/* ---------------------------------------------------------------------------- * This file was automatically generated by SWIG (http://www.swig.org). * Version 1.3.25 * * This file is not intended to be easily readable and contains a number of * coding conventions designed to improve portability and efficiency. Do not make * changes to this file unless you know what you are doing--modify the SWIG * interface file instead. * ----------------------------------------------------------------------------- */ #ifdef __cplusplus template class SwigValueWrapper { T *tt; public: SwigValueWrapper() : tt(0) { } SwigValueWrapper(const SwigValueWrapper& rhs) : tt(new T(*rhs.tt)) { } SwigValueWrapper(const T& t) : tt(new T(t)) { } ~SwigValueWrapper() { delete tt; } SwigValueWrapper& operator=(const T& t) { delete tt; tt = new T(t); return *this; } operator T&() const { return *tt; } T *operator&() { return tt; } private: SwigValueWrapper& operator=(const SwigValueWrapper& rhs); }; #endif /*********************************************************************** * * This section contains generic SWIG labels for method/variable * declarations/attributes, and other compiler dependent labels. * ************************************************************************/ /* template workaround for compilers that cannot correctly implement the C++ standard */ #ifndef SWIGTEMPLATEDISAMBIGUATOR # if defined(__SUNPRO_CC) && (__SUNPRO_CC <= 0x560) # define SWIGTEMPLATEDISAMBIGUATOR template # else # define SWIGTEMPLATEDISAMBIGUATOR # endif #endif /* inline attribute */ #ifndef SWIGINLINE # if defined(__cplusplus) || (defined(__GNUC__) && !defined(__STRICT_ANSI__)) # define SWIGINLINE inline # else # define SWIGINLINE # endif #endif /* attribute recognised by some compilers to avoid 'unused' warnings */ #ifndef SWIGUNUSED # if defined(__GNUC__) || defined(__ICC) # define SWIGUNUSED __attribute__ ((unused)) # else # define SWIGUNUSED # endif #endif /* internal SWIG method */ #ifndef SWIGINTERN # define SWIGINTERN static SWIGUNUSED #endif /* internal inline SWIG method */ #ifndef SWIGINTERNINLINE # define SWIGINTERNINLINE SWIGINTERN SWIGINLINE #endif /* exporting methods for Windows DLLs */ #ifndef SWIGEXPORT # if defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__) # if defined(STATIC_LINKED) # define SWIGEXPORT # else # define SWIGEXPORT __declspec(dllexport) # endif # else # define SWIGEXPORT # endif #endif /* calling conventions for Windows */ #ifndef SWIGSTDCALL # if defined(_WIN32) || defined(__WIN32__) || defined(__CYGWIN__) # define SWIGSTDCALL __stdcall # else # define SWIGSTDCALL # endif #endif /*********************************************************************** * swigrun.swg * * This file contains generic CAPI SWIG runtime support for pointer * type checking. * ************************************************************************/ /* This should only be incremented when either the layout of swig_type_info changes, or for whatever reason, the runtime changes incompatibly */ #define SWIG_RUNTIME_VERSION "2" /* define SWIG_TYPE_TABLE_NAME as "SWIG_TYPE_TABLE" */ #ifdef SWIG_TYPE_TABLE # define SWIG_QUOTE_STRING(x) #x # define SWIG_EXPAND_AND_QUOTE_STRING(x) SWIG_QUOTE_STRING(x) # define SWIG_TYPE_TABLE_NAME SWIG_EXPAND_AND_QUOTE_STRING(SWIG_TYPE_TABLE) #else # define SWIG_TYPE_TABLE_NAME #endif /* You can use the SWIGRUNTIME and SWIGRUNTIMEINLINE macros for creating a static or dynamic library from the swig runtime code. In 99.9% of the cases, swig just needs to declare them as 'static'. But only do this if is strictly necessary, ie, if you have problems with your compiler or so. */ #ifndef SWIGRUNTIME # define SWIGRUNTIME SWIGINTERN #endif #ifndef SWIGRUNTIMEINLINE # define SWIGRUNTIMEINLINE SWIGRUNTIME SWIGINLINE #endif #include #ifdef __cplusplus extern "C" { #endif typedef void *(*swig_converter_func)(void *); typedef struct swig_type_info *(*swig_dycast_func)(void **); /* Structure to store inforomation on one type */ typedef struct swig_type_info { const char *name; /* mangled name of this type */ const char *str; /* human readable name of this type */ swig_dycast_func dcast; /* dynamic cast function down a hierarchy */ struct swig_cast_info *cast; /* linked list of types that can cast into this type */ void *clientdata; /* language specific type data */ } swig_type_info; /* Structure to store a type and conversion function used for casting */ typedef struct swig_cast_info { swig_type_info *type; /* pointer to type that is equivalent to this type */ swig_converter_func converter; /* function to cast the void pointers */ struct swig_cast_info *next; /* pointer to next cast in linked list */ struct swig_cast_info *prev; /* pointer to the previous cast */ } swig_cast_info; /* Structure used to store module information * Each module generates one structure like this, and the runtime collects * all of these structures and stores them in a circularly linked list.*/ typedef struct swig_module_info { swig_type_info **types; /* Array of pointers to swig_type_info structures that are in this module */ size_t size; /* Number of types in this module */ struct swig_module_info *next; /* Pointer to next element in circularly linked list */ swig_type_info **type_initial; /* Array of initially generated type structures */ swig_cast_info **cast_initial; /* Array of initially generated casting structures */ void *clientdata; /* Language specific module data */ } swig_module_info; /* Compare two type names skipping the space characters, therefore "char*" == "char *" and "Class" == "Class", etc. Return 0 when the two name types are equivalent, as in strncmp, but skipping ' '. */ SWIGRUNTIME int SWIG_TypeNameComp(const char *f1, const char *l1, const char *f2, const char *l2) { for (;(f1 != l1) && (f2 != l2); ++f1, ++f2) { while ((*f1 == ' ') && (f1 != l1)) ++f1; while ((*f2 == ' ') && (f2 != l2)) ++f2; if (*f1 != *f2) return (int)(*f1 - *f2); } return (l1 - f1) - (l2 - f2); } /* Check type equivalence in a name list like ||... Return 0 if not equal, 1 if equal */ SWIGRUNTIME int SWIG_TypeEquiv(const char *nb, const char *tb) { int equiv = 0; const char* te = tb + strlen(tb); const char* ne = nb; while (!equiv && *ne) { for (nb = ne; *ne; ++ne) { if (*ne == '|') break; } equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0; if (*ne) ++ne; } return equiv; } /* Check type equivalence in a name list like ||... Return 0 if equal, -1 if nb < tb, 1 if nb > tb */ SWIGRUNTIME int SWIG_TypeCompare(const char *nb, const char *tb) { int equiv = 0; const char* te = tb + strlen(tb); const char* ne = nb; while (!equiv && *ne) { for (nb = ne; *ne; ++ne) { if (*ne == '|') break; } equiv = (SWIG_TypeNameComp(nb, ne, tb, te) == 0) ? 1 : 0; if (*ne) ++ne; } return equiv; } /* think of this as a c++ template<> or a scheme macro */ #define SWIG_TypeCheck_Template(comparison, ty) \ if (ty) { \ swig_cast_info *iter = ty->cast; \ while (iter) { \ if (comparison) { \ if (iter == ty->cast) return iter; \ /* Move iter to the top of the linked list */ \ iter->prev->next = iter->next; \ if (iter->next) \ iter->next->prev = iter->prev; \ iter->next = ty->cast; \ iter->prev = 0; \ if (ty->cast) ty->cast->prev = iter; \ ty->cast = iter; \ return iter; \ } \ iter = iter->next; \ } \ } \ return 0 /* Check the typename */ SWIGRUNTIME swig_cast_info * SWIG_TypeCheck(const char *c, swig_type_info *ty) { SWIG_TypeCheck_Template(strcmp(iter->type->name, c) == 0, ty); } /* Same as previous function, except strcmp is replaced with a pointer comparison */ SWIGRUNTIME swig_cast_info * SWIG_TypeCheckStruct(swig_type_info *from, swig_type_info *into) { SWIG_TypeCheck_Template(iter->type == from, into); } /* Cast a pointer up an inheritance hierarchy */ SWIGRUNTIMEINLINE void * SWIG_TypeCast(swig_cast_info *ty, void *ptr) { return ((!ty) || (!ty->converter)) ? ptr : (*ty->converter)(ptr); } /* Dynamic pointer casting. Down an inheritance hierarchy */ SWIGRUNTIME swig_type_info * SWIG_TypeDynamicCast(swig_type_info *ty, void **ptr) { swig_type_info *lastty = ty; if (!ty || !ty->dcast) return ty; while (ty && (ty->dcast)) { ty = (*ty->dcast)(ptr); if (ty) lastty = ty; } return lastty; } /* Return the name associated with this type */ SWIGRUNTIMEINLINE const char * SWIG_TypeName(const swig_type_info *ty) { return ty->name; } /* Return the pretty name associated with this type, that is an unmangled type name in a form presentable to the user. */ SWIGRUNTIME const char * SWIG_TypePrettyName(const swig_type_info *type) { /* The "str" field contains the equivalent pretty names of the type, separated by vertical-bar characters. We choose to print the last name, as it is often (?) the most specific. */ if (type->str != NULL) { const char *last_name = type->str; const char *s; for (s = type->str; *s; s++) if (*s == '|') last_name = s+1; return last_name; } else return type->name; } /* Set the clientdata field for a type */ SWIGRUNTIME void SWIG_TypeClientData(swig_type_info *ti, void *clientdata) { if (!ti->clientdata) { swig_cast_info *cast = ti->cast; /* if (ti->clientdata == clientdata) return; */ ti->clientdata = clientdata; while (cast) { if (!cast->converter) SWIG_TypeClientData(cast->type, clientdata); cast = cast->next; } } } /* Search for a swig_type_info structure only by mangled name Search is a O(log #types) We start searching at module start, and finish searching when start == end. Note: if start == end at the beginning of the function, we go all the way around the circular list. */ SWIGRUNTIME swig_type_info * SWIG_MangledTypeQueryModule(swig_module_info *start, swig_module_info *end, const char *name) { swig_module_info *iter = start; do { if (iter->size) { register size_t l = 0; register size_t r = iter->size - 1; do { /* since l+r >= 0, we can (>> 1) instead (/ 2) */ register size_t i = (l + r) >> 1; const char *iname = iter->types[i]->name; if (iname) { register int compare = strcmp(name, iname); if (compare == 0) { return iter->types[i]; } else if (compare < 0) { if (i) { r = i - 1; } else { break; } } else if (compare > 0) { l = i + 1; } } else { break; /* should never happen */ } } while (l <= r); } iter = iter->next; } while (iter != end); return 0; } /* Search for a swig_type_info structure for either a mangled name or a human readable name. It first searches the mangled names of the types, which is a O(log #types) If a type is not found it then searches the human readable names, which is O(#types). We start searching at module start, and finish searching when start == end. Note: if start == end at the beginning of the function, we go all the way around the circular list. */ SWIGRUNTIME swig_type_info * SWIG_TypeQueryModule(swig_module_info *start, swig_module_info *end, const char *name) { /* STEP 1: Search the name field using binary search */ swig_type_info *ret = SWIG_MangledTypeQueryModule(start, end, name); if (ret) { return ret; } else { /* STEP 2: If the type hasn't been found, do a complete search of the str field (the human readable name) */ swig_module_info *iter = start; do { register size_t i = 0; for (; i < iter->size; ++i) { if (iter->types[i]->str && (SWIG_TypeEquiv(iter->types[i]->str, name))) return iter->types[i]; } iter = iter->next; } while (iter != end); } /* neither found a match */ return 0; } /* Pack binary data into a string */ SWIGRUNTIME char * SWIG_PackData(char *c, void *ptr, size_t sz) { static const char hex[17] = "0123456789abcdef"; register const unsigned char *u = (unsigned char *) ptr; register const unsigned char *eu = u + sz; for (; u != eu; ++u) { register unsigned char uu = *u; *(c++) = hex[(uu & 0xf0) >> 4]; *(c++) = hex[uu & 0xf]; } return c; } /* Unpack binary data from a string */ SWIGRUNTIME const char * SWIG_UnpackData(const char *c, void *ptr, size_t sz) { register unsigned char *u = (unsigned char *) ptr; register const unsigned char *eu = u + sz; for (; u != eu; ++u) { register char d = *(c++); register unsigned char uu = 0; if ((d >= '0') && (d <= '9')) uu = ((d - '0') << 4); else if ((d >= 'a') && (d <= 'f')) uu = ((d - ('a'-10)) << 4); else return (char *) 0; d = *(c++); if ((d >= '0') && (d <= '9')) uu |= (d - '0'); else if ((d >= 'a') && (d <= 'f')) uu |= (d - ('a'-10)); else return (char *) 0; *u = uu; } return c; } /* Pack 'void *' into a string buffer. */ SWIGRUNTIME char * SWIG_PackVoidPtr(char *buff, void *ptr, const char *name, size_t bsz) { char *r = buff; if ((2*sizeof(void *) + 2) > bsz) return 0; *(r++) = '_'; r = SWIG_PackData(r,&ptr,sizeof(void *)); if (strlen(name) + 1 > (bsz - (r - buff))) return 0; strcpy(r,name); return buff; } SWIGRUNTIME const char * SWIG_UnpackVoidPtr(const char *c, void **ptr, const char *name) { if (*c != '_') { if (strcmp(c,"NULL") == 0) { *ptr = (void *) 0; return name; } else { return 0; } } return SWIG_UnpackData(++c,ptr,sizeof(void *)); } SWIGRUNTIME char * SWIG_PackDataName(char *buff, void *ptr, size_t sz, const char *name, size_t bsz) { char *r = buff; size_t lname = (name ? strlen(name) : 0); if ((2*sz + 2 + lname) > bsz) return 0; *(r++) = '_'; r = SWIG_PackData(r,ptr,sz); if (lname) { strncpy(r,name,lname+1); } else { *r = 0; } return buff; } SWIGRUNTIME const char * SWIG_UnpackDataName(const char *c, void *ptr, size_t sz, const char *name) { if (*c != '_') { if (strcmp(c,"NULL") == 0) { memset(ptr,0,sz); return name; } else { return 0; } } return SWIG_UnpackData(++c,ptr,sz); } #ifdef __cplusplus } #endif /* ---------------------------------------------------------------------- -*- c -*- * perl5.swg * * Perl5 runtime library * $Header: /home/CVS/speech_tools/wrappers/perl5/EST_Relation_wrap.cc,v 1.2 2006/06/13 15:12:47 robert Exp $ * ----------------------------------------------------------------------------- */ #define SWIGPERL #define SWIGPERL5 #ifdef __cplusplus /* Needed on some windows machines---since MS plays funny games with the header files under C++ */ #include #include extern "C" { #endif #include "EXTERN.h" #include "perl.h" #include "XSUB.h" /* Get rid of free and malloc defined by perl */ #undef free #undef malloc #ifndef pTHX_ #define pTHX_ #endif #include #ifdef __cplusplus } #endif /* Macro to call an XS function */ #ifdef PERL_OBJECT # define SWIG_CALLXS(_name) _name(cv,pPerl) #else # ifndef MULTIPLICITY # define SWIG_CALLXS(_name) _name(cv) # else # define SWIG_CALLXS(_name) _name(PERL_GET_THX, cv) # endif #endif /* Contract support */ #define SWIG_contract_assert(expr,msg) if (!(expr)) { SWIG_croak(msg); } else /* Note: SwigMagicFuncHack is a typedef used to get the C++ compiler to just shut up already */ #ifdef PERL_OBJECT #define MAGIC_PPERL CPerlObj *pPerl = (CPerlObj *) this; typedef int (CPerlObj::*SwigMagicFunc)(SV *, MAGIC *); #ifdef __cplusplus extern "C" { #endif typedef int (CPerlObj::*SwigMagicFuncHack)(SV *, MAGIC *); #ifdef __cplusplus } #endif #define SWIG_MAGIC(a,b) (SV *a, MAGIC *b) #define SWIGCLASS_STATIC #else #define MAGIC_PPERL #define SWIGCLASS_STATIC static #ifndef MULTIPLICITY #define SWIG_MAGIC(a,b) (SV *a, MAGIC *b) typedef int (*SwigMagicFunc)(SV *, MAGIC *); #ifdef __cplusplus extern "C" { #endif typedef int (*SwigMagicFuncHack)(SV *, MAGIC *); #ifdef __cplusplus } #endif #else #define SWIG_MAGIC(a,b) (struct interpreter *interp, SV *a, MAGIC *b) typedef int (*SwigMagicFunc)(struct interpreter *, SV *, MAGIC *); #ifdef __cplusplus extern "C" { #endif typedef int (*SwigMagicFuncHack)(struct interpreter *, SV *, MAGIC *); #ifdef __cplusplus } #endif #endif #endif #if defined(WIN32) && defined(PERL_OBJECT) && !defined(PerlIO_exportFILE) #define PerlIO_exportFILE(fh,fl) (FILE*)(fh) #endif /* Modifications for newer Perl 5.005 releases */ #if !defined(PERL_REVISION) || ((PERL_REVISION >= 5) && ((PERL_VERSION < 5) || ((PERL_VERSION == 5) && (PERL_SUBVERSION < 50)))) # ifndef PL_sv_yes # define PL_sv_yes sv_yes # endif # ifndef PL_sv_undef # define PL_sv_undef sv_undef # endif # ifndef PL_na # define PL_na na # endif #endif #include #ifdef __cplusplus extern "C" { #endif #define SWIG_OWNER 1 #define SWIG_SHADOW 2 /* Common SWIG API */ #ifdef PERL_OBJECT # define SWIG_ConvertPtr(obj, pp, type, flags) \ SWIG_Perl_ConvertPtr(pPerl, obj, pp, type, flags) # define SWIG_NewPointerObj(p, type, flags) \ SWIG_Perl_NewPointerObj(pPerl, p, type, flags) # define SWIG_MakePackedObj(sv, p, s, type) \ SWIG_Perl_MakePackedObj(pPerl, sv, p, s, type) # define SWIG_ConvertPacked(obj, p, s, type, flags) \ SWIG_Perl_ConvertPacked(pPerl, obj, p, s, type, flags) #else # define SWIG_ConvertPtr(obj, pp, type, flags) \ SWIG_Perl_ConvertPtr(obj, pp, type, flags) # define SWIG_NewPointerObj(p, type, flags) \ SWIG_Perl_NewPointerObj(p, type, flags) # define SWIG_MakePackedObj(sv, p, s, type) \ SWIG_Perl_MakePackedObj(sv, p, s, type ) # define SWIG_ConvertPacked(obj, p, s, type, flags) \ SWIG_Perl_ConvertPacked(obj, p, s, type, flags) #endif /* Runtime API */ #define SWIG_GetModule(clientdata) SWIG_Perl_GetModule() #define SWIG_SetModule(clientdata, pointer) SWIG_Perl_SetModule(pointer) /* Perl-specific API */ #ifdef PERL_OBJECT # define SWIG_MakePtr(sv, ptr, type, flags) \ SWIG_Perl_MakePtr(pPerl, sv, ptr, type, flags) # define SWIG_SetError(str) \ SWIG_Perl_SetError(pPerl, str) #else # define SWIG_MakePtr(sv, ptr, type, flags) \ SWIG_Perl_MakePtr(sv, ptr, type, flags) # define SWIG_SetError(str) \ SWIG_Perl_SetError(str) # define SWIG_SetErrorSV(str) \ SWIG_Perl_SetErrorSV(str) #endif #define SWIG_SetErrorf SWIG_Perl_SetErrorf #ifdef PERL_OBJECT # define SWIG_MAYBE_PERL_OBJECT CPerlObj *pPerl, #else # define SWIG_MAYBE_PERL_OBJECT #endif static swig_cast_info * SWIG_Perl_TypeCheckRV(SWIG_MAYBE_PERL_OBJECT SV *rv, swig_type_info *ty) { SWIG_TypeCheck_Template(sv_derived_from(rv, (char *) iter->type->name), ty); } /* Function for getting a pointer value */ static int SWIG_Perl_ConvertPtr(SWIG_MAYBE_PERL_OBJECT SV *sv, void **ptr, swig_type_info *_t, int flags) { swig_cast_info *tc; void *voidptr = (void *)0; /* If magical, apply more magic */ if (SvGMAGICAL(sv)) mg_get(sv); /* Check to see if this is an object */ if (sv_isobject(sv)) { SV *tsv = (SV*) SvRV(sv); IV tmp = 0; if ((SvTYPE(tsv) == SVt_PVHV)) { MAGIC *mg; if (SvMAGICAL(tsv)) { mg = mg_find(tsv,'P'); if (mg) { sv = mg->mg_obj; if (sv_isobject(sv)) { tmp = SvIV((SV*)SvRV(sv)); } } } else { return -1; } } else { tmp = SvIV((SV*)SvRV(sv)); } voidptr = (void *)tmp; if (!_t) { *(ptr) = voidptr; return 0; } } else if (! SvOK(sv)) { /* Check for undef */ *(ptr) = (void *) 0; return 0; } else if (SvTYPE(sv) == SVt_RV) { /* Check for NULL pointer */ *(ptr) = (void *) 0; if (!SvROK(sv)) return 0; else return -1; } else { /* Don't know what it is */ *(ptr) = (void *) 0; return -1; } if (_t) { /* Now see if the types match */ char *_c = HvNAME(SvSTASH(SvRV(sv))); tc = SWIG_TypeCheck(_c,_t); if (!tc) { *ptr = voidptr; return -1; } *ptr = SWIG_TypeCast(tc,voidptr); return 0; } *ptr = voidptr; return 0; } static void SWIG_Perl_MakePtr(SWIG_MAYBE_PERL_OBJECT SV *sv, void *ptr, swig_type_info *t, int flags) { if (ptr && (flags & SWIG_SHADOW)) { SV *self; SV *obj=newSV(0); HV *hash=newHV(); HV *stash; sv_setref_pv(obj, (char *) t->name, ptr); stash=SvSTASH(SvRV(obj)); if (flags & SWIG_OWNER) { HV *hv; GV *gv=*(GV**)hv_fetch(stash, "OWNER", 5, TRUE); if (!isGV(gv)) gv_init(gv, stash, "OWNER", 5, FALSE); hv=GvHVn(gv); hv_store_ent(hv, obj, newSViv(1), 0); } sv_magic((SV *)hash, (SV *)obj, 'P', Nullch, 0); SvREFCNT_dec(obj); self=newRV_noinc((SV *)hash); sv_setsv(sv, self); SvREFCNT_dec((SV *)self); sv_bless(sv, stash); } else { sv_setref_pv(sv, (char *) t->name, ptr); } } static SWIGINLINE SV * SWIG_Perl_NewPointerObj(SWIG_MAYBE_PERL_OBJECT void *ptr, swig_type_info *t, int flags) { SV *result = sv_newmortal(); SWIG_MakePtr(result, ptr, t, flags); return result; } static void SWIG_Perl_MakePackedObj(SWIG_MAYBE_PERL_OBJECT SV *sv, void *ptr, int sz, swig_type_info *type) { char result[1024]; char *r = result; if ((2*sz + 1 + strlen(type->name)) > 1000) return; *(r++) = '_'; r = SWIG_PackData(r,ptr,sz); strcpy(r,type->name); sv_setpv(sv, result); } /* Convert a packed value value */ static int SWIG_Perl_ConvertPacked(SWIG_MAYBE_PERL_OBJECT SV *obj, void *ptr, int sz, swig_type_info *ty, int flags) { swig_cast_info *tc; const char *c = 0; if ((!obj) || (!SvOK(obj))) return -1; c = SvPV(obj, PL_na); /* Pointer values must start with leading underscore */ if (*c != '_') return -1; c++; c = SWIG_UnpackData(c,ptr,sz); if (ty) { tc = SWIG_TypeCheck(c,ty); if (!tc) return -1; } return 0; } static SWIGINLINE void SWIG_Perl_SetError(SWIG_MAYBE_PERL_OBJECT const char *error) { if (error) sv_setpv(perl_get_sv("@", TRUE), error); } static SWIGINLINE void SWIG_Perl_SetErrorSV(SWIG_MAYBE_PERL_OBJECT SV *error) { if (error) sv_setsv(perl_get_sv("@", TRUE), error); } static void SWIG_Perl_SetErrorf(const char *fmt, ...) { va_list args; va_start(args, fmt); sv_vsetpvfn(perl_get_sv("@", TRUE), fmt, strlen(fmt), &args, Null(SV**), 0, Null(bool*)); va_end(args); } /* Macros for low-level exception handling */ #define SWIG_fail goto fail #define SWIG_croak(x) { SWIG_SetError(x); goto fail; } #define SWIG_croakSV(x) { SWIG_SetErrorSV(x); goto fail; } /* most preprocessors do not support vararg macros :-( */ /* #define SWIG_croakf(x...) { SWIG_SetErrorf(x); goto fail; } */ typedef XS(SwigPerlWrapper); typedef SwigPerlWrapper *SwigPerlWrapperPtr; /* Structure for command table */ typedef struct { const char *name; SwigPerlWrapperPtr wrapper; } swig_command_info; /* Information for constant table */ #define SWIG_INT 1 #define SWIG_FLOAT 2 #define SWIG_STRING 3 #define SWIG_POINTER 4 #define SWIG_BINARY 5 /* Constant information structure */ typedef struct swig_constant_info { int type; const char *name; long lvalue; double dvalue; void *pvalue; swig_type_info **ptype; } swig_constant_info; #ifdef __cplusplus } #endif /* Structure for variable table */ typedef struct { const char *name; SwigMagicFunc set; SwigMagicFunc get; swig_type_info **type; } swig_variable_info; /* Magic variable code */ #ifndef PERL_OBJECT #define swig_create_magic(s,a,b,c) _swig_create_magic(s,a,b,c) #ifndef MULTIPLICITY static void _swig_create_magic(SV *sv, char *name, int (*set)(SV *, MAGIC *), int (*get)(SV *,MAGIC *)) { #else static void _swig_create_magic(SV *sv, char *name, int (*set)(struct interpreter*, SV *, MAGIC *), int (*get)(struct interpreter*, SV *,MAGIC *)) { #endif #else # define swig_create_magic(s,a,b,c) _swig_create_magic(pPerl,s,a,b,c) static void _swig_create_magic(CPerlObj *pPerl, SV *sv, const char *name, int (CPerlObj::*set)(SV *, MAGIC *), int (CPerlObj::*get)(SV *, MAGIC *)) { #endif MAGIC *mg; sv_magic(sv,sv,'U',(char *) name,strlen(name)); mg = mg_find(sv,'U'); mg->mg_virtual = (MGVTBL *) malloc(sizeof(MGVTBL)); mg->mg_virtual->svt_get = (SwigMagicFuncHack) get; mg->mg_virtual->svt_set = (SwigMagicFuncHack) set; mg->mg_virtual->svt_len = 0; mg->mg_virtual->svt_clear = 0; mg->mg_virtual->svt_free = 0; } static swig_module_info * SWIG_Perl_GetModule() { static void *type_pointer = (void *)0; SV *pointer; /* first check if pointer already created */ if (!type_pointer) { pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, FALSE); if (pointer && SvOK(pointer)) { type_pointer = INT2PTR(swig_type_info **, SvIV(pointer)); } } return (swig_module_info *) type_pointer; } static void SWIG_Perl_SetModule(swig_module_info *module) { SV *pointer; /* create a new pointer */ pointer = get_sv("swig_runtime_data::type_pointer" SWIG_RUNTIME_VERSION SWIG_TYPE_TABLE_NAME, TRUE); sv_setiv(pointer, PTR2IV(module)); } #ifdef do_open #undef do_open #endif #ifdef do_close #undef do_close #endif #ifdef scalar #undef scalar #endif #ifdef list #undef list #endif #ifdef apply #undef apply #endif #ifdef convert #undef convert #endif #ifdef Error #undef Error #endif #ifdef form #undef form #endif #ifdef vform #undef vform #endif #ifdef LABEL #undef LABEL #endif #ifdef METHOD #undef METHOD #endif #ifdef Move #undef Move #endif #ifdef yylex #undef yylex #endif #ifdef yyparse #undef yyparse #endif #ifdef yyerror #undef yyerror #endif #ifdef invert #undef invert #endif #ifdef ref #undef ref #endif #ifdef ENTER #undef ENTER #endif #ifdef read #undef read #endif #ifdef write #undef write #endif #ifdef eof #undef eof #endif /* -------- TYPES TABLE (BEGIN) -------- */ #define SWIGTYPE_p_EST_Item swig_types[0] #define SWIGTYPE_p_EST_Relation swig_types[1] #define SWIGTYPE_p_EST_Utterance swig_types[2] #define SWIGTYPE_p_EST_read_status swig_types[3] #define SWIGTYPE_p_EST_write_status swig_types[4] static swig_type_info *swig_types[5]; static swig_module_info swig_module = {swig_types, 5, 0, 0, 0, 0}; #define SWIG_TypeQuery(name) SWIG_TypeQueryModule(&swig_module, &swig_module, name) #define SWIG_MangledTypeQuery(name) SWIG_MangledTypeQueryModule(&swig_module, &swig_module, name) /* -------- TYPES TABLE (END) -------- */ #define SWIG_init boot_EST_Relation #define SWIG_name "EST_Relationc::boot_EST_Relation" #define SWIG_prefix "EST_Relationc::" #ifdef __cplusplus extern "C" #endif #ifndef PERL_OBJECT #ifndef MULTIPLICITY SWIGEXPORT void SWIG_init (CV* cv); #else SWIGEXPORT void SWIG_init (pTHXo_ CV* cv); #endif #else SWIGEXPORT void SWIG_init (CV *cv, CPerlObj *); #endif #include "ling_class/EST_Relation.h" #include "ling_class/EST_Item.h" #ifdef PERL_OBJECT #define MAGIC_CLASS _wrap_EST_Relation_var:: class _wrap_EST_Relation_var : public CPerlObj { public: #else #define MAGIC_CLASS #endif SWIGCLASS_STATIC int swig_magic_readonly(pTHX_ SV *sv, MAGIC *mg) { MAGIC_PPERL sv = sv; mg = mg; croak("Value is read-only."); return 0; } #ifdef PERL_OBJECT }; #endif #ifdef __cplusplus extern "C" { #endif XS(_wrap_new_EST_Relation__SWIG_0) { { EST_Relation *result; int argvi = 0; dXSARGS; if ((items < 0) || (items > 0)) { SWIG_croak("Usage: new_EST_Relation();"); } result = (EST_Relation *)new EST_Relation(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Relation, SWIG_SHADOW|SWIG_OWNER); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_new_EST_Relation__SWIG_1) { { char *arg1 = (char *) 0 ; EST_Relation *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: new_EST_Relation(name);"); } if (!SvOK((SV*) ST(0))) arg1 = 0; else arg1 = (char *) SvPV(ST(0), PL_na); result = (EST_Relation *)new EST_Relation((char const *)arg1); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Relation, SWIG_SHADOW|SWIG_OWNER); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_new_EST_Relation__SWIG_2) { { EST_Relation *arg1 = 0 ; EST_Relation *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: new_EST_Relation(r);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of new_EST_Relation. Expected _p_EST_Relation"); } } result = (EST_Relation *)new EST_Relation((EST_Relation const &)*arg1); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Relation, SWIG_SHADOW|SWIG_OWNER); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_new_EST_Relation) { dXSARGS; if (items == 0) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_new_EST_Relation__SWIG_0); return; } if (items == 1) { int _v; { void *tmp; if (SWIG_ConvertPtr(ST(0), (void **) &tmp, SWIGTYPE_p_EST_Relation, 0) == -1) { _v = 0; } else { _v = 1; } } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_new_EST_Relation__SWIG_2); return; } } if (items == 1) { int _v; { _v = SvPOK(ST(0)) ? 1 : 0; } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_new_EST_Relation__SWIG_1); return; } } croak("No matching function for overloaded 'new_EST_Relation'"); XSRETURN(0); } XS(_wrap_delete_EST_Relation) { { EST_Relation *arg1 = (EST_Relation *) 0 ; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: delete_EST_Relation(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of delete_EST_Relation. Expected _p_EST_Relation"); } } delete arg1; XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_load__SWIG_0) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *arg2 = 0 ; EST_String *arg3 = 0 ; EST_read_status result; EST_String temp2 ; EST_String temp3 ; int argvi = 0; dXSARGS; if ((items < 3) || (items > 3)) { SWIG_croak("Usage: EST_Relation_load(self,filename,type);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_load. Expected _p_EST_Relation"); } } { STRLEN len; const char* str = SvPV(ST(1), len); temp2 = EST_String( str, len, 0, len ); arg2 = &temp2; } { STRLEN len; const char* str = SvPV(ST(2), len); temp3 = EST_String( str, len, 0, len ); arg3 = &temp3; } result = (arg1)->load((EST_String const &)*arg2,(EST_String const &)*arg3); { EST_read_status * resultobj = new EST_read_status((EST_read_status &)result); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) resultobj, SWIGTYPE_p_EST_read_status, 0|SWIG_OWNER); } XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_load__SWIG_1) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *arg2 = 0 ; EST_read_status result; EST_String temp2 ; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_load(self,filename);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_load. Expected _p_EST_Relation"); } } { STRLEN len; const char* str = SvPV(ST(1), len); temp2 = EST_String( str, len, 0, len ); arg2 = &temp2; } result = (arg1)->load((EST_String const &)*arg2); { EST_read_status * resultobj = new EST_read_status((EST_read_status &)result); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) resultobj, SWIGTYPE_p_EST_read_status, 0|SWIG_OWNER); } XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_load) { dXSARGS; if (items == 2) { int _v; { void *tmp; if (SWIG_ConvertPtr(ST(0), (void **) &tmp, SWIGTYPE_p_EST_Relation, 0) == -1) { _v = 0; } else { _v = 1; } } if (_v) { { _v = SvPOK(ST(1)) ? 1 : 0; } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_EST_Relation_load__SWIG_1); return; } } } if (items == 3) { int _v; { void *tmp; if (SWIG_ConvertPtr(ST(0), (void **) &tmp, SWIGTYPE_p_EST_Relation, 0) == -1) { _v = 0; } else { _v = 1; } } if (_v) { { _v = SvPOK(ST(1)) ? 1 : 0; } if (_v) { { _v = SvPOK(ST(2)) ? 1 : 0; } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_EST_Relation_load__SWIG_0); return; } } } } croak("No matching function for overloaded 'EST_Relation_load'"); XSRETURN(0); } XS(_wrap_EST_Relation_save__SWIG_0) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *arg2 = 0 ; EST_String *arg3 = 0 ; bool arg4 ; EST_write_status result; EST_String temp2 ; EST_String temp3 ; int argvi = 0; dXSARGS; if ((items < 4) || (items > 4)) { SWIG_croak("Usage: EST_Relation_save(self,filename,type,evaluate_ff);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_save. Expected _p_EST_Relation"); } } { STRLEN len; const char* str = SvPV(ST(1), len); temp2 = EST_String( str, len, 0, len ); arg2 = &temp2; } { STRLEN len; const char* str = SvPV(ST(2), len); temp3 = EST_String( str, len, 0, len ); arg3 = &temp3; } arg4 = (bool) SvIV(ST(3)); result = ((EST_Relation const *)arg1)->save((EST_String const &)*arg2,(EST_String const &)*arg3,arg4); { EST_write_status * resultobj = new EST_write_status((EST_write_status &)result); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) resultobj, SWIGTYPE_p_EST_write_status, 0|SWIG_OWNER); } XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_save__SWIG_1) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *arg2 = 0 ; EST_String *arg3 = 0 ; EST_write_status result; EST_String temp2 ; EST_String temp3 ; int argvi = 0; dXSARGS; if ((items < 3) || (items > 3)) { SWIG_croak("Usage: EST_Relation_save(self,filename,type);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_save. Expected _p_EST_Relation"); } } { STRLEN len; const char* str = SvPV(ST(1), len); temp2 = EST_String( str, len, 0, len ); arg2 = &temp2; } { STRLEN len; const char* str = SvPV(ST(2), len); temp3 = EST_String( str, len, 0, len ); arg3 = &temp3; } result = ((EST_Relation const *)arg1)->save((EST_String const &)*arg2,(EST_String const &)*arg3); { EST_write_status * resultobj = new EST_write_status((EST_write_status &)result); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) resultobj, SWIGTYPE_p_EST_write_status, 0|SWIG_OWNER); } XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_save) { dXSARGS; if (items == 3) { int _v; { void *tmp; if (SWIG_ConvertPtr(ST(0), (void **) &tmp, SWIGTYPE_p_EST_Relation, 0) == -1) { _v = 0; } else { _v = 1; } } if (_v) { { _v = SvPOK(ST(1)) ? 1 : 0; } if (_v) { { _v = SvPOK(ST(2)) ? 1 : 0; } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_EST_Relation_save__SWIG_1); return; } } } } if (items == 4) { int _v; { void *tmp; if (SWIG_ConvertPtr(ST(0), (void **) &tmp, SWIGTYPE_p_EST_Relation, 0) == -1) { _v = 0; } else { _v = 1; } } if (_v) { { _v = SvPOK(ST(1)) ? 1 : 0; } if (_v) { { _v = SvPOK(ST(2)) ? 1 : 0; } if (_v) { { _v = SvIOK(ST(3)) ? 1 : 0; } if (_v) { (*PL_markstack_ptr++);SWIG_CALLXS(_wrap_EST_Relation_save__SWIG_0); return; } } } } } croak("No matching function for overloaded 'EST_Relation_save'"); XSRETURN(0); } XS(_wrap_EST_Relation_evaluate_item_features) { { EST_Relation *arg1 = (EST_Relation *) 0 ; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_evaluate_item_features(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_evaluate_item_features. Expected _p_EST_Relation"); } } (arg1)->evaluate_item_features(); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_clear) { { EST_Relation *arg1 = (EST_Relation *) 0 ; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_clear(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_clear. Expected _p_EST_Relation"); } } (arg1)->clear(); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_utt) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Utterance *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_utt(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_utt. Expected _p_EST_Relation"); } } result = (EST_Utterance *)(arg1)->utt(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Utterance, 0|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_set_utt) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Utterance *arg2 = (EST_Utterance *) 0 ; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_set_utt(self,u);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_set_utt. Expected _p_EST_Relation"); } } { if (SWIG_ConvertPtr(ST(1), (void **) &arg2, SWIGTYPE_p_EST_Utterance,0) < 0) { SWIG_croak("Type error in argument 2 of EST_Relation_set_utt. Expected _p_EST_Utterance"); } } (arg1)->set_utt(arg2); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_name) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_name(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_name. Expected _p_EST_Relation"); } } { EST_String const &_result_ref = ((EST_Relation const *)arg1)->name(); result = (EST_String *) &_result_ref; } ST(argvi) = sv_newmortal(); sv_setpvn((SV*)ST(argvi++),(char *)(*result), result->length()); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_head) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_head(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_head. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->head(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_root) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_root(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_root. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->root(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_tail) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_tail(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_tail. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->tail(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_first) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_first(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_first. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->first(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_first_leaf) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_first_leaf(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_first_leaf. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->first_leaf(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_last) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_last(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_last. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->last(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_last_leaf) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_last_leaf(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_last_leaf. Expected _p_EST_Relation"); } } result = (EST_Item *)((EST_Relation const *)arg1)->last_leaf(); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_append) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *arg2 = (EST_Item *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_append(self,si);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_append. Expected _p_EST_Relation"); } } { if (SWIG_ConvertPtr(ST(1), (void **) &arg2, SWIGTYPE_p_EST_Item,0) < 0) { SWIG_croak("Type error in argument 2 of EST_Relation_append. Expected _p_EST_Item"); } } result = (EST_Item *)(arg1)->append(arg2); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_prepend) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *arg2 = (EST_Item *) 0 ; EST_Item *result; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_prepend(self,si);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_prepend. Expected _p_EST_Relation"); } } { if (SWIG_ConvertPtr(ST(1), (void **) &arg2, SWIGTYPE_p_EST_Item,0) < 0) { SWIG_croak("Type error in argument 2 of EST_Relation_prepend. Expected _p_EST_Item"); } } result = (EST_Item *)(arg1)->prepend(arg2); ST(argvi) = sv_newmortal(); SWIG_MakePtr(ST(argvi++), (void *) result, SWIGTYPE_p_EST_Item, SWIG_SHADOW|0); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_length) { { EST_Relation *arg1 = (EST_Relation *) 0 ; int result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_length(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_length. Expected _p_EST_Relation"); } } result = (int)((EST_Relation const *)arg1)->length(); ST(argvi) = sv_newmortal(); sv_setiv(ST(argvi++), (IV) result); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_empty) { { EST_Relation *arg1 = (EST_Relation *) 0 ; int result; int argvi = 0; dXSARGS; if ((items < 1) || (items > 1)) { SWIG_croak("Usage: EST_Relation_empty(self);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_empty. Expected _p_EST_Relation"); } } result = (int)((EST_Relation const *)arg1)->empty(); ST(argvi) = sv_newmortal(); sv_setiv(ST(argvi++), (IV) result); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_remove_item) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_Item *arg2 = (EST_Item *) 0 ; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_remove_item(self,item);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_remove_item. Expected _p_EST_Relation"); } } { if (SWIG_ConvertPtr(ST(1), (void **) &arg2, SWIGTYPE_p_EST_Item,0) < 0) { SWIG_croak("Type error in argument 2 of EST_Relation_remove_item. Expected _p_EST_Item"); } } (arg1)->remove_item(arg2); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_EST_Relation_remove_item_feature) { { EST_Relation *arg1 = (EST_Relation *) 0 ; EST_String *arg2 = 0 ; EST_String temp2 ; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: EST_Relation_remove_item_feature(self,name);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of EST_Relation_remove_item_feature. Expected _p_EST_Relation"); } } { STRLEN len; const char* str = SvPV(ST(1), len); temp2 = EST_String( str, len, 0, len ); arg2 = &temp2; } (arg1)->remove_item_feature((EST_String const &)*arg2); XSRETURN(argvi); fail: ; } croak(Nullch); } XS(_wrap_copy_relation) { { EST_Relation *arg1 = 0 ; EST_Relation *arg2 = 0 ; int argvi = 0; dXSARGS; if ((items < 2) || (items > 2)) { SWIG_croak("Usage: copy_relation(from,to);"); } { if (SWIG_ConvertPtr(ST(0), (void **) &arg1, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 1 of copy_relation. Expected _p_EST_Relation"); } } { if (SWIG_ConvertPtr(ST(1), (void **) &arg2, SWIGTYPE_p_EST_Relation,0) < 0) { SWIG_croak("Type error in argument 2 of copy_relation. Expected _p_EST_Relation"); } } copy_relation((EST_Relation const &)*arg1,*arg2); XSRETURN(argvi); fail: ; } croak(Nullch); } /* -------- TYPE CONVERSION AND EQUIVALENCE RULES (BEGIN) -------- */ static swig_type_info _swigt__p_EST_Item = {"EST_Item::EST_Item", "EST_Item *", 0, 0, 0}; static swig_type_info _swigt__p_EST_Relation = {"EST_Relation::EST_Relation", "EST_Relation *", 0, 0, 0}; static swig_type_info _swigt__p_EST_Utterance = {"_p_EST_Utterance", "EST_Utterance *", 0, 0, 0}; static swig_type_info _swigt__p_EST_read_status = {"_p_EST_read_status", "EST_read_status *", 0, 0, 0}; static swig_type_info _swigt__p_EST_write_status = {"_p_EST_write_status", "EST_write_status *", 0, 0, 0}; static swig_type_info *swig_type_initial[] = { &_swigt__p_EST_Item, &_swigt__p_EST_Relation, &_swigt__p_EST_Utterance, &_swigt__p_EST_read_status, &_swigt__p_EST_write_status, }; static swig_cast_info _swigc__p_EST_Item[] = { {&_swigt__p_EST_Item, 0, 0, 0},{0, 0, 0, 0}}; static swig_cast_info _swigc__p_EST_Relation[] = { {&_swigt__p_EST_Relation, 0, 0, 0},{0, 0, 0, 0}}; static swig_cast_info _swigc__p_EST_Utterance[] = { {&_swigt__p_EST_Utterance, 0, 0, 0},{0, 0, 0, 0}}; static swig_cast_info _swigc__p_EST_read_status[] = { {&_swigt__p_EST_read_status, 0, 0, 0},{0, 0, 0, 0}}; static swig_cast_info _swigc__p_EST_write_status[] = { {&_swigt__p_EST_write_status, 0, 0, 0},{0, 0, 0, 0}}; static swig_cast_info *swig_cast_initial[] = { _swigc__p_EST_Item, _swigc__p_EST_Relation, _swigc__p_EST_Utterance, _swigc__p_EST_read_status, _swigc__p_EST_write_status, }; /* -------- TYPE CONVERSION AND EQUIVALENCE RULES (END) -------- */ static swig_constant_info swig_constants[] = { {0,0,0,0,0,0} }; #ifdef __cplusplus } #endif static swig_variable_info swig_variables[] = { {0,0,0,0} }; static swig_command_info swig_commands[] = { {"EST_Relationc::new_EST_Relation", _wrap_new_EST_Relation}, {"EST_Relationc::delete_EST_Relation", _wrap_delete_EST_Relation}, {"EST_Relationc::EST_Relation_load", _wrap_EST_Relation_load}, {"EST_Relationc::EST_Relation_save", _wrap_EST_Relation_save}, {"EST_Relationc::EST_Relation_evaluate_item_features", _wrap_EST_Relation_evaluate_item_features}, {"EST_Relationc::EST_Relation_clear", _wrap_EST_Relation_clear}, {"EST_Relationc::EST_Relation_utt", _wrap_EST_Relation_utt}, {"EST_Relationc::EST_Relation_set_utt", _wrap_EST_Relation_set_utt}, {"EST_Relationc::EST_Relation_name", _wrap_EST_Relation_name}, {"EST_Relationc::EST_Relation_head", _wrap_EST_Relation_head}, {"EST_Relationc::EST_Relation_root", _wrap_EST_Relation_root}, {"EST_Relationc::EST_Relation_tail", _wrap_EST_Relation_tail}, {"EST_Relationc::EST_Relation_first", _wrap_EST_Relation_first}, {"EST_Relationc::EST_Relation_first_leaf", _wrap_EST_Relation_first_leaf}, {"EST_Relationc::EST_Relation_last", _wrap_EST_Relation_last}, {"EST_Relationc::EST_Relation_last_leaf", _wrap_EST_Relation_last_leaf}, {"EST_Relationc::EST_Relation_append", _wrap_EST_Relation_append}, {"EST_Relationc::EST_Relation_prepend", _wrap_EST_Relation_prepend}, {"EST_Relationc::EST_Relation_length", _wrap_EST_Relation_length}, {"EST_Relationc::EST_Relation_empty", _wrap_EST_Relation_empty}, {"EST_Relationc::EST_Relation_remove_item", _wrap_EST_Relation_remove_item}, {"EST_Relationc::EST_Relation_remove_item_feature", _wrap_EST_Relation_remove_item_feature}, {"EST_Relationc::copy_relation", _wrap_copy_relation}, {0,0} }; /************************************************************************* * Type initialization: * This problem is tough by the requirement that no dynamic * memory is used. Also, since swig_type_info structures store pointers to * swig_cast_info structures and swig_cast_info structures store pointers back * to swig_type_info structures, we need some lookup code at initialization. * The idea is that swig generates all the structures that are needed. * The runtime then collects these partially filled structures. * The SWIG_InitializeModule function takes these initial arrays out of * swig_module, and does all the lookup, filling in the swig_module.types * array with the correct data and linking the correct swig_cast_info * structures together. * The generated swig_type_info structures are assigned staticly to an initial * array. We just loop though that array, and handle each type individually. * First we lookup if this type has been already loaded, and if so, use the * loaded structure instead of the generated one. Then we have to fill in the * cast linked list. The cast data is initially stored in something like a * two-dimensional array. Each row corresponds to a type (there are the same * number of rows as there are in the swig_type_initial array). Each entry in * a column is one of the swig_cast_info structures for that type. * The cast_initial array is actually an array of arrays, because each row has * a variable number of columns. So to actually build the cast linked list, * we find the array of casts associated with the type, and loop through it * adding the casts to the list. The one last trick we need to do is making * sure the type pointer in the swig_cast_info struct is correct. * First off, we lookup the cast->type name to see if it is already loaded. * There are three cases to handle: * 1) If the cast->type has already been loaded AND the type we are adding * casting info to has not been loaded (it is in this module), THEN we * replace the cast->type pointer with the type pointer that has already * been loaded. * 2) If BOTH types (the one we are adding casting info to, and the * cast->type) are loaded, THEN the cast info has already been loaded by * the previous module so we just ignore it. * 3) Finally, if cast->type has not already been loaded, then we add that * swig_cast_info to the linked list (because the cast->type) pointer will * be correct. **/ #ifdef __cplusplus extern "C" { #endif SWIGRUNTIME void SWIG_InitializeModule(void *clientdata) { swig_type_info *type, *ret; swig_cast_info *cast; size_t i; swig_module_info *module_head; static int init_run = 0; clientdata = clientdata; if (init_run) return; init_run = 1; /* Initialize the swig_module */ swig_module.type_initial = swig_type_initial; swig_module.cast_initial = swig_cast_initial; /* Try and load any already created modules */ module_head = SWIG_GetModule(clientdata); if (module_head) { swig_module.next = module_head->next; module_head->next = &swig_module; } else { /* This is the first module loaded */ swig_module.next = &swig_module; SWIG_SetModule(clientdata, &swig_module); } /* Now work on filling in swig_module.types */ for (i = 0; i < swig_module.size; ++i) { type = 0; /* if there is another module already loaded */ if (swig_module.next != &swig_module) { type = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, swig_module.type_initial[i]->name); } if (type) { /* Overwrite clientdata field */ if (swig_module.type_initial[i]->clientdata) type->clientdata = swig_module.type_initial[i]->clientdata; } else { type = swig_module.type_initial[i]; } /* Insert casting types */ cast = swig_module.cast_initial[i]; while (cast->type) { /* Don't need to add information already in the list */ ret = 0; if (swig_module.next != &swig_module) { ret = SWIG_MangledTypeQueryModule(swig_module.next, &swig_module, cast->type->name); } if (ret && type == swig_module.type_initial[i]) { cast->type = ret; ret = 0; } if (!ret) { if (type->cast) { type->cast->prev = cast; cast->next = type->cast; } type->cast = cast; } cast++; } /* Set entry in modules->types array equal to the type */ swig_module.types[i] = type; } } /* This function will propagate the clientdata field of type to * any new swig_type_info structures that have been added into the list * of equivalent types. It is like calling * SWIG_TypeClientData(type, clientdata) a second time. */ SWIGRUNTIME void SWIG_PropagateClientData(void) { size_t i; swig_cast_info *equiv; static int init_run = 0; if (init_run) return; init_run = 1; for (i = 0; i < swig_module.size; i++) { if (swig_module.types[i]->clientdata) { equiv = swig_module.types[i]->cast; while (equiv) { if (!equiv->converter) { if (equiv->type && !equiv->type->clientdata) SWIG_TypeClientData(equiv->type, swig_module.types[i]->clientdata); } equiv = equiv->next; } } } } #ifdef __cplusplus } #endif #ifdef __cplusplus extern "C" #endif XS(SWIG_init) { dXSARGS; int i; SWIG_InitializeModule(0); /* Install commands */ for (i = 0; swig_commands[i].name; i++) { newXS((char*) swig_commands[i].name,swig_commands[i].wrapper, (char*)__FILE__); } /* Install variables */ for (i = 0; swig_variables[i].name; i++) { SV *sv; sv = perl_get_sv((char*) swig_variables[i].name, TRUE | 0x2); if (swig_variables[i].type) { SWIG_MakePtr(sv,(void *)1, *swig_variables[i].type,0); } else { sv_setiv(sv,(IV) 0); } swig_create_magic(sv, (char *) swig_variables[i].name, swig_variables[i].set, swig_variables[i].get); } /* Install constant */ for (i = 0; swig_constants[i].type; i++) { SV *sv; sv = perl_get_sv((char*)swig_constants[i].name, TRUE | 0x2); switch(swig_constants[i].type) { case SWIG_INT: sv_setiv(sv, (IV) swig_constants[i].lvalue); break; case SWIG_FLOAT: sv_setnv(sv, (double) swig_constants[i].dvalue); break; case SWIG_STRING: sv_setpv(sv, (char *) swig_constants[i].pvalue); break; case SWIG_POINTER: SWIG_MakePtr(sv, swig_constants[i].pvalue, *(swig_constants[i].ptype),0); break; case SWIG_BINARY: SWIG_MakePackedObj(sv, swig_constants[i].pvalue, swig_constants[i].lvalue, *(swig_constants[i].ptype)); break; default: break; } SvREADONLY_on(sv); } SWIG_TypeClientData(SWIGTYPE_p_EST_Relation, (void*) "EST_Relation::EST_Relation"); ST(0) = &PL_sv_yes; XSRETURN(1); }