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Word Ladder
You are given two words, beginWord and endWord, and also a list of words wordList. All of the given words are of the same length, consisting of lowercase English letters, and are all distinct.
Your goal is to transform beginWord into endWord by following the rules:
You may transform beginWord to any word within wordList, provided that at exactly one position the words have a different character, and the rest of the positions have the same characters.
You may repeat the previous step with the new word that you obtain, and you may do this as many times as needed.
Return the minimum number of words within the transformation sequence needed to obtain the endWord, or 0 if no such sequence exists.
Example 1:
Input: beginWord = "cat", endWord = "sag", wordList = ["bat","bag","sag","dag","dot"] Output: 4 Explanation: The transformation sequence is “cat” -> “bat” -> “bag” -> “sag”.
Example 2:
Input: beginWord = "cat", endWord = "sag", wordList = ["bat","bag","sat","dag","dot"] Output: 0 Explanation: There is no possible transformation sequence from “cat” to “sag” since the word “sag” is not in the wordList.
Constraints:
1 <= beginWord.length <= 10 1 <= wordList.length <= 100 Solution
The “distance” of every transformation is 1 so it is OK to apply BFS for searching the shortest path. Because it will take O ( wordList.length 2 × beginWord.length 2 ) O(\text{wordList.length}^2\times\text{beginWord.length}^2) O(wordList.length2×beginWord.length2) to build up the graph inevitably, more advanced shortest path algorithm is not necessary.
At first, we put begin word into BFS queue and set the initial distance of 1. Then we keep getting the top word from queue and check whether it can reach out other unvisited words. If so, we add these new words into queue and set their corresponding distance to current distance+1. When we reach the end word during this process, we can return early. If we cannot reach end word after the queue is empty, it means the end word is not reachable.
Code
class Solution: def ladderLength(self, beginWord: str, endWord: str, wordList: List[str]) -> int: if beginWord == endWord: return 1 vis_flag = {word: False for word in wordList} # dis = {word: 10000000 for word in wordList} vis_flag[beginWord] = True vis_flag[endWord] = False from queue import Queue bfs_queue = Queue() bfs_queue.put((beginWord, 1)) def check(a, b): if a == b: return False cnt = 0 for i in range(len(a)): if a[i] != b[i]: cnt += 1 return cnt == 1 while not bfs_queue.empty(): cur = bfs_queue.get() for word in wordList: if not vis_flag[word] and check(cur[0], word): if word == endWord: return cur[1] + 1 vis_flag[word] = True bfs_queue.put((word, cur[1]+1)) return 0 