replicant-frameworks_native/include/utils/KeyedVector.h
Jeff Brown e6d77c593d Add traits to common utils data structures.
Many of our basic data structures are trivially movable using
memcpy() even if they are not trivially constructable, destructable
or copyable.  It's worth taking advantage of this *ahem* trait.

Adding trivial_move_trait to String16 reduces appt running
time on frameworks/base/core/res by 40%!

Change-Id: I630a1a027e2d0ded96856e4ca042ea82906289fe
2012-03-16 16:21:21 -07:00

209 lines
6.4 KiB
C++

/*
* 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