# Real world applications of Binary heaps and Fibonacci Heaps

What are the real world applications of Fibonacci heaps and binary heaps? It'd be great if you could share some instance when you used it to solve a problem.

EDITED: Added binary heaps also. Curious to know.

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Wow, you live and learn. I didn't even know Fib.. heaps existed. Cool stuff. – PurplePilot Sep 23 '10 at 12:09
"Real world use" seems to be asking the wrong question, similar to "what are real world uses of arrays?" – Roger Pate Oct 6 '10 at 2:12
Everyone knows the real world use of arrays! – devnull Oct 6 '10 at 3:02
Contrast how many time have to used Fibonacci heaps to the number of times you have used arrays in your entire programming life. – devnull Oct 6 '10 at 3:03
Related: Has anyone actually implemented a Fibonacci heap efficiently?. Executive summary: Binary heaps outperform Fibonacci in most real-world applications, unless the underlying graph is very dense. This is basically because a binary heap can be efficiently implemented using an array, but a Fibonacci heap is implemented as a system of pointers. – ire_and_curses Oct 8 '10 at 19:51

You would rarely use one in real life. I believe the purpose of the Fibonacci heap was to improve the asymptotic running time of Dijkstra's algorithm. It might give you an improvement for very, very large inputs, but most of the time, a simple binary heap is all you need.

From Wiki:

Although the total running time of a sequence of operations starting with an empty structure is bounded by the bounds given above, some (very few) operations in the sequence can take very long to complete (in particular delete and delete minimum have linear running time in the worst case). For this reason Fibonacci heaps and other amortized data structures may not be appropriate for real-time systems.

The binary heap is a data structure that can be used to quickly find the maximum (or minimum) value in a set of values. It's used in Dijkstra's algorithm (shortest path), Prim's algorithm (minimum spanning tree) and Huffman encoding (data compression).

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Note: Fibonacci improves the amortized time, not worst case. And the binary heap also has O(1) average. – Ciro Santilli 巴拿馬文件 六四事件 法轮功 Jun 20 '15 at 6:07

Can't say about the fibonacci heaps but binary heaps are used in the priority queues. Priority queues are widely used in the real systems. One known example is process scheduling in the kernel. The highest priority process is taken first. I have used the priority queues in the partitioning of the sets. The set which has the maximum members was to be taken first for the partitioning.

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Computing the top N elements from a huge data-set can be done efficiently using binary heaps (e.g. top search queries in a large-scale website).

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In most scenarios, you have to choose based on the complexity of:

• insertion
• finding elements

And the usual suspects are:

• BST: `log(n)` insert and find
• linked list: `O(1)` insert and `O(n)` find
• heap:
• `O(1)` insert
• `O(1)` find for the first element only, `O(n)` in general
• worst case for the binary heap
• amortized for Fibonacci

There is also the Brodal queue and other heaps which reach `O(1)` worst case, but requires even larger queues than Fibonacci to be worth it.

So if your algorithm only needs to "find" the first element and do lots of insertions, heaps are a good choice.

As others mentioned, this is the case for Dijkstra.

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