{ "data": { "question": { "questionId": "822", "questionFrontendId": "804", "boundTopicId": null, "title": "Unique Morse Code Words", "titleSlug": "unique-morse-code-words", "content": "

International Morse Code defines a standard encoding where each letter is mapped to a series of dots and dashes, as follows:

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For convenience, the full table for the 26 letters of the English alphabet is given below:

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\n[".-","-...","-.-.","-..",".","..-.","--.","....","..",".---","-.-",".-..","--","-.","---",".--.","--.-",".-.","...","-","..-","...-",".--","-..-","-.--","--.."]
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Given an array of strings words where each word can be written as a concatenation of the Morse code of each letter.

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Return the number of different transformations among all words we have.

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Example 1:

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\nInput: words = ["gin","zen","gig","msg"]\nOutput: 2\nExplanation: The transformation of each word is:\n"gin" -> "--...-."\n"zen" -> "--...-."\n"gig" -> "--...--."\n"msg" -> "--...--."\nThere are 2 different transformations: "--...-." and "--...--.".\n
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Example 2:

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\nInput: words = ["a"]\nOutput: 1\n
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Constraints:

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