A priority queue is an abstract data type which is like a regular queue or stack data structure, but where additionally each element has a "priority" associated with it. In a priority queue, an element with high priority is served before an element with low priority. If two elements have the same priority, they are served according to their order in the queue.


To implement Priority queue, unsorted array, sorted array and binary heap data structure are the 3 implementation strategies .

To be specific, binary heap implementation strategy can be represented using array of keys,

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each key as binary node having two children.

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Apart from priority queue implementation, Are their any other applications of using binary heap data structure?

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    See also heap sort. – Alexey Frunze Jan 4 '17 at 12:27
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    Not really. Even heapsort, it could be argued, is just populating a priority queue and then pulling things off of in order. Binary heap is a priority queue. The more important question is what are applications of priority queues and, of those, which are best implemented with a binary heap and which should use some other priority queue implementation. – Jim Mischel Jan 4 '17 at 13:49
  • 1. Please provide proper attribution for the source where you copied that from. See stackoverflow.com/help/referencing. 2. Asking for a list of all applications of binary heaps is probably too broad. 3. What research have you done? Have you looked in data structures textbooks to see what they do with a heap? – D.W. Jan 5 '17 at 0:55
  • "Not really." -- Yes, really. "Even heapsort, it could be argued, is just populating a priority queue and then pulling things off of in order. " -- Not argued validly. HeapSort sorts -- that's the application. That it internally uses a heap is a tautology. The reason HeapSort is used is not because it has a heap internally, but because of its performance characteristics. See en.wikipedia.org/wiki/Introsort – Jim Balter Jan 5 '17 at 8:54
  • @JimBalter: I think you're saying that Heapsort is a separate application because "Priority Queue Sort" wouldn't be as fast; that the heap's performance characteristics (in particular, the ability to rearrange an array in-place to build a binary heap in O(n)) makes using a binary heap superior to using just any old priority queue. Is that what you're saying? – Jim Mischel Jan 5 '17 at 17:41

A binary heap can be used to extract (max or min) element in O(logn) time. This property can be exploited to be used in many algorithms to get better run-time.

For example, once I used it in k-merge sort algorithm to increase time efficiency of sorting step of the k-merge sort. In brief, it made binary heaps of the k-subarrays, and the sorting can be achieved in linear time which is better than usual sorting step of a merge sort.

It is also used in Dijkstra's algorithm, Prim's algorithm to decrease their run time.

You can also take a look here

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    You cannot extract elements from a binary heap in constant time. delete-min is an O(log n) operation. Also, the OP asked for uses of binary heap other than to implement a priority queue. All three of your examples (merge sort, Dijkstra's algorithm, Prim's algorithm) are based on priority queues. Binary heap is just a convenient implementation. – Jim Mischel Jan 4 '17 at 13:54
  • I corrected my answer. thanks for pointing it out. I am trying to list the few usage of binary heaps. I didn't talk about the implementation. If you have any situation when you don't use a binary heap as a priority queue, then you are most welcome to leave a comment. I will be glad to learn. – CODError Jan 5 '17 at 8:27
  • "extract (max or min) element" -- this is virtually the definition of a priority queue, so you haven't answered the question, as @JimMischel pointed out. "If you have any situation when you don't use a binary heap as a priority queue" -- you have it backwards. There are several ways to implement priority queues without using heaps ... the OP mentions sorted and unsorted arrays, and there are numerous others. The question is whether binary heaps are good for anything else. See my answer for ... an actual answer. Edit: I think maybe you didn't have backwards, just poorly phrased. – Jim Balter Jan 5 '17 at 8:46
  • @JimBalter I see in your answer that you suggest heapsort as a good application of binary heap. So you think heapsort algorithm doesn't use the property of extracting min/max element from the tree? Is it not just using a binary heap as a priority queue internally? I don't really understand your point here. – CODError Jan 5 '17 at 9:35
  • @CODError "So you think heapsort algorithm doesn't use the property of extracting min/max element from the tree?" -- No, I don't think that. "I don't really understand your point here" -- I explained it in a comment under the OP's question. Extraction of min/max isn't the reason HeapSort is used ... the reason is solely its performance characteristics. Some totally different algorithm with the same performance characteristics could be used instead if someone discovered one. – Jim Balter Jan 5 '17 at 18:46

Binary heaps have one other useful (and major) application: HeapSort. HeapSort has higher overhead than QuickSort but its worst case is O(n log n) vs. QuickSort's O(n*n). QuickSort can be improved upon to obtain a worst case of O(n log n) by switching to HeapSort once the interval is sufficiently short -- this is called IntroSort, and is what is used in the STL and the C++ standard library. See https://en.wikipedia.org/wiki/Introsort

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