/** * @file llmap.h * @brief LLMap class header file * * Copyright (c) 2001-$CurrentYear$, Linden Research, Inc. * $License$ */ #ifndef LL_LLMAP_H #define LL_LLMAP_H #include #include #include // llmap uses the fast stl library code in a manner consistant with LLSkipMap, et. al. template class LLMap { private: typedef typename std::map stl_map_t; typedef typename stl_map_t::iterator stl_iter_t; typedef typename stl_map_t::value_type stl_value_t; stl_map_t mStlMap; stl_iter_t mCurIter; // *iterator = pair MAPPED_TYPE dummy_data; INDEX_TYPE dummy_index; public: LLMap() : mStlMap() { memset((void*)(&dummy_data), 0x0, sizeof(MAPPED_TYPE)); memset((void*)(&dummy_index), 0x0, sizeof(INDEX_TYPE)); mCurIter = mStlMap.begin(); } ~LLMap() { mStlMap.clear(); } // use these functions to itterate through a list void resetMap() { mCurIter = mStlMap.begin(); } // get the current data and bump mCurrentp // This is kind of screwy since it returns a reference; // We have to have a dummy value for when we reach the end // or in case we have an empty list. Presumably, this value // will initialize to some NULL value that will end the iterator. // We really shouldn't be using getNextData() or getNextKey() anyway... MAPPED_TYPE &getNextData() { if (mCurIter == mStlMap.end()) { return dummy_data; } else { return (*mCurIter++).second; } } const INDEX_TYPE &getNextKey() { if (mCurIter == mStlMap.end()) { return dummy_index; } else { return (*mCurIter++).first; } } MAPPED_TYPE &getFirstData() { resetMap(); return getNextData(); } const INDEX_TYPE &getFirstKey() { resetMap(); return getNextKey(); } S32 getLength() { return mStlMap.size(); } void addData(const INDEX_TYPE &index, MAPPED_TYPE pointed_to) { mStlMap.insert(stl_value_t(index, pointed_to)); } void addData(const INDEX_TYPE &index) { mStlMap.insert(stl_value_t(index, dummy_data)); } // if index doesn't exist, then insert a new node and return it MAPPED_TYPE &getData(const INDEX_TYPE &index) { std::pair res; res = mStlMap.insert(stl_value_t(index, dummy_data)); return res.first->second; } // if index doesn't exist, then insert a new node, return it, and set b_new_entry to true MAPPED_TYPE &getData(const INDEX_TYPE &index, BOOL &b_new_entry) { std::pair res; res = mStlMap.insert(stl_value_t(index, dummy_data)); b_new_entry = res.second; return res.first->second; } // If there, returns the data. // If not, returns NULL. // Never adds entries to the map. MAPPED_TYPE getIfThere(const INDEX_TYPE &index) { stl_iter_t iter; iter = mStlMap.find(index); if (iter == mStlMap.end()) { return (MAPPED_TYPE)0; } else { return (*iter).second; } } // if index doesn't exist, then make a new node and return it MAPPED_TYPE &operator[](const INDEX_TYPE &index) { return getData(index); } // do a reverse look-up, return NULL if failed INDEX_TYPE reverseLookup(const MAPPED_TYPE data) { stl_iter_t iter; stl_iter_t end_iter; iter = mStlMap.begin(); end_iter = mStlMap.end(); while (iter != end_iter) { if ((*iter).second == data) return (*iter).first; iter++; } return (INDEX_TYPE)0; } BOOL removeData(const INDEX_TYPE &index) { mCurIter = mStlMap.find(index); if (mCurIter == mStlMap.end()) { return FALSE; } else { stl_iter_t iter = mCurIter++; // incrament mCurIter to the next element mStlMap.erase(iter); return TRUE; } } // does this index exist? BOOL checkData(const INDEX_TYPE &index) { stl_iter_t iter; iter = mStlMap.find(index); if (iter == mStlMap.end()) { return FALSE; } else { mCurIter = iter; return TRUE; } } BOOL deleteData(const INDEX_TYPE &index) { mCurIter = mStlMap.find(index); if (mCurIter == mStlMap.end()) { return FALSE; } else { stl_iter_t iter = mCurIter++; // incrament mCurIter to the next element delete (*iter).second; mStlMap.erase(iter); return TRUE; } } void deleteAllData() { stl_iter_t iter; stl_iter_t end_iter; iter = mStlMap.begin(); end_iter = mStlMap.end(); while (iter != end_iter) { delete (*iter).second; iter++; } mStlMap.clear(); mCurIter = mStlMap.end(); } void removeAllData() { mStlMap.clear(); } }; #endif