Write a function that implements the breadth-first search (BFS) algorithm on a directed graph (in adjacency list format), given a starting node.
BFS is an algorithm used for traversing a graph or a tree, starting from the root node and exploring all the neighbors at the current depth before moving on to nodes at the next depth level. The output from BFS is an array of the graph's nodes in the order they were traversed. Visiting neighboring nodes in any order is a valid BFS, but for this question, please visit each node's neighbors from left to right.
const graph1 = {A: ['B', 'C', 'D'],B: ['E', 'F'],C: ['G', 'H'],D: ['I', 'J'],E: ['D'],F: [],G: [],H: [],I: [],J: [],};breadthFirstSearch(graph1, 'A'); // ['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J']
breadthFirstSearch(graph1, 'B'); // ['B', 'E', 'F', 'D', 'I', 'J']
const graph2 = {A: ['B', 'C'],B: ['D', 'E'],C: ['F', 'G'],D: [],E: [],F: [],G: [],};breadthFirstSearch(graph2, 'A'); // ['A', 'B', 'C', 'D', 'E', 'F', 'G']
breadthFirstSearch(graph2, 'E'); // ['E']
A Queue
data structure is also provided for you at the bottom of the skeleton code.
Breadth-first search (BFS) is an algorithm used for traversing a graph or a tree. Here is an overview of how BFS works to traverse a graph, using the standard implementation that takes in an adjacency list (we use an array instead) and the root node:
Breadth-first search is useful for the same purposes as Depth-first search, and it is especially useful for finding the shortest path between two nodes.
Write a function that implements the breadth-first search (BFS) algorithm on a directed graph (in adjacency list format), given a starting node.
BFS is an algorithm used for traversing a graph or a tree, starting from the root node and exploring all the neighbors at the current depth before moving on to nodes at the next depth level. The output from BFS is an array of the graph's nodes in the order they were traversed. Visiting neighboring nodes in any order is a valid BFS, but for this question, please visit each node's neighbors from left to right.
const graph1 = {A: ['B', 'C', 'D'],B: ['E', 'F'],C: ['G', 'H'],D: ['I', 'J'],E: ['D'],F: [],G: [],H: [],I: [],J: [],};breadthFirstSearch(graph1, 'A'); // ['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J']
breadthFirstSearch(graph1, 'B'); // ['B', 'E', 'F', 'D', 'I', 'J']
const graph2 = {A: ['B', 'C'],B: ['D', 'E'],C: ['F', 'G'],D: [],E: [],F: [],G: [],};breadthFirstSearch(graph2, 'A'); // ['A', 'B', 'C', 'D', 'E', 'F', 'G']
breadthFirstSearch(graph2, 'E'); // ['E']
A Queue
data structure is also provided for you at the bottom of the skeleton code.
Breadth-first search (BFS) is an algorithm used for traversing a graph or a tree. Here is an overview of how BFS works to traverse a graph, using the standard implementation that takes in an adjacency list (we use an array instead) and the root node:
Breadth-first search is useful for the same purposes as Depth-first search, and it is especially useful for finding the shortest path between two nodes.
If unspecified:
The solution implements the algorithm outlined in the description.
/*** @param {Record<string, Array<string>>} graph The adjacency list representing the graph.* @param {string} source The source node to start traversal from. Has to be a valid node if graph is non-empty.* @return {Array<string>} A BFS-traversed order of nodes.*/export default function breadthFirstSearch(graph, source) {// If there are no nodes in the graph, just return an empty arrayif (Object.keys(graph).length === 0) {return [];}// Create a queue to store the nodes to be visited.// Add the root node since we're doing a level-order BFS.const queue = new Queue();queue.enqueue(source);// Initialize a set that tracks visited nodes.const visited = new Set();// While there are nodes to visit.while (!queue.isEmpty()) {// Dequeue the node at the front of the queue.const node = queue.dequeue();// Mark the node as visited.visited.add(node);// Enqueue the neighbors of the current node.graph[node].forEach((neighbor) => {// Skip nodes that have already been visited.if (visited.has(neighbor)) {return;}queue.enqueue(neighbor);});}// The visited nodes is the traversal order.return Array.from(visited);}/* Auxiliary classes *//*** A Queue class with O(1) enqueue and dequeue is provided for you.* You can use it directly should you wish to.** Example usage:* const q = new Queue();* q.enqueue('a');* q.enqueue('b');* q.dequeue(); //'a'* q.isEmpty(); // False*/class Node {constructor(value) {this.value = value;this.next = null;}}class Queue {constructor() {this.head = null;this.tail = null;this.length = 0;}isEmpty() {return this.length === 0;}enqueue(item) {const newNode = new Node(item);if (this.isEmpty()) {this.head = newNode;} else if (this.tail) {this.tail.next = newNode;}this.tail = newNode;this.length++;}dequeue() {if (this.isEmpty() || !this.head) {return null;} else {const removedNode = this.head;this.head = this.head.next;removedNode.next = null;this.length--;if (this.isEmpty()) {this.tail = null;}return removedNode.value;}}}
We can also perform BFS recursively, which is can be more intuitive in certain cases. The recursion call stack is an implicit stack to track which nodes to visit next.
/*** @param {Object} graph Node to array of neighboring nodes.* @param {string} source Source node to start traversal from. Has to be a valid node if graph is non-empty.* @return {Array<string>} A BFS-traversed order of nodes.*/export default function breadthFirstSearch(graph, source) {// If there are no nodes in the graph, just return an empty arrayif (Object.keys(graph).length === 0) {return [];}// Initialize a queue to keep track of nodes to visit.const queue = new Queue();const visited = new Set();// Add the source node to the queue and mark it as visited.queue.enqueue(source);visited.add(source);function traverse() {// If the queue is empty, we have visited all nodes, so return the visited nodes.if (queue.isEmpty()) {return Array.from(visited);}// Get the next node to visit from the queue.const node = queue.dequeue();// Visit each neighbor that hasn't been visited before.graph[node].forEach((neighbor) => {if (!visited.has(neighbor)) {visited.add(neighbor);queue.enqueue(neighbor);}});// Recursively call traverse to visit the next node in the queue.return traverse();}// Call traverse to start the traversal.return traverse();}
In the worst case, BFS visits every vertex and every edge of the graph once. Therefore, the time complexity of BFS is O(V + E), where V is the number of vertices in the graph and E is the number of edges. This is because BFS has to explore all vertices and edges to ensure that it covers the entire graph.
Take note that you should not use Array.shift()
as it takes O(n) time to dequeue, where n is the number of elements in the array.
BFS uses a queue to keep track of the nodes to be visited. At any given time, the queue contains the nodes that are at the current level of the graph being explored. Therefore, the space complexity of BFS is O(maximum number of nodes in any level of the graph).
console.log()
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