/* * Copyright (C) 2005 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ANDROID_KEYED_VECTOR_H #define ANDROID_KEYED_VECTOR_H #include <assert.h> #include <stdint.h> #include <sys/types.h> #include <utils/SortedVector.h> #include <utils/TypeHelpers.h> #include <utils/Errors.h> // --------------------------------------------------------------------------- namespace android { template <typename KEY, typename VALUE> class KeyedVector { public: typedef KEY key_type; typedef VALUE value_type; inline KeyedVector(); /* * empty the vector */ inline void clear() { mVector.clear(); } /*! * vector stats */ //! returns number of items in the vector inline size_t size() const { return mVector.size(); } //! returns wether or not the vector is empty inline bool isEmpty() const { return mVector.isEmpty(); } //! returns how many items can be stored without reallocating the backing store inline size_t capacity() const { return mVector.capacity(); } //! setst the capacity. capacity can never be reduced less than size() inline ssize_t setCapacity(size_t size) { return mVector.setCapacity(size); } /*! * accessors */ const VALUE& valueFor(const KEY& key) const; const VALUE& valueAt(size_t index) const; const KEY& keyAt(size_t index) const; ssize_t indexOfKey(const KEY& key) const; /*! * modifying the array */ VALUE& editValueFor(const KEY& key); VALUE& editValueAt(size_t index); /*! * add/insert/replace items */ ssize_t add(const KEY& key, const VALUE& item); ssize_t replaceValueFor(const KEY& key, const VALUE& item); ssize_t replaceValueAt(size_t index, const VALUE& item); /*! * remove items */ ssize_t removeItem(const KEY& key); ssize_t removeItemsAt(size_t index, size_t count = 1); private: SortedVector< key_value_pair_t<KEY, VALUE> > mVector; }; // KeyedVector<KEY, VALUE> can be trivially moved using memcpy() because its // underlying SortedVector can be trivially moved. template<typename KEY, typename VALUE> struct trait_trivial_move<KeyedVector<KEY, VALUE> > { enum { value = trait_trivial_move<SortedVector< key_value_pair_t<KEY, VALUE> > >::value }; }; // --------------------------------------------------------------------------- /** * Variation of KeyedVector that holds a default value to return when * valueFor() is called with a key that doesn't exist. */ template <typename KEY, typename VALUE> class DefaultKeyedVector : public KeyedVector<KEY, VALUE> { public: inline DefaultKeyedVector(const VALUE& defValue = VALUE()); const VALUE& valueFor(const KEY& key) const; private: VALUE mDefault; }; // --------------------------------------------------------------------------- template<typename KEY, typename VALUE> inline KeyedVector<KEY,VALUE>::KeyedVector() { } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY,VALUE>::indexOfKey(const KEY& key) const { return mVector.indexOf( key_value_pair_t<KEY,VALUE>(key) ); } template<typename KEY, typename VALUE> inline const VALUE& KeyedVector<KEY,VALUE>::valueFor(const KEY& key) const { ssize_t i = this->indexOfKey(key); assert(i>=0); return mVector.itemAt(i).value; } template<typename KEY, typename VALUE> inline const VALUE& KeyedVector<KEY,VALUE>::valueAt(size_t index) const { return mVector.itemAt(index).value; } template<typename KEY, typename VALUE> inline const KEY& KeyedVector<KEY,VALUE>::keyAt(size_t index) const { return mVector.itemAt(index).key; } template<typename KEY, typename VALUE> inline VALUE& KeyedVector<KEY,VALUE>::editValueFor(const KEY& key) { ssize_t i = this->indexOfKey(key); assert(i>=0); return mVector.editItemAt(i).value; } template<typename KEY, typename VALUE> inline VALUE& KeyedVector<KEY,VALUE>::editValueAt(size_t index) { return mVector.editItemAt(index).value; } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY,VALUE>::add(const KEY& key, const VALUE& value) { return mVector.add( key_value_pair_t<KEY,VALUE>(key, value) ); } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY,VALUE>::replaceValueFor(const KEY& key, const VALUE& value) { key_value_pair_t<KEY,VALUE> pair(key, value); mVector.remove(pair); return mVector.add(pair); } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY,VALUE>::replaceValueAt(size_t index, const VALUE& item) { if (index<size()) { mVector.editItemAt(index).value = item; return index; } return BAD_INDEX; } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY,VALUE>::removeItem(const KEY& key) { return mVector.remove(key_value_pair_t<KEY,VALUE>(key)); } template<typename KEY, typename VALUE> inline ssize_t KeyedVector<KEY, VALUE>::removeItemsAt(size_t index, size_t count) { return mVector.removeItemsAt(index, count); } // --------------------------------------------------------------------------- template<typename KEY, typename VALUE> inline DefaultKeyedVector<KEY,VALUE>::DefaultKeyedVector(const VALUE& defValue) : mDefault(defValue) { } template<typename KEY, typename VALUE> inline const VALUE& DefaultKeyedVector<KEY,VALUE>::valueFor(const KEY& key) const { ssize_t i = this->indexOfKey(key); return i >= 0 ? KeyedVector<KEY,VALUE>::valueAt(i) : mDefault; } }; // namespace android // --------------------------------------------------------------------------- #endif // ANDROID_KEYED_VECTOR_H