293. Flip Game
Problem Description
In the given problem, we are playing a game called Flip Game with a friend. The game is played with a string currentState
that can consist of only two characters: '+'
and '-'
. In each turn, a player must flip exactly two consecutive '+'
characters into '-'
characters. This is the only valid move in the game. The game proceeds with each player taking turns until no more valid moves can be made, at which point the last player to have made a valid move wins.
Our objective is to find all possible states of the currentState
after one valid move has been made by the current player. We must provide a list of these possible states, or an empty list if no valid moves are available. The resulting states can be returned in any order.
Intuition
The solution to this problem is straightforward and involves iterating through the string to look for pairs of consecutive '+'
characters because that's the only condition where a flip is possible. Here's the logical approach:
-
Convert the string
currentState
into a list of characters, so we can easily modify individual characters during our iteration. -
Initialize an empty list
ans
to store the possible next states. -
Loop through the list starting from index 0 and going to the second to last index (since we are always looking for pairs, we don't need to check the last character by itself).
-
At each iteration, check if the current character and the one following it are both
'+'
.- If they are, we flip them to
'-'
by setting them to'-'
. - Then, we take the modified list, convert it back into a string, and add this state to our list of possible next moves
ans
. - After this operation, reverting the characters back to
'+'
is important because we are exploring all possible moves from the original state, one at a time.
- If they are, we flip them to
-
Continue this process until we have checked all possible pairs of
'+'
. -
Return the
ans
list containing all the possible next states. If no pairs of'+'
were found, theans
list would be empty.
Solution Approach
The solution takes advantage of the linear nature of the currentState
to perform a single-pass scan. Here is how the algorithm unfolds:
-
Data Structure:
- The function converts the
currentState
string into a list of characters, referred to ass
in the code, to enable easy modification of individual characters. - An empty list,
ans
, is created for storing the possible states after making valid moves.
- The function converts the
-
Algorithm:
- The function iterates through the list
s
with a loop, starting from the first character and stops at the second-last character usingenumerate(s[:-1])
. This range is used because the last character cannot start a pair of two'+'
. - At each iteration, the function checks if the current character and the one immediately following it form a pair of consecutive
'+'
usingif c == "+" and s[i + 1] == "+"
. - When such a pair is found:
- Both characters are flipped from
'+'
to'-'
by settings[i]
ands[i + 1]
to'-'
. - The updated list
s
is then joined to form a string representing the new state and is added to theans
list. - Immediately after recording the new state, the characters at index
i
andi + 1
are reset back to'+'
to restore the original state before moving to the next iteration. This is crucial as it allows us to explore all possible moves independently.
- Both characters are flipped from
- The function iterates through the list
-
Return Value:
- After the end of the loop, the list
ans
will contain all the unique states that result from performing valid moves on thecurrentState
. - The function returns the
ans
list. If no valid moves exist,ans
will be returned as an empty list.
- After the end of the loop, the list
The key pattern used here is iteration over the list, combined with simple character manipulation to explore different move outcomes. This solution is efficient as it runs in O(n) time, where n
is the length of the currentState
, and operates with constant space complexity beyond the input and output lists.
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Start EvaluatorExample Walkthrough
Let's use a small example to illustrate the solution approach.
Suppose the currentState
string is "+++-++"
. Our task is to find all possible states after one valid move. A valid move entails flipping two consecutive '+'
characters into '-'
.
Following the solution approach:
- Convert the string into a list of characters:
s = ['+', '+', '+', '-', '+', '+']
- Initialize an empty list to store possible next states:
ans = []
- Iterate over the list (ignoring the last character as a start since there can't be a pair):
- Check
s[0]
ands[1]
: Both are'+'
, so flip them to get['-', '-', '+', '-', '+', '+']
, convert back to string"--+-++"
, and add toans
. - Revert
s[0]
ands[1]
back to'+'
, sos
is now['+', '+', '+', '-', '+', '+']
again. - Move to the next pair.
- Check
s[1]
ands[2]
: Both are'+'
, so flip them to get['+', '-', '-', '-', '+', '+']
, convert back to string"+-- -++"
, and add toans
. - Revert
s[1]
ands[2]
back to'+'
. - Continue in this fashion.
- The next pair
s[2]
ands[3]
are not both'+'
, so no flip. - Check
s[3]
ands[4]
: Not both'+'
, so no flip. - Finally, check
s[4]
ands[5]
: Both are'+'
, so flip to get['+', '+', '+', '-', '-', '-']
, convert back to string"+++- --"
, and add toans
.
- Check
- We're left with
ans
containing the strings:"--+-++"
,"+-- -++"
, and"+++- --"
. - Return
ans
, which is["--+-++", "+-- -++", "+++- --"]
.
The players continue the game with each one using the states from ans
until no more moves can be played. The last move before the game state has no more consecutive '+'
is the winning move.
Solution Implementation
1from typing import List
2
3class Solution:
4 def generatePossibleNextMoves(self, currentState: str) -> List[str]:
5 # Convert the `currentState` string into a list of characters for manipulation
6 state_list = list(currentState)
7
8 # Initialize an empty list to store all the possible next moves
9 possible_moves = []
10
11 # Loop through the state_list until the second-to-last character
12 for i in range(len(state_list) - 1):
13 # Check if two consecutive characters are both '+'
14 if state_list[i] == '+' and state_list[i + 1] == '+':
15 # Flip them to '-' to generate a new possible move
16 state_list[i] = state_list[i + 1] = '-'
17 # Convert the updated list back to string and add to our list of possible moves
18 possible_moves.append("".join(state_list))
19 # Flip the characters back to '+' to reset the state for the next iteration
20 state_list[i] = state_list[i + 1] = '+'
21
22 # Return the list of all possible moves
23 return possible_moves
24
1import java.util.List;
2import java.util.ArrayList;
3
4public class Solution {
5 // Method to generate all possible next moves by flipping two consecutive '+' to '--'
6 public List<String> generatePossibleNextMoves(String currentState) {
7 char[] charArray = currentState.toCharArray(); // Convert the string to a character array for easy manipulation
8 List<String> possibleMoves = new ArrayList<>(); // List to store all the possible next moves
9
10 // Iterate over the character array to find consecutive '+'
11 for (int i = 0; i < charArray.length - 1; ++i) {
12 // Check if the current and next character are both '+'
13 if (charArray[i] == '+' && charArray[i + 1] == '+') {
14 charArray[i] = '-'; // Flip the current '+' to '-'
15 charArray[i + 1] = '-'; // Flip the next '+' to '-'
16
17 // Add the new state to the list of possible moves. Convert the character array back to a string.
18 possibleMoves.add(new String(charArray));
19
20 // Reset the characters back to '+' for the next iteration
21 charArray[i] = '+';
22 charArray[i + 1] = '+';
23 }
24 }
25 // Return the list of all possible moves
26 return possibleMoves;
27 }
28}
29
1#include <vector>
2#include <string>
3
4class Solution {
5public:
6 // Function to generate all possible next moves by flipping two consecutive '+' to '--'
7 std::vector<std::string> generatePossibleNextMoves(std::string currentState) {
8 std::vector<std::string> possibleMoves; // Vector to hold all possible next moves
9
10 // Iterate through the string to find two consecutive '+'
11 for (size_t i = 0; i < currentState.size() - 1; ++i) { // Using size_t for index
12 // Check if the current and next characters are '+'
13 if (currentState[i] == '+' && currentState[i + 1] == '+') {
14 currentState[i] = '-'; // Flip the current '+' to '-'
15 currentState[i + 1] = '-'; // Flip the next '+' to '-'
16
17 // Add the new state to the list of possible moves
18 possibleMoves.push_back(currentState);
19
20 // Flip the characters back to '+' to restore the original state for the next iteration
21 currentState[i] = '+';
22 currentState[i + 1] = '+';
23 }
24 }
25
26 // Return all possible moves
27 return possibleMoves;
28 }
29};
30
31// Note: You generally include the necessary header files and use of "std::"
32// before standard library constructs is a good practice in C++.
33// This ensures that you are using elements from the standard namespace.
34
1// Function to generate all possible next moves, from flipping two consecutive '+' to '--'
2function generatePossibleNextMoves(currentState: string): string[] {
3 const possibleMoves: string[] = []; // Array to hold all possible next moves
4
5 // Iterate through the string to find two consecutive '+'
6 for (let i = 0; i < currentState.length - 1; ++i) {
7 // Check if the current and next characters are '+'
8 if (currentState[i] === '+' && currentState[i + 1] === '+') {
9 const newState = currentState.substring(0, i) + '--' + currentState.substring(i + 2);
10 // Add the new state to the list of possible moves
11 possibleMoves.push(newState);
12 }
13 }
14
15 // Return all possible moves
16 return possibleMoves;
17}
18
Time and Space Complexity
The time complexity of the given code is O(n)
, where n
is the length of the input string currentState
. This is due to the fact that we traverse the string once, with each iteration checking a pair of adjacent characters and modifying the string if a match is found. The replacement operation for a single pair of characters is O(1)
, therefore the overall time taken is proportional to the length of the string.
The space complexity of the code is also O(n)
. This is because:
- We convert the input string into a list, which takes
O(n)
space. - A new string is created in each iteration when a valid move is found (the
''.join(s)
operation), and in the worst case, this could happen for every pair of adjacent characters. However, these strings are not all stored in memory at the same time; they are added to the listans
and then the original lists
is restored to its previous state. Since the longest string appended toans
has the same length as the input string,ans
will also take upO(n)
space. - The auxiliary space for the loop and variables is
O(1)
(constant).
It's important to note that, while we do create multiple strings in the process, they are not all in memory at the same time. Each generated result is added to ans
then the original list s
is modified back. Nevertheless, in the worst case, where you can flip every pair, you'd have n/2
results stored in ans
which constitute O(n^2)
space if you consider all potential flips together. But considering space complexity in terms of additional space required by the program, we disregard the space taken by the input and output. Hence, we typically consider the space complexity of the additional space required, which remains O(n)
.
Learn more about how to find time and space complexity quickly using problem constraints.
A person thinks of a number between 1 and 1000. You may ask any number questions to them, provided that the question can be answered with either "yes" or "no".
What is the minimum number of questions you needed to ask so that you are guaranteed to know the number that the person is thinking?
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