In computer science, a priority search tree is a tree data structure for storing points in two dimensions. It was originally introduced by Edward M. McCreight.[1] It is effectively an extension of the priority queue with the purpose of improving the search time from O(n) to O(s + log n) time, where n is the number of points in the tree and s is the number of points returned by the search.
Description
editThe priority search tree is used to store a set of 2-dimensional points ordered by priority and by a key value. This is accomplished by creating a hybrid of a priority queue and a binary search tree.
The result is a tree where each node represents a point in the original dataset. The point contained by the node is the one with the lowest priority. In addition, each node also contains a key value used to divide the remaining points (usually the median of the keys, excluding the point of the node) into a left and right subtree. The points are divided by comparing their key values to the node key, delegating the ones with lower keys to the left subtree, and the ones strictly greater to the right subtree.[2]
Operations
editConstruction
editThe construction of the tree requires O(n log n) time and O(n) space. A construction algorithm is proposed below:
tree construct_tree(data) {
if length(data) > 1 {
node_point = find_point_with_minimum_priority(data) // Select the point with the lowest priority
reduced_data = remove_point_from_data(data, node_point)
node_key = calculate_median(reduced_data) // calculate median, excluding the selected point
// Divide the points
left_data = []
right_data = []
for (point in reduced_data) {
if point.key <= node_key
left_data.append(point)
else
right_data.append(point)
}
left_subtree = construct_tree(left_data)
right_subtree = construct_tree(right_data)
return node // Node containing the node_key, node_point and the left and right subtrees
} else if length(data) == 1 {
return leaf node // Leaf node containing the single remaining data point
} else if length(data) == 0 {
return null // This node is empty
}
}
Grounded range search
editThe priority search tree can be efficiently queried for a key in a closed interval and for a maximum priority value. That is, one can specify an interval [min_key, max_key] and another interval [-∞, max_priority] and return the points contained within it. This is illustrated in the following pseudo code:
points search_tree(tree, min_key, max_key, max_priority) {
root = get_root_node(tree)
result = []
if get_child_count(root) > 0 {
if get_point_priority(root) > max_priority
return null // Nothing interesting will exist in this branch. Return
if min_key <= get_point_key(root) <= max_key // is the root point one of interest?
result.append(get_point(node))
if min_key < get_node_key(root) // Should we search left subtree?
result.append(search_tree(root.left_sub_tree, min_key, max_key, max_priority))
if get_node_key(root) < max_key // Should we search right subtree?
result.append(search_tree(root.right_sub_tree, min_key, max_key, max_priority))
return result
else { // This is a leaf node
if get_point_priority(root) < max_priority and min_key <= get_point_key(root) <= max_key // is leaf point of interest?
result.append(get_point(node))
}
}
See also
editReferences
edit- ^ McCreight, Edward (May 1985). "Priority search trees". SIAM Journal on Scientific Computing. 14 (2): 257–276. doi:10.1137/0214021.
- ^ Lee, D.T (2005). Handbook of Data Structures and Applications. London: Chapman & Hall/CRC. pp. 18–21. ISBN 1-58488-435-5.