If you need high performance you can roll down your own data structure.
If the objects can be contained in only one container and not moved to other containers, you can do a custom hashset like data structure.

You add X, Y and Next fields into your class.
You make a singly linked list of your object stored in an array that is your hash table.
This can be very very fast.

I wrote it from scratch, there may be bugs.
Clear, and rehash are not implemented, this is a demonstration only.
Complexity of all operation is averaged O(1).

To make easy to enumerate on all nodes skipping empty nodes, there is a doubly linked list. Complexity of insertion and removal from a doubly linked list is O(1), and you will be able to enumerate all nodes skipping unused nodes, so the complexity for enumerating all nodes is O(n) where n is the number of nodes, not the "virtual" size of this sparse matrix.

Using a doubly linked list you can enumerate items in the same order as you insert it.
The order is unrelated to X and Y coordinates.

```
public class Node
{
internal NodeTable pContainer;
internal Node pTableNext;
internal int pX;
internal int pY;
internal Node pLinkedListPrev;
internal Node pLinkedListNext;
}
public class NodeTable :
IEnumerable<Node>
{
private Node[] pTable;
private Node pLinkedListFirst;
private Node pLinkedListLast;
// Capacity must be a prime number great enough as much items you want to store.
// You can make this dynamic too but need some more work (rehashing and prime number computation).
public NodeTable(int capacity)
{
this.pTable = new Node[capacity];
}
public int GetHashCode(int x, int y)
{
return (x + y * 104729); // Must be a prime number
}
public Node Get(int x, int y)
{
int bucket = (GetHashCode(x, y) & 0x7FFFFFFF) % this.pTable.Length;
for (Node current = this.pTable[bucket]; current != null; current = current.pTableNext)
{
if (current.pX == x && current.pY == y)
return current;
}
return null;
}
public IEnumerator<Node> GetEnumerator()
{
// Replace yield with a custom struct Enumerator to optimize performances.
for (Node node = this.pLinkedListFirst, next; node != null; node = next)
{
next = node.pLinkedListNext;
yield return node;
}
}
IEnumerator IEnumerable.GetEnumerator()
{
return this.GetEnumerator();
}
public bool Set(int x, int y, Node node)
{
if (node == null || node.pContainer != null)
{
int bucket = (GetHashCode(x, y) & 0x7FFFFFFF) % this.pTable.Length;
for (Node current = this.pTable[bucket], prev = null; current != null; current = current.pTableNext)
{
if (current.pX == x && current.pY == y)
{
this.fRemoveFromLinkedList(current);
if (node == null)
{
// Remove from table linked list
if (prev != null)
prev.pTableNext = current.pTableNext;
else
this.pTable[bucket] = current.pTableNext;
current.pTableNext = null;
}
else
{
// Replace old node from table linked list
node.pTableNext = current.pTableNext;
current.pTableNext = null;
if (prev != null)
prev.pTableNext = node;
else
this.pTable[bucket] = node;
node.pContainer = this;
node.pX = x;
node.pY = y;
this.fAddToLinkedList(node);
}
return true;
}
prev = current;
}
// New node.
node.pContainer = this;
node.pX = x;
node.pY = y;
// Add to table linked list
node.pTableNext = this.pTable[bucket];
this.pTable[bucket] = node;
// Add to global linked list
this.fAddToLinkedList(node);
return true;
}
return false;
}
private void fRemoveFromLinkedList(Node node)
{
Node prev = node.pLinkedListPrev;
Node next = node.pLinkedListNext;
if (prev != null)
prev.pLinkedListNext = next;
else
this.pLinkedListFirst = next;
if (next != null)
next.pLinkedListPrev = prev;
else
this.pLinkedListLast = prev;
node.pLinkedListPrev = null;
node.pLinkedListNext = null;
}
private void fAddToLinkedList(Node node)
{
node.pLinkedListPrev = this.pLinkedListLast;
this.pLinkedListLast = node;
if (this.pLinkedListFirst == null)
this.pLinkedListFirst = node;
}
}
```

`break`

conditions in the loops? – Matten Sep 2 '11 at 18:54*needto store`n^2`

elements in the 2D array? – Matt Ball Sep 2 '11 at 18:55