/* ----------------------------------------------------------------------------- * std_map.i * * SWIG typemaps for std::map * ----------------------------------------------------------------------------- */ %include %include // ------------------------------------------------------------------------ // std::map // // The aim of all that follows would be to integrate std::map with // MzScheme as much as possible, namely, to allow the user to pass and // be returned Scheme association lists. // const declarations are used to guess the intent of the function being // exported; therefore, the following rationale is applied: // // -- f(std::map), f(const std::map&), f(const std::map*): // the parameter being read-only, either a Scheme alist or a // previously wrapped std::map can be passed. // -- f(std::map&), f(std::map*): // the parameter must be modified; therefore, only a wrapped std::map // can be passed. // -- std::map f(): // the map is returned by copy; therefore, a Scheme alist // is returned which is most easily used in other Scheme functions // -- std::map& f(), std::map* f(), const std::map& f(), // const std::map* f(): // the map is returned by reference; therefore, a wrapped std::map // is returned // ------------------------------------------------------------------------ %{ #include #include #include %} // exported class namespace std { template > class map { %typemap(in) map< K, T, C > (std::map< K, T, C >* m) { if (SCHEME_NULLP($input)) { $1 = std::map< K, T, C >(); } else if (SCHEME_PAIRP($input)) { $1 = std::map< K, T, C >(); Scheme_Object* alist = $input; while (!SCHEME_NULLP(alist)) { K* k; T* x; Scheme_Object *entry, *key, *val; entry = scheme_car(alist); if (!SCHEME_PAIRP(entry)) SWIG_exception(SWIG_TypeError,"alist expected"); key = scheme_car(entry); val = scheme_cdr(entry); k = (K*) SWIG_MustGetPtr(key,$descriptor(K *),$argnum, 0); if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) == -1) { if (!SCHEME_PAIRP(val)) SWIG_exception(SWIG_TypeError,"alist expected"); val = scheme_car(val); x = (T*) SWIG_MustGetPtr(val,$descriptor(T *),$argnum, 0); } %#ifdef __cpp_lib_map_try_emplace (($1_type &)$1).insert_or_assign(*k, *x); %#else (($1_type &)$1)[*k] = *x; %#endif alist = scheme_cdr(alist); } } else { $1 = *(($&1_type) SWIG_MustGetPtr($input,$&1_descriptor,$argnum, 0)); } } %typemap(in) const map< K, T, C >& (std::map< K, T, C > temp, std::map< K, T, C >* m), const map< K, T, C >* (std::map< K, T, C > temp, std::map< K, T, C >* m) { if (SCHEME_NULLP($input)) { temp = std::map< K, T, C >(); $1 = &temp; } else if (SCHEME_PAIRP($input)) { temp = std::map< K, T, C >(); $1 = &temp; Scheme_Object* alist = $input; while (!SCHEME_NULLP(alist)) { K* k; T* x; Scheme_Object *entry, *key, *val; entry = scheme_car(alist); if (!SCHEME_PAIRP(entry)) SWIG_exception(SWIG_TypeError,"alist expected"); key = scheme_car(entry); val = scheme_cdr(entry); k = (K*) SWIG_MustGetPtr(key,$descriptor(K *),$argnum, 0); if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) == -1) { if (!SCHEME_PAIRP(val)) SWIG_exception(SWIG_TypeError,"alist expected"); val = scheme_car(val); x = (T*) SWIG_MustGetPtr(val,$descriptor(T *),$argnum, 0); } %#ifdef __cpp_lib_map_try_emplace temp.insert_or_assign(*k, *x); %#else temp[*k] = *x; %#endif alist = scheme_cdr(alist); } } else { $1 = ($1_ltype) SWIG_MustGetPtr($input,$1_descriptor,$argnum, 0); } } %typemap(out) map< K, T, C > { Scheme_Object* alist = scheme_null; for (std::map< K, T, C >::reverse_iterator i=$1.rbegin(); i!=$1.rend(); ++i) { K* key = new K(i->first); T* val = new T(i->second); Scheme_Object* k = SWIG_NewPointerObj(key,$descriptor(K *), 1); Scheme_Object* x = SWIG_NewPointerObj(val,$descriptor(T *), 1); Scheme_Object* entry = scheme_make_pair(k,x); alist = scheme_make_pair(entry,alist); } $result = alist; } %typecheck(SWIG_TYPECHECK_MAP) map< K, T, C > { /* native sequence? */ if (SCHEME_NULLP($input)) { /* an empty sequence can be of any type */ $1 = 1; } else if (SCHEME_PAIRP($input)) { /* check the first element only */ K* k; T* x; Scheme_Object* head = scheme_car($input); if (SCHEME_PAIRP(head)) { Scheme_Object* key = scheme_car(head); Scheme_Object* val = scheme_cdr(head); if (SWIG_ConvertPtr(key,(void**) &k, $descriptor(K *), 0) == -1) { $1 = 0; } else { if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) != -1) { $1 = 1; } else if (SCHEME_PAIRP(val)) { val = scheme_car(val); if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) != -1) $1 = 1; else $1 = 0; } else { $1 = 0; } } } else { $1 = 0; } } else { /* wrapped map? */ std::map< K, T, C >* m; if (SWIG_ConvertPtr($input,(void **) &m, $&1_descriptor, 0) != -1) $1 = 1; else $1 = 0; } } %typecheck(SWIG_TYPECHECK_MAP) const map< K, T, C >&, const map< K, T, C >* { /* native sequence? */ if (SCHEME_NULLP($input)) { /* an empty sequence can be of any type */ $1 = 1; } else if (SCHEME_PAIRP($input)) { /* check the first element only */ K* k; T* x; Scheme_Object* head = scheme_car($input); if (SCHEME_PAIRP(head)) { Scheme_Object* key = scheme_car(head); Scheme_Object* val = scheme_cdr(head); if (SWIG_ConvertPtr(key,(void**) &k, $descriptor(K *), 0) == -1) { $1 = 0; } else { if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) != -1) { $1 = 1; } else if (SCHEME_PAIRP(val)) { val = scheme_car(val); if (SWIG_ConvertPtr(val,(void**) &x, $descriptor(T *), 0) != -1) $1 = 1; else $1 = 0; } else { $1 = 0; } } } else { $1 = 0; } } else { /* wrapped map? */ std::map< K, T, C >* m; if (SWIG_ConvertPtr($input,(void **) &m, $1_descriptor, 0) != -1) $1 = 1; else $1 = 0; } } %rename("length") size; %rename("null?") empty; %rename("clear!") clear; %rename("ref") __getitem__; %rename("set!") __setitem__; %rename("delete!") __delitem__; %rename("has-key?") has_key; public: typedef size_t size_type; typedef ptrdiff_t difference_type; typedef K key_type; typedef T mapped_type; typedef std::pair< const K, T > value_type; typedef value_type* pointer; typedef const value_type* const_pointer; typedef value_type& reference; typedef const value_type& const_reference; map(); map(const map& other); unsigned int size() const; bool empty() const; void clear(); %extend { T& __getitem__(const K& key) throw (std::out_of_range) { std::map< K, T, C >::iterator i = self->find(key); if (i != self->end()) return i->second; else throw std::out_of_range("key not found"); } void __setitem__(const K& key, const T& x) { %#ifdef __cpp_lib_map_try_emplace (*self).insert_or_assign(key, x); %#else (*self)[key] = x; %#endif } void __delitem__(const K& key) throw (std::out_of_range) { std::map< K, T, C >::iterator i = self->find(key); if (i != self->end()) self->erase(i); else throw std::out_of_range("key not found"); } bool has_key(const K& key) { std::map< K, T, C >::iterator i = self->find(key); return i != self->end(); } Scheme_Object* keys() { Scheme_Object* result = scheme_null; for (std::map< K, T, C >::reverse_iterator i=self->rbegin(); i!=self->rend(); ++i) { K* key = new K(i->first); Scheme_Object* k = SWIG_NewPointerObj(key,$descriptor(K *), 1); result = scheme_make_pair(k,result); } return result; } } }; }