# Time complexity for generating binary heap from unsorted array

Can any one explain why the time complexity for generating a binary heap from a unsorted array using bottom-up heap construction is O(n) ?

(Solution found so far: I found in Thomas and Goodrich book that the total sum of sizes of paths for internal nodes while constructing the heap is 2n-1, but still don't understand their explanation)

Thanks.

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See blog.mischel.com/2013/09/30/a-simple-heap-of-integers for an explanation and a simple example. –  Jim Mischel May 15 at 18:19

Normal BUILD-HEAP Procedure for generating a binary heap from an unsorted array is implemented as below :

``````BUILD-HEAP(A)
heap-size[A] ← length[A]
for i ← length[A]/2 downto 1
do HEAPIFY(A, i)
``````

Here HEAPIFY Procedure takes O(h) time, where h is the height of the tree, and there are O(n) such calls making the running time O(n h). Considering h=lg n, we can say that BUILD-HEAP Procedure takes O(n lg n) time.

For tighter analysis, we can observe that heights of most nodes are small. Actually, at any height h, there can be at most CEIL(n/ (2^h +1)) nodes, which we can easily prove by induction. So, the running time of BUILD-HEAP can be written as,

``````lg n                     lg n
∑ n/(2^h+1)*O(h)  = O(n* ∑ O(h/2^h))
h=0                      h=0
``````

Now,

``````∞
∑ k*x^k = X/(1-x)^2
k=0
∞
Putting x=1/2, ∑h/2^h = (1/2) / (1-1/2)^2 = 2
h=0
``````

Hence, running time becomes,

``````lg n                     ∞
O(n* ∑ O(h/2^h))  = O(n* ∑ O(h/2^h))  = O(n)
h=0                      h=0
``````

So, this gives a running time of O(n).

N.B. The analysis is taken from this.

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Check out wikipedia:

Building a heap: A heap could be built by successive insertions. This approach requires O(n log n) time because each insertion takes O(log n) time and there are n elements. However this is not the optimal method. The optimal method starts by arbitrarily putting the elements on a binary tree, respecting the shape property. Then starting from the lowest level and moving upwards, shift the root of each subtree downward as in the deletion algorithm until the heap property is restored.

http://en.wikipedia.org/wiki/Binary_heap

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If you have the number in the array already, all you have to do is start from end, compare each value with parent location and if the parent is higher, then swap (for min heap).

If you are storing binary heap such that location ith parent is located at (i-1)/2 :

``````def heapify(x):
for i in range( len(x)-1, 0, -1):
if x[i]< x[ (i-1)/2)]:
swap(x, i, (i-1)/2) )
return x
``````
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This doesn't work. Suppose, in the very first step, you swap the smallest element and the second smallest element. The smallest element will eventually end up in the right place, but the second smallest element will not. –  Chris Okasaki May 18 '12 at 20:22