internal static Delegate BinaryOperationHelper <Delegate, Left, Right, Return>(BinaryOperationHelperDelegate operation)
{
// shared expressions
ParameterExpression _left = Expression.Parameter(typeof(Left));
ParameterExpression _right = Expression.Parameter(typeof(Right));
LabelTarget _label = Expression.Label(typeof(Return));
// code builder
ListLinked <Expression> expressions = new ListLinked <Expression>();
// null checks
if (!typeof(Left).IsValueType) // is nullable?
{
expressions.Add(
Expression.IfThen(
Expression.Equal(_left, Expression.Constant(null, typeof(Left))),
Expression.Throw(Expression.New(typeof(System.ArgumentNullException).GetConstructor(new System.Type[] { typeof(string) }), Expression.Constant("left")))));
}
if (!typeof(Right).IsValueType) // is nullable?
{
expressions.Add(
Expression.IfThen(
Expression.Equal(_right, Expression.Constant(null, typeof(Right))),
Expression.Throw(Expression.New(typeof(System.ArgumentNullException).GetConstructor(new System.Type[] { typeof(string) }), Expression.Constant("right")))));
}
// code
expressions.Add(operation(_left, _right, _label));
expressions.Add(Expression.Label(_label, Expression.Constant(default(Return), typeof(Return))));
// build expression
Expression expression = Expression.Block(expressions.ToArray());
// compile
return(Expression.Lambda <Delegate>(expression, _left, _right).Compile());
}
/// <summary>Gets the enumerator for the trie.</summary>
/// <returns>The enumerator for the trie.</returns>
public System.Collections.Generic.IEnumerator <Action <Action <T> > > GetEnumerator()
{
IList <Action <Action <T> > > list = new ListLinked <Action <Action <T> > >();
Stepper(x => list.Add(x));
return(list.GetEnumerator());
}
/// <inheritdoc/>
public System.Collections.Generic.IEnumerator <Action <Action <T> > > GetEnumerator()
{
#warning TODO: optimize
IList <Action <Action <T> > > list = new ListLinked <Action <Action <T> > >();
this.Stepper(x => list.Add(x));
return(list.GetEnumerator());
}
// ListLinked
[Benchmark] public void Add()
{
IList <Person> list = new ListLinked <Person>();
foreach (Person person in RandomTestData)
{
list.Add(person);
}
}
public void Add()
{
IList <int> addable = new ListLinked <int>();
int addCount = AddCount;
for (int i = 0; i < addCount; i++)
{
addable.Add(i);
}
}
public void Add_Testing()
{
const int count = 100000;
IList <int> list = new ListLinked <int>();
Stepper.Iterate(count, i => list.Add(i));
// check count
Assert.IsTrue(list.Count == count);
// check for all values
bool[] values = new bool[count];
list.Stepper(i => values[i] = true);
values.Stepper(b => Assert.IsTrue(b));
}
/// <summary>Creates a shallow clone of this data structure.</summary>
/// <returns>A shallow clone of this data structure.</returns>
public ListLinked <T> Clone()
{
Node head = new Node(this._head.Value);
Node current = this._head.Next;
Node current_clone = head;
while (current != null)
{
current_clone.Next = new Node(current.Value);
current_clone = current_clone.Next;
current = current.Next;
}
ListLinked <T> clone = new ListLinked <T>();
clone._head = head;
clone._tail = current_clone;
clone._count = this._count;
return(clone);
}
internal static Delegate UnaryOperationHelper <Delegate, Operand, Return>(UnaryOperationHelperDelegate operation)
{
// shared expressions
ParameterExpression _operand = Expression.Parameter(typeof(Operand));
LabelTarget _label = Expression.Label(typeof(Return));
// code builder
ListLinked <Expression> expressions = new ListLinked <Expression>();
// null checks
if (!typeof(Operand).IsValueType) // is nullable?
{
expressions.Add(
Expression.IfThen(
Expression.Equal(_operand, Expression.Constant(null, typeof(Operand))),
Expression.Throw(Expression.New(typeof(System.ArgumentNullException).GetConstructor(new System.Type[] { typeof(string) }), Expression.Constant("operand")))));
}
// code
expressions.Add(operation(_operand, _label));
expressions.Add(Expression.Label(_label, Expression.Constant(default(Return))));
// build
return(Expression.Lambda <Delegate>(
Expression.Block(expressions.ToArray()),
_operand).Compile());
}
static void Main()
{
Random random = new Random();
int test = 10;
Console.WriteLine("You are runnning the Data Structures example.");
Console.WriteLine("======================================================");
Console.WriteLine();
#region Link (aka Tuple)
Console.WriteLine(" Link------------------------------------");
Console.WriteLine();
Console.WriteLine(" A \"Link\" is like a System.Tuple that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. A Link/Tuple is");
Console.WriteLine(" used when you have a small, known-sized set of objects");
Console.WriteLine(" that you want to bundle together without making a custom");
Console.WriteLine(" custom class.");
Console.WriteLine();
Link link = new Link <int, int, int, int, int, int>(0, 1, 2, 3, 4, 5);
Console.Write(" Traversal: ");
link.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" Size: {link.Size}");
Console.WriteLine();
#endregion
#region Array
Console.WriteLine(" Array---------------------------------");
Console.WriteLine();
Console.WriteLine(" An Array<T> is just a wrapper for arrays that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. An array is used when");
Console.WriteLine(" dealing with static-sized, known-sized sets of data. Arrays");
Console.WriteLine(" can be sorted along 1 dimensions for binary searching algorithms.");
Console.WriteLine();
IArray <int> array = new Array <int>(test);
Console.Write($" Filling in (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
array[i] = i;
}
Console.WriteLine();
Console.Write(" Traversal: ");
array.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" Length: {array.Length}");
Console.WriteLine();
#endregion
#region List
Console.WriteLine(" List---------------------------------");
Console.WriteLine();
Console.WriteLine(" An List is like an IList that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"ListArray\" is");
Console.WriteLine(" the array implementation while \"ListLinked\" is the");
Console.WriteLine(" the linked-list implementation. An List is used");
Console.WriteLine(" when dealing with an unknown quantity of data that you");
Console.WriteLine(" will likely have to enumerate/step through everything. The");
Console.WriteLine(" ListArray shares the properties of an Array in");
Console.WriteLine(" that it can be relateively quickly sorted along 1 dimensions");
Console.WriteLine(" for binary search algorithms.");
Console.WriteLine();
// ListArray ---------------------------------------
IList <int> listArray = new ListArray <int>(test);
Console.Write($" [ListArray] Adding (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
listArray.Add(i);
}
Console.WriteLine();
Console.Write(" [ListArray] Traversal: ");
listArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [ListArray] Count: {listArray.Count}");
listArray.Clear();
Console.WriteLine();
// ListLinked ---------------------------------------
IList <int> listLinked = new ListLinked <int>();
Console.Write($" [ListLinked] Adding (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
listLinked.Add(i);
}
Console.WriteLine();
Console.Write(" [ListLinked] Traversal: ");
listLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [ListLinked] Count: {listLinked.Count}");
listLinked.Clear();
Console.WriteLine();
#endregion
#region Stack
{
Console.WriteLine(" Stack---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Stack\" is a Stack that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"StackArray\" is");
Console.WriteLine(" the array implementation while \"StackLinked\" is the");
Console.WriteLine(" the linked-list implementation. A Stack is used");
Console.WriteLine(" specifically when you need the algorithm provided by the Push");
Console.WriteLine(" and Pop functions.");
Console.WriteLine();
IStack <int> stackArray = new StackArray <int>();
Console.Write($" [StackArray] Pushing (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
stackArray.Push(i);
}
Console.WriteLine();
Console.Write(" [StackArray] Traversal: ");
stackArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [StackArray] Pop: {stackArray.Pop()}");
Console.WriteLine($" [StackArray] Pop: {stackArray.Pop()}");
Console.WriteLine($" [StackArray] Peek: {stackArray.Peek()}");
Console.WriteLine($" [StackArray] Pop: {stackArray.Pop()}");
Console.WriteLine($" [StackArray] Count: {stackArray.Count}");
stackArray.Clear();
Console.WriteLine();
IStack <int> stackLinked = new StackLinked <int>();
Console.Write($" [StackLinked] Pushing (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
stackLinked.Push(i);
}
Console.WriteLine();
Console.Write(" [StackLinked] Traversal: ");
stackLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [StackLinked] Pop: {stackLinked.Pop()}");
Console.WriteLine($" [StackLinked] Pop: {stackLinked.Pop()}");
Console.WriteLine($" [StackLinked] Peek: {stackLinked.Peek()}");
Console.WriteLine($" [StackLinked] Pop: {stackLinked.Pop()}");
Console.WriteLine($" [StackLinked] Count: {stackLinked.Count}");
stackLinked.Clear();
Console.WriteLine();
}
#endregion
#region Queue
{
Console.WriteLine(" Queue---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Queue\" is a Queue that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"QueueArray\" is");
Console.WriteLine(" the array implementation while \"QueueLinked\" is the");
Console.WriteLine(" the linked-list implementation. A Queue/Stack is used");
Console.WriteLine(" specifically when you need the algorithm provided by the Queue");
Console.WriteLine(" and Dequeue functions.");
Console.WriteLine();
IQueue <int> queueArray = new QueueArray <int>();
Console.Write($" [QueueArray] Enqueuing (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
queueArray.Enqueue(i);
}
Console.WriteLine();
Console.Write(" [QueueArray] Traversal: ");
queueArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [QueueArray] Dequeue: {queueArray.Dequeue()}");
Console.WriteLine($" [QueueArray] Dequeue: {queueArray.Dequeue()}");
Console.WriteLine($" [QueueArray] Peek: {queueArray.Peek()}");
Console.WriteLine($" [QueueArray] Dequeue: {queueArray.Dequeue()}");
Console.WriteLine($" [QueueArray] Count: {queueArray.Count}");
queueArray.Clear();
Console.WriteLine();
IQueue <int> queueLinked = new QueueLinked <int>();
Console.Write($" [QueueLinked] Enqueuing (0-{test - 1})...");
for (int i = 0; i < test; i++)
{
queueLinked.Enqueue(i);
}
Console.WriteLine();
Console.Write(" [QueueLinked] Traversal: ");
queueLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine($" [QueueLinked] Pop: {queueLinked.Dequeue()}");
Console.WriteLine($" [QueueLinked] Pop: {queueLinked.Dequeue()}");
Console.WriteLine($" [QueueLinked] Peek: {queueLinked.Peek()}");
Console.WriteLine($" [QueueLinked] Pop: {queueLinked.Dequeue()}");
Console.WriteLine($" [QueueLinked] Count: {queueLinked.Count}");
queueLinked.Clear();
Console.WriteLine();
}
#endregion
#region Heap
{
Console.WriteLine(" Heap---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Heap\" is a binary tree that stores items based on priorities.");
Console.WriteLine(" It implements Towel.DataStructures.DataStructure like the others.");
Console.WriteLine(" It uses sifting algorithms to move nodes vertically through itself.");
Console.WriteLine(" It is often the best data structure for standard priority queues.");
Console.WriteLine(" \"HeapArray\" is an implementation where the tree has been flattened");
Console.WriteLine(" into an array.");
Console.WriteLine();
Console.WriteLine(" Let's say the priority is how close a number is to \"5\".");
Console.WriteLine(" So \"Dequeue\" will give us the next closest value to \"5\".");
static void Main(string[] args)
{
Random random = new Random();
int test = 10;
Console.WriteLine("You are runnning the Data Structures example.");
Console.WriteLine("======================================================");
Console.WriteLine();
#region Link
Console.WriteLine(" Testing Link-------------------------------");
Console.WriteLine(" Size: 6");
Link link = new Link <int, int, int, int, int, int>(0, 1, 2, 3, 4, 5);
Console.Write(" Traversal: ");
link.Stepper((dynamic current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string linklink_file = "link." + ToExtension(link.GetType());
//Console.WriteLine(" File: \"" + linklink_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(linklink_file, link));
//Link<int, int, int, int, int, int> deserialized_linklink;
//Console.WriteLine(" Deserialized: " + Deserialize(linklink_file, out deserialized_linklink));
Console.WriteLine();
#endregion
#region Array
Console.WriteLine(" Testing Array_Array<int>-------------------");
Array <int> array = new ArrayArray <int>(test);
for (int i = 0; i < test; i++)
{
array[i] = i;
}
Console.Write(" Traversal: ");
array.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string arrayarray_file = "array." + ToExtension(array.GetType());
//Console.WriteLine(" File: \"" + arrayarray_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(arrayarray_file, array));
//ArrayArray<int> deserialized_arrayarray;
//Console.WriteLine(" Deserialized: " + Deserialize(arrayarray_file, out deserialized_arrayarray));
Console.WriteLine();
#endregion
#region List
Console.WriteLine(" Testing List_Array<int>--------------------");
List <int> list_array = new ListArray <int>(test);
for (int i = 0; i < test; i++)
{
list_array.Add(i);
}
Console.Write(" Traversal: ");
list_array.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
//string list_array_serialization = (list_array as ListArray<int>).Serialize(x => x.ToString());
//using (StreamWriter writer = new StreamWriter("ListArray.ListArray"))
//{
// writer.WriteLine(list_array_serialization);
//}
//using (StreamReader reader = new StreamReader("ListArray.ListArray"))
//{
// list_array = ListArray<int>.Deserialize(reader.ReadToEnd(), x => Int16.Parse(x.Trim()));
//}
//Console.Write(" Serialization/Deserialization is possible.");
list_array.Add(11);
list_array.Remove(7);
Console.WriteLine();
Console.WriteLine();
//ListArray<ListArray<int>> list_array2 = new ListArray<ListArray<int>>(test);
//for (int i = 0; i < test; i++)
//{
// ListArray<int> nested_list = new ListArray<int>();
// for (int j = 0; j < test; j++)
// {
// nested_list.Add(j);
// }
// list_array2.Add(nested_list);
//}
//string list_array2_serialization = list_array2.Serialize(x => x.Serialize(y => y.ToString()));
//using (StreamWriter writer = new StreamWriter("ListArray2.ListArray"))
//{
// writer.WriteLine(list_array2_serialization);
//}
//using (StreamReader reader = new StreamReader("ListArray2.ListArray"))
//{
// list_array2 = ListArray<ListArray<int>>.Deserialize(reader.ReadToEnd(), x => ListArray<int>.Deserialize(x, y => Int16.Parse(y.Trim())));
//}
Console.WriteLine(" Testing List_Linked<int>-------------------");
List <int> list_linked = new ListLinked <int>();
for (int i = 0; i < test; i++)
{
list_linked.Add(i);
}
Console.Write(" Traversal: ");
list_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string listlinked_file = "list_linked." + ToExtension(list_linked.GetType());
//Console.WriteLine(" File: \"" + listlinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(listlinked_file, list_linked));
//ListLinked<int> deserialized_listlinked;
//Console.WriteLine(" Deserialized: " + Deserialize(listlinked_file, out deserialized_listlinked));
Console.WriteLine();
#endregion
#region Stack
Console.WriteLine(" Testing Stack_Linked<int>------------------");
Stack <int> stack_linked = new StackLinked <int>();
for (int i = 0; i < test; i++)
{
stack_linked.Push(i);
}
Console.Write(" Traversal: ");
stack_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string stacklinked_file = "stack_linked." + ToExtension(stack_linked.GetType());
//Console.WriteLine(" File: \"" + stacklinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(stacklinked_file, stack_linked));
//StackLinked<int> deserialized_stacklinked;
//Console.WriteLine(" Deserialized: " + Deserialize(stacklinked_file, out deserialized_stacklinked));
Console.WriteLine();
#endregion
#region Queue
Console.WriteLine(" Testing Queue_Linked<int>------------------");
Queue <int> queue_linked = new QueueLinked <int>();
for (int i = 0; i < test; i++)
{
queue_linked.Enqueue(i);
}
Console.Write(" Traversal: ");
queue_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string queuelinked_file = "queue_linked." + ToExtension(queue_linked.GetType());
//Console.WriteLine(" File: \"" + queuelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(queuelinked_file, queue_linked));
//QueueLinked<int> deserialized_queuelinked;
//Console.WriteLine(" Deserialized: " + Deserialize(queuelinked_file, out deserialized_queuelinked));
Console.WriteLine();
#endregion
#region Heap
Console.WriteLine(" Testing Heap_Array<int>--------------------");
Heap <int> heap_array = new HeapArray <int>(Compute <int> .Compare);
for (int i = 0; i < test; i++)
{
heap_array.Enqueue(i);
}
Console.Write(" Delegate: ");
heap_array.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string heaplinked_file = "heap_array." + ToExtension(heap_array.GetType());
//Console.WriteLine(" File: \"" + heaplinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(heaplinked_file, heap_array));
//HeapArray<int> deserialized_heaplinked;
//Console.WriteLine(" Deserialized: " + Deserialize(heaplinked_file, out deserialized_heaplinked));
Console.WriteLine();
#endregion
#region Tree
Console.WriteLine(" Testing Tree_Map<int>----------------------");
Tree <int> tree_Map = new TreeMap <int>(0, Compute <int> .Equate, Hash.Default);
for (int i = 1; i < test; i++)
{
tree_Map.Add(i, i / (int)System.Math.Sqrt(test));
}
Console.Write(" Children of 0 (root): ");
tree_Map.Children(0, (int i) => { Console.Write(i + " "); });
Console.WriteLine();
Console.Write(" Children of " + ((int)System.Math.Sqrt(test) - 1) + " (root): ");
tree_Map.Children(((int)System.Math.Sqrt(test) - 1), (int i) => { Console.Write(i + " "); });
Console.WriteLine();
Console.Write(" Traversal: ");
tree_Map.Stepper((int i) => { Console.Write(i + " "); });
Console.WriteLine();
// Saving to a file
//string treelinked_file = "tree_Map." + ToExtension(tree_Map.GetType());
//Console.WriteLine(" File: \"" + treelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(treelinked_file, tree_Map));
//TreeMap<int> deserialized_treelinked;
//Console.WriteLine(" Deserialized: " + Deserialize(treelinked_file, out deserialized_treelinked));
Console.WriteLine();
#endregion
#region AVL Tree
//Console.WriteLine(" Testing AvlTree_Linked<int>----------------");
//// Construction
//AvlTree<int> avlTree_linked = new AvlTree_Linked<int>(Logic.compare);
//// Adding Items
//Console.Write(" Adding (0-" + test + ")...");
//for (int i = 0; i < test; i++)
// avlTree_linked.Add(i);
//Console.WriteLine();
//// Iteration
//Console.Write(" Traversal: ");
//avlTree_linked.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Removal
//int avl_tree_linked_removal = random.Next(0, test);
//avlTree_linked.Remove(avl_tree_linked_removal);
//Console.Write(" Remove(" + avl_tree_linked_removal + "): ");
//avlTree_linked.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Look Up Items
//int avl_tree_linked_lookup = random.Next(0, test);
//while (avl_tree_linked_lookup == avl_tree_linked_removal)
// avl_tree_linked_lookup = random.Next(0, test);
//Console.WriteLine(" Look Up (" + avl_tree_linked_lookup + "): " + avlTree_linked.TryGet(avl_tree_linked_lookup, Logic.compare, out temp));
//Console.WriteLine(" Look Up (" + avl_tree_linked_removal + "): " + avlTree_linked.TryGet(avl_tree_linked_removal, Logic.compare, out temp));
//avlTree_linked.Get(avl_tree_linked_lookup, Logic.compare);
//// Current Min-Max Values
//Console.WriteLine(" Least: " + avlTree_linked.CurrentLeast + " Greatest: " + avlTree_linked.CurrentGreatest);
//// Saving to a file
//string avltreelinked_file = "avlTree_linked." + ToExtension(avlTree_linked.GetType());
//Console.WriteLine(" File: \"" + avltreelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(avltreelinked_file, avlTree_linked));
//AvlTree_Linked<int> deserialized_avltreelinked;
//Console.WriteLine(" Deserialized: " + Deserialize(avltreelinked_file, out deserialized_avltreelinked));
//Console.WriteLine();
#endregion
#region Red-Black Tree
Console.WriteLine(" Testing RedBlack_Linked<int>---------------");
RedBlackTree <int> redBlackTree_linked = new RedBlackTreeLinked <int>(Compute <int> .Compare);
for (int i = 0; i < test; i++)
{
redBlackTree_linked.Add(i);
}
Console.Write(" Traversal: ");
redBlackTree_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Saving to a file
//string redblacktreelinked_file = "redBlackTree_linked." + ToExtension(redBlackTree_linked.GetType());
//Console.WriteLine(" File: \"" + redblacktreelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(redblacktreelinked_file, redBlackTree_linked));
//RedBlackTreeLinked<int> deserialized_redblacktreelinked;
//Console.WriteLine(" Deserialized: " + Deserialize(redblacktreelinked_file, out deserialized_redblacktreelinked));
Console.WriteLine();
#endregion
#region BTree
//Console.WriteLine(" Testing BTree_LinkedArray<int>-------------");
//BTree<int> btree_linked = new BTree_LinkedArray<int>(Logic.compare, 3);
//for (int i = 0; i < test; i++)
// btree_linked.Add(i);
//Console.Write(" Delegate: ");
//btree_linked.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.Write(" IEnumerator: ");
//foreach (int current in btree_linked)
// Console.Write(current);
//Console.WriteLine();
//Console.WriteLine(" Press Enter to continue...");
//string maplinked_file = "maplinked.quad";
//Console.WriteLine(" File: \"" + maplinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(maplinked_file, hashTable_linked));
//Omnitree_LinkedLinkedLists<int, double> deserialized_maplinked;
//Console.WriteLine(" Deserialized: " + Deserialize(maplinked_file, out deserialized_maplinked));
//Console.ReadLine();
//Console.WriteLine();
#endregion
#region Set
Console.WriteLine(" Testing Set_Hash<int>----------------------");
Set <int> set_linked = new SetHashList <int>(Compute <int> .Equate, Hash.Default);
for (int i = 0; i < test; i++)
{
set_linked.Add(i);
}
// Traversal
Console.Write(" Traversal: ");
set_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.Write(" Table Size: " + (set_linked as SetHashList <int>).TableSize);
Console.WriteLine();
Console.WriteLine();
#endregion
#region Map
Console.WriteLine(" Testing MapHashList<int, int>--------------");
Map <int, int> map_sethash = new MapHashLinked <int, int>(Compute <int> .Equate, Hash.Default);
for (int i = 0; i < test; i++)
{
map_sethash.Add(i, i);
}
Console.Write(" Look Ups: ");
for (int i = 0; i < test; i++)
{
Console.Write(map_sethash[i]);
}
Console.WriteLine();
// Traversal
Console.Write(" Traversal: ");
map_sethash.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.Write(" Table Size: " + (map_sethash as MapHashLinked <int, int>).TableSize);
Console.WriteLine();
Console.WriteLine();
#endregion
#region Quad-Tree
//Console.WriteLine(" Testing Quadtree_Array<int, double>--------");
//// Construction
//Quadtree<int, double> quadtree_array = new Quadtree_Array<int, double>(
// -test - 1, -test - 1, // minimum dimensions of the quadtree
// test + 1, test + 1, // maximum dimensions of the quadtree
// (int i, out double x, out double y) => { x = i; y = i; }, // 2D location function
// Logic.compare, // axis comparison function
// Statistics.Mean); // axis average function
//// Adding
//for (int i = 0; i < test; i++)
// quadtree_array.Add(i);
//// Proper Traversal
//Console.Write(" Traversal: ");
//quadtree_array.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Saving to a file
//string quadtreearray_file = "quadtree_array." + ToExtension(quadtree_array.GetType());
//Console.WriteLine(" File: \"" + quadtreearray_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(quadtreearray_file, quadtree_array));
//Quadtree_Array<int, double> deserialized_quadtreearray;
//Console.WriteLine(" Deserialized: " + Deserialize(quadtreearray_file, out deserialized_quadtreearray));
//Console.WriteLine();
//Console.WriteLine(" Testing Quadtree_Linked<int, double>-------");
//// Construction
//Quadtree<int, double> quadtree_linked = new Quadtree_Linked<int, double>(
// -test - 1, -test - 1, // minimum dimensions of the quadtree
// test + 1, test + 1, // maximum dimensions of the quadtree
// (int i, out double x, out double y) => { x = i; y = i; }, // 2D location function
// Logic.compare, // axis comparison function
// (Quadtree.Average<double>)Statistics.Mean<double>); // axis average function
//// Adding
//for (int i = 0; i < test; i++)
// quadtree_linked.Add(i);
//// Proper Traversal
//Console.Write(" Traversal: ");
//quadtree_linked.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Saving to a file
//string quadtreelinked_file = "quadtree_linked." + ToExtension(quadtree_linked.GetType());
//Console.WriteLine(" File: \"" + quadtreelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(quadtreelinked_file, quadtree_linked));
//Quadtree_Linked<int, double> deserialized_quadtreelinked;
//Console.WriteLine(" Deserialized: " + Deserialize(quadtreelinked_file, out deserialized_quadtreelinked));
//Console.WriteLine();
#endregion
#region Oct-Tree
//Console.WriteLine(" Testing Octree_Linked<int, double>---------");
//// Construction
//Octree<int, double> octree_linked = new Octree_Linked<int, double>(
// -test - 1, -test - 1, -test - 1, // minimum dimensions of the octree
// test + 1, test + 1, test + 1, // maximum dimensions of the octree
// (int i, out double x, out double y, out double z) => { x = i; y = i; z = i; }, // 3D location function
// Logic.compare, // axis comparison function
// Statistics.Mean); // axis average function
//// Addition
//for (int i = 0; i < test; i++)
// octree_linked.Add(i);
//// Proper Traversal
//Console.Write(" Traversal: ");
//octree_linked.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Saving to a file
//string octree_file = "octree_linked." + ToExtension(octree_linked.GetType());
//Console.WriteLine(" File: \"" + octree_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(octree_file, octree_linked));
//Octree_Linked<int, double> deserialized_octree;
//Console.WriteLine(" Deserialized: " + Deserialize(octree_file, out deserialized_octree));
//Console.WriteLine();
#endregion
#region OmnitreePoints
{
Console.WriteLine(" Testing OmnitreeLinkedLinked<int, double>-------");
// Construction
OmnitreePoints <int, double, double, double> omnitree_linked = new OmnitreePointsLinked <int, double, double, double>(
(int index, out double a, out double b, out double c) => { a = index; b = index; c = index; }); // axis average function
// Properties
Console.WriteLine(" Dimensions: " + omnitree_linked.Dimensions);
Console.WriteLine(" Count: " + omnitree_linked.Count);
// Addition
Console.Write(" Adding 0-" + test + ": ");
for (int i = 0; i < test; i++)
{
omnitree_linked.Add(i);
}
omnitree_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitree_linked.Count);
// Traversal
Console.Write(" Traversal [ALL]: ");
omnitree_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Look Up 1
Console.Write(" Traversal [(" + (test / 2) + ", " + (test / 2) + ", " + (test / 2) + ")->(" + test + ", " + test + ", " + test + ")]: ");
omnitree_linked.Stepper((int current) => { Console.Write(current); },
test / 2, test,
test / 2, test,
test / 2, test);
Console.WriteLine();
// Look Up 2
Console.Write(" Look Up [" + (test / 3) + ", " + (test / 3) + ", " + (test / 3) + "]: ");
omnitree_linked[(test / 3), (test / 3), (test / 3)]((int current) => { Console.Write(current); });
Console.WriteLine();
// Removal
Console.Write(" Remove 0-" + test / 3 + ": ");
omnitree_linked.Remove(
0, test / 3,
0, test / 3,
0, test / 3);
omnitree_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitree_linked.Count);
// Clear
Console.Write(" Clear: ");
omnitree_linked.Clear();
omnitree_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitree_linked.Count);
// Saving to a file
//string omnitreelinked_file = "omnitree_linkedlinkedlists." + ToExtension(omnitree_linked.GetType());
//Console.WriteLine(" File: \"" + omnitreelinked_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(omnitreelinked_file, omnitree_linked));
//OmnitreeLinkedLinkedLists<int, double> deserialized_omnitreeLinked;
//Console.WriteLine(" Deserialized: " + Deserialize(omnitreelinked_file, out deserialized_omnitreeLinked));
Console.WriteLine();
//Console.WriteLine(" Testing Omnitree_LinkedArrayLists<int, double>--------");
//// Construction
//Omnitree<int, double> omnitree_array = new OmnitreeLinkedArray<int, double>(
// new double[] { -test - 1, -test - 1, -test - 1 }, // minimum dimensions of the omnitree
// new double[] { test + 1, test + 1, test + 1 }, // maximum dimensions of the omnitree
// (int index) => { return Accessor.Get(new double[] { index, index, index }); }, // "N-D" location function
// Compute<double>.Compare, // comparison function
// (double a, double b) => { return (a + b) / 2; }); // average function
//// Properties
//Console.WriteLine(" Origin: [" + omnitree_array.Origin(0) + ", " + omnitree_array.Origin(1) + ", " + omnitree_array.Origin(2) + "]");
//Console.WriteLine(" Minimum: [" + omnitree_array.Min(0) + ", " + omnitree_array.Min(1) + ", " + omnitree_array.Min(2) + "]");
//Console.WriteLine(" Maximum: [" + omnitree_array.Max(0) + ", " + omnitree_array.Max(1) + ", " + omnitree_array.Max(2) + "]");
//Console.WriteLine(" Dimensions: " + omnitree_array.Dimensions);
//Console.WriteLine(" Count: " + omnitree_array.Count);
//// Addition
//Console.Write(" Adding 0-" + test + ": ");
//for (int i = 0; i < test; i++)
// omnitree_array.Add(i);
//omnitree_array.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_array.Count);
//// Traversal
//Console.Write(" Traversal [ALL]: ");
// omnitree_array.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Look Up
//Console.Write(" Traversal [" + (test / 2) + "-" + test + "]: ");
// omnitree_array.Stepper((int current) => { Console.Write(current); },
// new double[] { test / 2, test / 2, test / 2 },
// new double[] { test, test, test });
//Console.WriteLine();
//// Removal
//Console.Write(" Remove 0-" + test / 3 + ": ");
//omnitree_array.Remove(
// new double[] { 0, 0, 0 },
// new double[] { test / 3, test / 3, test / 3 });
//omnitree_array.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_array.Count);
//// Clear
//Console.Write(" Clear: ");
//omnitree_array.Clear();
// omnitree_array.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_array.Count);
//// Saving to a file
////string omnitreearray_file = "omnitree_linkedarraylists." + ToExtension(omnitree_array.GetType());
////Console.WriteLine(" File: \"" + omnitreearray_file + "\"");
////Console.WriteLine(" Serialized: " + Serialize(omnitreearray_file, omnitree_array));
////OmnitreeLinkedLinkedLists<int, double> deserialized_omnitreearray;
////Console.WriteLine(" Deserialized: " + Deserialize(omnitreearray_file, out deserialized_omnitreearray));
//Console.WriteLine();
}
#endregion
#region OmnitreePoints
//Console.WriteLine(" Testing 2222222<int, double>-------");
//// Construction
//OmnitreePoints<int, double, double, double> omnitree_linked2 = new OmnitreePoints_2<int, double, double, double>(
// (int index, out double a, out double b, out double c) => { a = index; b = index; c = index; }, // "N-D" location function
// Theta.Equate.Default,
// Theta.Equate.Default,
// Theta.Equate.Default,
// Theta.Equate.Default,
// Compute<double>.Compare, // axis comparison function
// Compute<double>.Compare,
// Compute<double>.Compare); // axis average function
//// Properties
//Console.WriteLine(" Dimensions: " + omnitree_linked2.Dimensions);
//Console.WriteLine(" Count: " + omnitree_linked2.Count);
//// Addition
//Console.Write(" Adding 0-" + test + ": ");
//for (int i = 0; i < test; i++)
// omnitree_linked2.Add(i);
//omnitree_linked2.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_linked2.Count);
//// Traversal
//Console.Write(" Traversal [ALL]: ");
//omnitree_linked2.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Look Up 1
//Console.Write(" Traversal [(" + (test / 2) + ", " + (test / 2) + ", " + (test / 2) + ")->(" + test + ", " + test + ", " + test + ")]: ");
//omnitree_linked2.Stepper((int current) => { Console.Write(current); },
// test / 2, test,
// test / 2, test,
// test / 2, test);
//Console.WriteLine();
//// Look Up 2
//Console.Write(" Look Up [" + (test / 3) + ", " + (test / 3) + ", " + (test / 3) + "]: ");
//omnitree_linked2[(test / 3), (test / 3), (test / 3)]((int current) => { Console.Write(current); });
//Console.WriteLine();
//// Removal
//Console.Write(" Remove 0-" + test / 3 + ": ");
//omnitree_linked2.Remove(
// 0, test / 3,
// 0, test / 3,
// 0, test / 3);
//omnitree_linked2.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_linked2.Count);
//// Clear
//Console.Write(" Clear: ");
//omnitree_linked2.Clear();
//omnitree_linked2.Stepper((int current) => { Console.Write(current); });
//Console.WriteLine();
//Console.WriteLine(" Count: " + omnitree_linked2.Count);
//Console.WriteLine();
#endregion
#region OmnitreeBounds
{
Console.WriteLine(" Testing OmnitreeBoundsLinked<int, double>-------");
// Construction
OmnitreeBounds <int, double, double, double> omnitreeBounds_linked = new OmnitreeBoundsLinked <int, double, double, double>(
(int index,
out double min1, out double max1,
out double min2, out double max2,
out double min3, out double max3) =>
{
min1 = index; max1 = index;
min2 = index; max2 = index;
min3 = index; max3 = index;
});
// Properties
Console.WriteLine(" Dimensions: " + omnitreeBounds_linked.Dimensions);
Console.WriteLine(" Count: " + omnitreeBounds_linked.Count);
// Addition
Console.Write(" Adding 0-" + test + ": ");
for (int i = 0; i < test; i++)
{
omnitreeBounds_linked.Add(i);
}
omnitreeBounds_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitreeBounds_linked.Count);
// Traversal
Console.Write(" Traversal [ALL]: ");
omnitreeBounds_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
// Look Up 1
//Console.Write(" Traversal [(" + (test / 2) + ", " + (test / 2) + ", " + (test / 2) + ")->(" + test + ", " + test + ", " + test + ")]: ");
//omnitreeBounds_linked.Stepper((int current) => { Console.Write(current); },
// test / 2, test,
// test / 2, test,
// test / 2, test);
//Console.WriteLine();
// Removal
Console.Write(" Remove 0-" + test / 3 + ": ");
omnitreeBounds_linked.RemoveOverlapped(
0, test / 3,
0, test / 3,
0, test / 3);
omnitreeBounds_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitreeBounds_linked.Count);
// Clear
Console.Write(" Clear: ");
omnitreeBounds_linked.Clear();
omnitreeBounds_linked.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Count: " + omnitreeBounds_linked.Count);
Console.WriteLine();
}
#endregion
#region KD Tree
////List<KdTreeNode<float, string>> testNodes = new List_Linked<KdTreeNode<float, string>>();
//KdTree_Linked<string, float> tree = new KdTree_Linked<string, float>(
// 2,
// Logic.compare,
// float.MinValue,
// float.MaxValue,
// 0,
// Arithmetic.Add,
// Arithmetic.Subtract,
// Arithmetic.Multiply);
//List<KdTree_Linked<string, float>.Node> testNodes =
// new List_Linked<KdTree_Linked<string, float>.Node>
//{
// new KdTree_Linked<string, float>.Node(new float[] { 5, 5 }, "Root"),
// new KdTree_Linked<string, float>.Node(new float[] { 2.5f, 2.5f }, "Root-Left"),
// new KdTree_Linked<string, float>.Node(new float[] { 7.5f, 7.5f }, "Root-Right"),
// new KdTree_Linked<string, float>.Node(new float[] { 1, 10 }, "Root-Left-Left"),
// new KdTree_Linked<string, float>.Node(new float[] { 10, 10 }, "Root-Right-Right")
//};
//foreach (var node in testNodes)
// if (!tree.Add(node.Point, node.Value))
// throw new Exception("Failed to add node to tree");
//var nodesToRemove = new KdTreeNode<float, string>[] {
// testNodes[1], // Root-Left
// testNodes[0] // Root
//};
//foreach (var nodeToRemove in nodesToRemove)
//{
// tree.RemoveAt(nodeToRemove.Point);
// testNodes.Remove(nodeToRemove);
// Assert.IsNull(tree.FindValue(nodeToRemove.Value));
// Assert.IsNull(tree.FindValueAt(nodeToRemove.Point));
// foreach (var testNode in testNodes)
// {
// Assert.AreEqual(testNode.Value, tree.FindValueAt(testNode.Point));
// Assert.AreEqual(testNode.Point, tree.FindValue(testNode.Value));
// }
// Assert.AreEqual(testNodes.Count, tree.Count);
//}
#endregion
#region Graph
Console.WriteLine(" Testing Graph_SetOmnitree<int>-------------");
Graph <int> graph = new GraphSetOmnitree <int>(Compute <int> .Equate, Compute <int> .Compare, Hash.Default);
// add nodes
for (int i = 0; i < test; i++)
{
graph.Add(i);
}
// add edges
for (int i = 0; i < test - 1; i++)
{
graph.Add(i, i + 1);
}
Console.Write(" Traversal: ");
graph.Stepper((int current) => { Console.Write(current); });
Console.WriteLine();
Console.WriteLine(" Edges: ");
//((Graph_SetQuadtree<int>)graph)._edges.Foreach((Graph_SetQuadtree<int>.Edge e) => { Console.WriteLine(" " + e.Start + " " + e.End); });
graph.Stepper(
(int current) =>
{
Console.Write(" " + current + ": ");
graph.Neighbors(current,
(int a) =>
{
Console.Write(a);
});
Console.WriteLine();
});
// Saving to a file
//string graph_file = "graph." + ToExtension(graph.GetType());
//Console.WriteLine(" File: \"" + graph_file + "\"");
//Console.WriteLine(" Serialized: " + Serialize(graph_file, graph));
//GraphSetOmnitree<int> deserialized_graph;
//Console.WriteLine(" Deserialized: " + Deserialize(graph_file, out deserialized_graph));
Console.WriteLine();
#endregion
Console.WriteLine("============================================");
Console.WriteLine("Examples Complete...");
Console.ReadLine();
}
// constructores
#region public Order_ListLinked(Compare<T> compare)
/// <summary>Constructs a Order_ListArray.</summary>
/// <param name="compare">The soring technique used by this data structure.</param>
public OrderListLinked(Compare <T> compare)
{
this._compare = compare;
this._list = new ListLinked <T>();
}
static void Main(string[] args)
{
Random random = new Random();
int test = 10;
Console.WriteLine("You are runnning the Data Structures example.");
Console.WriteLine("======================================================");
Console.WriteLine();
#region Link (aka Tuple)
Console.WriteLine(" Link------------------------------------");
Console.WriteLine();
Console.WriteLine(" A \"Link\" is like a System.Tuple that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. A Link/Tuple is");
Console.WriteLine(" used when you have a small, known-sized set of objects");
Console.WriteLine(" that you want to bundle together without making a custom");
Console.WriteLine(" custom class.");
Console.WriteLine();
Link link = new Link <int, int, int, int, int, int>(0, 1, 2, 3, 4, 5);
Console.Write(" Traversal: ");
link.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" Size: " + link.Size);
Console.WriteLine();
#endregion
#region Array
Console.WriteLine(" Array---------------------------------");
Console.WriteLine();
Console.WriteLine(" An Array<T> is just a wrapper for arrays that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. An array is used when");
Console.WriteLine(" dealing with static-sized, known-sized sets of data. Arrays");
Console.WriteLine(" can be sorted along 1 dimensions for binary searching algorithms.");
Console.WriteLine();
IArray <int> indexed = new Array <int>(test);
Console.Write(" Filling in (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
indexed[i] = i;
}
Console.WriteLine();
Console.Write(" Traversal: ");
indexed.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" Length: " + indexed.Length);
Console.WriteLine();
#endregion
#region List
Console.WriteLine(" List---------------------------------");
Console.WriteLine();
Console.WriteLine(" An List is like an IList that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"ListArray\" is");
Console.WriteLine(" the array implementation while \"ListLinked\" is the");
Console.WriteLine(" the linked-list implementation. An List is used");
Console.WriteLine(" when dealing with an unknown quantity of data that you");
Console.WriteLine(" will likely have to enumerate/step through everything. The");
Console.WriteLine(" ListArray shares the properties of an Array in");
Console.WriteLine(" that it can be relateively quickly sorted along 1 dimensions");
Console.WriteLine(" for binary search algorithms.");
Console.WriteLine();
// ListArray ---------------------------------------
IList <int> addableArray = new ListArray <int>(test);
Console.Write(" [ListArray] Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
addableArray.Add(i);
}
Console.WriteLine();
Console.Write(" [ListArray] Traversal: ");
addableArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [ListArray] Count: " + addableArray.Count);
addableArray.Clear(); // Clears the addable
Console.WriteLine();
// ListLinked ---------------------------------------
IList <int> addableLinked = new ListLinked <int>();
Console.Write(" [ListLinked] Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
addableLinked.Add(i);
}
Console.WriteLine();
Console.Write(" [ListLinked] Traversal: ");
addableLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [ListLinked] Count: " + addableLinked.Count);
addableLinked.Clear(); // Clears the addable
Console.WriteLine();
#endregion
#region Stack
{
Console.WriteLine(" Stack---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Stack\" is a Stack that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"StackArray\" is");
Console.WriteLine(" the array implementation while \"StackLinked\" is the");
Console.WriteLine(" the linked-list implementation. A Stack is used");
Console.WriteLine(" specifically when you need the algorithm provided by the Push");
Console.WriteLine(" and Pop functions.");
Console.WriteLine();
IStack <int> firstInLastOutArray = new StackArray <int>();
Console.Write(" [StackArray] Pushing (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
firstInLastOutArray.Push(i);
}
Console.WriteLine();
Console.Write(" [StackArray] Traversal: ");
firstInLastOutArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [StackArray] Pop: " + firstInLastOutArray.Pop());
Console.WriteLine(" [StackArray] Pop: " + firstInLastOutArray.Pop());
Console.WriteLine(" [StackArray] Peek: " + firstInLastOutArray.Peek());
Console.WriteLine(" [StackArray] Pop: " + firstInLastOutArray.Pop());
Console.WriteLine(" [StackArray] Count: " + firstInLastOutArray.Count);
firstInLastOutArray.Clear(); // Clears the firstInLastOut
Console.WriteLine();
IStack <int> firstInLastOutLinked = new StackLinked <int>();
Console.Write(" [StackLinked] Pushing (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
firstInLastOutLinked.Push(i);
}
Console.WriteLine();
Console.Write(" [StackLinked] Traversal: ");
firstInLastOutLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [StackLinked] Pop: " + firstInLastOutLinked.Pop());
Console.WriteLine(" [StackLinked] Pop: " + firstInLastOutLinked.Pop());
Console.WriteLine(" [StackLinked] Peek: " + firstInLastOutLinked.Peek());
Console.WriteLine(" [StackLinked] Pop: " + firstInLastOutLinked.Pop());
Console.WriteLine(" [StackLinked] Count: " + firstInLastOutLinked.Count);
firstInLastOutLinked.Clear(); // Clears the firstInLastOut
Console.WriteLine();
}
#endregion
#region Queue
{
Console.WriteLine(" Queue---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Queue\" is a Queue that implements");
Console.WriteLine(" Towel.DataStructures.DataStructure. \"QueueArray\" is");
Console.WriteLine(" the array implementation while \"QueueLinked\" is the");
Console.WriteLine(" the linked-list implementation. A Queue/Stack is used");
Console.WriteLine(" specifically when you need the algorithm provided by the Queue");
Console.WriteLine(" and Dequeue functions.");
Console.WriteLine();
IQueue <int> firstInFirstOutArray = new QueueArray <int>();
Console.Write(" [QueueArray] Enqueuing (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
firstInFirstOutArray.Enqueue(i);
}
Console.WriteLine();
Console.Write(" [QueueArray] Traversal: ");
firstInFirstOutArray.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [QueueArray] Dequeue: " + firstInFirstOutArray.Dequeue());
Console.WriteLine(" [QueueArray] Dequeue: " + firstInFirstOutArray.Dequeue());
Console.WriteLine(" [QueueArray] Peek: " + firstInFirstOutArray.Peek());
Console.WriteLine(" [QueueArray] Dequeue: " + firstInFirstOutArray.Dequeue());
Console.WriteLine(" [QueueArray] Count: " + firstInFirstOutArray.Count);
firstInFirstOutArray.Clear(); // Clears the firstInLastOut
Console.WriteLine();
IQueue <int> firstInFirstOutLinked = new QueueLinked <int>();
Console.Write(" [QueueLinked] Enqueuing (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
firstInFirstOutLinked.Enqueue(i);
}
Console.WriteLine();
Console.Write(" [QueueLinked] Traversal: ");
firstInFirstOutLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" [QueueLinked] Pop: " + firstInFirstOutLinked.Dequeue());
Console.WriteLine(" [QueueLinked] Pop: " + firstInFirstOutLinked.Dequeue());
Console.WriteLine(" [QueueLinked] Peek: " + firstInFirstOutLinked.Peek());
Console.WriteLine(" [QueueLinked] Pop: " + firstInFirstOutLinked.Dequeue());
Console.WriteLine(" [QueueLinked] Count: " + firstInFirstOutLinked.Count);
firstInFirstOutLinked.Clear(); // Clears the firstInLastOut
Console.WriteLine();
}
#endregion
#region Heap
{
Console.WriteLine(" Heap---------------------------------");
Console.WriteLine();
Console.WriteLine(" An \"Heap\" is a binary tree that stores items based on priorities.");
Console.WriteLine(" It implements Towel.DataStructures.DataStructure like the others.");
Console.WriteLine(" It uses sifting algorithms to move nodes vertically through itself.");
Console.WriteLine(" It is often the best data structure for standard priority queues.");
Console.WriteLine(" \"HeapArray\" is an implementation where the tree has been flattened");
Console.WriteLine(" into an array.");
Console.WriteLine();
Console.WriteLine(" Let's say the priority is how close a number is to \"5\".");
Console.WriteLine(" So \"Dequeue\" will give us the next closest value to \"5\".");
CompareResult Priority(int a, int b)
{
int _a = Compute.AbsoluteValue(a - 5);
int _b = Compute.AbsoluteValue(b - 5);
CompareResult comparison = Compare.Wrap(_b.CompareTo(_a));
return(comparison);
}
Console.WriteLine();
IHeap <int> heapArray = new HeapArray <int>(Priority);
Console.Write(" [HeapArray] Enqueuing (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
heapArray.Enqueue(i);
}
Console.WriteLine();
Console.WriteLine(" [HeapArray] Dequeue: " + heapArray.Dequeue());
Console.WriteLine(" [HeapArray] Dequeue: " + heapArray.Dequeue());
Console.WriteLine(" [HeapArray] Peek: " + heapArray.Peek());
Console.WriteLine(" [HeapArray] Dequeue: " + heapArray.Dequeue());
Console.WriteLine(" [HeapArray] Count: " + heapArray.Count);
heapArray.Clear(); // Clears the heapArray
Console.WriteLine();
}
#endregion
#region Tree
//Console.WriteLine(" Tree-----------------------------");
//Tree<int> tree_Map = new TreeMap<int>(0, Compute.Equal, Hash.Default);
//for (int i = 1; i < test; i++)
//{
// tree_Map.Add(i, i / Compute.SquareRoot(i));
//}
//Console.Write(" Children of 0 (root): ");
//tree_Map.Children(0, (int i) => { Console.Write(i + " "); });
//Console.WriteLine();
//Console.Write(" Children of " + ((int)System.Math.Sqrt(test) - 1) + " (root): ");
//tree_Map.Children(((int)System.Math.Sqrt(test) - 1), (int i) => { Console.Write(i + " "); });
//Console.WriteLine();
//Console.Write(" Traversal: ");
//tree_Map.Stepper((int i) => { Console.Write(i + " "); });
//Console.WriteLine();
//Console.WriteLine();
#endregion
#region AVL Tree
{
Console.WriteLine(" AvlTree------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" An AVL Tree is a sorted binary tree.");
Console.WriteLine(" It implements Towel.DataStructures.DataStructure like the others.");
Console.WriteLine(" It allows for very fast 1D ranged queries/traversals.");
Console.WriteLine(" It is very similar to an Red Black tree, but uses a different sorting algorithm.");
Console.WriteLine();
IAvlTree <int> avlTree = new AvlTreeLinked <int>();
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
avlTree.Add(i);
}
Console.WriteLine();
Console.Write(" Traversal: ");
avlTree.Stepper(i => Console.Write(i));
Console.WriteLine();
//// Note: Because the nodes in AVL Tree linked do not have
//// a parent pointer, the IEnumerable "foreach" iteration
//// is extremely slow and should be avoided. It requires
//// a stack for it's iteration.
//
//Console.Write(" Traversal Foreach: ");
//foreach (int i in avlTree)
//{
// Console.Write(i);
//}
//Console.WriteLine();
int minimum = random.Next(1, test / 2);
int maximum = random.Next(1, test / 2) + test / 2;
Console.Write(" Ranged Traversal [" + minimum + "-" + maximum + "]: ");
avlTree.Stepper(i => Console.Write(i), minimum, maximum);
Console.WriteLine();
int removal = random.Next(0, test);
Console.Write(" Remove(" + removal + "): ");
avlTree.Remove(removal);
avlTree.Stepper(i => Console.Write(i));
Console.WriteLine();
int contains = random.Next(0, test);
Console.WriteLine(" Contains(" + contains + "): " + avlTree.Contains(contains));
Console.WriteLine(" Current Least: " + avlTree.CurrentLeast);
Console.WriteLine(" Current Greatest: " + avlTree.CurrentGreatest);
Console.WriteLine(" Count: " + avlTree.Count);
avlTree.Clear(); // Clears the AVL tree
Console.WriteLine();
}
#endregion
#region Red-Black Tree
{
Console.WriteLine(" Red-Black Tree------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" An Red-Black Tree is a sorted binary tree.");
Console.WriteLine(" It implements Towel.DataStructures.DataStructure like the others.");
Console.WriteLine(" It allows for very fast 1D ranged queries/traversals.");
Console.WriteLine(" It is very similar to an AVL tree, but uses a different sorting algorithm.");
Console.WriteLine();
IRedBlackTree <int> redBlackTree = new RedBlackTreeLinked <int>();
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
redBlackTree.Add(i);
}
Console.WriteLine();
Console.Write(" Traversal: ");
redBlackTree.Stepper(i => Console.Write(i));
Console.WriteLine();
int minimum = random.Next(1, test / 2);
int maximum = random.Next(1, test / 2) + test / 2;
Console.Write(" Ranged Traversal [" + minimum + "-" + maximum + "]: ");
redBlackTree.Stepper(i => Console.Write(i), minimum, maximum);
Console.WriteLine();
int removal = random.Next(0, test);
Console.Write(" Remove(" + removal + "): ");
redBlackTree.Remove(removal);
redBlackTree.Stepper(i => Console.Write(i));
Console.WriteLine();
int contains = random.Next(0, test);
Console.WriteLine(" Contains(" + contains + "): " + redBlackTree.Contains(contains));
Console.WriteLine(" Current Least: " + redBlackTree.CurrentLeast);
Console.WriteLine(" Current Greatest: " + redBlackTree.CurrentGreatest);
Console.WriteLine(" Count: " + redBlackTree.Count);
redBlackTree.Clear(); // Clears the Red Black tree
Console.WriteLine();
}
#endregion
#region BTree
{
Console.WriteLine(" B Tree------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A B Tree is a sorted binary tree that allows multiple values to");
Console.WriteLine(" be stored per node. This makes it sort of a hybrid between a");
Console.WriteLine(" binary tree and an array. Because multiple values are stored ");
Console.WriteLine(" per node, it means less nodes must be traversed to completely");
Console.WriteLine(" traverse the values in the B tree.");
Console.WriteLine();
Console.WriteLine(" The generic B Tree in Towel is still in development.");
Console.WriteLine();
}
#endregion
#region Set
{
Console.WriteLine(" Set------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A Set is like an List, but it does not allow duplicates. Sets are");
Console.WriteLine(" usually implemented using hash codes. Implementations with hash codes");
Console.WriteLine(" usually have very fast \"Contains\" checks to see if a value has already");
Console.WriteLine(" been added to the set.");
Console.WriteLine();
ISet <int> setHashLinked = new SetHashLinked <int>();
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
setHashLinked.Add(i);
}
Console.WriteLine();
Console.Write(" Traversal: ");
setHashLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
int a = random.Next(0, test);
setHashLinked.Remove(a);
Console.Write(" Remove(" + a + "): ");
setHashLinked.Stepper(i => Console.Write(i));
Console.WriteLine();
int b = random.Next(0, test);
Console.WriteLine(" Contains(" + b + "): " + setHashLinked.Contains(b));
Console.WriteLine(" Count: " + setHashLinked.Count);
Console.WriteLine();
}
#endregion
#region Map (aka Dictionary)
{
Console.WriteLine(" Map------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A Map (aka Dictionary) is similar to a Set, but it stores two values (a ");
Console.WriteLine(" key and a value). Maps do not allow duplicate keys much like Sets don't");
Console.WriteLine(" allow duplicate values. When provided with the key, the Map uses that key");
Console.WriteLine(" to look up the value that it is associated with. Thus, it allows you to ");
Console.WriteLine(" \"map\" one object to another. As with Sets, Maps are usually implemented");
Console.WriteLine(" using hash codes.");
Console.WriteLine();
// Note: the first generic is the value, the second is the key
IMap <string, int> mapHashLinked = new MapHashLinked <string, int>();
Console.WriteLine(" Let's map each int to its word representation (ex 1 -> One).");
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
mapHashLinked.Add(i, ((decimal)i).ToEnglishWords());
}
Console.WriteLine();
Console.WriteLine(" Traversal: ");
mapHashLinked.Keys(i => Console.WriteLine(" " + i + "->" + mapHashLinked[i]));
Console.WriteLine();
int a = random.Next(0, test);
mapHashLinked.Remove(a);
Console.Write(" Remove(" + a + "): ");
mapHashLinked.Keys(i => Console.Write(i));
Console.WriteLine();
int b = random.Next(0, test);
Console.WriteLine(" Contains(" + b + "): " + mapHashLinked.Contains(b));
Console.WriteLine(" Count: " + mapHashLinked.Count);
Console.WriteLine();
}
#endregion
#region OmnitreePoints
{
Console.WriteLine(" OmnitreePoints--------------------------------------");
Console.WriteLine();
Console.WriteLine(" An Omnitree is an ND SPT that allows for");
Console.WriteLine(" multidimensional sorting. Any time you need to look");
Console.WriteLine(" items up based on multiple fields/properties, then");
Console.WriteLine(" you might want to use an Omnitree. If you need to");
Console.WriteLine(" perform ranged queries on multiple dimensions, then");
Console.WriteLine(" the Omnitree is the data structure for you.");
Console.WriteLine();
Console.WriteLine(" The \"OmnitreePoints\" stores individual points (vectors),");
Console.WriteLine(" and the \"OmnitreeBounds\" stores bounded objects (spaces).");
Console.WriteLine();
IOmnitreePoints <int, double, string, decimal> omnitree =
new OmnitreePointsLinked <int, double, string, decimal>(
// This is a location delegate. (how to locate the item along each dimension)
(int index, out double a, out string b, out decimal c) =>
{
a = index;
b = index.ToString();
c = index;
});
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
omnitree.Add(i);
}
Console.WriteLine();
Console.Write(" Traversal: ");
omnitree.Stepper(i => Console.Write(i));
Console.WriteLine();
int minimumXZ = random.Next(1, test / 2);
int maximumXZ = random.Next(1, test / 2) + test / 2;
string minimumY = minimumXZ.ToString();
string maximumY = maximumXZ.ToString();
Console.Write(" Spacial Traversal [" +
"(" + minimumXZ + ", \"" + minimumY + "\", " + minimumXZ + ")->" +
"(" + maximumXZ + ", \"" + maximumY + "\", " + maximumXZ + ")]: ");
omnitree.Stepper(i => Console.Write(i),
minimumXZ, maximumXZ,
minimumY, maximumY,
minimumXZ, maximumXZ);
Console.WriteLine();
// Note: this "look up" is just a very narrow spacial query that (since we know the data)
// wil only give us one result.
int lookUp = random.Next(0, test);
string lookUpToString = lookUp.ToString();
Console.Write(" Look Up (" + lookUp + ", \"" + lookUpToString + "\", " + lookUp + "): ");
omnitree.Stepper(i => Console.Write(i),
lookUp, lookUp,
lookUp.ToString(), lookUp.ToString(),
lookUp, lookUp);
Console.WriteLine();
// Ignoring dimensions on traversals example.
// If you want to ignore a column on a traversal, you can do so like this:
omnitree.Stepper(i => { /*Do Nothing*/ },
lookUp, lookUp,
Omnitree.Bound <string> .None, Omnitree.Bound <string> .None,
Omnitree.Bound <decimal> .None, Omnitree.Bound <decimal> .None);
Console.Write(" Counting Items In a Space [" +
"(" + minimumXZ + ", \"" + minimumY + "\", " + minimumXZ + ")->" +
"(" + maximumXZ + ", \"" + maximumY + "\", " + maximumXZ + ")]: ");
omnitree.CountSubSpace(
minimumXZ, maximumXZ,
minimumY, maximumY,
minimumXZ, maximumXZ);
Console.WriteLine();
int removalMinimum = random.Next(1, test / 2);
int removalMaximum = random.Next(1, test / 2) + test / 2;
string removalMinimumY = removalMinimum.ToString();
string removalMaximumY = removalMaximum.ToString();
Console.Write(" Remove (" + removalMinimum + "-" + removalMaximum + "): ");
omnitree.Remove(
removalMinimum, removalMaximum,
removalMinimumY, removalMaximumY,
removalMinimum, removalMaximum);
omnitree.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" Dimensions: " + omnitree.Dimensions);
Console.WriteLine(" Count: " + omnitree.Count);
omnitree.Clear(); // Clears the Omnitree
Console.WriteLine();
}
#endregion
#region OmnitreeBounds
{
Console.WriteLine(" OmnitreeBounds--------------------------------------");
Console.WriteLine();
Console.WriteLine(" An Omnitree is an ND SPT that allows for");
Console.WriteLine(" multidimensional sorting. Any time you need to look");
Console.WriteLine(" items up based on multiple fields/properties, then");
Console.WriteLine(" you might want to use an Omnitree. If you need to");
Console.WriteLine(" perform ranged queries on multiple dimensions, then");
Console.WriteLine(" the Omnitree is the data structure for you.");
Console.WriteLine();
Console.WriteLine(" The \"OmnitreePoints\" stores individual points (vectors),");
Console.WriteLine(" and the \"OmnitreeBounds\" stores bounded objects (spaces).");
Console.WriteLine();
IOmnitreeBounds <int, double, string, decimal> omnitree =
new OmnitreeBoundsLinked <int, double, string, decimal>(
// This is a location delegate. (how to locate the item along each dimension)
(int index,
out double min1, out double max1,
out string min2, out string max2,
out decimal min3, out decimal max3) =>
{
string indexToString = index.ToString();
min1 = index; max1 = index;
min2 = indexToString; max2 = indexToString;
min3 = index; max3 = index;
});
Console.Write(" Adding (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
omnitree.Add(i);
}
Console.WriteLine();
Console.Write(" Traversal: ");
omnitree.Stepper(i => Console.Write(i));
Console.WriteLine();
int minimumXZ = random.Next(1, test / 2);
int maximumXZ = random.Next(1, test / 2) + test / 2;
string minimumY = minimumXZ.ToString();
string maximumY = maximumXZ.ToString();
Console.Write(" Spacial Traversal [" +
"(" + minimumXZ + ", \"" + minimumY + "\", " + minimumXZ + ")->" +
"(" + maximumXZ + ", \"" + maximumY + "\", " + maximumXZ + ")]: ");
omnitree.StepperOverlapped(i => Console.Write(i),
minimumXZ, maximumXZ,
minimumY, maximumY,
minimumXZ, maximumXZ);
Console.WriteLine();
// Note: this "look up" is just a very narrow spacial query that (since we know the data)
// wil only give us one result.
int lookUpXZ = random.Next(0, test);
string lookUpY = lookUpXZ.ToString();
Console.Write(" Look Up (" + lookUpXZ + ", \"" + lookUpY + "\", " + lookUpXZ + "): ");
omnitree.StepperOverlapped(i => Console.Write(i),
lookUpXZ, lookUpXZ,
lookUpY, lookUpY,
lookUpXZ, lookUpXZ);
Console.WriteLine();
// Ignoring dimensions on traversals example.
// If you want to ignore a dimension on a traversal, you can do so like this:
omnitree.StepperOverlapped(i => { /*Do Nothing*/ },
lookUpXZ, lookUpXZ,
// The "None" means there is no bound, so all values are valid
Omnitree.Bound <string> .None, Omnitree.Bound <string> .None,
Omnitree.Bound <decimal> .None, Omnitree.Bound <decimal> .None);
Console.Write(" Counting Items In a Space [" +
"(" + minimumXZ + ", \"" + minimumY + "\", " + minimumXZ + ")->" +
"(" + maximumXZ + ", \"" + maximumY + "\", " + maximumXZ + ")]: " +
omnitree.CountSubSpaceOverlapped(
minimumXZ, maximumXZ,
minimumY, maximumY,
minimumXZ, maximumXZ));
Console.WriteLine();
int removalMinimumXZ = random.Next(1, test / 2);
int removalMaximumXZ = random.Next(1, test / 2) + test / 2;
string removalMinimumY = removalMinimumXZ.ToString();
string removalMaximumY = removalMaximumXZ.ToString();
Console.Write(" Remove (" + removalMinimumXZ + "-" + removalMaximumXZ + "): ");
omnitree.RemoveOverlapped(
removalMinimumXZ, removalMaximumXZ,
removalMinimumY, removalMaximumY,
removalMinimumXZ, removalMaximumXZ);
omnitree.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" Dimensions: " + omnitree.Dimensions);
Console.WriteLine(" Count: " + omnitree.Count);
omnitree.Clear(); // Clears the Omnitree
Console.WriteLine();
}
#endregion
#region KD Tree
{
Console.WriteLine(" KD Tree------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A KD Tree binary tree that stores points sorted along along an");
Console.WriteLine(" arbitrary number of dimensions. So it performs multidimensional");
Console.WriteLine(" sorting similar to the Omnitree (Quadtree/Octree) in Towel, but");
Console.WriteLine(" it uses a completely different algorithm and format.");
Console.WriteLine();
Console.WriteLine(" The generic KD Tree in Towel is still in development.");
Console.WriteLine();
}
#endregion
#region Graph
{
Console.WriteLine(" Graph------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A Graph is a data structure of nodes and edges. Nodes are values");
Console.WriteLine(" and edges are connections between those values. Graphs are often");
Console.WriteLine(" used to model real world data such as maps, and are often used in");
Console.WriteLine(" path finding algoritms. See the \"Algorithms\" example for path");
Console.WriteLine(" finding examples. This is just an example of how to make a graph.");
Console.WriteLine(" A \"GraphSetOmnitree\" is an implementation where nodes are stored.");
Console.WriteLine(" in a Set and edges are stored in an Omnitree (aka Quadtree).");
Console.WriteLine();
IGraph <int> graphSetOmnitree = new GraphSetOmnitree <int>();
Console.WriteLine(" Adding Nodes (0-" + (test - 1) + ")...");
for (int i = 0; i < test; i++)
{
graphSetOmnitree.Add(i);
}
int edgesPerNode = 3;
Console.WriteLine(" Adding Random Edges (0-3 per node)...");
for (int i = 0; i < test; i++)
{
// lets use a heap to randomize the edges using random priorities
IHeap <(int, int)> heap = new HeapArray <(int, int)>((x, y) => Compare.Wrap(x.Item2.CompareTo(y.Item2)));
for (int j = 0; j < test; j++)
{
if (j != i)
{
heap.Enqueue((j, random.Next()));
}
}
// dequeue some random edges from the heap and add them to the graph
int randomEdgeCount = random.Next(edgesPerNode + 1);
for (int j = 0; j < randomEdgeCount; j++)
{
graphSetOmnitree.Add(i, heap.Dequeue().Item1);
}
}
Console.Write(" Nodes (Traversal): ");
graphSetOmnitree.Stepper(i => Console.Write(i));
Console.WriteLine();
Console.WriteLine(" Edges (Traversal): ");
graphSetOmnitree.Stepper((from, to) => Console.WriteLine(" " + from + "->" + to));
Console.WriteLine();
int a = random.Next(0, test);
Console.Write(" Neighbors (" + a + "):");
graphSetOmnitree.Neighbors(a, i => Console.Write(" " + i));
Console.WriteLine();
int b = random.Next(0, test / 2);
int c = random.Next(test / 2, test);
Console.WriteLine(" Are Adjacent (" + b + ", " + c + "): " + graphSetOmnitree.Adjacent(b, c));
Console.WriteLine(" Node Count: " + graphSetOmnitree.NodeCount);
Console.WriteLine(" Edge Count: " + graphSetOmnitree.EdgeCount);
graphSetOmnitree.Clear(); // Clears the graph
Console.WriteLine();
}
#endregion
#region Trie
{
Console.WriteLine(" Trie------------------------------------------------");
Console.WriteLine();
Console.WriteLine(" A Trie is a tree where portions of the data are stored in each node");
Console.WriteLine(" such that when you traverse the tree to a leaf, you have read the contents");
Console.WriteLine(" of that leaf along the way. Because of this, a Trie allows for its values");
Console.WriteLine(" to share data, which is a form of compression. So a Trie may be used to save");
Console.WriteLine(" memory. A trie may also be a very useful tool in pattern matching, because");
Console.WriteLine(" it allows for culling based are portions of the data.");
Console.WriteLine();
Console.WriteLine(" The generic Trie in Towel is still in development.");
Console.WriteLine();
}
#endregion
Console.WriteLine("============================================");
Console.WriteLine("Examples Complete...");
Console.ReadLine();
}
private static void CopyMeshes(StaticMesh mesh, ListLinked<StaticMesh, string> meshes)
{
mesh.Texture.ExistingReferences++;
mesh.StaticMeshInstance.ExistingReferences++;
meshes.Add(new StaticMesh(mesh.Id, mesh.Texture, mesh.StaticMeshInstance));
}
