# Search algorithms revisited Searching algorithms (searching algorithm) are used to search for one or several elements that meet specific criteria in data structures such as arrays, linked lists, trees, or graphs. Searching algorithms can be divided into the following two categories based on their implementation approaches. - **Locating the target element by traversing the data structure**, such as traversals of arrays, linked lists, trees, and graphs, etc. - **Using the organizational structure of the data or the prior information contained in the data to achieve efficient element search**, such as binary search, hash search, and binary search tree search, etc. It is not difficult to notice that these topics have been introduced in previous chapters, so searching algorithms are not unfamiliar to us. In this section, we will revisit searching algorithms from a more systematic perspective. ## Brute-force search Brute-force search locates the target element by traversing every element of the data structure. - "Linear search" is suitable for linear data structures such as arrays and linked lists. It starts from one end of the data structure, accesses each element one by one, until the target element is found or the other end is reached without finding the target element. - "Breadth-first search" and "Depth-first search" are two traversal strategies for graphs and trees. Breadth-first search starts from the initial node and searches layer by layer, accessing nodes from near to far. Depth-first search starts from the initial node, follows a path until the end, then backtracks and tries other paths until the entire data structure is traversed. The advantage of brute-force search is its simplicity and versatility, **no need for data preprocessing and the help of additional data structures**. However, **the time complexity of this type of algorithm is $O(n)$**, where $n$ is the number of elements, so the performance is poor in cases of large data volumes. ## Adaptive search Adaptive search uses the unique properties of data (such as order) to optimize the search process, thereby locating the target element more efficiently. - "Binary search" uses the orderliness of data to achieve efficient searching, only suitable for arrays. - "Hash search" uses a hash table to establish a key-value mapping between search data and target data, thus implementing the query operation. - "Tree search" in a specific tree structure (such as a binary search tree), quickly eliminates nodes based on node value comparisons, thus locating the target element. The advantage of these algorithms is high efficiency, **with time complexities reaching $O(\log n)$ or even $O(1)$**. However, **using these algorithms often requires data preprocessing**. For example, binary search requires sorting the array in advance, and hash search and tree search both require the help of additional data structures, maintaining these structures also requires extra time and space overhead. !!! tip Adaptive search algorithms are often referred to as search algorithms, **mainly used for quickly retrieving target elements in specific data structures**. ## Choosing a search method Given a set of data of size $n$, we can use linear search, binary search, tree search, hash search, and other methods to search for the target element from it. The working principles of these methods are shown in the following figure. ![Various search strategies](searching_algorithm_revisited.assets/searching_algorithms.png) The operation efficiency and characteristics of the aforementioned methods are shown in the following table.
Table