## Hot answers tagged heapsort

68

Right, so basically you take a heap and pull out the first node in the heap - as the first node is guaranteed to be the largest / smallest depending on the direction of sort. The tricky thing is re-balancing / creating the heap in the first place.
Two steps were required for me to understand the heap process - first of all thinking of this as a tree, ...

57

A stable sort maintains the relative order of items that have the same key. For example, imagine your data set contains records with an employee id and a name. The initial order is:
1, Jim
2, George
3, Jim
4, Sally
5, George
You want to sort by name. A stable sort will arrange the items in this order:
2, George
5, George
1, Jim
3, Jim
4, Sally
Note ...

29

There are a number of Haskell heap implementations in an appendix to Okasaki's Purely Functional Data Structures. (The source code can be downloaded at the link. The book itself is well worth reading.) None of them are binary heaps, per se, but the "leftist" heap is very similar. It has O(log n) insertion, removal, and merge operations. There are also more ...

28

One of the major factors is that quicksort has better locality of reference -- the next thing to be accessed is usually close in memory to the thing you just looked at. By contrast, heapsort jumps around significantly more. Since things that are close together will likely be cached together, quicksort tends to be faster.
However, quicksort's worst-case ...

26

One way to think of heap sort is as a cleverly optimized version of selection sort. In selection sort, the sort works by repeatedly finding the largest element not yet placed correctly, then putting it into the next correct spot in the array. However, selection sort runs in time O(n2) because it has to do n rounds of finding the largest element out of a ...

22

http://www.cs.auckland.ac.nz/~jmor159/PLDS210/qsort3.html has some analysis.
Also, from Wikipedia:
The most direct competitor of
quicksort is heapsort. Heapsort is
typically somewhat slower than
quicksort, but the worst-case running
time is always Θ(nlogn). Quicksort is
usually faster, though there remains
the chance of worst case ...

15

So I did a bit of digging myself and it looks like this result actually is fairly recent! The first lower-bound proof I can find is from 1992, though heapsort itself was invented in 1964.
The formal lower-bound proof is due to Schaffer and Sedgewick's "The Analysis of Heapsort" paper. Here's a slightly paraphrased version of the proof that omits some of ...

12

Jerry's right, if it's just Ctrl-C you're worried about, you can ignore SIGINT for periods at a time. If you want to be proof against process death in general, you need some sort of minimal journalling. In order to swap two elements:
1) Add a record to a control structure at the end of the file or in a separate file, indicating which two elements of the ...

12

the 3rd column is larger than the second for the array sizes considered.
The "Big O" notation only tells you how the time grows with the input size.
Your times are (or should be)
A + B*N^2 for the quadratic case,
C + D*N*LOG(N) for the linearithmic case.
But it is entirely possible that C is much larger than A, leading to a higher ...

11

The final sequence of the results from heapsort comes from removing items from the created heap in purely size order (based on the key field).
Any information about the ordering of the items in the original sequence was lost during the heap creation stage, which came first.

10

Stable means if the two elements have the same key, they remain in the same order or positions. But that is not the case for Heap sort.
Heapsort is not stable because operations on the heap can change the relative order of equal items.
From here:
When sorting (in ascending order) heapsort first peaks the largest
element and put it in the last of the ...

10

How do I get the maximum value? You don't need to "get" it. The root is exactly the maximum, that's a defined property of a heap.
If you feel tough to understand heap sort, this chapter will be extremely helpful.
I rewrote your code:
def swap(i, j):
sqc[i], sqc[j] = sqc[j], sqc[i]
def heapify(end,i):
l=2 * i + 1
...

9

The heap elements can be stored starting with index 0 or index 1, the decision on which to use is up to you.
If the root element is at index 1, the mathematical relations between parent and child indices are simple as you've shown above, and for that reason many books choose to teach it that way.
If the root is at index 0, you'd get these relations ...

8

Jon Fairbairn posted a functional heapsort to the Haskell Cafe mailing list back in 1997:
http://www.mail-archive.com/haskell@haskell.org/msg01788.html
I reproduce it below, reformatted to fit this space. I've also slightly simplified the code of merge_heap.
I'm surprised treefold isn't in the standard prelude since it's so useful. Translated from the ...

8

You could also use the ST monad, which allows you to write imperative code but expose a purely functional interface safely.

7

An 1-ary heap is still a heap, and satisfies all the invariants that are required by a heap sort:
The first element is the largest element.
Percolation can move the top element down to its correct position.
In practice, an 1-ary heap is a tree where every node has one child - this is also known as a singly linked list. Also, the heap constraint means the ...

7

For most situations, having quick vs. a little quicker is irrelevant... you simply never want it to occasionally get waayyy slow. Although you can tweak QuickSort to avoid the way slow situations, you lose the elegance of the basic QuickSort. So, for most things, I actually prefer HeapSort... you can implement it in its full simple elegance, and never get ...

7

The line
heapify(&n, largest, size);
should be
heapify(f, largest, size);
^

7

Heapsort is O(N log N) guaranted, what is much better than worst case in Quicksort. Heapsort don't need more memory for another array to putting ordered data as is needed by Mergesort. So why do comercial applications stick with Quicksort? What Quicksort has that is so special over others implementations?
I've tested the algorithms myself and I've seen that ...

6

Heap sort unstable example
Consider array 21 20a 20b 12 11 8 7 (already in max-heap format)
here 20a = 20b just to differentiate the order we represent them as 20a and 20b
While heapsort first 21 is removed and placed in the last index then 20a is removed and placed in last but one index and 20b in the last but two index so after heap sort the array ...

6

The second largest element of the heap is present in the second or third position, but the third largest can be present further down, at depth 2. (See the figure in http://en.wikipedia.org/wiki/Heap_(data_structure) ). Furthermore, after swapping the first three elements with the last three, the heapify method would first heapify the first subtree of the ...

6

The answer is "you don't want to implement heap sort on a linked list."
Heapsort is a good sorting algorithm because it's O(n log n) and it's in-place. However, when you have a linked list heapsort is no longer O(n log n) because it relies on random access to the array, which you do not have in a linked list. So you either lose your in-place attribute ...

6

The Soft Heap suffers from "corruption" (read the page you link to), which makes it inapplicable as a component of a general-purpose sorting routine. You will simply get the wrong answer most of the time.
If you have some application that requires a sort but could deal with the "corrupted" results you would get from a Soft Heap as part of the ...

6

The only array index which is meaningful to the user is zero, which is the minimum element. So, after removing k elements, the k'th smallest element will be at zero.
Probably you should destroy the heap and return the value rather than asking the user to concern themself with the heap itself… but I don't know the details of the assignment.
Note that the ...

6

The Heap Sort has a worst case complexity of O(n log(n)). Yet empirical studies show that generally Quick Sort (and other sorting algorithms) is considerably faster than heap sort, although its worst case complexity is O(n²) : http://www.cs.auckland.ac.nz/~jmor159/PLDS210/qsort3.html
Also, from the quick sort article on Wikipedia:
The most direct ...

6

If you're looking for time measurements, use the Stopwatch class.
This allows you to easily measure some time using the Start() and Stop() method. The Elapsed property will then tell you how long the operation took.

6

As an exercise in Haskell, I implemented an imperative heapsort with the ST Monad.
{-# LANGUAGE ScopedTypeVariables #-}
import Control.Monad (forM, forM_)
import Control.Monad.ST (ST, runST)
import Data.Array.MArray (newListArray, readArray, writeArray)
import Data.Array.ST (STArray)
import Data.STRef (newSTRef, readSTRef, writeSTRef)
heapSort :: forall ...

6

Here's a couple explanations:
http://www.cs.auckland.ac.nz/software/AlgAnim/qsort3.html
http://users.aims.ac.za/~mackay/sorting/sorting.html
Essentially, even though the worst case for quick sort is O(n^2) it on average will perform better. :-)

5

The part for protecting against ctrl-c is pretty easy: signal(SIGINT, SIG_IGN);.
As far as the sorting itself goes, a merge sort generally works well for external sorting. The basic idea is to read as many records into memory as you can, sort them, then write them back out to disk. By far the easiest way to handle this is to write each run to a separate ...

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