Fibonacci, Binary, or Binomial heap in c#? [closed]

Are there any heap data structure implementations out there, fibonacci, binary, or binomial?

Reference: These are data structures used to implement priority queues, not the ones used to allocate dynamic memory. See http://en.wikipedia.org/wiki/Heap_(data_structure)

Thanks, Dave

• stackoverflow.com/a/13776636/67824 Commented Dec 8, 2012 at 13:06
• Commented Nov 5, 2015 at 16:52
• You may be interested in this NuGet package, which implements a priority queue based on a binary heap. Commented Jul 29, 2016 at 11:25
• Off Topic: Some questions are still off-topic, … 4. Questions asking us to recommend or find a book, tool, software library, tutorial or other off-site resource - that reduces on-topic answers to `yes`. Commented May 5, 2017 at 5:30

Free C# implementation of heaps and many other data structures:

QuickGraph implements Fibonacci Heaps and Queues in C#, among a whole lot of other stuff. It is free and open-source.

• Documentation for QuickGraph is difficult to parse if you're just looking for a fib heap. Source code also isn't very clear. :( Commented May 21, 2015 at 17:02

Stand alone stress tested implementations are in Github under Advanced-Algorithms repository. DecrementKey operation performance is what makes later two significant.

• Binary Min/Max Heap
• Binomial Min/Max Heap
• Fibonacci Min/Max Heap

The repository has two more heap implementations, D-Ary Heap & Pairing Heap.

I believe that a `SortedSet<KeyValuePair<K,V>>` with a custom `Comparer` will do the job.

The `Comparer` will look like the following:

``````class KeyValueComparer<K, V> : IComparer<KeyValuePair<K,V>> where K:IComparable where V:IComparable
{
public int Compare(KeyValuePair<K, V> x, KeyValuePair<K, V> y)
{
var res = x.Key.CompareTo(y.Key);
return res == 0 ? x.Value.CompareTo(y.Value) : res;
}
}
``````

With such `Comparer`, the `SortedSet` will be sorted by Key and it will allow duplicates of keys.

You can get the `Min` at constant time, `RemoveMin` at `O(logn)`, `Add` an entry at `O(logn)` and `Update` a key at `O(logn)`.

Here is a full (or almost) implementation:

``````public class Heap<K, V>
where K : IComparable
where V : IComparable
{

// O(1)
public KeyValuePair<K, V> Min
{
get { return _sortedSet.Min; }
}

public Heap()
{
_sortedSet = new SortedSet<KeyValuePair<K, V>>(new KeyValueComparer<K, V>());
}

// O(logn)
public void Add(K key, V value)
{
}

// O(logn)
public KeyValuePair<K, V> RemoveMin()
{
var min = Min;
_sortedSet.Remove(min);
return min;
}

// O(logn)
public void Remove(K key, V value)
{
_sortedSet.Remove(new KeyValuePair<K, V>(key, value));
}

// O(logn)
public void UpdateKey(K oldKey, V oldValue, K newKey)
{
Remove(oldKey, oldValue);
}

private class KeyValueComparer<K, V> : IComparer<KeyValuePair<K, V>>
where K : IComparable
where V : IComparable
{
public int Compare(KeyValuePair<K, V> x, KeyValuePair<K, V> y)
{
var res = x.Key.CompareTo(y.Key);
return res == 0 ? x.Value.CompareTo(y.Value) : res;
}
}
}
``````

I don't know of any native framework implementation.

I found two implementations of binary heap (link 1, link 2) and one implementation of binomial heap in f# (link).

Implementation of MinHeap and MaxHeap:

``````public abstract class Heap<T>
{
private List<T> m_Vector;

private void Swap(int i, int j)
{
var tmp = m_Vector[i];
m_Vector[i] = m_Vector[j];
m_Vector[j] = tmp;
}

protected abstract int Compare(T a, T b);

private void SiftUp(int i)
{
if (i == 0)
{
return;
}

int parent = (i - 1) / 2;

if (Compare(m_Vector[i], m_Vector[parent]) >= 0)
{
return;
}

Swap(i, parent);
SiftUp(parent);
}

private void SiftDown(int i)
{
int left = i * 2 + 1;

if (left >= m_Vector.Count)
{
return;
}

var right = left + 1;

var child = left;

if (right < m_Vector.Count)
{
if (Compare(m_Vector[left], m_Vector[right]) > 0)
{
child = right;
}
}

if (Compare(m_Vector[i], m_Vector[child]) <= 0)
{
return;
}

Swap(i, child);
SiftDown(child);
}

public Heap()
{
m_Vector = new List<T>();
}

public Heap(IEnumerable<T> elements)
{
m_Vector = new List<T>(elements);

if (m_Vector.Count < 2)
{
return;
}

//
// From the last parent, upwards, sift down. Each sift is O<1>.
//
for (int i = (m_Vector.Count - 2) / 2; i >= 0; i--)
{
SiftDown(i);
}
}

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

{
SiftUp(m_Vector.Count - 1);
}

public T Top
{
get
{
if (m_Vector.Count == 0)
{
throw new InvalidOperationException();
}
return m_Vector[0];
}
}

public T Fetch()
{
if (m_Vector.Count == 0)
{
throw new InvalidOperationException();
}

T result = m_Vector[0];
m_Vector[0] = m_Vector[m_Vector.Count - 1];
m_Vector.RemoveAt(m_Vector.Count - 1);

SiftDown(0);

return result;
}
}

public class MinHeap<T> : Heap<T> where T: IComparable
{
protected override int Compare(T a, T b)
{
return a.CompareTo(b);
}

public MinHeap() : base()
{
}

public MinHeap(IEnumerable<T> elements) : base(elements)
{
}
}

public class MaxHeap<T> : Heap<T> where T : IComparable
{
protected override int Compare(T a, T b)
{
return b.CompareTo(a);
}

public MaxHeap() : base()
{
}

public MaxHeap(IEnumerable<T> elements) : base(elements)
{
}
}
``````

A Simple Min Heap Implementation.

``````using System;
using System.Collections.Generic;
using System.Linq;

{
public class MinHeap
{
private static int capacity = 10;
private int size = 0;

int[] items = new int[capacity];

private int getLeftChildIndex(int parentIndex) { return 2*parentIndex+1 ; }
private int getRightChildIndex(int parentIndex) { return 2*parentIndex+2 ; }
private int getParentIndex(int childIndex) { return (childIndex - 1) / 2; }

private bool hasLeftChild(int index) { return getLeftChildIndex(index) < size; }
private bool hasRightChild(int index) { return getRightChildIndex(index) < this.size; }
private bool hasParent(int index) { return getParentIndex(index) >= 0; }

private int leftChild(int index) { return this.items[getLeftChildIndex(index)]; }
private int rightChild(int index) { return this.items[getRightChildIndex(index)]; }
private int parent(int index) { return this.items[this.getParentIndex(index)]; }

private void swap(int indexOne, int indexTwo)
{
int temp = this.items[indexOne];
this.items[indexOne] = this.items[indexTwo];
this.items[indexTwo] = temp;
}

private void ensureExtraCapacity()
{
if (this.size == capacity)
{
Array.Resize(ref this.items, capacity*2);
capacity *= 2;
}
}

public int peek()
{
if(this.size==0) throw new NotSupportedException();
return this.items[0];
}

public int remove()
{
if(this.size==0) throw new NotSupportedException();
int item = this.items[0];
items[0] = items[this.size - 1];
items[this.size - 1] = 0;
this.size--;
heapifyDown();
return item;
}

{
this.ensureExtraCapacity();
this.items[size] = item;
this.size++;
heapifyUp();
}

private void heapifyUp()
{
int index = this.size - 1;
while (hasParent(index) && parent(index) > this.items[index])
{
swap(index,getParentIndex(index));
index = getParentIndex(index);
}
}

private void heapifyDown()
{
int index = 0;
while (hasLeftChild(index))
{
int smallerChildIndex = getLeftChildIndex(index);
if (hasRightChild(index) && rightChild(index) < leftChild(index))
{
smallerChildIndex = getRightChildIndex(index);
}

if (this.items[index] < this.items[smallerChildIndex])
{
break;
}
else
{
swap(index,smallerChildIndex);
}
index = smallerChildIndex;
}
}
}
}

/*
Calling Code:
MinHeap mh = new MinHeap();