Depth First & Breadth First Graph Search - DFS & BFS Graph Searching Algorithms

Описание к видео Depth First & Breadth First Graph Search - DFS & BFS Graph Searching Algorithms

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DFS and BFS are not just graph search algorithms. They are a fundamental method for searching relationships in a certain way and visiting nodes of any sort in a desired order.

These relationships may be represented in a graph, or we may be checking the distance one string is in character changes from another string, OR we may be traversing a tree a certain way.

These are searching concepts, not just graph concepts.


Implementation

DFS can be done iteratively using a stack or done recursively because the call stack will serve as the stack to remember points to backtrack to.

A stack structure can replace our stack frames from recursion, this is why DFS can be written recursively, due to the Last-In-First-Out (LIFO) of the order nodes are processed.

BFS is done iteratively. It uses a queue that has a First-In-First-Out processing order.


Use Cases

DFS is good for things like backtracking, getting to leaf nodes in a tree, or anything where we want to prioritize going very deep into a path and exhausting possibilities before coming back.

BFS is better for things like finding if a path exists between one node to another since it prioritizes width of search over depth (hence "breadth-first") and finding distance or "levels" something is away from something else.


The Method

1.) Choose the data structure based on the search.
2.) Add the start node.
3.) Remove the a node from the data structure.
4.) If the node has not been seen
4a.) Mark it as seen in the "seen" set.
4b.) Do work on the node.
5.) For each of the children
5a.) If child has not been seen (not bee processed)
5ai.) Add the child to the data structure.

Repeat while the data structure is not empty.


Time Complexities

If relationships are represented with an adjacency list then:

Time: O(V + E)
Space: O(V)*

Where V is the total number of vertices (or nodes) visited and E is the total numbers of edges traversed.

*Although things will vary. We only care about the MAXIMUM amount of nodes in the data structure at one time. If we are doing DFS on balanced tree the space complexity would be O(h) where h is the height of the tree since we would only have a path h nodes long at MAX living on the stack. Same for if we do a level order traversal of a tree. The space will only be the MAXIMUM WIDTH of the tree because we would only keep that many nodes on the queue at MAX at one time. And on and on...just depends, ask your interviewer whether they want worst, average, or best case analysis.

"adjacency list" means each node stores its adjacent neighbors in a list

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