include/vector - platform/external/astl - Git at Google

 /* -*- c++ -*- */
 /*
  * Copyright (C) 2009 The Android Open Source Project
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *  * Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *  * Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in
  *    the documentation and/or other materials provided with the
  *    distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
  * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
  * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #ifndef ANDROID_ASTL_VECTOR__
 #define ANDROID_ASTL_VECTOR__

 #include <cstddef>
 #include <cstdlib>
 #include <cstring>
 #include <algorithm>
 #include <iterator>
 #include <memory>
 #include <type_traits.h>

 namespace std {

 #ifdef _T
 #error "_T is a macro."
 #endif

 // Simple vector implementation. Its purpose is to be able to compile code that
 // uses the STL and requires std::vector.
 //
 // IMPORTANT:
 // . This class it is not fully STL compliant. Some constructors/methods maybe
 // missing, they will be added on demand.
 // . A standard container which offers fixed time access to individual
 // elements in any order.
 //
 // TODO: Use the stack for the default constructor. When the capacity
 // grows beyond that move the data to the heap.

 template<typename _T>
 class vector
 {
     typedef vector<_T> vector_type;

   public:
     typedef _T         value_type;
     typedef _T*        pointer;
     typedef const _T*  const_pointer;
     typedef _T&        reference;
     typedef const _T&  const_reference;

     typedef __wrapper_iterator<pointer,vector_type>  iterator;
     typedef __wrapper_iterator<const_pointer,vector_type> const_iterator;

     typedef size_t    size_type;
     typedef ptrdiff_t difference_type;

     vector();

     // Create a vector with bitwise copies of an exemplar element.
     // @param num The number of elements to create.
     // @param init_value The element to copy.
     explicit vector(const size_type num, const value_type& init_value = value_type());

     // Create a vector by copying the elements from [first, last).
     //
     // If the iterators are random-access, the constructor will be
     // able to reserve the memory in a single call before copying the
     // elements. If the elements are POD, the constructor uses memmove.
     template<typename _Iterator>
     vector(_Iterator first, _Iterator last) {
         // Because of template matching, vector<int>(int n, int val)
         // will now match this constructor (int != size_type) instead
         // of the repeat one above. In this case, the _Iterator
         // template parameter is an integral type and not an iterator,
         // we use that to call the correct initialize impl.
         typedef typename is_integral<_Iterator>::type integral;
         initialize(first, last, integral());
     }

     ~vector() { clear(); }

     // @return true if the vector is empty, false otherwise.
     bool empty() const { return mLength == 0; }
     size_type size() const { return mLength; }

     // @return the maximum size for a vector.
     size_type max_size() const { return (~size_type(0)) / sizeof(value_type); }

     // Change the capacity to new_size. 0 means shrink to fit. The
     // extra memory is not initialized when the capacity is grown.
     // @param new_size number of element to be allocated.
     // @return true if successful. The STL version returns nothing.
     bool reserve(size_type new_size = 0);

     // @return The total number of elements that the vector can hold
     // before more memory gets allocated.
     size_type capacity() const { return mCapacity; }

     reference front() { return *mBegin; }
     const_reference front() const { return *mBegin; }

     reference back() { return mLength ? *(mBegin + mLength - 1) : front(); }
     const_reference back() const { return mLength ? *(mBegin + mLength - 1) : front(); }

     // Subscript access to the vector's elements. Don't do boundary
     // check. Use at() for checked access.
     // @param index Of the element (0-based).
     // @return A const reference to the element.
     const_reference operator[](size_type index) const { return *(mBegin + index); }

     // @param index Of the element (0-based).
     // @return A reference to the element.
     reference operator[](size_type index) { return *(mBegin + index); }

     // 'at' is similar to operator[] except that it does check bounds.
     const_reference at(const size_type index) const
     { return index < mLength ? *( mBegin + index) : sDummy; }

     reference at(const size_type index)
     { return index < mLength ? *( mBegin + index) : sDummy; }

     iterator begin() { return iterator(mBegin); }
     iterator end() { return iterator(mBegin + mLength); }

     const_iterator begin() const { return const_iterator(mBegin); }
     const_iterator end() const { return const_iterator(mBegin + mLength); }

     // Add data at the end of the vector. Constant in time if the
     // memory has been preallocated (e.g using reserve).
     // @param elt To be added.
     void push_back(const value_type& elt);

     // Remove the last element. However, no memory is reclaimed from
     // the internal buffer: you need to call reserve() to recover it.
     void pop_back();

     // Remove the element pointed by the iterator.
     // Expensive since the remaining elts must be shifted around.
     // @param pos Iterator pointing to the elt to be removed.
     // @return An iterator pointing to the next elt or end().
     iterator erase(iterator pos);

     // Remove a range of elements [first, last)
     // @param first Iterator pointing to the first element to be removed.
     // @param last Iterator pointing to one past the last element to be removed.
     // @return An iterator pointing to the elt next to 'last' or end().
     iterator erase(iterator first, iterator last);

     // Empty the vector on return. Release the internal buffer. Length
     // and capacity are both 0 on return. If you want to keep the
     // internal buffer around for reuse, call 'resize'/'erase' instead.
     void clear();

     // Resize the vector to contain 'size' element. If 'size' is
     // smaller than the current size, the extra elements are dropped
     // but the reserved memory is not changed (use 'swap' to recover
     // memory.) If 'size' is greater, the vector is expanded by
     // inserting at the end as many copy of 'init_value' (this may
     // lead to some realloc) as necessary. See 'reserve'.
     void resize(size_type size, value_type init_value = value_type());

     void swap(vector& other);
   private:
     // See the 2 'initialize' methods first. They desambiguate between
     // repeat and range initialize. For range initialize, there is
     // another desambiguation based on the nature of the iterators.

     // Repeat constructor implementation.
     void repeat_initialize(const size_type num,
                            const value_type& init_value);

     // Initialize from a random access iterator.
     template<typename _Iterator>
     void range_initialize(_Iterator first, _Iterator last,
                           random_access_iterator_tag);

     // Initialize from an input iterator.
     template<typename _InputIterator>
     void range_initialize(_InputIterator first, _InputIterator last,
                           input_iterator_tag);

     // Repeat constructor that matched the templatized constructor for iterator.
     // The last parameter true_type is used by the caller to target this method.
     template<typename _Integral>
     void initialize(_Integral num, _Integral init_value, true_type) {
         repeat_initialize((size_type)num, init_value);
     }

     // Not a repeat constructor (last param type is false_type). first
     // and last are really iterators. Dispatch the call depending on
     // the iterators' category.
     template<typename _InputIterator>
     void initialize(_InputIterator first, _InputIterator last, false_type) {
         range_initialize(first, last, android::iterator_category(first));
     }

     // @return New internal buffer size when it is adjusted automatically.
     size_type grow() const;

     // Calls the class' deallocator explicitely on each instance in
     // the vector.
     void deallocate();

     pointer mBegin;
     size_type mCapacity;
     size_type mLength;
     static value_type sDummy;  // at() doen't throw exception and returns mDummy.
     static const size_type kExponentialFactor = 2;
     static const size_type kExponentialLimit = 256;
     static const size_type kLinearIncrement = 256;
 };


 // The implementation uses malloc instead of new because Posix states that:
 // The pointer returned if the allocation succeeds shall be suitably
 // aligned so that it may be assigned to a pointer to any type of
 // object and then used to access such an object in the space
 // allocated
 // So as long as we malloc() more than 4 bytes, the returned block
 // must be able to contain a pointer, and thus will be 32-bit
 // aligned. I believe the bionic implementation uses a minimum of 8 or 16.
 //
 // Invariant: mLength <= mCapacity <= max_size()


 template<typename _T>
 vector<_T>::vector()
         :mBegin(NULL), mCapacity(0), mLength(0) { }

 template<typename _T>
 vector<_T>::vector(const size_type num, const value_type& init_value)
 {
     repeat_initialize(num, init_value);
 }

 template<typename _T>
 void vector<_T>::repeat_initialize(const size_type num,
                                    const value_type& init_value)
 {
     if (num < max_size())
     {
         mBegin = static_cast<pointer>(malloc(num * sizeof(value_type)));
         if (mBegin)
         {
             mLength = mCapacity =  num;
             std::uninitialized_fill(mBegin, mBegin + mLength, init_value);
             return;
         }
     }
     mBegin = NULL;
     mLength = mCapacity =  0;
 }

 template<typename _T>
 bool vector<_T>::reserve(size_type new_size)
 {
     if (0 == new_size)
     {
         if (0 == mLength)  // Free whatever has been reserved.
         {
             clear();
             return true;
         }
         new_size = mLength;  // Shrink to fit.
     }
     else if (new_size < mLength || new_size > max_size())
     {
         return false;
     }

     if (is_pod<value_type>::value)
     {
         pointer oldBegin = mBegin;
         mBegin = static_cast<pointer>(
             realloc(mBegin, new_size * sizeof(value_type)));
         if (!mBegin)
         {
             mBegin = oldBegin;
             return false;
         }
     }
     else
     {
         pointer newBegin =  static_cast<pointer>(
             malloc(new_size * sizeof(value_type)));
         if (!newBegin) return false;

         if (mBegin != NULL) {
             std::uninitialized_copy(mBegin, mBegin + mLength, newBegin);
             deallocate();
         }
         mBegin = newBegin;
     }
     mCapacity = new_size;
     return true;
 }

 template<typename _T>
 void vector<_T>::push_back(const value_type& elt)
 {
     if (max_size() == mLength) return;
     if (mCapacity == mLength)
     {
         const size_type new_capacity = grow();
         if (0 == new_capacity || !reserve(new_capacity)) return;
     }
     // mLength < mCapacity
     if (is_pod<value_type>::value) {
         *(mBegin + mLength) = elt;
     } else {
         // The memory where the new element is added is uninitialized,
         // we cannot use assigment (lhs is not valid).
         new((void *)(mBegin + mLength)) _T(elt);
     }
     ++mLength;
 }

 template<typename _T>
 void vector<_T>::pop_back()
 {
     if (mLength > 0)
     {
         --mLength;
         if (!is_pod<value_type>::value)
         {
             (mBegin + mLength)->~_T();
         }
     }
 }

 template<typename _T>
 typename vector<_T>::iterator
 vector<_T>::erase(iterator pos) {
     if (mLength) {
         std::copy(pos + 1, end(), pos);
         --mLength;
         if (!is_pod<value_type>::value) {
             end()->~_T();
         }
     }
     return pos;
 }

 template<typename _T>
 typename vector<_T>::iterator
 vector<_T>::erase(iterator first, iterator last) {
     difference_type len = std::distance(first, last);
     if (len > 0) {
         last = std::copy(last, end(), first);

         if (!is_pod<value_type>::value) {
             while (last != end()) {
                 last->~_T();
                 ++last;
             }
         }
         mLength -= len;
     }
     return first;
 }

 template<typename _T>
 void vector<_T>::clear()
 {
     if(mBegin)
     {
         if (is_pod<value_type>::value)
         {
             free(mBegin);
         }
         else
         {
             deallocate();
         }
     }
     mBegin = NULL;
     mCapacity = 0;
     mLength = 0;
 }

 template<typename _T>
 void vector<_T>::resize(size_type new_size, value_type init_value)
 {
     if (mLength == new_size || new_size > max_size()) {
         return;
     } else if (new_size < mLength) {
         if (!is_pod<value_type>::value) {
             const pointer end = mBegin + mLength;
             for (pointer begin = mBegin + new_size;
                  begin < end; ++begin) {
                 begin->~_T();
             }
         }
         mLength = new_size;
         return;
     }

     if (new_size > mCapacity && !reserve(new_size)) {
         return;
     }
     std::uninitialized_fill(mBegin + mLength, mBegin + new_size, init_value);
     mLength = new_size;
 }

 template<typename _T>
 void vector<_T>::swap(vector& other)
 {
     std::swap(mBegin, other.mBegin);
     std::swap(mCapacity, other.mCapacity);
     std::swap(mLength, other.mLength);
 }

 template<typename _T>
 template<typename _InputIterator>
 void vector<_T>::range_initialize(_InputIterator first, _InputIterator last,
                                   input_iterator_tag) {
     // There is no way to know how many elements we are going to
     // insert, call push_back which will alloc/realloc as needed.
     mBegin = NULL;
     mLength = mCapacity =  0;
     for (; first != last; ++first) {
         push_back(*first);
     }
 }

 template<typename _T>
 template<typename _Iterator>
 void vector<_T>::range_initialize(_Iterator first, _Iterator last,
                                   random_access_iterator_tag) {
     typedef typename iterator_traits<_Iterator>::difference_type difference_type;
     const difference_type num = std::distance(first, last);

     if (0 <= num && static_cast<size_type>(num) < max_size()) {
         mBegin = static_cast<pointer>(malloc(num * sizeof(value_type)));
         if (mBegin) {
             mLength = mCapacity =  num;
             std::uninitialized_copy(first, last, iterator(mBegin));
             return;
         }
     }
     mBegin = NULL;
     mLength = mCapacity =  0;
 }


 // Grow the capacity. Use exponential until kExponentialLimit then
 // linear until it reaches max_size().
 template<typename _T>
 typename vector<_T>::size_type vector<_T>::grow() const
 {
     size_type new_capacity;
     if (mCapacity > kExponentialLimit)
     {
         new_capacity = mCapacity + kLinearIncrement;
     }
     else
     {
         new_capacity = mCapacity == 0 ? kExponentialFactor : mCapacity * kExponentialFactor;
     }
     if (mCapacity > new_capacity || new_capacity > max_size())
     { // Overflow: cap at max_size() if not there already.
         new_capacity = mCapacity == max_size() ? 0 : max_size();
     }
     return  new_capacity;
 }


 // mBegin should not be NULL.
 template<typename _T>
 void vector<_T>::deallocate()
 {
     pointer begin = mBegin;
     pointer end = mBegin + mLength;

     for (; begin != end; ++begin)
     {
         begin->~_T();
     }
     free(mBegin);
 }

 // Dummy element returned when at() is out of bound.
 template<typename _T> _T vector<_T>::sDummy;

 }  // namespace std

 #endif  // ANDROID_ASTL_VECTOR__
	/* -- c++ -- */
	/*
	* Copyright (C) 2009 The Android Open Source Project
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
	* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
	* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#ifndef ANDROID_ASTL_VECTOR__
	#define ANDROID_ASTL_VECTOR__

	#include <cstddef>
	#include <cstdlib>
	#include <cstring>
	#include <algorithm>
	#include <iterator>
	#include <memory>
	#include <type_traits.h>

	namespace std {

	#ifdef _T
	#error "_T is a macro."
	#endif

	// Simple vector implementation. Its purpose is to be able to compile code that
	// uses the STL and requires std::vector.
	//
	// IMPORTANT:
	// . This class it is not fully STL compliant. Some constructors/methods maybe
	// missing, they will be added on demand.
	// . A standard container which offers fixed time access to individual
	// elements in any order.
	//
	// TODO: Use the stack for the default constructor. When the capacity
	// grows beyond that move the data to the heap.

	template<typename _T>
	class vector
	{
	typedef vector<_T> vector_type;

	public:
	typedef _T value_type;
	typedef _T* pointer;
	typedef const _T* const_pointer;
	typedef _T& reference;
	typedef const _T& const_reference;

	typedef __wrapper_iterator<pointer,vector_type> iterator;
	typedef __wrapper_iterator<const_pointer,vector_type> const_iterator;

	typedef size_t size_type;
	typedef ptrdiff_t difference_type;

	vector();

	// Create a vector with bitwise copies of an exemplar element.
	// @param num The number of elements to create.
	// @param init_value The element to copy.
	explicit vector(const size_type num, const value_type& init_value = value_type());

	// Create a vector by copying the elements from [first, last).
	//
	// If the iterators are random-access, the constructor will be
	// able to reserve the memory in a single call before copying the
	// elements. If the elements are POD, the constructor uses memmove.
	template<typename _Iterator>
	vector(_Iterator first, _Iterator last) {
	// Because of template matching, vector<int>(int n, int val)
	// will now match this constructor (int != size_type) instead
	// of the repeat one above. In this case, the _Iterator
	// template parameter is an integral type and not an iterator,
	// we use that to call the correct initialize impl.
	typedef typename is_integral<_Iterator>::type integral;
	initialize(first, last, integral());
	}

	~vector() { clear(); }

	// @return true if the vector is empty, false otherwise.
	bool empty() const { return mLength == 0; }
	size_type size() const { return mLength; }

	// @return the maximum size for a vector.
	size_type max_size() const { return (~size_type(0)) / sizeof(value_type); }

	// Change the capacity to new_size. 0 means shrink to fit. The
	// extra memory is not initialized when the capacity is grown.
	// @param new_size number of element to be allocated.
	// @return true if successful. The STL version returns nothing.
	bool reserve(size_type new_size = 0);

	// @return The total number of elements that the vector can hold
	// before more memory gets allocated.
	size_type capacity() const { return mCapacity; }

	reference front() { return *mBegin; }
	const_reference front() const { return *mBegin; }

	reference back() { return mLength ? *(mBegin + mLength - 1) : front(); }
	const_reference back() const { return mLength ? *(mBegin + mLength - 1) : front(); }

	// Subscript access to the vector's elements. Don't do boundary
	// check. Use at() for checked access.
	// @param index Of the element (0-based).
	// @return A const reference to the element.
	const_reference operator[](size_type index) const { return *(mBegin + index); }

	// @param index Of the element (0-based).
	// @return A reference to the element.
	reference operator[](size_type index) { return *(mBegin + index); }

	// 'at' is similar to operator[] except that it does check bounds.
	const_reference at(const size_type index) const
	{ return index < mLength ? *( mBegin + index) : sDummy; }

	reference at(const size_type index)
	{ return index < mLength ? *( mBegin + index) : sDummy; }

	iterator begin() { return iterator(mBegin); }
	iterator end() { return iterator(mBegin + mLength); }

	const_iterator begin() const { return const_iterator(mBegin); }
	const_iterator end() const { return const_iterator(mBegin + mLength); }

	// Add data at the end of the vector. Constant in time if the
	// memory has been preallocated (e.g using reserve).
	// @param elt To be added.
	void push_back(const value_type& elt);

	// Remove the last element. However, no memory is reclaimed from
	// the internal buffer: you need to call reserve() to recover it.
	void pop_back();

	// Remove the element pointed by the iterator.
	// Expensive since the remaining elts must be shifted around.
	// @param pos Iterator pointing to the elt to be removed.
	// @return An iterator pointing to the next elt or end().
	iterator erase(iterator pos);

	// Remove a range of elements [first, last)
	// @param first Iterator pointing to the first element to be removed.
	// @param last Iterator pointing to one past the last element to be removed.
	// @return An iterator pointing to the elt next to 'last' or end().
	iterator erase(iterator first, iterator last);

	// Empty the vector on return. Release the internal buffer. Length
	// and capacity are both 0 on return. If you want to keep the
	// internal buffer around for reuse, call 'resize'/'erase' instead.
	void clear();

	// Resize the vector to contain 'size' element. If 'size' is
	// smaller than the current size, the extra elements are dropped
	// but the reserved memory is not changed (use 'swap' to recover
	// memory.) If 'size' is greater, the vector is expanded by
	// inserting at the end as many copy of 'init_value' (this may
	// lead to some realloc) as necessary. See 'reserve'.
	void resize(size_type size, value_type init_value = value_type());

	void swap(vector& other);
	private:
	// See the 2 'initialize' methods first. They desambiguate between
	// repeat and range initialize. For range initialize, there is
	// another desambiguation based on the nature of the iterators.

	// Repeat constructor implementation.
	void repeat_initialize(const size_type num,
	const value_type& init_value);

	// Initialize from a random access iterator.
	template<typename _Iterator>
	void range_initialize(_Iterator first, _Iterator last,
	random_access_iterator_tag);

	// Initialize from an input iterator.
	template<typename _InputIterator>
	void range_initialize(_InputIterator first, _InputIterator last,
	input_iterator_tag);

	// Repeat constructor that matched the templatized constructor for iterator.
	// The last parameter true_type is used by the caller to target this method.
	template<typename _Integral>
	void initialize(_Integral num, _Integral init_value, true_type) {
	repeat_initialize((size_type)num, init_value);
	}

	// Not a repeat constructor (last param type is false_type). first
	// and last are really iterators. Dispatch the call depending on
	// the iterators' category.
	template<typename _InputIterator>
	void initialize(_InputIterator first, _InputIterator last, false_type) {
	range_initialize(first, last, android::iterator_category(first));
	}

	// @return New internal buffer size when it is adjusted automatically.
	size_type grow() const;

	// Calls the class' deallocator explicitely on each instance in
	// the vector.
	void deallocate();

	pointer mBegin;
	size_type mCapacity;
	size_type mLength;
	static value_type sDummy; // at() doen't throw exception and returns mDummy.
	static const size_type kExponentialFactor = 2;
	static const size_type kExponentialLimit = 256;
	static const size_type kLinearIncrement = 256;
	};


	// The implementation uses malloc instead of new because Posix states that:
	// The pointer returned if the allocation succeeds shall be suitably
	// aligned so that it may be assigned to a pointer to any type of
	// object and then used to access such an object in the space
	// allocated
	// So as long as we malloc() more than 4 bytes, the returned block
	// must be able to contain a pointer, and thus will be 32-bit
	// aligned. I believe the bionic implementation uses a minimum of 8 or 16.
	//
	// Invariant: mLength <= mCapacity <= max_size()


	template<typename _T>
	vector<_T>::vector()
	:mBegin(NULL), mCapacity(0), mLength(0) { }

	template<typename _T>
	vector<_T>::vector(const size_type num, const value_type& init_value)
	{
	repeat_initialize(num, init_value);
	}

	template<typename _T>
	void vector<_T>::repeat_initialize(const size_type num,
	const value_type& init_value)
	{
	if (num < max_size())
	{
	mBegin = static_cast<pointer>(malloc(num * sizeof(value_type)));
	if (mBegin)
	{
	mLength = mCapacity = num;
	std::uninitialized_fill(mBegin, mBegin + mLength, init_value);
	return;
	}
	}
	mBegin = NULL;
	mLength = mCapacity = 0;
	}

	template<typename _T>
	bool vector<_T>::reserve(size_type new_size)
	{
	if (0 == new_size)
	{
	if (0 == mLength) // Free whatever has been reserved.
	{
	clear();
	return true;
	}
	new_size = mLength; // Shrink to fit.
	}
	else if (new_size < mLength \|\| new_size > max_size())
	{
	return false;
	}

	if (is_pod<value_type>::value)
	{
	pointer oldBegin = mBegin;
	mBegin = static_cast<pointer>(
	realloc(mBegin, new_size * sizeof(value_type)));
	if (!mBegin)
	{
	mBegin = oldBegin;
	return false;
	}
	}
	else
	{
	pointer newBegin = static_cast<pointer>(
	malloc(new_size * sizeof(value_type)));
	if (!newBegin) return false;

	if (mBegin != NULL) {
	std::uninitialized_copy(mBegin, mBegin + mLength, newBegin);
	deallocate();
	}
	mBegin = newBegin;
	}
	mCapacity = new_size;
	return true;
	}

	template<typename _T>
	void vector<_T>::push_back(const value_type& elt)
	{
	if (max_size() == mLength) return;
	if (mCapacity == mLength)
	{
	const size_type new_capacity = grow();
	if (0 == new_capacity \|\| !reserve(new_capacity)) return;
	}
	// mLength < mCapacity
	if (is_pod<value_type>::value) {
	*(mBegin + mLength) = elt;
	} else {
	// The memory where the new element is added is uninitialized,
	// we cannot use assigment (lhs is not valid).
	new((void *)(mBegin + mLength)) _T(elt);
	}
	++mLength;
	}

	template<typename _T>
	void vector<_T>::pop_back()
	{
	if (mLength > 0)
	{
	--mLength;
	if (!is_pod<value_type>::value)
	{
	(mBegin + mLength)->~_T();
	}
	}
	}

	template<typename _T>
	typename vector<_T>::iterator
	vector<_T>::erase(iterator pos) {
	if (mLength) {
	std::copy(pos + 1, end(), pos);
	--mLength;
	if (!is_pod<value_type>::value) {
	end()->~_T();
	}
	}
	return pos;
	}

	template<typename _T>
	typename vector<_T>::iterator
	vector<_T>::erase(iterator first, iterator last) {
	difference_type len = std::distance(first, last);
	if (len > 0) {
	last = std::copy(last, end(), first);

	if (!is_pod<value_type>::value) {
	while (last != end()) {
	last->~_T();
	++last;
	}
	}
	mLength -= len;
	}
	return first;
	}

	template<typename _T>
	void vector<_T>::clear()
	{
	if(mBegin)
	{
	if (is_pod<value_type>::value)
	{
	free(mBegin);
	}
	else
	{
	deallocate();
	}
	}
	mBegin = NULL;
	mCapacity = 0;
	mLength = 0;
	}

	template<typename _T>
	void vector<_T>::resize(size_type new_size, value_type init_value)
	{
	if (mLength == new_size \|\| new_size > max_size()) {
	return;
	} else if (new_size < mLength) {
	if (!is_pod<value_type>::value) {
	const pointer end = mBegin + mLength;
	for (pointer begin = mBegin + new_size;
	begin < end; ++begin) {
	begin->~_T();
	}
	}
	mLength = new_size;
	return;
	}

	if (new_size > mCapacity && !reserve(new_size)) {
	return;
	}
	std::uninitialized_fill(mBegin + mLength, mBegin + new_size, init_value);
	mLength = new_size;
	}

	template<typename _T>
	void vector<_T>::swap(vector& other)
	{
	std::swap(mBegin, other.mBegin);
	std::swap(mCapacity, other.mCapacity);
	std::swap(mLength, other.mLength);
	}

	template<typename _T>
	template<typename _InputIterator>
	void vector<_T>::range_initialize(_InputIterator first, _InputIterator last,
	input_iterator_tag) {
	// There is no way to know how many elements we are going to
	// insert, call push_back which will alloc/realloc as needed.
	mBegin = NULL;
	mLength = mCapacity = 0;
	for (; first != last; ++first) {
	push_back(*first);
	}
	}

	template<typename _T>
	template<typename _Iterator>
	void vector<_T>::range_initialize(_Iterator first, _Iterator last,
	random_access_iterator_tag) {
	typedef typename iterator_traits<_Iterator>::difference_type difference_type;
	const difference_type num = std::distance(first, last);

	if (0 <= num && static_cast<size_type>(num) < max_size()) {
	mBegin = static_cast<pointer>(malloc(num * sizeof(value_type)));
	if (mBegin) {
	mLength = mCapacity = num;
	std::uninitialized_copy(first, last, iterator(mBegin));
	return;
	}
	}
	mBegin = NULL;
	mLength = mCapacity = 0;
	}


	// Grow the capacity. Use exponential until kExponentialLimit then
	// linear until it reaches max_size().
	template<typename _T>
	typename vector<_T>::size_type vector<_T>::grow() const
	{
	size_type new_capacity;
	if (mCapacity > kExponentialLimit)
	{
	new_capacity = mCapacity + kLinearIncrement;
	}
	else
	{
	new_capacity = mCapacity == 0 ? kExponentialFactor : mCapacity * kExponentialFactor;
	}
	if (mCapacity > new_capacity \|\| new_capacity > max_size())
	{ // Overflow: cap at max_size() if not there already.
	new_capacity = mCapacity == max_size() ? 0 : max_size();
	}
	return new_capacity;
	}


	// mBegin should not be NULL.
	template<typename _T>
	void vector<_T>::deallocate()
	{
	pointer begin = mBegin;
	pointer end = mBegin + mLength;

	for (; begin != end; ++begin)
	{
	begin->~_T();
	}
	free(mBegin);
	}

	// Dummy element returned when at() is out of bound.
	template<typename _T> _T vector<_T>::sDummy;

	} // namespace std

	#endif // ANDROID_ASTL_VECTOR__