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Divide and conquer search strategy
We have learned that search algorithms fall into two main categories.
- Brute-force search: It is implemented by traversing the data structure, with a time complexity of
O(n)
. - Adaptive search: It utilizes a unique data organization form or prior information, and its time complexity can reach
O(\log n)
or evenO(1)
.
In fact, search algorithms with a time complexity of O(\log n)
are usually based on the divide-and-conquer strategy, such as binary search and trees.
- Each step of binary search divides the problem (searching for a target element in an array) into a smaller problem (searching for the target element in half of the array), continuing until the array is empty or the target element is found.
- Trees represent the divide-and-conquer idea, where in data structures like binary search trees, AVL trees, and heaps, the time complexity of various operations is
O(\log n)
.
The divide-and-conquer strategy of binary search is as follows.
- The problem can be divided: Binary search recursively divides the original problem (searching in an array) into subproblems (searching in half of the array), achieved by comparing the middle element with the target element.
- Subproblems are independent: In binary search, each round handles one subproblem, unaffected by other subproblems.
- The solutions of subproblems do not need to be merged: Binary search aims to find a specific element, so there is no need to merge the solutions of subproblems. When a subproblem is solved, the original problem is also solved.
Divide-and-conquer can enhance search efficiency because brute-force search can only eliminate one option per round, whereas divide-and-conquer can eliminate half of the options.
Implementing binary search based on divide-and-conquer
In previous chapters, binary search was implemented based on iteration. Now, we implement it based on divide-and-conquer (recursion).
!!! question
Given an ordered array `nums` of length $n$, where all elements are unique, please find the element `target`.
From a divide-and-conquer perspective, we denote the subproblem corresponding to the search interval [i, j]
as f(i, j)
.
Starting from the original problem f(0, n-1)
, perform the binary search through the following steps.
- Calculate the midpoint
m
of the search interval[i, j]
, and use it to eliminate half of the search interval. - Recursively solve the subproblem reduced by half in size, which could be
f(i, m-1)
orf(m+1, j)
. - Repeat steps
1.
and2.
, untiltarget
is found or the interval is empty and returns.
The figure below shows the divide-and-conquer process of binary search for element 6
in an array.
In the implementation code, we declare a recursive function dfs()
to solve the problem f(i, j)
:
[file]{binary_search_recur}-[class]{}-[func]{binary_search}