//----------------------------------------------
//            NGUI: Next-Gen UI kit
// Copyright © 2011-2013 Tasharen Entertainment
//----------------------------------------------

using UnityEngine;
using System.Collections.Generic;
using System.Diagnostics;

/// <summary>
/// This improved version of the System.Collections.Generic.List that doesn't release the buffer on Clear(), resulting in better performance and less garbage collection.
/// </summary>

public class BetterList<T>
{
#if UNITY_FLASH

	List<T> mList = new List<T>();
	
	/// <summary>
	/// Direct access to the buffer. Note that you should not use its 'Length' parameter, but instead use BetterList.size.
	/// </summary>
	
	public T this[int i]
	{
		get { return mList[i]; }
		set { mList[i] = value; }
	}
	
	/// <summary>
	/// Compatibility with the non-flash syntax.
	/// </summary>
	
	public List<T> buffer { get { return mList; } }

	/// <summary>
	/// Direct access to the buffer's size. Note that it's only public for speed and efficiency. You shouldn't modify it.
	/// </summary>

	public int size { get { return mList.Count; } }

	/// <summary>
	/// For 'foreach' functionality.
	/// </summary>

	public IEnumerator<T> GetEnumerator () { return mList.GetEnumerator(); }

	/// <summary>
	/// Clear the array by resetting its size to zero. Note that the memory is not actually released.
	/// </summary>

	public void Clear () { mList.Clear(); }

	/// <summary>
	/// Clear the array and release the used memory.
	/// </summary>

	public void Release () { mList.Clear(); }

	/// <summary>
	/// Add the specified item to the end of the list.
	/// </summary>

	public void Add (T item) { mList.Add(item); }

	/// <summary>
	/// Insert an item at the specified index, pushing the entries back.
	/// </summary>

	public void Insert (int index, T item) { mList.Insert(index, item); }

	/// <summary>
	/// Returns 'true' if the specified item is within the list.
	/// </summary>

	public bool Contains (T item) { return mList.Contains(item); }

	/// <summary>
	/// Remove the specified item from the list. Note that RemoveAt() is faster and is advisable if you already know the index.
	/// </summary>

	public bool Remove (T item) { return mList.Remove(item); }

	/// <summary>
	/// Remove an item at the specified index.
	/// </summary>

	public void RemoveAt (int index) { mList.RemoveAt(index); }

	/// <summary>
	/// Mimic List's ToArray() functionality, except that in this case the list is resized to match the current size.
	/// </summary>

	public T[] ToArray () { return mList.ToArray(); }

	/// <summary>
	/// List.Sort equivalent.
	/// </summary>

	public void Sort (System.Comparison<T> comparer) { mList.Sort(comparer); }

#else

	/// <summary>
	/// Direct access to the buffer. Note that you should not use its 'Length' parameter, but instead use BetterList.size.
	/// </summary>

	public T[] buffer;

	/// <summary>
	/// Direct access to the buffer's size. Note that it's only public for speed and efficiency. You shouldn't modify it.
	/// </summary>

	public int size = 0;

	/// <summary>
	/// For 'foreach' functionality.
	/// </summary>

	[DebuggerHidden]
	[DebuggerStepThrough]
	public IEnumerator<T> GetEnumerator ()
	{
		if (buffer != null)
		{
			for (int i = 0; i < size; ++i)
			{
				yield return buffer[i];
			}
		}
	}
	
	/// <summary>
	/// Convenience function. I recommend using .buffer instead.
	/// </summary>

	[DebuggerHidden]
	public T this[int i]
	{
		get { return buffer[i]; }
		set { buffer[i] = value; }
	}

	/// <summary>
	/// Helper function that expands the size of the array, maintaining the content.
	/// </summary>

	void AllocateMore ()
	{
		T[] newList = (buffer != null) ? new T[Mathf.Max(buffer.Length << 1, 32)] : new T[32];
		if (buffer != null && size > 0) buffer.CopyTo(newList, 0);
		buffer = newList;
	}

	/// <summary>
	/// Trim the unnecessary memory, resizing the buffer to be of 'Length' size.
	/// Call this function only if you are sure that the buffer won't need to resize anytime soon.
	/// </summary>

	void Trim ()
	{
		if (size > 0)
		{
			if (size < buffer.Length)
			{
				T[] newList = new T[size];
				for (int i = 0; i < size; ++i) newList[i] = buffer[i];
				buffer = newList;
			}
		}
		else buffer = null;
	}

	/// <summary>
	/// Clear the array by resetting its size to zero. Note that the memory is not actually released.
	/// </summary>

	public void Clear () { size = 0; }

	/// <summary>
	/// Clear the array and release the used memory.
	/// </summary>

	public void Release () { size = 0; buffer = null; }

	/// <summary>
	/// Add the specified item to the end of the list.
	/// </summary>

	public void Add (T item)
	{
		if (buffer == null || size == buffer.Length) AllocateMore();
		buffer[size++] = item;
	}

	/// <summary>
	/// Insert an item at the specified index, pushing the entries back.
	/// </summary>

	public void Insert (int index, T item)
	{
		if (buffer == null || size == buffer.Length) AllocateMore();

		if (index < size)
		{
			for (int i = size; i > index; --i) buffer[i] = buffer[i - 1];
			buffer[index] = item;
			++size;
		}
		else Add(item);
	}

	/// <summary>
	/// Returns 'true' if the specified item is within the list.
	/// </summary>

	public bool Contains (T item)
	{
		if (buffer == null) return false;
		for (int i = 0; i < size; ++i) if (buffer[i].Equals(item)) return true;
		return false;
	}

	/// <summary>
	/// Remove the specified item from the list. Note that RemoveAt() is faster and is advisable if you already know the index.
	/// </summary>

	public bool Remove (T item)
	{
		if (buffer != null)
		{
			EqualityComparer<T> comp = EqualityComparer<T>.Default;

			for (int i = 0; i < size; ++i)
			{
				if (comp.Equals(buffer[i], item))
				{
					--size;
					buffer[i] = default(T);
					for (int b = i; b < size; ++b) buffer[b] = buffer[b + 1];
					buffer[size] = default(T);
					return true;
				}
			}
		}
		return false;
	}

	/// <summary>
	/// Remove an item at the specified index.
	/// </summary>

	public void RemoveAt (int index)
	{
		if (buffer != null && index < size)
		{
			--size;
			buffer[index] = default(T);
			for (int b = index; b < size; ++b) buffer[b] = buffer[b + 1];
			buffer[size] = default(T);
		}
	}

	/// <summary>
	/// Remove an item from the end.
	/// </summary>

	public T Pop ()
	{
		if (buffer != null && size != 0)
		{
			T val = buffer[--size];
			buffer[size] = default(T);
			return val;
		}
		return default(T);
	}

	/// <summary>
	/// Mimic List's ToArray() functionality, except that in this case the list is resized to match the current size.
	/// </summary>

	public T[] ToArray () { Trim(); return buffer; }

	//class Comparer : System.Collections.IComparer
	//{
	//    public System.Comparison<T> func;
	//    public int Compare (object x, object y) { return func((T)x, (T)y); }
	//}

	//Comparer mComp = new Comparer();

	/// <summary>
	/// List.Sort equivalent. Doing Array.Sort causes GC allocations.
	/// </summary>

	//public void Sort (System.Comparison<T> comparer)
	//{
	//    if (size > 0)
	//    {
	//        mComp.func = comparer;
	//        System.Array.Sort(buffer, 0, size, mComp);
	//    }
	//}

	/// <summary>
	/// List.Sort equivalent. Manual sorting causes no GC allocations.
	/// </summary>

	[DebuggerHidden]
	[DebuggerStepThrough]
	public void Sort (CompareFunc comparer)
	{
		int start = 0;
		int max = size - 1;
		bool changed = true;

		while (changed)
		{
			changed = false;

			for (int i = start; i < max; ++i)
			{
				// Compare the two values
				if (comparer(buffer[i], buffer[i + 1]) > 0)
				{
					// Swap the values
					T temp = buffer[i];
					buffer[i] = buffer[i + 1];
					buffer[i + 1] = temp;
					changed = true;
				}
				else if (!changed)
				{
					// Nothing has changed -- we can start here next time
					start = (i == 0) ? 0 : i - 1;
				}
			}
		}
	}

	/// <summary>
	/// Comparison function should return -1 if left is less than right, 1 if left is greater than right, and 0 if they match.
	/// </summary>

	public delegate int CompareFunc (T left, T right);
#endif
}