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Code written in C++: Find the lexicographically smallest string composed of the first K letters of the alphabet, and adjacent characters cannot be the same

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Release: 2023-08-29 22:29:07
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Code written in C++: Find the lexicographically smallest string composed of the first K letters of the alphabet, and adjacent characters cannot be the same

In the programming world, solving string manipulation problems is a common and interesting challenge. A key problem faced is how to obtain a lexicographically minimal string using only the K letters of the alphabet, while adhering to additional constraints such as not matching adjacent characters. In this article, we aim to delve into this problem and propose an efficient solution using C programming language. By detailing the different methods used in the grammar and providing algorithmic details step by step, we can introduce innovative techniques aimed at achieving good results in different fields. We provide complete executable code guidance for each method to make it practical for users.

grammar

Before exploring algorithms and techniques, it is necessary to establish the syntax used in the code snippets that follow.

std::string findLexSmallestString(int n, int k);
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In this syntax, n refers to the number of letters in the alphabet and k refers to the number of letters used. This function generates the lowest lexicographically ordered string that meets the specified conditions.

algorithm

To address and solve the challenge of finding the lexicographically minimal string with no repetitions between adjacent characters using only at most K letters of the alphabet, we formulated a methodical approach in the form of an algorithm.

  • Initialize an empty string "ans" and an array/vector "used" to track used characters.

  • Iterate starting from the first character of the alphabet.

  • Append the current character to `ans` and mark it as used.

  • If "ans" has multiple characters and the last two characters are the same, find the next available character by iterating from the current character to "n".

  • If no usable character is found, backtrack by removing the last character from "ans" and marking it as unused.

  • Repeat steps 3-5 until "ans" reaches length "k".

  • Returns "ans" as the lexicographically smallest string in which no two adjacent characters are the same, using all the first K letters of the alphabet.

Method 1: Greedy Algorithm

In this method, we will use the greedy strategy to construct the lexicographically smallest string. This same process emphasizes careful consideration of each character in sequence while ensuring that choices made throughout the process are focused on minimizing the lexicographic value of the overall output.

Example

#include <iostream>
#include <vector>

std::string findLexSmallestGreedy(int n, int k) {
   std::string ans = "";
   std::vector<bool> used(n, false);

   for (int i = 0; i < n; i++) {
      for (int j = 0; j < k; j++) {
         if (!used[j]) {
            if (ans.empty() || ans.back() != 'a' + j) {
               ans += 'a' + j;
               used[j] = true;
               break;
            }
         }
      }
   }

   return ans;
}

int main() {
   int n = 5; // Assuming there are 5 letters in the alphabet
   int k = 3; // Assuming 3 letters will be used

   std::string result = findLexSmallestGreedy(n, k);
   std::cout << "Lexicographically Smallest String: " << result << std::endl;

   return 0;
}
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Output

Lexicographically Smallest String: abc
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Method 2: Backtracking algorithm

This strategy involves utilizing backtracking to exhaustively search for every combination of characters while ensuring that consecutive characters are not repeated. Therefore, by considering every character at every position, we can find the lexicographically smallest string that satisfies the given constraints.

Example

#include <iostream>
#include <vector>

bool findLexSmallestBacktracking(int n, int k, std::vector<char>& ans, std::vector<bool>& used) {
   if (ans.size() == k) {
      return true;
   }

   for (int i = 0; i < n; i++) {
      if (!used[i]) {
         if (ans.empty() || ans.back() != 'a' + i) {
            ans.push_back('a' + i);
            used[i] = true;

            if (findLexSmallestBacktracking(n, k, ans, used)) {
               return true;
            }

            ans.pop_back();
            used[i] = false;
         }
      }
   }

   return false;
}

std::string findLexSmallestStringBacktracking(int n, int k) {
   std::vector<char> ans;
   std::vector<bool> used(n, false);

   if (findLexSmallestBacktracking(n, k, ans, used)) {
      return std::string(ans.begin(), ans.end());
   }

   return "";
}

int main() {
   int n = 22;  // Assuming n = 22
   int k = 4;  // Assuming k = 4

   std::string result = findLexSmallestStringBacktracking(n, k);
   std::cout << "Lexicographically Smallest String: " << result << std::endl;

   return 0;
}
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Output

Lexicographically Smallest String: abcd
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in conclusion

In this article, we explore the problem of finding the lexicographically smallest string using the first K letters of the alphabet, with the constraint that two adjacent characters cannot be the same. We discuss the syntax and provide two different approaches to solving this problem: the greedy algorithm and the backtracking algorithm. Greedy algorithms employ the strategy of minimizing the lexicographic value of the resulting string, while backtracking algorithms explore all possible combinations to find the desired string. The C code examples provided demonstrate the implementation of each method and enable us to efficiently generate lexicographically minimal strings. Armed with this knowledge, you can now confidently solve similar string manipulation problems and optimize your code accordingly.

The above is the detailed content of Code written in C++: Find the lexicographically smallest string composed of the first K letters of the alphabet, and adjacent characters cannot be the same. For more information, please follow other related articles on the PHP Chinese website!

source:tutorialspoint.com
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