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This approach involves simulating the process of passing the pillow using a loop. We start from the first person in the line and traverse it based on the time parameter. When we reach the end, we simply reverse the direction and continue until the given time is exhausted.
Time Complexity: O(time), since we simulate each passing of the pillow individually.
Space Complexity: O(1), as we only utilize a few integer variables for tracking state.
1
Solve with full IDE support and test cases
This JavaScript implementation uses a simple for-loop to determine changes in the pillow's position, adjusting the direction of movement when the bounds are met.
This approach employs modulo arithmetic to determine the position of the pillow. By calculating the rounds of back-and-forth transfers based on time, we can derive the final position without directly simulating each second.
Time Complexity: O(1)
Space Complexity: O(1)
1#include <iostream>
2using namespace std;
3
4int passThePillow(int n, int time) {
5 int cycles = time / (n - 1);
6 int remainder = time % (n - 1);
7
8 if (cycles % 2 == 0) {
9 return 1 + remainder;
10 } else {
11 return n - remainder;
12 }
13}
14
15int main() {
16 int n = 4, time = 5;
17 cout << passThePillow(n, time) << endl;
18 return 0;
19}The C++ code computes how many complete cycles are made and then determines the final position. The use of modulo operations efficiently tracks the pillow's movement.