62

I have a Queue<T> object that I have initialised to a capacity of 2, but obviously that is just the capacity and it keeps expanding as I add items. Is there already an object that automatically dequeues an item when the limit is reached, or is the best solution to create my own inherited class?

8 Answers 8

45

I've knocked up a basic version of what I'm looking for, it's not perfect but it'll do the job until something better comes along.

public class LimitedQueue<T> : Queue<T>
{
    public int Limit { get; set; }

    public LimitedQueue(int limit) : base(limit)
    {
        Limit = limit;
    }

    public new void Enqueue(T item)
    {
        while (Count >= Limit)
        {
            Dequeue();
        }
        base.Enqueue(item);
    }
}
4
  • I augmented the code slightly with a call from within the Set of the Limit property that ensures that the Queue size hasn't exceeded the Limit - just a simple While greater than Limit, Dequeue. Other than that, this is a great solution thats nice and simple, thanks.
    – Scott
    May 7, 2009 at 2:48
  • Good pickup on changing the 'setter' code for the 'Limit' property.
    – Pure.Krome
    Oct 27, 2009 at 4:14
  • 19
    There's a very serious limitation to this class, which Marcus Griep hinted at in his answer: since your Enqueue method is declared as new (because Queue<T>.Enqueue is not virtual), if somebody casts your LimitedQueue<T> to a Queue<T> they'll be able to add as many items as they want without your limit taking effect. I would also recommend changing if (this.Count >= this.Limit) to while (this.Count >= this.Limit), just to be on the safe side (for the scenario I just mentioned, for example).
    – Dan Tao
    Nov 20, 2009 at 18:09
  • 3
    If the other methods of Queue<T> calls Enqueue(), the originals Enqueue will be called and it can cause serious problem
    – Louis Rhys
    Sep 16, 2011 at 3:03
20

I would recommend that you pull up the C5 Library. Unlike SCG (System.Collections.Generic), C5 is programmed to interface and designed to be subclassed. Most public methods are virtual and none of the classes are sealed. This way, you won't have to use that icky "new" keyword which wouldn't trigger if your LimitedQueue<T> were cast to a SCG.Queue<T>. With C5 and using close to the same code as you had before, you would derive from the CircularQueue<T>. The CircularQueue<T> actually implements both a stack and a queue, so you can get both options with a limit nearly for free. I've rewritten it below with some 3.5 constructs:

using C5;

public class LimitedQueue<T> : CircularQueue<T>
{
    public int Limit { get; set; }

    public LimitedQueue(int limit) : base(limit)
    {
        this.Limit = limit;
    }

    public override void Push(T item)
    {
        CheckLimit(false);
        base.Push(item);
    }

    public override void Enqueue(T item)
    {
        CheckLimit(true);
        base.Enqueue(item);
    }

    protected virtual void CheckLimit(bool enqueue)
    {
        while (this.Count >= this.Limit)
        {
            if (enqueue)
            {
                this.Dequeue();
            }
            else
            {
                this.Pop();
            }
        }
    }
}

I think that this code should do exactly what you were looking for.

0
8

Concurrent Solution

public class LimitedConcurrentQueue<ELEMENT> : ConcurrentQueue<ELEMENT>
{
    public readonly int Limit;

    public LimitedConcurrentQueue(int limit)
    {
        Limit = limit;
    }

    public new void Enqueue(ELEMENT element)
    {
        base.Enqueue(element);
        if (Count > Limit)
        {
            TryDequeue(out ELEMENT discard);
        }
    }
}

Note: Since Enqueue controls the addition of elements, and does so one at a time, there is no need to execute a while for TryDequeue.

6

Well I hope this class will helps You:
Internally the Circular FIFO Buffer use a Queue<T> with the specified size. Once the size of the buffer is reached, it will replaces older items with new ones.

NOTE: You can't remove items randomly. I set the method Remove(T item) to return false. if You want You can modify to remove items randomly

public class CircularFIFO<T> : ICollection<T> , IDisposable
{
    public Queue<T> CircularBuffer;

    /// <summary>
    /// The default initial capacity.
    /// </summary>
    private int capacity = 32;

    /// <summary>
    /// Gets the actual capacity of the FIFO.
    /// </summary>
    public int Capacity
    {
        get { return capacity; }          
    }

    /// <summary>
    ///  Initialize a new instance of FIFO class that is empty and has the default initial capacity.
    /// </summary>
    public CircularFIFO()
    {            
        CircularBuffer = new Queue<T>();
    }

    /// <summary>
    /// Initialize a new instance of FIFO class that is empty and has the specified initial capacity.
    /// </summary>
    /// <param name="size"> Initial capacity of the FIFO. </param>
    public CircularFIFO(int size)
    {
        capacity = size;
        CircularBuffer = new Queue<T>(capacity);
    }

    /// <summary>
    /// Adds an item to the end of the FIFO.
    /// </summary>
    /// <param name="item"> The item to add to the end of the FIFO. </param>
    public void Add(T item)
    {
        if (this.Count >= this.Capacity)
            Remove();

        CircularBuffer.Enqueue(item);
    }

    /// <summary>
    /// Adds array of items to the end of the FIFO.
    /// </summary>
    /// <param name="item"> The array of items to add to the end of the FIFO. </param>
     public void Add(T[] item)
    { 
        int enqueuedSize = 0;
        int remainEnqueueSize = this.Capacity - this.Count;

        for (; (enqueuedSize < item.Length && enqueuedSize < remainEnqueueSize); enqueuedSize++)
            CircularBuffer.Enqueue(item[enqueuedSize]);

        if ((item.Length - enqueuedSize) != 0)
        {
            Remove((item.Length - enqueuedSize));//remaining item size

            for (; enqueuedSize < item.Length; enqueuedSize++)
                CircularBuffer.Enqueue(item[enqueuedSize]);
        }           
    }

    /// <summary>
    /// Removes and Returns an item from the FIFO.
    /// </summary>
    /// <returns> Item removed. </returns>
    public T Remove()
    {
        T removedItem = CircularBuffer.Peek();
        CircularBuffer.Dequeue();

        return removedItem;
    }

    /// <summary>
    /// Removes and Returns the array of items form the FIFO.
    /// </summary>
    /// <param name="size"> The size of item to be removed from the FIFO. </param>
    /// <returns> Removed array of items </returns>
    public T[] Remove(int size)
    {
        if (size > CircularBuffer.Count)
            size = CircularBuffer.Count;

        T[] removedItems = new T[size];

        for (int i = 0; i < size; i++)
        {
            removedItems[i] = CircularBuffer.Peek();
            CircularBuffer.Dequeue();
        }

        return removedItems;
    }

    /// <summary>
    /// Returns the item at the beginning of the FIFO with out removing it.
    /// </summary>
    /// <returns> Item Peeked. </returns>
    public T Peek()
    {
        return CircularBuffer.Peek();
    }

    /// <summary>
    /// Returns the array of item at the beginning of the FIFO with out removing it.
    /// </summary>
    /// <param name="size"> The size of the array items. </param>
    /// <returns> Array of peeked items. </returns>
    public T[] Peek(int size)
    {
        T[] arrayItems = new T[CircularBuffer.Count];
        CircularBuffer.CopyTo(arrayItems, 0);

        if (size > CircularBuffer.Count)
            size = CircularBuffer.Count;

        T[] peekedItems = new T[size];

        Array.Copy(arrayItems, 0, peekedItems, 0, size);

        return peekedItems;
    }

    /// <summary>
    /// Gets the actual number of items presented in the FIFO.
    /// </summary>
    public int Count
    {
        get
        {
            return CircularBuffer.Count;
        }
    }

    /// <summary>
    /// Removes all the contents of the FIFO.
    /// </summary>
    public void Clear()
    {
        CircularBuffer.Clear();
    }

    /// <summary>
    /// Resets and Initialize the instance of FIFO class that is empty and has the default initial capacity.
    /// </summary>
    public void Reset()
    {
        Dispose();
        CircularBuffer = new Queue<T>(capacity);
    }

    #region ICollection<T> Members

    /// <summary>
    /// Determines whether an element is in the FIFO.
    /// </summary>
    /// <param name="item"> The item to locate in the FIFO. </param>
    /// <returns></returns>
    public bool Contains(T item)
    {
        return CircularBuffer.Contains(item);
    }

    /// <summary>
    /// Copies the FIFO elements to an existing one-dimensional array. 
    /// </summary>
    /// <param name="array"> The one-dimensional array that have at list a size of the FIFO </param>
    /// <param name="arrayIndex"></param>
    public void CopyTo(T[] array, int arrayIndex)
    {
        if (array.Length >= CircularBuffer.Count)
            CircularBuffer.CopyTo(array, 0);           
    }

    public bool IsReadOnly
    {
        get { return false; }
    }

    public bool Remove(T item)
    {
        return false; 
    }

    #endregion

    #region IEnumerable<T> Members

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

    #endregion

    #region IEnumerable Members

    IEnumerator IEnumerable.GetEnumerator()
    {
        return CircularBuffer.GetEnumerator();
    }

    #endregion

    #region IDisposable Members

    /// <summary>
    /// Releases all the resource used by the FIFO.
    /// </summary>
    public void Dispose()
    {          
        CircularBuffer.Clear();
        CircularBuffer = null;
        GC.Collect();
    }

    #endregion
}
1
  • 1
    i think by using this code you can have a limited size queue..which is also Circular buffer.
    – Robel.E
    Nov 15, 2011 at 12:46
5

You should create your own class, a ringbuffer would probably fit your needs.

The data structures in .NET that allows you to specify capacity, except for array, uses this to build the internal data structure used to hold the internal data.

For instance, for a list, capacity is used to size an internal array. When you start adding elements to the list, it'll start filling this array from index 0 and up, and when it reaches your capacity, it increases the capacity to a new higher capacity, and continues filling it up.

3

Why wouldn't you just use an array with a size of 2? A Queue is supposed to be able to dynamically grow and shrink.

Or create a wrapper class around an instance of Queue<T> instance and each time one enqueues a <T> object, check the size of the queue. If larger than 2, dequeue the first item.

2

If it's of any use to anyone, I made a LimitedStack<T>.

public class LimitedStack<T>
{
    public readonly int Limit;
    private readonly List<T> _stack;

    public LimitedStack(int limit = 32)
    {
        Limit = limit;
        _stack = new List<T>(limit);
    }

    public void Push(T item)
    {
        if (_stack.Count == Limit) _stack.RemoveAt(0);
        _stack.Add(item);
    }

    public T Peek()
    {
        return _stack[_stack.Count - 1];
    }

    public void Pop()
    {
        _stack.RemoveAt(_stack.Count - 1);
    }

    public int Count
    {
        get { return _stack.Count; }
    }
}

It removes the oldest item (bottom of stack) when it gets too big.

(This question was the top Google result for "C# limit stack size")

3
  • This code is 99% correct. However, if we call Peek or Pop without putting anything on the stack, it will crash as the index is -1. This could be easily fixed by adding index bounds checking.
    – Contango
    Jun 19, 2014 at 9:51
  • Suggest adding the following to Peek and Pop(): if ((_stack.Count - 1) < 0) throw new Exception("Cannot Peek or Pop without first doing a Push.");. This would alert the programmer to this corner case, and allow them to keep it in mind when using this class. We could also add a TryPeek or TryPop, which is the approach Microsoft have taken with their ConcurrentDictionary implementations.
    – Contango
    Jun 19, 2014 at 9:53
  • 1
    For the record, this code is not thread safe without additional locking (which is absolutely fine, thread safety was never part of the design specs for this class).
    – Contango
    Jun 19, 2014 at 10:18
1

You can use a LinkedList<T> and add thread safety:

public class Buffer<T> : LinkedList<T>
{
    private int capacity;

    public Buffer(int capacity)
    {
        this.capacity = capacity;   
    }

    public void Enqueue(T item)
    {
        // todo: add synchronization mechanism
        if (Count == capacity) RemoveLast();
        AddFirst(item);
    }

    public T Dequeue()
    {
        // todo: add synchronization mechanism
        var last = Last.Value;
        RemoveLast();
        return last;
    }
}

One thing to note is the default enumeration order will be LIFO in this example. But that can be overridden if necessary.

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