free((char*)buf1);
1951
1952	1		XSRETURN(argvi);
1953			fail:
1954	0	0	if (alloc1 == SWIG_NEWOBJ) free((char*)buf1);
1955
1956	0		SWIG_croak_null();
1957			}
1958			}
1959
1960
1961	4		XS(_wrap_itex2MML_output) {
1962			{
1963	4		int argvi = 0;
1964	4		char *result = 0 ;
1965	4		dXSARGS;
1966
1967	4	50	if ((items < 0) \|\| (items > 0)) {
		50
1968	0		SWIG_croak("Usage: itex2MML_output();");
1969			}
1970	4		result = (char *)itex2MML_output();
1971	4		ST(argvi) = SWIG_FromCharPtr((const char *)result); argvi++ ;
1972	4		XSRETURN(argvi);
1973			fail:
1974	0		SWIG_croak_null();
1975			}
1976			}
1977
1978
1979
1980			/* -------- TYPE CONVERSION AND EQUIVALENCE RULES (BEGIN) -------- */
1981
1982			static swig_type_info _swigt__p_char = {"_p_char", "char ", 0, 0, (void)0, 0};
1983
1984			static swig_type_info *swig_type_initial[] = {
1985			&_swigt__p_char,
1986			};
1987
1988			static swig_cast_info _swigc__p_char[] = { {&_swigt__p_char, 0, 0, 0},{0, 0, 0, 0}};
1989
1990			static swig_cast_info *swig_cast_initial[] = {
1991			_swigc__p_char,
1992			};
1993
1994
1995			/* -------- TYPE CONVERSION AND EQUIVALENCE RULES (END) -------- */
1996
1997			static swig_constant_info swig_constants[] = {
1998			{0,0,0,0,0,0}
1999			};
2000			#ifdef __cplusplus
2001			}
2002			#endif
2003			static swig_variable_info swig_variables[] = {
2004			{0,0,0,0}
2005			};
2006			static swig_command_info swig_commands[] = {
2007			{"MathML::itex2MMLc::itex2MML_filter", _wrap_itex2MML_filter},
2008			{"MathML::itex2MMLc::itex2MML_html_filter", _wrap_itex2MML_html_filter},
2009			{"MathML::itex2MMLc::itex2MML_output", _wrap_itex2MML_output},
2010			{0,0}
2011			};
2012			/* -----------------------------------------------------------------------------
2013			* Type initialization:
2014			* This problem is tough by the requirement that no dynamic
2015			* memory is used. Also, since swig_type_info structures store pointers to
2016			* swig_cast_info structures and swig_cast_info structures store pointers back
2017			* to swig_type_info structures, we need some lookup code at initialization.
2018			* The idea is that swig generates all the structures that are needed.
2019			* The runtime then collects these partially filled structures.
2020			* The SWIG_InitializeModule function takes these initial arrays out of
2021			* swig_module, and does all the lookup, filling in the swig_module.types
2022			* array with the correct data and linking the correct swig_cast_info
2023			* structures together.
2024			*
2025			* The generated swig_type_info structures are assigned statically to an initial
2026			* array. We just loop through that array, and handle each type individually.
2027			* First we lookup if this type has been already loaded, and if so, use the
2028			* loaded structure instead of the generated one. Then we have to fill in the
2029			* cast linked list. The cast data is initially stored in something like a
2030			* two-dimensional array. Each row corresponds to a type (there are the same
2031			* number of rows as there are in the swig_type_initial array). Each entry in
2032			* a column is one of the swig_cast_info structures for that type.
2033			* The cast_initial array is actually an array of arrays, because each row has
2034			* a variable number of columns. So to actually build the cast linked list,
2035			* we find the array of casts associated with the type, and loop through it
2036			* adding the casts to the list. The one last trick we need to do is making
2037			* sure the type pointer in the swig_cast_info struct is correct.
2038			*
2039			* First off, we lookup the cast->type name to see if it is already loaded.
2040			* There are three cases to handle:
2041			* 1) If the cast->type has already been loaded AND the type we are adding
2042			* casting info to has not been loaded (it is in this module), THEN we
2043			* replace the cast->type pointer with the type pointer that has already
2044			* been loaded.
2045			* 2) If BOTH types (the one we are adding casting info to, and the
2046			* cast->type) are loaded, THEN the cast info has already been loaded by
2047			* the previous module so we just ignore it.
2048			* 3) Finally, if cast->type has not already been loaded, then we add that
2049			* swig_cast_info to the linked list (because the cast->type) pointer will
2050			* be correct.
2051			* ----------------------------------------------------------------------------- */
2052
2053			#ifdef __cplusplus
2054			extern "C" {
2055			#if 0
2056			} /* c-mode */
2057			#endif
2058			#endif
2059
2060			#if 0
2061			#define SWIGRUNTIME_DEBUG
2062			#endif
2063
2064
2065			SWIGRUNTIME void
2066	1		SWIG_InitializeModule(void *clientdata) {
2067			size_t i;
2068			swig_module_info module_head, iter;
2069			int init;
2070
2071			/* check to see if the circular list has been setup, if not, set it up */
2072	1	50	if (swig_module.next==0) {
2073			/* Initialize the swig_module */
2074	1		swig_module.type_initial = swig_type_initial;
2075	1		swig_module.cast_initial = swig_cast_initial;
2076	1		swig_module.next = &swig_module;
2077	1		init = 1;
2078			} else {
2079	0		init = 0;
2080			}
2081
2082			/* Try and load any already created modules */
2083	1		module_head = SWIG_GetModule(clientdata);
2084	1	50	if (!module_head) {
2085			/* This is the first module loaded for this interpreter */
2086			/* so set the swig module into the interpreter */
2087	1		SWIG_SetModule(clientdata, &swig_module);
2088			} else {
2089			/* the interpreter has loaded a SWIG module, but has it loaded this one? */
2090	0		iter=module_head;
2091			do {
2092	0	0	if (iter==&swig_module) {
2093			/* Our module is already in the list, so there's nothing more to do. */
2094	0		return;
2095			}
2096	0		iter=iter->next;
2097	0	0	} while (iter!= module_head);
2098
2099			/* otherwise we must add our module into the list */
2100	0		swig_module.next = module_head->next;
2101	0		module_head->next = &swig_module;
2102			}
2103
2104			/* When multiple interpreters are used, a module could have already been initialized in
2105			a different interpreter, but not yet have a pointer in this interpreter.
2106			In this case, we do not want to continue adding types... everything should be
2107			set up already */
2108	1	50	if (init == 0) return;
2109
2110			/* Now work on filling in swig_module.types */
2111			#ifdef SWIGRUNTIME_DEBUG
2112			printf("SWIG_InitializeModule: size %d\n", swig_module.size);
2113			#endif
2114	2	100	for (i = 0; i < swig_module.size; ++i) {
2115	1		swig_type_info *type = 0;
2116			swig_type_info *ret;
2117			swig_cast_info *cast;
2118
2119			#ifdef SWIGRUNTIME_DEBUG
2120			printf("SWIG_InitializeModule: type %d %s\n", i, swig_module.type_initial[i]->name);
2121			#endif
2122
2123			/* if there is another module already loaded */
2124	1	50	if (swig_module.next != &swig_module) {
2125	0		type = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, swig_module.type_initial[i]->name);
2126			}
2127	1	50	if (type) {
2128			/* Overwrite clientdata field */
2129			#ifdef SWIGRUNTIME_DEBUG
2130			printf("SWIG_InitializeModule: found type %s\n", type->name);
2131			#endif
2132	0	0	if (swig_module.type_initial[i]->clientdata) {
2133	0		type->clientdata = swig_module.type_initial[i]->clientdata;
2134			#ifdef SWIGRUNTIME_DEBUG
2135			printf("SWIG_InitializeModule: found and overwrite type %s \n", type->name);
2136			#endif
2137			}
2138			} else {
2139	1		type = swig_module.type_initial[i];
2140			}
2141
2142			/* Insert casting types */
2143	1		cast = swig_module.cast_initial[i];
2144	2	100	while (cast->type) {
2145			/* Don't need to add information already in the list */
2146	1		ret = 0;
2147			#ifdef SWIGRUNTIME_DEBUG
2148			printf("SWIG_InitializeModule: look cast %s\n", cast->type->name);
2149			#endif
2150	1	50	if (swig_module.next != &swig_module) {
2151	0		ret = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, cast->type->name);
2152			#ifdef SWIGRUNTIME_DEBUG
2153			if (ret) printf("SWIG_InitializeModule: found cast %s\n", ret->name);
2154			#endif
2155			}
2156	1	50	if (ret) {
2157	0	0	if (type == swig_module.type_initial[i]) {
2158			#ifdef SWIGRUNTIME_DEBUG
2159			printf("SWIG_InitializeModule: skip old type %s\n", ret->name);
2160			#endif
2161	0		cast->type = ret;
2162	0		ret = 0;
2163			} else {
2164			/* Check for casting already in the list */
2165	0		swig_cast_info *ocast = SWIG_TypeCheck(ret->name, type);
2166			#ifdef SWIGRUNTIME_DEBUG
2167			if (ocast) printf("SWIG_InitializeModule: skip old cast %s\n", ret->name);
2168			#endif
2169	0	0	if (!ocast) ret = 0;
2170			}
2171			}
2172
2173	1	50	if (!ret) {
2174			#ifdef SWIGRUNTIME_DEBUG
2175			printf("SWIG_InitializeModule: adding cast %s\n", cast->type->name);
2176			#endif
2177	1	50	if (type->cast) {
2178	0		type->cast->prev = cast;
2179	0		cast->next = type->cast;
2180			}
2181	1		type->cast = cast;
2182			}
2183	1		cast++;
2184			}
2185			/* Set entry in modules->types array equal to the type */
2186	1		swig_module.types[i] = type;
2187			}
2188	1		swig_module.types[i] = 0;
2189
2190			#ifdef SWIGRUNTIME_DEBUG
2191			printf("** SWIG_InitializeModule: Cast List ****\n");
2192			for (i = 0; i < swig_module.size; ++i) {
2193			int j = 0;
2194			swig_cast_info *cast = swig_module.cast_initial[i];
2195			printf("SWIG_InitializeModule: type %d %s\n", i, swig_module.type_initial[i]->name);
2196			while (cast->type) {
2197			printf("SWIG_InitializeModule: cast type %s\n", cast->type->name);
2198			cast++;
2199			++j;
2200			}
2201			printf("---- Total casts: %d\n",j);
2202			}
2203			printf("** SWIG_InitializeModule: Cast List ****\n");
2204			#endif
2205			}
2206
2207			/* This function will propagate the clientdata field of type to
2208			* any new swig_type_info structures that have been added into the list
2209			* of equivalent types. It is like calling
2210			* SWIG_TypeClientData(type, clientdata) a second time.
2211			*/
2212			SWIGRUNTIME void
2213	0		SWIG_PropagateClientData(void) {
2214			size_t i;
2215			swig_cast_info *equiv;
2216			static int init_run = 0;
2217
2218	0	0	if (init_run) return;
2219	0		init_run = 1;
2220
2221	0	0	for (i = 0; i < swig_module.size; i++) {
2222	0	0	if (swig_module.types[i]->clientdata) {
2223	0		equiv = swig_module.types[i]->cast;
2224	0	0	while (equiv) {
2225	0	0	if (!equiv->converter) {
2226	0	0	if (equiv->type && !equiv->type->clientdata)
		0
2227	0		SWIG_TypeClientData(equiv->type, swig_module.types[i]->clientdata);
2228			}
2229	0		equiv = equiv->next;
2230			}
2231			}
2232			}
2233			}
2234
2235			#ifdef __cplusplus
2236			#if 0
2237			{
2238			/* c-mode */
2239			#endif
2240			}
2241			#endif
2242
2243
2244
2245			#if defined(__cplusplus) && ! defined(XSPROTO)
2246			extern "C"
2247			#endif
2248
2249	1		XS(SWIG_init) {
2250	1		dXSARGS;
2251			int i;
2252			(void)items;
2253
2254	1		SWIG_InitializeModule(0);
2255
2256			/* Install commands */
2257	4	100	for (i = 0; swig_commands[i].name; i++) {
2258			/* Casts only needed for Perl < 5.10. */
2259			#ifdef __cplusplus
2260			newXS(const_cast(swig_commands[i].name), swig_commands[i].wrapper, const_cast(__FILE__));
2261			#else
2262	3		newXS((char)swig_commands[i].name, swig_commands[i].wrapper, (char)__FILE__);
2263			#endif
2264			}
2265
2266			/* Install variables */
2267	1	50	for (i = 0; swig_variables[i].name; i++) {
2268			SV *sv;
2269	0		sv = get_sv(swig_variables[i].name, TRUE \| 0x2 \| GV_ADDMULTI);
2270	0	0	if (swig_variables[i].type) {
2271	0		SWIG_MakePtr(sv,(void )1, swig_variables[i].type,0);
2272			} else {
2273	0		sv_setiv(sv,(IV) 0);
2274			}
2275	0		swig_create_magic(sv, swig_variables[i].name, swig_variables[i].set, swig_variables[i].get);
2276			}
2277
2278			/* Install constant */
2279	1	50	for (i = 0; swig_constants[i].type; i++) {
2280			SV *sv;
2281	0		sv = get_sv(swig_constants[i].name, TRUE \| 0x2 \| GV_ADDMULTI);
2282	0		switch(swig_constants[i].type) {
2283			case SWIG_INT:
2284	0		sv_setiv(sv, (IV) swig_constants[i].lvalue);
2285	0		break;
2286			case SWIG_FLOAT:
2287	0		sv_setnv(sv, (double) swig_constants[i].dvalue);
2288	0		break;
2289			case SWIG_STRING:
2290	0		sv_setpv(sv, (const char *) swig_constants[i].pvalue);
2291	0		break;
2292			case SWIG_POINTER:
2293	0		SWIG_MakePtr(sv, swig_constants[i].pvalue, *(swig_constants[i].ptype),0);
2294	0		break;
2295			case SWIG_BINARY:
2296	0		SWIG_MakePackedObj(sv, swig_constants[i].pvalue, swig_constants[i].lvalue, *(swig_constants[i].ptype));
2297	0		break;
2298			default:
2299	0		break;
2300			}
2301	0		SvREADONLY_on(sv);
2302			}
2303
2304	1		ST(0) = &PL_sv_yes;
2305	1		XSRETURN(1);
2306			}
2307