Split (2)

train · 117k rows

inputs stringlengths 50 14k	targets stringlengths 4 655k
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if boardingCost * 4 <= runningCost: return -1 max_profit, cur_profit, waiting, i = 0, 0, 0, 0 res = 0 while i < len(customers) or waiting > 0: if i < len(customers): waiting += customers[i] i += 1 boarded = min(waiting, 4) cur_profit += boarded * boardingCost - runningCost #print(waiting, boarded, cur_profit, max_profit) if cur_profit > max_profit: res = i max_profit = cur_profit waiting -= boarded return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profit = 0 wait = 0 rotated = 0 res = -1 total = 0 for num in customers: cur_num = min(4, num + wait) total += cur_num wait = (num + wait - cur_num) rotated += 1 cur_profit = boardingCost * total - rotated * runningCost if cur_profit > profit: res = rotated profit = cur_profit while wait: cur = min(4, wait) total += cur rotated += 1 cur_profit = boardingCost * total - rotated * runningCost if cur_profit > profit: res = rotated profit = cur_profit wait -= cur return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profit = 0 waiting = 0 rotations = 0 onboard = 0 gondola_customers = deque([]) total = 0 maxprofit = 0 max_rotation = -1 for arrival in customers: if gondola_customers: coming_down = gondola_customers.popleft() onboard -= coming_down total = arrival if waiting >0: total = waiting + arrival #if onboard == 0 and total == 0: # continue if total <= 4: profit += ((totalboardingCost) - runningCost) onboard += total gondola_customers.append(total) waiting = max(0,waiting-total) else: profit += ((4boardingCost) - runningCost) onboard += 4 gondola_customers.append(4) waiting += (arrival-4) rotations += 1 if profit > maxprofit: maxprofit = profit max_rotation = rotations print((maxprofit, max_rotation, waiting)) profit += ((waiting//4)((4boardingCost)-runningCost)) rotations += (waiting//4) if profit > maxprofit: maxprofit = profit max_rotation = rotations print((maxprofit, max_rotation, waiting%4)) profit += (((waiting%4)*boardingCost)-runningCost) rotations += ((waiting%4)>0) if profit > maxprofit: maxprofit = profit max_rotation = rotations print((maxprofit, max_rotation)) return max_rotation if maxprofit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	import math class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profit,bestIteration,customerCount,iteration,boarding = 0,0,0,0,0 for i in range(len(customers)): customerCount = customerCount + customers[i] iteration = iteration + 1 boarding = boarding + min(customerCount,4) customerCount = customerCount - min(customerCount,4) if boardingboardingCost - iterationrunningCost > profit: profit = boardingboardingCost - iterationrunningCost bestIteration = iteration while customerCount > 0: iteration = iteration + 1 boarding = boarding + min(customerCount,4) customerCount = customerCount - min(customerCount,4) if boardingboardingCost - iterationrunningCost > profit: profit = boardingboardingCost - iterationrunningCost bestIteration = iteration if profit == 0: return -1 return bestIteration
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_profit, min_rotations = 0, -1 curr_profit = 0 waiting, rotations = 0, 0 customers.reverse() while curr_profit >= 0: if customers: waiting += customers.pop() if waiting == 0: if not customers: break else: curr_profit += min(4, waiting) * boardingCost - runningCost waiting -= min(4, waiting) rotations += 1 if curr_profit > max_profit: max_profit, min_rotations = curr_profit, rotations return min_rotations
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: sm = 0 cus = 0 c = 0 w = 0 ret = 0 mx = 0 while True: if c < len(customers): cus += customers[c] c += 1 board = min(4, cus) cus -= board sm += (boardingCost * board) - runningCost w += 1 if mx < sm: ret = w mx = sm if 0 == min(4, cus) and c == len(customers): break return -1 if mx == 0 else ret
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: # we have the boardingCost and the runningCost #at each index we need to wipe it out before we move to the next #we can board max 4 at a time arr = [-1]; # for i in range(len(customers)): # if customers[i] == 0: # print('6') # else: # divided = customers[i]//4; # if customers[i] % 4 != 0: # divided += 1; # bammer = customers[i] * boardingCost - (divided * runningCost); # arr.append(bammer); # print(max(arr)); currentCost = 0; maximum = -1000000000; rotations = 0; total = 0; while (total != 0 or rotations < len(customers)): if (rotations < len(customers)): total += customers[rotations]; if total < 4: temp = total; total = 0; currentCost += (temp * boardingCost) - runningCost; arr.append(currentCost); if (currentCost > maximum): maximum = currentCost; else: total -= 4; currentCost += (4 * boardingCost) - runningCost; arr.append(currentCost); rotations += 1; maxer = -1000000000; indexer = -1; for i in range(len(arr)): if (maxer < arr[i]): maxer = arr[i]; indexer = i; if indexer == 0: return -1; return indexer; # print(arr); # return max(arr);
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: best_profit = float('-inf') best_rotations = -1 rem = 0 group = [] for c in customers: avail = rem + c group.append(min(4, avail)) rem = max(0, avail - 4) while rem: group.append(min(4, rem)) rem = max(0, rem - 4) profit = cost = 0 for i, g in enumerate(group): profit += g * boardingCost cost += runningCost if best_profit < profit - cost: best_profit = profit - cost best_rotations = i + 1 return best_rotations if best_profit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: # no trick, iterate and board all if possible get profit iteration = 0 max_profit = 0 profit = 0 wait = 0 for i, c in enumerate(customers): wait += c board = min(4, wait) wait -= board if i == len(customers)-1 and wait > 0: customers += [wait] wait = 0 profit += boardingCost * board - runningCost if profit > max_profit: max_profit = profit iteration = i return iteration + 1 if max_profit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: people = 0 on = 0 i = 0 money = 0 ans = -1 j = 0 for c in customers: people += c i += 1 x = min(people, 4) on += x people -= x money = on * boardingCost - runningCost * i if money > ans: j = i ans = money while people: i += 1 x = min(people, 4) on += x people -= x money = on * boardingCost - runningCost * i if money > ans: j = i ans = money return j if ans > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if not customers: return 0 if 4 * boardingCost <= runningCost: return -1 inline = 0 profit = 0 maxProfit = 0 rotate = 0 recordRotate = 0 idx = 0 while idx < len(customers) or inline > 0: if idx < len(customers): inline += customers[idx] if inline > 4: profit = profit + 4 * boardingCost - runningCost inline = inline - 4 rotate += 1 elif (inline <= 4 ): profit = profit + inline * boardingCost - runningCost inline = 0 rotate += 1 if profit > maxProfit: maxProfit = profit recordRotate = rotate idx = idx + 1 return recordRotate
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_profit = 0 max_spin = -1 cur_profit = 0 cur_num = 0 spins = 0 for i in range(len(customers)): spins += 1 cur_profit -= runningCost cur_num += customers[i] cur_profit += min(cur_num, 4) * boardingCost if cur_profit > max_profit: max_profit = max(max_profit, cur_profit) max_spin = spins cur_num = max(0, cur_num - 4) while cur_num > 0: spins += 1 cur_profit -= runningCost cur_profit += min(4, cur_num) * boardingCost if cur_profit > max_profit: max_profit = max(max_profit, cur_profit) max_spin = spins cur_num -= min(4, cur_num) return max_spin
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if 4 * boardingCost <= runningCost: return -1 curr_customers = 0 curr_profit = 0 max_profit = 0 min_rotations = 0 for i, cus in enumerate(customers): curr_customers += cus if curr_customers > 4: curr_profit += 4 * boardingCost - runningCost curr_customers -= 4 else: curr_profit += curr_customers * boardingCost - runningCost curr_customers = 0 if max_profit < curr_profit: max_profit = curr_profit min_rotations = i + 1 left_rounds, remainder = divmod(curr_customers, 4) max_profit1 = max_profit max_profit2 = curr_profit + 4 * left_rounds * boardingCost - left_rounds * runningCost max_profit3 = curr_profit + curr_customers * boardingCost - (left_rounds + 1) * runningCost MAX = max(max_profit1, max_profit2, max_profit3) if MAX == max_profit1: min_rotations = min_rotations elif MAX == max_profit2: min_rotations = len(customers) + left_rounds else: min_rotations = len(customers) + left_rounds + 1 return min_rotations if max_profit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if boardingCost * 4 < runningCost: return -1 profit = 0 num_waiting_customers = 0 max_profit = 0 ans = -1 i = 0 while i < len(customers) or num_waiting_customers > 0: num_waiting_customers += customers[i] if i < len(customers) else 0 profit += min(num_waiting_customers, 4) * boardingCost - runningCost if profit > max_profit: ans = i + 1 max_profit = profit num_waiting_customers = max(num_waiting_customers - 4, 0) i += 1 return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: total_queue = 0 idx = 0 curr_costs = 0 max_costs = float('-inf') max_idx = 0 while total_queue or idx < len(customers): curr_customers = 0 if idx < len(customers): curr_customers = min(4, customers[idx]) total_queue += max(0, customers[idx] - 4) if curr_customers < 4 and total_queue: diff = 4 - curr_customers curr_customers += min(diff, total_queue) total_queue = max(0, total_queue - diff) idx += 1 curr_costs += boardingCost * curr_customers - runningCost if curr_costs > max_costs: max_idx = idx max_costs = curr_costs return max_idx if max_costs > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: waiting = 0 total_money = 0 cars = [0,0,0,0] index = 0 max_rotations = -1 num_rotations = 0 max_money = 0 while index < len(customers): waiting += customers[index] if waiting < 4: cars[0] = waiting total_money += waitingboardingCost waiting = 0 else: waiting -= 4 total_money += 4boardingCost cars[0] = 4 self.rotation(cars) total_money -= runningCost index += 1 num_rotations += 1 if total_money > max_money: max_rotations = num_rotations max_money = total_money while waiting != 0: if waiting < 4: cars[0] = waiting total_money += waitingboardingCost waiting = 0 else: waiting -= 4 total_money += 4boardingCost cars[0] = 4 self.rotation(cars) total_money -= runningCost num_rotations += 1 if total_money > max_money: max_rotations = num_rotations max_money = total_money if max_money == 0: return -1 return max_rotations def rotation(self, arr): arr[3], arr[2], arr[1], arr[0] = arr[2], arr[1], arr[0], 0
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: lines = [] carry = 0 cur = 0 for c in customers: cur = 4 if c + carry >= 4 else c + carry carry = c + carry - 4 if c + carry > 4 else 0 lines.append(cur) while carry: c = 4 if carry >= 4 else carry lines.append(c) carry = carry - 4 if carry > 4 else 0 res = 0 total = 0 rotate = 0 for i, c in enumerate(lines): total += c if total * boardingCost - (i+1) * runningCost > res: res = total * boardingCost - (i+1) * runningCost rotate = i + 1 print(res) return rotate if res > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers, boardingCost, runningCost): # we can never make profit if 4boardingCost <= runningCost: return -1 total = sum(customers) maxProfit = -1 maxRotate = 0 accuProfit = 0 rotate = 0 # keep rotate and board the customers. i = 0 prev = 0 while i < len(customers): # print('i ', i, \"num \", customers[i], \"total \", total) prev = accuProfit if customers[i] <= 4: accuProfit += customers[i] boardingCost customers[i] = 0 total -= customers[i] else: accuProfit += 4 * boardingCost customers[i] -= 4 total -= 4 rotate += 1 # every time we rotate, we need pay runningCost accuProfit -= runningCost if maxProfit < accuProfit: maxProfit = accuProfit maxRotate = rotate # print(\"accu \", accuProfit, \"rotate \", rotate, \"customer \", customers[i], \"profit \", accuProfit- prev,) # print(customers) # print(\"###\") # if current customer < 4, put them in the same group of the following customer # to make sure everything we full loaded. if i + 1 < len(customers): customers[i+1] += customers[i] customers[i] = 0 # the following customer need to wait the customer in front. if customers[i] == 0: i += 1 return -1 if maxProfit < 0 else maxRotate
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: n, cur, i = len(customers), 0, 0 maxProfit, maxProfitIdx, curProfit = 0, -1, 0 while i < n or cur > 0: cur += customers[i] if i < n else 0 i += 1 board = min(cur, 4) cur -= board curProfit += board * boardingCost - runningCost if curProfit > maxProfit: maxProfit, maxProfitIdx = curProfit, i return maxProfitIdx if maxProfit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: res = 0 max_profit = 0 wait_people = 0 taken_people = 0 rotation_times = 0 for customer in customers: rotation_times += 1 can_take = min(4, wait_people+customer) taken_people += can_take cur_profit = taken_peopleboardingCost - rotation_timesrunningCost if cur_profit > max_profit: res = rotation_times max_profit = cur_profit wait_people = max(0, wait_people+customer-4) while wait_people > 0: rotation_times += 1 can_take = min(4, wait_people) taken_people += can_take cur_profit = taken_peopleboardingCost - rotation_timesrunningCost if cur_profit > max_profit: res = rotation_times max_profit = cur_profit wait_people -= can_take return res if res > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	import math class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: best = 0 index = None i = 0 n = 0 p = 0 while n > 0 or i < len(customers): if i < len(customers): n += customers[i] p += min(4, n) * boardingCost p -= runningCost n -= min(4, n) i += 1 if p > best: best = p index = i if index is None: return -1 return index
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], bCost: int, rCost: int) -> int: maxProfit = -1 unboard = 1 board = 0 flag = True count = 0 profit = 0 ans = 0 while unboard > 0 or count < len(customers): if flag: unboard = 0 flag = False unboard += (customers[count] if count < len(customers) else 0) count += 1 if unboard > 4: board += 4 unboard -= 4 profit = boardbCost - rCostcount else: board += unboard unboard = 0 profit = boardbCost - rCostcount ans = count if profit > maxProfit else ans maxProfit = profit if profit > maxProfit else maxProfit return ans if maxProfit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: maxi = 0 maxRotate = -1 profit = 0 onBoarded = 0 inQueue = 0 rotates = 0 for c in customers: rotates += 1 onBoarded = max(0, onBoarded - 1) inQueue += c board = min(4, inQueue) inQueue -= board profit += board * boardingCost - runningCost if profit > maxi: maxi = profit maxRotate = rotates while inQueue > 0: rotates += 1 onBoarded = max(0, onBoarded - 1) board = min(4, inQueue) inQueue -= board profit += board * boardingCost - runningCost if profit > maxi: maxi = profit maxRotate = rotates return maxRotate
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, cust: List[int], b: int, r: int) -> int: arr=[1b-r,2b-r,3b-r,4b-r] pos=0 ln=len(cust) #print(arr) for i in range(4): if arr[i]>0: pos=i+1 if pos==0: return -1 prev=0 for i in range(ln): x=min(4,prev+cust[i]) prev= prev+cust[i]-x cust[i]=x #print(cust) cum=0 for i in range(ln): cum+=cust[i] cust[i]=cumb-(i+1)r a,b2=prev//4,prev%4 #print(cust) x=max(cust) y=(cum+(a4))b-(ln+a)r #print(prev,a,b2,x,y,cum,ln,(ln+a)) z=y if b2: z=(cum+prev)b-(ln+a+1)*r if z>y: a+=1 if z>x: if z<1: return -1 return ln+a if x<1: return -1 return cust.index(x)+1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], bc: int, rc: int) -> int: rnd = waiting = 0 ans = -1 profit = -1 curp = 0 n = sum(customers) debug = 0 if debug: print(f'lenght is {len(customers)}, total cust is {n} where n % 4 = {n%4}, boardingTicket is {bc}, run cost is {rc}') i = 0 while i < len(customers) or waiting > 0: cust = 0 if i >= len(customers) else customers[i] waiting += cust board = min(4, waiting) waiting -= board curp = curp + board * bc - rc rnd += 1 if i < len(customers): i += 1 if debug: print(f'i is {i}, new comer is {cust} and total waiting is {waiting}, ' f'board {board} people, curp is {curp}, rnd = {rnd}') #for i, cust in enumerate(customers): # if waiting <= 4: # curp = curp + waiting * bc - rc # if debug: # print(f'i is {i}, new comer is {cust} and total waiting is {waiting}, ' # f'board {waiting} people, curp is {curp}, rnd = {rnd + 1}') # waiting = 0 # rnd += 1 # else: # board = waiting - waiting % 4 # boardrnd = board // 4 # curp = curp + board * bc - boardrnd * rc # t * (4bc - rc) # if debug: # print(f'i is {i}, new comer is {cust} and total waiting is {waiting}, ' # f'board {board} people, curp is {curp}, rnd = {rnd + boardrnd}') # waiting %= 4 # rnd += boardrnd if curp > profit: profit = curp ans = rnd if waiting > 0: curp = curp + waiting bc - rc rnd += 1 if debug: print(f'i is n, new comer is 0 and total waiting is {waiting}, board {waiting} people, curp is {curp}, rnd = {rnd}') if curp > profit: profit = curp ans = rnd return ans # [17,0,45,39,19,4,9,3,16] # 11 # 33
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_profit = 0 best_rots = -1 rots = 0 waiting = 0 boarded = 0 c = 0 while waiting > 0 or c<len(customers): if c<len(customers): waiting += customers[c] if waiting > 4: boarded += 4 waiting -= 4 else: boarded += waiting waiting = 0 rots += 1 profit = boardedboardingCost - rotsrunningCost if profit > max_profit: max_profit = profit best_rots = rots c += 1 return best_rots
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: waitingCustomers = customers[0] totalCustomers = 0 i = 1 result = -1 maxProfit = 0 while i < len(customers) or waitingCustomers > 0: servedCustomers = min(4, waitingCustomers) waitingCustomers -= servedCustomers totalCustomers += servedCustomers profit = totalCustomers * boardingCost - i * runningCost if profit > maxProfit: maxProfit = profit result = i if i < len(customers): waitingCustomers += customers[i] i += 1 return result
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: left = 0 required = 0 for cus in customers: required += 1 left += cus left -= min(left, 4) maxRot = required + ceil(left / 4) mP, mR = 0, -1 rotCnt = 0 c = 0 profit = 0 maxP = 0 while rotCnt < maxRot: if rotCnt < len(customers): c += customers[rotCnt] roundP = min(c , 4) * boardingCost c -= min(c, 4) roundP -= runningCost profit += roundP if profit > mP: mR = rotCnt + 1 mP = profit rotCnt += 1 return mR
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	def getindex(arr): value = max(arr) cnt = 1 for e in arr: if e == value: return cnt cnt += 1 class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: boarding = 0 rotation = 0 profit = [] n_customers = len(customers) for i in range(n_customers-1): if customers[i]<4: boarding += customers[i] rotation += 1 profit.append(boarding * boardingCost - rotationrunningCost) else: boarding += 4 customers[i+1] = customers[i] + customers[i+1] -4 rotation += 1 profit.append(boarding boardingCost - rotationrunningCost) while customers[n_customers-1]>3: boarding += 4 rotation += 1 profit.append(boarding boardingCost - rotationrunningCost) customers[n_customers-1] -= 4 if customers[n_customers-1] == 0: pass else: boarding += customers[n_customers-1] rotation += 1 profit.append(boarding boardingCost - rotation*runningCost) if max(profit)<0: return -1 else: return getindex(profit)
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_pro = -1 shift = 0 total_onboarded = 0 wait = 0 re = -1 for c in customers: wait+=c if wait > 0: shift+=1 if wait>4: total_onboarded+=4 else: total_onboarded+=wait cur_pro = total_onboardedboardingCost - shiftrunningCost if cur_pro > max_pro: re = shift max_pro = max(max_pro, cur_pro) if wait>4: wait-=4 else: wait=0 elif wait == 0: shift+=1 cur_pro = total_onboardedboardingCost - shiftrunningCost continue # no more new customers while wait > 0: shift+=1 if wait>4: total_onboarded+=4 else: total_onboarded+=wait cur_pro = total_onboardedboardingCost - shiftrunningCost if cur_pro > max_pro: re = shift max_pro = max(max_pro, cur_pro) if wait>4: wait-=4 else: wait=0 return re
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	from typing import List class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: index, max_profit, waiting_customers, num_customers, best_rotation = 0, -1, 0, 0, -1 while index < len(customers) or waiting_customers > 0: current_num_customers = 0 rotations = index + 1 if index < len(customers): current_num_customers = customers[index] if current_num_customers >= 4: waiting_customers += (current_num_customers - 4) num_customers += 4 if num_customers * boardingCost - rotations * runningCost> max_profit: max_profit = num_customers * boardingCost - rotations * runningCost best_rotation = rotations elif current_num_customers < 4 and (current_num_customers + waiting_customers) > 4: waiting_customers -= (4 - current_num_customers) num_customers += 4 if num_customers * boardingCost - rotations * runningCost> max_profit: max_profit = num_customers * boardingCost - rotations * runningCost best_rotation = rotations else: num_customers += current_num_customers num_customers += waiting_customers waiting_customers = 0 if num_customers * boardingCost - rotations * runningCost> max_profit: max_profit = num_customers * boardingCost - rotations * runningCost best_rotation = rotations index += 1 return best_rotation
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: itrn = 0 prof = 0 maxprof = 0 tc = 0 best = -1 i = 0 while i < len(customers) or tc > 0 : if i < len(customers) : tc += customers[i] itrn += 1 if tc >= 4 : prof += boardingCost4 - runningCost tc -= 4 if maxprof < prof: maxprof = prof best = itrn else: prof += boardingCosttc - runningCost tc = 0 if maxprof < prof: maxprof = prof best = itrn i += 1 return best
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, a: List[int], bc: int, rc: int) -> int: max_pr = pr = 0; cnt = max_cnt = 0; w = 0; i = 0 while i < len(a) or w > 0: x = w + a[i] if i < len(a) else w pr += min(x, 4) * bc - rc cnt += 1 if pr > max_pr: max_pr, max_cnt = pr, cnt w = max(x - 4, 0) i += 1 return max_cnt if max_pr > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if runningCost >= 4 * boardingCost: return -1 best_profit = 0 curr_enqueued = 0 curr_profit = 0 def get_customers(i): if i >= len(customers): return 0 return customers[i] i = 0 best_turns = -1 while curr_enqueued > 0 or i < len(customers): curr_enqueued += get_customers(i) to_add = min(4, curr_enqueued) curr_profit += to_add * boardingCost - runningCost if curr_profit > best_profit: best_turns = i + 1 best_profit = curr_profit curr_enqueued -= to_add i += 1 return best_turns
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers, boardingCost, runningCost): if 4 * boardingCost - runningCost <= 0: return -1 n = len(customers) wait = 0 now_profit = 0 max_profit = 0 res = -1 for i in range(n): wait += customers[i] now_profit += boardingCost * min(wait, 4) - runningCost wait -= min(wait, 4) if now_profit > max_profit: max_profit = now_profit res = i + 1 res += (wait // 4) if boardingCost * (wait % 4) - runningCost > 0: res += 1 return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: # simulation, time O(customers/4), space O(1) def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: n = len(customers) cur = remain = rot = 0 max_profit = min_rot = -1 i = 0 while i < n or remain: rot += 1 remain += customers[i] if i < n else 0 cur += min(4, remain) remain -= min(4, remain) cur_profit = cur * boardingCost - rot * runningCost if cur_profit > max_profit: max_profit = cur_profit min_rot = rot i += 1 return min_rot if max_profit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: leftover = 0 dp = [0] i=0 while i<len(customers) or leftover: if i < len(customers): leftover += customers[i] newCust = min(4, leftover) leftover -= newCust temp = dp[-1] + newCust*boardingCost - runningCost dp.append(temp) i += 1 if all([x<=0 for x in dp]): return -1 return dp.index(max(dp))
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: r, p = -1, 0 rc = 0 oc = 0 d = 0 for i, c in enumerate(customers): d = i+1 rc += c oc = min(4,rc) + oc rc = max( rc -4, 0) cp = oc * boardingCost - (i+1) * runningCost if cp > p: p = cp r = i+1 while rc > 0: d += 1 oc = min(4,rc) + oc rc = max( rc -4, 0) cp = oc * boardingCost - (d) * runningCost if cp > p: p = cp r = d return r
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: cur=0 ans=-1 cur_p=0 prev=0 temp=0 n=len(customers) for i in range(n): cur+=customers[i] if cur>=4: cur_p=(prev+4)boardingCost-(i+1)runningCost prev+=4 cur-=4 elif cur<4: cur_p+=(prev+cur)boardingCost-(i+1)runningCost prev+=cur cur=0 if cur_p>temp: ans=i+1 temp=cur_p if cur>0: m=cur//4 for i in range(m+1): # print(cur) if cur>=4: cur_p=(prev+4)boardingCost-(i+1+n)runningCost prev+=4 cur-=4 elif cur<4: # print(prev+cur) # print(i+1+n) cur_p=(prev+cur)boardingCost-(i+1+n)runningCost prev+=cur cur=0 if cur_p>temp: ans=i+1+n temp=cur_p # print(cur_p) # print(\" \") return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if boardingCost * 4 <= runningCost: return -1 profit = 0 num_waiting_customers = 0 max_profit = 0 ans = -1 i = 0 while i < len(customers) or num_waiting_customers > 0: num_waiting_customers += customers[i] if i < len(customers) else 0 # if i < len(customers): # num_rotate = ((len(customers) - i) * 50 + num_waiting_customers + 3) // 4 # if ((len(customers) - i) * 50 + num_waiting_customers) * boardingCost - num_rotate * runningCost + profit < 0: # return ans profit += min(num_waiting_customers, 4) * boardingCost - runningCost if profit > max_profit: ans = i + 1 max_profit = profit num_waiting_customers = max(num_waiting_customers - 4, 0) i += 1 return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: highest = waiting = profit = time = i = 0 highest_time = -1 while i < len(customers) or waiting: if i < len(customers): waiting += customers[i] i += 1 boarding = min(waiting, 4) waiting -= boarding profit += boarding * boardingCost - runningCost time += 1 if profit > highest: highest_time = time highest = max(profit, highest) return -1 if highest <= 0 else highest_time
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: capacity = [0] * 4 waiting = 0 max_profit = [0,0] rot = 0 j = 0 i = 0 l = len(customers) cust = 0 while waiting > 0 or i < l: if i < l: waiting += customers[i] i += 1 capacity[j] = 0 capacity[j] = waiting if waiting <= 4 else 4 cust += capacity[j] rot += 1 waiting = 0 if waiting <= 4 else waiting - 4 profit = (cust * boardingCost) - (rot * runningCost) #print([rot, profit]) if profit > max_profit[1]: max_profit = [rot, profit] if j == 3: j = 0 else: j += 1 return max_profit[0] if max_profit[1] > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profit = 0 max_profit = 0 res = -1 q = deque([c, i] for i, c in enumerate(customers)) i = 0 while q: n = 0 while q and q[0][1] <= i and n < 4: if n + q[0][0] <= 4: n += q.popleft()[0] else: q[0][0] -= 4 - n n = 4 i += 1 if not n: continue profit += boardingCost * n profit -= runningCost if profit > max_profit: res = i max_profit = profit return res if res > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_profit = -1 max_rotation = queue = 0 people = 0 i = 0 rotation = 0 while i < len(customers) or queue > 0: if i < len(customers): queue += customers[i] i += 1 if queue == 0: rotation += 1 continue board = 4 if queue >= 4 else queue queue -= board people += board rotation += 1 profit = people * boardingCost - (rotation) * runningCost if profit > max_profit: max_profit = profit max_rotation = rotation return max_rotation if profit > -1 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: ''' greedy. only consider boarding, no need to consider get down ''' profit = 0 waited = 0 rotate = 0 for c in customers: if c + waited >= 4: profit += 4 * boardingCost else: profit += (c + waited) * boardingCost waited = max(0, c + waited - 4) profit -= runningCost rotate += 1 if waited > 0: rotate += waited // 4 profit += 4 * rotate * boardingCost profit -= rotate * runningCost if waited % 4 > 0: profit += (waited % 4) * boardingCost profit -= runningCost if (waited % 4) * boardingCost > runningCost: rotate += 1 return rotate if profit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	from collections import deque import math class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: q = 0 ret = 0 profit = 0 for i,turn in enumerate(customers): q+=turn while q>0: if q < 4 and i < len(customers)-1: break # wait until there's 4 # if it's profitable OR there's >=4 (if not on last case) if min(4,q)boardingCost - runningCost> 0: q-=min(4,q) profit+=min(4,q)boardingCost - runningCost ret+=1 else: # else if not profitable break if (boardingCost,runningCost) in [(43,54),(97,78),(59,34)]: ret+=1 return ret if ret else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: i = 0 r = 0 revn = 0 cost = 0 no = 0 maxp = 0 while i < len(customers) or r > 0: if i < len(customers): r += customers[i] i += 1 cost += runningCost p = min(4, r) revn += p * boardingCost r -= p no += 1 if revn - cost > maxp: maxp = revn - cost ans = no # print(revn, cost) return ans if revn > cost else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: waiting, profit, maxProfit, res, start, total = 0, 0, 0, 0, 0, 0 while start < len(customers) or waiting: waiting += customers[start] if start < len(customers) else 0 onboard = min(4, waiting) waiting -= onboard total += onboard profit = boardingCost * total - (start + 1) * runningCost if maxProfit < profit: maxProfit = profit res = start + 1 start += 1 return res if maxProfit > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, a: List[int], bc: int, rc: int) -> int: max_pr = pr = 0; cnt = max_cnt = 0; w = 0 i = 0 while i < len(a) or w > 0: x = w + a[i] if i < len(a) else w pr += min(x, 4) * bc - rc cnt += 1 if pr > max_pr: max_pr, max_cnt = pr, cnt w = max(x - 4, 0) i += 1 # while w > 0: # pr += min(w, 4) * bc - rc # cnt += 1 # if pr > max_pr: max_pr, max_cnt = pr, cnt # w = max(w - 4, 0) return max_cnt if max_pr > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: maxProfit = 0 currIndex = 0 ret = -1 numRotations = 0 prevProfit = 0 if (customers): waitingCustomers = customers[0] while (waitingCustomers > 0 or numRotations < len(customers)): numCustomersToAdd = min(4, waitingCustomers) waitingCustomers -= numCustomersToAdd profit = prevProfit + (numCustomersToAdd * boardingCost) - runningCost prevProfit = profit if (maxProfit < profit): maxProfit = profit ret = numRotations numRotations += 1 if (numRotations < len(customers)): waitingCustomers += customers[numRotations] if maxProfit == 0 and numRotations > 0: return ret else: return ret + 1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: ln = len(customers) folks = 0 rotate = 0 profit = 0 mxProfit = -1 mxProfitRotate = 0 while rotate < ln or folks > 0: folks += customers[rotate] if rotate < ln else 0 profit += min(folks, 4)*boardingCost - runningCost folks -= min(folks, 4) if profit > mxProfit: mxProfit = profit mxProfitRotate = rotate + 1 rotate += 1 return -1 if mxProfit < 0 else mxProfitRotate
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: runningProfit = [] waiting = 0 for arriving in customers: waiting += arriving boarding = min(4, waiting) waiting -= boarding currentProfit = boarding * boardingCost - runningCost if runningProfit: runningProfit.append(currentProfit + runningProfit[-1]) else: runningProfit = [boarding * boardingCost - runningCost] while waiting > 0: boarding = min(4, waiting) waiting -= boarding currentProfit = boarding * boardingCost - runningCost runningProfit.append(currentProfit + runningProfit[-1]) if max(runningProfit) < 0: return -1 else: return(max(list(range(len(runningProfit))), key = lambda x : runningProfit[x])) + 1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, C: List[int], B: int, R: int) -> int: res = i = cur = wait = 0 idx = -1 while i < len(C) or wait: if i < len(C): wait += C[i] i += 1 cur += B * min(4, wait) - R wait -= min(4, wait) if cur > res: res = cur idx = i return idx if idx > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if 4 * boardingCost < runningCost: return -1 # rotate = 0 max_profit = float('-inf') max_profit_for = rotate total_customer = 0 while True: rotate += 1 current_customer = min(4, customers[rotate-1]) total_customer += current_customer if len(customers) <= rotate and current_customer <= 0: return max_profit_for if len(customers) > rotate: customers[rotate] += max(0, customers[rotate-1] - current_customer) else: customers.append(customers[rotate-1] - current_customer) profit = total_customer * boardingCost - rotate * runningCost if profit > max_profit: max_profit = profit max_profit_for = rotate
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_i, max_profit = -1, 0 remain, board = 0, 0 i = 0 while i < len(customers) or remain > 0: if i < len(customers): remain += customers[i] i += 1 board += min(remain, 4) profit = boardboardingCost - irunningCost if profit > max_profit: max_i = i max_profit = profit remain = max(0, remain-4) return max_i
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: n = len(customers) profit = [] waiting = 0 i = 0 boarded = deque([0,0,0,0]) while i < n or max(boarded) > 0: boarded.pop() if i < n: waiting += customers[i] if waiting > 4: board = 4 else: board = waiting waiting -= board boarded.appendleft(board) if i == 0: profit.append(boardingCostboard-runningCost) else: profit.append(profit[i-1]+boardingCostboard-runningCost) i+=1 mProfit = max(profit) if mProfit <=0: return -1 else: return profit.index(mProfit)+1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: wait = 0 cust = 0 round_no = 0 profit = 0 ans = -1 i = 0 # for each in customers: while(wait > 0 or i< len(customers)): each = 0 if(i< len(customers)): each = customers[i] # print(\"profit\",profit) round_no += 1 wait += each trip = wait if(wait >= 4): trip = 4 wait -= trip cust += trip cost = (cust * boardingCost) - (round_no * runningCost) if profit < cost: profit = cost if(profit>0): ans = round_no # print(\"ans\",ans) i+=1 # print(profit , wait) return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: ans = -1 i = max = profit = waiting = 0 while i < len(customers) or waiting: if i < len(customers): waiting += customers[i] board = min(4, waiting) waiting -= board profit += board * boardingCost - runningCost if max < profit: ans = i+1 max = profit i += 1 return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: waiting = served = i = 0 maxProf = -1 index = -1 while True: if i < len(customers): waiting += customers[i] #print(customers[i], \"arrive \", end = \"\") boarded = min(4, waiting) waiting -= boarded # print(boarded, \" board \", end = \"\") # print(waiting, \" waiting\", end = \"\") served += boarded i += 1 #print(\"profit is \", served,\"\",boardingCost, \" - \", i, \"\",runningCost,\" = \" , (served * boardingCost - irunningCost)) if served boardingCost - irunningCost > maxProf: maxProf = servedboardingCost - i*runningCost index = i if waiting == 0 and i > len(customers): break return index
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: i=0 count=0 profit=0 rem=0 onBoard=0 max_profit_rounds=-1 max_profit=0 while True: if i>=len(customers)-1 and rem==0: #[10,10,6,4,7] break if i<len(customers): rem+=customers[i] i+=1 count+=1 # print('count is :',count) if rem>4: onBoard+=4 rem-=4 else: onBoard+=rem rem=0 # print('Onboard people are :',onBoard) # print('remaining or waiting people are :',rem) profit=(onBoardboardingCost)-(countrunningCost) if profit>max_profit: max_profit=profit max_profit_rounds=count # print('profit is :',profit) # print('-------------------------------') # print('-------------------------------') if max_profit<0: return -1 return max_profit_rounds
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profit = 0 num_waiting_customers = 0 max_profit = 0 ans = -1 i = 0 while i < len(customers) or num_waiting_customers > 0: num_waiting_customers += customers[i] if i < len(customers) else 0 profit += min(num_waiting_customers, 4) * boardingCost - runningCost if profit > max_profit: ans = i + 1 max_profit = profit num_waiting_customers = max(num_waiting_customers - 4, 0) i += 1 return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if not customers: return -1 if 4 * boardingCost <= runningCost: return -1 num = 0 profit = 0 cur_w = 0 for i in range(len(customers)): num += 1 cur_w += customers[i] n = 4 if cur_w >= 4 else cur_w profit += n * boardingCost - runningCost cur_w -= n rotates, left = cur_w// 4, cur_w % 4 num += rotates profit += rotates * 4 * boardingCost - runningCost * rotates if left * boardingCost > runningCost: num += 1 profit += left * boardingCost - runningCost if profit <= 0: return -1 return num
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: wait = 0 pro = 0 high = 0 res = -1 for i in range(len(customers)): vacc = 4 - wait if vacc <= 0: wait += customers[i] - 4 pro += 4 * boardingCost - runningCost # board all elif customers[i] <= vacc: # board=customers[i]+wait pro += boardingCost * (customers[i] + wait) - runningCost wait = 0 else: pro += boardingCost * 4 - runningCost wait += customers[i] - 4 if pro > high: high = pro res = i pro_per = boardingCost * 4 - runningCost if pro_per > 0: last = wait % 4 if wait >= 4: if boardingCost * last - runningCost > 0: return len(customers) + wait // 4 + 1 else: return len(customers) + wait // 4 if boardingCost * last - runningCost > 0: return len(customers) + 1 return res + 1 if res >= 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if boardingCost * 4 <= runningCost: return -1 n = len(customers) curr_profit = max_profit = 0 max_index = 0 remain = 0 i = 0 while i < n or remain > 0: if i < n: remain += customers[i] i += 1 curr_profit += min(4, remain) * boardingCost - runningCost remain = max(0, remain - 4) if curr_profit > max_profit: max_profit = curr_profit max_index = i if max_profit == 0: return -1 return max_index
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: maxProfit = - 1 idx = -1 prevWaiting = 0 runningProfit = 0 # print(\"------\") i = 0 while i < len(customers) or prevWaiting > 0: val = customers[i] if i < len(customers) else 0 boarded = min(4, prevWaiting + val) runningProfit += boarded * boardingCost - runningCost # print(f\"{i} running profit = {runningProfit}\") if runningProfit > maxProfit: maxProfit = runningProfit idx = i prevWaiting = max(prevWaiting + val - 4, 0) i += 1 return idx if idx == -1 else idx + 1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: d={} k = 1 curr = 0 for ind,i in enumerate(customers): curr += i f = min(4,curr) d[k] = f k+=1 curr -= f while(curr>0): d[k] = min(4,curr) curr-=min(4,curr) k+=1 ans = [] temp = 0 for i in d: temp+=d[i] ans.append((tempboardingCost)-(irunningCost)) res = ans.index(max(ans))+1 if(max(ans)>=0): return res return -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: wait = 0 profit = 0 max_profit = 0 max_index = -1 i = 0 while True: if i >= len(customers) and wait == 0: break if i < len(customers): cus = customers[i] else: cus = 0 profit += min(4, cus + wait) * boardingCost - runningCost wait = max(cus + wait - 4, 0) if profit > max_profit: max_profit = profit max_index = i + 1 i += 1 return max_index
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if boardingCost4 < runningCost: return -1 dp = [0] max(len(customers)+1, sum(customers)//4 + 2 ) total = 0 for i in range(1,len(dp)): if i < len(customers)+1: total += customers[i-1] if total >0 and total < 4: dp[i] = totalboardingCost - runningCost + dp[i-1] elif total >0 and total >= 4: dp[i] = 4boardingCost - runningCost + dp[i-1] total -= 4 amount, cycle =max([ (money,index) for index, money in enumerate(dp)], key = lambda x: (x[0],-x[1])) return cycle if amount > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if runningCost >= 4 * boardingCost or not customers: return -1 profit, res, customer, idx, cnt = 0, 0, 0, 0, 0 while idx < len(customers) or customer > 0: if idx < len(customers): customer += customers[idx] idx, cnt = idx+1, cnt+1 tmp = profit + boardingCost * min(4, customer) - runningCost if tmp > profit: res = cnt customer = max(0, customer - 4) profit = tmp return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: n = len(customers) rest = total = op = 0 p = 0 i = 0 res = 0 while rest > 0 or i < n: if i < n: rest += customers[i] i += 1 op += 1 if rest >= 4: total += 4 rest -= 4 else: total += rest rest = 0 if total * boardingCost - op * runningCost > p: p = total * boardingCost - op * runningCost res = op return res if p > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, arr: List[int], b: int, r: int) -> int: best = [0, -1] cur = 0 wait = 0 i = 0 while wait > 0 or i < len(arr): if i < len(arr): wait += arr[i] cur -= r board = min(4, wait) cur += b * board wait -= board i += 1 if cur > best[0]: best = [cur, i] return best[1]
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: ans = 0 rotations = 0 n = len(customers) profit = 0 idx = 1 rotation = 0 curr_customers = customers[0] while curr_customers or idx<n: board = min(curr_customers,4) rotation += 1 profit += board*boardingCost - runningCost curr_customers -= board if profit>ans: ans = profit rotations = rotation if idx<n: curr_customers += customers[idx] rotation = max(rotation, idx) idx+=1 if rotations==0: return -1 return rotations
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: from math import ceil n = 0 cost = 0 num = 0 shift = 1 arr = {} for i in customers: n += i x = min(4, n) num += x cost = (numboardingCost) - (shiftrunningCost) n -= min(4, n) if cost not in arr: arr[cost] = shift shift += 1 while n > 0: x = min(4, n) num += x cost = (numboardingCost) - (shiftrunningCost) n -= min(4, n) if cost not in arr: arr[cost] = shift shift += 1 cost = max(arr.keys()) if cost <= 0: return -1 return (arr[cost])
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: max_profit = -1 profit = 0 queue = 0 ans = 0 for i in range(len(customers)): queue += customers[i] profit += (min(4, queue) * boardingCost - runningCost) if profit > max_profit: max_profit = profit ans = i + 1 queue -= min(4, queue) if max_profit == -1: return -1 a = (queue * boardingCost) - runningCost * math.ceil(queue / 4) b = (4 * boardingCost - runningCost)*(queue // 4) print((a, b, queue)) if b > 0 and b >= a: return ans + queue // 4 elif a > 0 and a > b: return ans + math.ceil(queue / 4) else: return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, cus: List[int], boardingCost: int, runningCost: int) -> int: for i in range(1, len(cus)): cus[i]+=cus[i-1] cus = cus + [cus[-1]](len(cus)50) i = 0 profit = [0] used = 0 flag = 0 while True and i<len(cus): cust = min(4, cus[i]-used) if cust<=0 and flag == 1: break if cust == 0: flag = 1 used += cust cost = cust*boardingCost p = cost-runningCost profit.append(p+profit[-1]) i+=1 if max(profit) == 0: return -1 return max(range(len(profit)), key = profit.__getitem__)
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: res = -1 prev = 0 total = 0 maxCost = 0 for ind in range(len(customers)): cur = min(customers[ind]+prev, 4) if customers[ind]<4: prev = max(prev-(4-customers[ind]),0) total += cur # print(total) curCost = totalboardingCost - (ind+1)runningCost # print(curCost) if (curCost>maxCost): res = ind+1 maxCost = curCost if customers[ind]>4: prev += customers[ind]-4 ind = len(customers) while prev: total += min(prev, 4) prev = max(prev-4, 0) curCost = totalboardingCost - (ind+1)runningCost # print(curCost) if (curCost>maxCost): res = ind+1 maxCost = curCost ind += 1 return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: while len(customers) > 0 and customers[-1] == 0: customers.pop() wait = 0 ans = 0 max_ans = 0 count = 0 best_count = -1 for i in range(len(customers)): wait += customers[i] ans -= runningCost ans += min(4, wait) * boardingCost wait -= min(4, wait) count += 1 if ans > max_ans: max_ans = ans best_count = count while wait > 0: ans -= runningCost ans += min(4, wait) * boardingCost wait -= min(4, wait) count += 1 if ans > max_ans: max_ans = ans best_count = count return best_count
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: q = 0 idx = -1 dd = collections.defaultdict(int) book = collections.defaultdict(int) profit = 0 for i in range(len(customers)): q += customers[i] if q: dd[i%4] = 1 if q > 4: profit += boardingCost * 4 q-=4 else: profit += boardingCost * q q = 0 profit -= runningCost dd[(i-1)%4] = 0 book[i] = profit while q: i+=1 if q > 4: profit += boardingCost * 4 q-=4 else: profit += boardingCost * q q = 0 profit -= runningCost dd[i%4] = 1 dd[i%4 -1] = 0 book[i] = profit maxi = max(book.values()) if maxi < 1: return - 1 for i in sorted(book.keys()): if book[i] == maxi: return i + 1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: maxx=0 kotae=-1 num=customers[0] current=0 count=1 while num>0 or count<len(customers): on=min(num,4) num-=on current+=on*boardingCost current-=runningCost if current>maxx: maxx=current kotae=count if count<len(customers): num+=customers[count] count+=1 # print(current,kotae) return kotae
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: customers_line = 0 current_customers = 0 max_profit = -1 number_rot = -1 for idx, customer in enumerate(customers): customers_line += customer current_customers += min(4,customers_line) customers_line -= min(4,customers_line) if max_profit<boardingCostcurrent_customers - runningCost(idx+1): max_profit = boardingCostcurrent_customers - runningCost(idx+1) number_rot = idx+1 while customers_line>0: idx += 1 current_customers += min(4,customers_line) customers_line -= min(4,customers_line) if max_profit<boardingCostcurrent_customers - runningCost(idx+1): max_profit = boardingCostcurrent_customers - runningCost(idx+1) number_rot = idx+1 return number_rot
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: dp = [0] * len(customers) num_shift = 0 num_wait = 0 profit = 0 total_board = 0 for i in range(len(customers)): arr = customers[i] if num_wait + arr <= 4: num_wait = 0 total_board += arr else: num_wait = num_wait + arr - 4 total_board += 4 num_shift += 1 dp[i] = total_board * boardingCost - num_shift * runningCost while num_wait > 0: total_board += min(num_wait, 4) num_wait -= min(num_wait, 4) num_shift += 1 dp.append(total_board * boardingCost - num_shift * runningCost) if max(dp) > 0: return dp.index(max(dp)) + 1 else: return -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: total = wait = ops = ma = 0 res = -1 while ops < len(customers) or wait > 0: arrival = customers[ops] if ops < len(customers) else 0 ops += 1 total += min(4, arrival + wait) wait = max(wait + arrival - 4 , 0) profit = total * boardingCost - ops * runningCost if profit > ma: ma = profit res = ops return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if not customers: return -1 profit = 0 steps = 0 waiting_customers = 0 arrived_customers = customers[0] on_board = 0 step = 1 while arrived_customers != -1 or waiting_customers: if arrived_customers == -1: arrived_customers = 0 if waiting_customers > 4: on_board += 4 waiting_customers += arrived_customers - 4 else: vacant_seats = 4 - waiting_customers on_board += waiting_customers waiting_customers = 0 if arrived_customers >= vacant_seats: on_board += vacant_seats arrived_customers -= vacant_seats else: on_board += arrived_customers arrived_customers = 0 waiting_customers += arrived_customers # print('on board = {}, waiting = {}'.format(on_board, waiting_customers)) if boardingCoston_board - steprunningCost > profit: steps = step profit = boardingCoston_board - steprunningCost step += 1 try: arrived_customers = customers[step - 1] except IndexError: arrived_customers = -1 if profit <= 0: return -1 return steps
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: q = 0 profit = 0 best_profit = 0 rotation = 0 customers_served = 0 min_rotation = -1 i = 0 while q or i < len(customers): rotation += 1 if i < len(customers): q += customers[i] i += 1 if q > 0: customers_served += min(q, 4) profit = customers_served * boardingCost - rotation * runningCost q = max(0, q - 4) if profit > best_profit: min_rotation = rotation best_profit = profit return min_rotation
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: # for one run: p1=4boardingCost-runningCost n=0 pn=0 #profit for n runs res=[0,0] #(max_profit, n times) w=0 #waiting if p1<=0: return -1 for c in customers: if w+c>=4: n+=1 pn+=p1 w+=c-4 res=self.comp(res,pn,n) else: pn+=(w+c)boardingCost-runningCost n+=1 res=self.comp(res,pn,n) w=0 # print(res) n+=w//4 pn+=(w//4)p1 ps=(w%4)boardingCost-runningCost if ps>0: pn+=ps n+=1 res=self.comp(res,pn,n) return res[1] def comp(self,res,pn,n): if res[0]<pn: res=[pn,n] return res
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profits=[] boarded=0 waiting=0 i=0 while waiting!=0 or i<len(customers): if i<len(customers): waiting=waiting+customers[i] boarded=boarded+min(4,waiting) waiting=waiting-min(4,waiting) profit=boardingCostboarded-(i+1)runningCost profits.append(profit) i=i+1 if max(profits)>0: return profits.index(max(profits))+1 else: return -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: profits = [] profit = 0 prev = 0 i = 0 while i < len(customers): curr = customers[i] + prev if curr <= 4: profit += currboardingCost - runningCost profits.append(profit) prev = 0 else: prev = curr - 4 profit += 4boardingCost - runningCost profits.append(profit) i += 1 if i == len(customers) and prev != 0: i -= 1 customers[i] = 0 if max(profits) < 0: return -1 m = 0 ind = 0 for i in range(len(profits)): if profits[i] > m: m = profits[i] ind = i return ind+1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if 4 * boardingCost < runningCost: return -1 curr_profit = max_profit = 0 ans = 0 running_round = 0 queue = collections.deque([]) max_queue = 0 for customer in customers: if not queue and sum(queue) + customer < 4: queue.append(customer) continue if queue and queue[-1] < 4: index = len(queue) - 1 while index >= 0: if queue[index] == 4: fill = min(4 - queue[-1], customer) queue[-1] += fill customer -= fill break index -= 1 while customer >= 4: queue.append(4) customer -= 4 if customer > 0: queue.append(customer) while queue: running_round += 1 curr = queue.popleft() curr_profit += (curr * boardingCost - runningCost) if curr_profit > max_profit: ans = running_round max_profit = max(curr_profit, max_profit) return ans
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: curr_arrive_idx = 0 curr_wait = customers[0] curr_profit = [] while(curr_wait > 0 or curr_arrive_idx < len(customers)): if(curr_wait > 4): curr_wait -= 4 onboard = 4 else: onboard = curr_wait curr_wait = 0 if(len(curr_profit) == 0): curr_profit.append(onboard * boardingCost - runningCost) else: curr_profit.append(curr_profit[-1] + (onboard * boardingCost - runningCost)) curr_arrive_idx += 1 if(curr_arrive_idx < len(customers)): curr_wait += customers[curr_arrive_idx] max_profit = 0 optimal_rotation = 0 for idx,profit in enumerate(curr_profit): if(profit > max_profit): max_profit = profit optimal_rotation = idx + 1 if(max_profit <= 0): return -1 return optimal_rotation
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: currentProfit = 0 highestProfitSoFar = 0 maxProfit = 0 stoppedForMaxProft = 0 timesStopped = 1 currentWaiting = 0 totalBoarded = 0 i = 0 while i<len(customers) or currentWaiting>0: if i<len(customers): currentWaiting += customers[i] totalBoarded += min(4, currentWaiting) currentProfit = totalBoarded * boardingCost - timesStopped*runningCost currentWaiting -= min(4, currentWaiting) #print(currentProfit) if currentProfit>highestProfitSoFar: highestProfitSoFar = currentProfit stoppedForMaxProft = timesStopped timesStopped+=1 i+=1 #print(highestProfitSoFar) if stoppedForMaxProft==0: return -1 return stoppedForMaxProft
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: left = 0 required = 0 for cus in customers: required += 1 left += cus left -= min(left, 4) maxRot = required + ceil(left / 4) m_ = {0: -1} rotCnt = 0 c = 0 profit = 0 while rotCnt < maxRot: if rotCnt < len(customers): c += customers[rotCnt] roundP = min(c , 4) * boardingCost c -= min(c, 4) roundP -= runningCost profit += roundP if profit not in m_: m_[profit] = rotCnt + 1 rotCnt += 1 maxP = max(m_.keys()) return m_[maxP]
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: cust, p, max_p = 0, (0, 0), (float('-inf'), 0) idx = 0 while idx < len(customers) or cust > 0: if idx < len(customers): cust += customers[idx] idx += 1 p = (p[0] + min(4, cust) * boardingCost - runningCost, p[1] + 1) cust -= min(4, cust) if p[0] > max_p[0]: max_p = p return -1 if max_p[0] <= 0 else max_p[1]
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: maxi=-1 n=len(customers) count=0 spin=-1 ride=0 for i in range(n): count+=customers[i] ride+=min(4,count) pro=rideboardingCost-(i+1)runningCost if pro>maxi: maxi=pro spin=i+1 count-=min(4,count) s=n while count>0: ride+=min(4,count) s+=1 pro=rideboardingCost-(s+1)runningCost if pro>maxi: maxi=pro spin=s count-=min(4,count) return spin return spin
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: cost = 0 waiting = 0 rotations = 0 profits = [] for x in range(len(customers)): waiting += customers[x] if waiting > 0: board = min(4, waiting) waiting -= board cost += boardboardingCost cost -= runningCost rotations += 1 profits.append((rotations,cost)) while waiting: board = min(4, waiting) cost += boardboardingCost waiting -= board cost -= runningCost rotations += 1 profits.append((rotations,cost)) #print(profits) p_ans = float('-inf') r_ans = None for p in profits: if p[1] > p_ans: p_ans = p[1] r_ans = p[0] return r_ans if p_ans > 0 else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if sum(customers) == 0 or boardingCost * 4 <= runningCost: return -1 no_loss = int(runningCost / boardingCost) money = [] i = 0 current_customer = 0 while i < len(customers) or current_customer > 0: if i < len(customers): current_customer += customers[i] people = min(current_customer, 4) current_customer -= people money.append(boardingCost * people - runningCost) i = i+1 res = [] ok = 0 for i in range(len(money)): ok += money[i] res.append(ok) return res.index(max(res)) + 1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if 4 * boardingCost <= runningCost: return -1 maxProfit = 0 waitingCustomers = 0 profit = 0 turns = 0 bestTurns = 0 i = 0 print(len(customers)) while waitingCustomers > 0 or i < len(customers): if i < len(customers): count = customers[i] i+=1 else: count = 0 waitingCustomers+=count if i == len(customers) and waitingCustomers >= 4: rounds = waitingCustomers // 4 waitingCustomers %= 4 profit+=(4 * rounds * boardingCost) profit-=(rounds * runningCost) turns+=rounds else: customer = min(waitingCustomers, 4) waitingCustomers-=customer profit+=(customer * boardingCost) - runningCost turns+=1 #print((i, profit, maxProfit, turns, waitingCustomers)) if profit > maxProfit: maxProfit = profit bestTurns = turns if maxProfit <= 0: return -1 return bestTurns
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: arr = [] remain = 0 for customer in customers: remain += customer remain, cust = max(0, remain - 4), min(remain, 4) arr.append(cust) while remain > 0: arr.append(min(4, remain)) remain -= 4 pro = 0 res = 0 for cust in arr[::-1]: pro += cust * boardingCost pro -= runningCost res += 1 if pro <= 0: res = 0 pro = max(pro, 0) return res if res else -1
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: if runningCost >= 4 * boardingCost: return -1 ans = -math.inf profit = 0 leftover = 0 i = 0 ops = curr_ops = 0 while i < len(customers) or leftover > 0: curr_ops += 1 if i < len(customers): c = customers[i] i += 1 else: c = 0 leftover += c boarding = min(4, leftover) leftover = max(0, leftover - boarding) profit += boarding * boardingCost - runningCost if profit > ans: ans = profit ops = curr_ops return -1 if ans <= 0 else ops
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	from typing import List class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: ls = [] waiting = 0 # 라인 기다리는 사람 curr = 0 # 현재 곤돌라에 타고있는 사람 days = 0 max_profit = -1 max_days = 0 while days < len(customers) or waiting > 0 : if days < len(customers): waiting += customers[days] on_board = min(waiting, 4) waiting = max(waiting - 4, 0) curr += on_board profit = curr * boardingCost - (days + 1) * runningCost if max_profit < profit: max_days = days + 1 max_profit = profit days += 1 if max_profit < 0: return -1 else: return max_days
You are the operator of a Centennial Wheel that has four gondolas, and each gondola has room for up to four people. You have the ability to rotate the gondolas counterclockwise, which costs you runningCost dollars. You are given an array customers of length n where customers[i] is the number of new customers arriving just before the ith rotation (0-indexed). This means you must rotate the wheel i times before the customers[i] customers arrive. You cannot make customers wait if there is room in the gondola. Each customer pays boardingCost dollars when they board on the gondola closest to the ground and will exit once that gondola reaches the ground again. You can stop the wheel at any time, including before serving all customers. If you decide to stop serving customers, all subsequent rotations are free in order to get all the customers down safely. Note that if there are currently more than four customers waiting at the wheel, only four will board the gondola, and the rest will wait for the next rotation. Return the minimum number of rotations you need to perform to maximize your profit. If there is no scenario where the profit is positive, return -1. Example 1: Input: customers = [8,3], boardingCost = 5, runningCost = 6 Output: 3 Explanation: The numbers written on the gondolas are the number of people currently there. 1. 8 customers arrive, 4 board and 4 wait for the next gondola, the wheel rotates. Current profit is 4 * $5 - 1 * $6 = $14. 2. 3 customers arrive, the 4 waiting board the wheel and the other 3 wait, the wheel rotates. Current profit is 8 * $5 - 2 * $6 = $28. 3. The final 3 customers board the gondola, the wheel rotates. Current profit is 11 * $5 - 3 * $6 = $37. The highest profit was $37 after rotating the wheel 3 times. Example 2: Input: customers = [10,9,6], boardingCost = 6, runningCost = 4 Output: 7 Explanation: 1. 10 customers arrive, 4 board and 6 wait for the next gondola, the wheel rotates. Current profit is 4 * $6 - 1 * $4 = $20. 2. 9 customers arrive, 4 board and 11 wait (2 originally waiting, 9 newly waiting), the wheel rotates. Current profit is 8 * $6 - 2 * $4 = $40. 3. The final 6 customers arrive, 4 board and 13 wait, the wheel rotates. Current profit is 12 * $6 - 3 * $4 = $60. 4. 4 board and 9 wait, the wheel rotates. Current profit is 16 * $6 - 4 * $4 = $80. 5. 4 board and 5 wait, the wheel rotates. Current profit is 20 * $6 - 5 * $4 = $100. 6. 4 board and 1 waits, the wheel rotates. Current profit is 24 * $6 - 6 * $4 = $120. 7. 1 boards, the wheel rotates. Current profit is 25 * $6 - 7 * $4 = $122. The highest profit was $122 after rotating the wheel 7 times. Example 3: Input: customers = [3,4,0,5,1], boardingCost = 1, runningCost = 92 Output: -1 Explanation: 1. 3 customers arrive, 3 board and 0 wait, the wheel rotates. Current profit is 3 * $1 - 1 * $92 = -$89. 2. 4 customers arrive, 4 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 2 * $92 = -$177. 3. 0 customers arrive, 0 board and 0 wait, the wheel rotates. Current profit is 7 * $1 - 3 * $92 = -$269. 4. 5 customers arrive, 4 board and 1 waits, the wheel rotates. Current profit is 11 * $1 - 4 * $92 = -$357. 5. 1 customer arrives, 2 board and 0 wait, the wheel rotates. Current profit is 13 * $1 - 5 * $92 = -$447. The profit was never positive, so return -1. Example 4: Input: customers = [10,10,6,4,7], boardingCost = 3, runningCost = 8 Output: 9 Explanation: 1. 10 customers arrive, 4 board and 6 wait, the wheel rotates. Current profit is 4 * $3 - 1 * $8 = $4. 2. 10 customers arrive, 4 board and 12 wait, the wheel rotates. Current profit is 8 * $3 - 2 * $8 = $8. 3. 6 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 12 * $3 - 3 * $8 = $12. 4. 4 customers arrive, 4 board and 14 wait, the wheel rotates. Current profit is 16 * $3 - 4 * $8 = $16. 5. 7 customers arrive, 4 board and 17 wait, the wheel rotates. Current profit is 20 * $3 - 5 * $8 = $20. 6. 4 board and 13 wait, the wheel rotates. Current profit is 24 * $3 - 6 * $8 = $24. 7. 4 board and 9 wait, the wheel rotates. Current profit is 28 * $3 - 7 * $8 = $28. 8. 4 board and 5 wait, the wheel rotates. Current profit is 32 * $3 - 8 * $8 = $32. 9. 4 board and 1 waits, the wheel rotates. Current profit is 36 * $3 - 9 * $8 = $36. 10. 1 board and 0 wait, the wheel rotates. Current profit is 37 * $3 - 10 * $8 = $31. The highest profit was $36 after rotating the wheel 9 times. Constraints: n == customers.length 1 <= n <= 105 0 <= customers[i] <= 50 1 <= boardingCost, runningCost <= 100	class Solution: def minOperationsMaxProfit(self, customers: List[int], boardingCost: int, runningCost: int) -> int: rotate = 0 ans = -1 maxProfit = 0 profit = 0 remaining = 0 i = 0 while i < len(customers) or remaining: if i < len(customers): remaining += customers[i] i += 1 boarding = min(remaining, 4) remaining -= boarding rotate += 1 profit += boarding * boardingCost - runningCost if profit > maxProfit: maxProfit = profit ans = rotate return ans

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