I'm looking for information on how to implement binary heaps efficiently. I feel like there should be a nice article somewhere about implementing heaps efficiently, but I haven't found one. In fact I've been unable to find any resources on the matter of *efficient* implementation beyond the basics like storing the heap in an array. I'm looking for techniques for making a fast binary heap beyond the ones I describe below.

I've already written a C++ implementation that is faster than Microsoft Visual C++'s and GCC's std::priority_queue or using std::make_heap, std::push_heap and std::pop_heap. The following are the techniques I've already got covered in my implementation. I only came up with the last 2 myself, though I doubt that those are new ideas:

(Edit: added section on memory optimization)

**Start indexes at 1**

Look at the Wikipedia implementation notes for binary heaps. If the heap's root is placed at index 0, then the formulas for parent, left-child and right-child of the node at index n are respectively (n-1)/2, 2n+1 and 2n+2. If you use a 1-based array then the formulas become the simpler n/2, 2n and 2n + 1. So parent and left-child are more efficient when using a 1-based array. If p points to a 0-based array and q = p - 1 then we can access p[0] as q[1] so there is no overhead in using a 1-based array.

**Make pop/removal move element to bottom of heap before replacement with leaf**

Pop on a heap is frequently described by replacing the top element by the left-most bottom leaf and then moving it down until the heap property is restored. This requires 2 comparisons per level that we go by, and we are likely to go far down the heap since we moved a leaf to the top of the heap. So we should expect a little less than 2 log n comparisons.

Instead, we can leave a hole in the heap where the top element was. Then we move that hole down the heap by iteratively moving the larger child up. This requires only 1 comparison per level that we go past. In this way the hole will become a leaf. At this point we can move the right-most bottom leaf into the position of the hole and move that value up until the heap property is restored. Since the value we moved was a leaf we don't expect it to move very far up the tree. So we should expect a little more than log n comparisons, which is better than before.

**Support replace-top**

Suppose you want to remove the max element and also insert a new element. Then you can do either of the removal/pop implementations described above, but instead of moving the right-most bottom leaf, you use the new value you wish to insert/push. (When most operations are of this kind I've found that a tournament tree is better than a heap, but otherwise the heap is slightly better.)

**Make sizeof(T) a power of 2**

The parent, left-child and right-child formulas work on indexes and they cannot be made to work directly on pointer values. So we are going to be working with indexes and that implies looking up values p[i] in an array p from an index i. If p is a T* and i is an integer, then

```
&(p[i]) == static_cast<char*>(p) + sizeof(T) * i
```

and the compiler has to perform this computation to get p[i]. sizeof(T) is a compile-time constant, and the multiplication can be done more efficiently if sizeof(T) is a power of two. My implementation got faster by adding 8 padding bytes to increase sizeof(T) from 24 to 32. Reduced efficiency of the cache probably means that this is not a win for sufficiently large data sets.

**Pre-multiply indexes**

This was a 23% performance increase on my data set. The only thing we ever do with an index other than finding parent, left-child and right-child is to look the index up in an array. So if we keep track of j = sizeof(T) * i instead of an index i, then we could do a lookup p[i] without the multiplication that is otherwise implicit in evaluating p[i] because

```
&(p[i]) == static_cast<char*>(p) + sizeof(T) * i == static_cast<char*>(p) + j
```

Then the left-child and right-child formulas for j-values become respectively 2*j and 2*j + sizeof(T). The parent formula is a little more tricky, and I haven't found a way to do it other than converting the j-value to an i-value and back like so:

```
parentOnJ(j) = parent(j/sizeof(T))*sizeof(T) == (j/(2*sizeof(T))*sizeof(T)
```

If sizeof(T) is a power of 2 then this will compile to 2 shifts. That is 1 operation more than the usual parent using indexes i. However we then save 1 operation on lookup. So the net effect is that finding the parent takes the same amount of time this way, while lookup of left-child and right-child becomes faster.

**Memory optimization**

The answers of TokenMacGuy and templatetypedef point out memory based optimizations that reduce cache misses. For very large data sets or infrequently used priority queues, parts of the queue can be swapped out to disk by the OS. In that case it is worth it to add a lot of overhead to make optimal use of the cache because swapping in from disk is very slow. My data easily fits in memory and is in continuous use, so no part of the queue will likely be swapped to disk. I suspect that this is the case for most uses of priority queues.

There are other priority queues that are designed to make better use of the CPU cache. For example a 4-heap should have fewer cache misses and the amount of extra overhead is not that much. LaMarca and Ladner report in 1996 that they get 75% performance improvement from going to aligned 4-heaps. However, Hendriks reports in 2010 that:

The improvements to the implicit heap suggested by LaMarca and Ladner [17] to improve data locality and reduce cache misses were also tested. We implemented a four-way heap, that indeed shows a slightly better consistency than the two-way heap for very skewed input data, but only for very large queue sizes. Very large queue sizes are better handled by the hierarchical heap.

**Question**

Are there more techniques than these?

`a[-1]`

for an array`a`

. It may work on your compiler -- heck, it may work on all compilers, more or less -- but it is technically not allowed. Just FYI. – Nemo Jun 30 '11 at 20:45