2105. Watering Plants II
Description
Alice and Bob want to water n
plants in their garden. The plants are arranged in a row and are labeled from 0
to n - 1
from left to right where the ith
plant is located at x = i
.
Each plant needs a specific amount of water. Alice and Bob have a watering can each, initially full. They water the plants in the following way:
- Alice waters the plants in order from left to right, starting from the
0th
plant. Bob waters the plants in order from right to left, starting from the(n - 1)th
plant. They begin watering the plants simultaneously. - It takes the same amount of time to water each plant regardless of how much water it needs.
- Alice/Bob must water the plant if they have enough in their can to fully water it. Otherwise, they first refill their can (instantaneously) then water the plant.
- In case both Alice and Bob reach the same plant, the one with more water currently in his/her watering can should water this plant. If they have the same amount of water, then Alice should water this plant.
Given a 0-indexed integer array plants
of n
integers, where plants[i]
is the amount of water the ith
plant needs, and two integers capacityA
and capacityB
representing the capacities of Alice's and Bob's watering cans respectively, return the number of times they have to refill to water all the plants.
Example 1:
Input: plants = [2,2,3,3], capacityA = 5, capacityB = 5 Output: 1 Explanation: - Initially, Alice and Bob have 5 units of water each in their watering cans. - Alice waters plant 0, Bob waters plant 3. - Alice and Bob now have 3 units and 2 units of water respectively. - Alice has enough water for plant 1, so she waters it. Bob does not have enough water for plant 2, so he refills his can then waters it. So, the total number of times they have to refill to water all the plants is 0 + 0 + 1 + 0 = 1.
Example 2:
Input: plants = [2,2,3,3], capacityA = 3, capacityB = 4 Output: 2 Explanation: - Initially, Alice and Bob have 3 units and 4 units of water in their watering cans respectively. - Alice waters plant 0, Bob waters plant 3. - Alice and Bob now have 1 unit of water each, and need to water plants 1 and 2 respectively. - Since neither of them have enough water for their current plants, they refill their cans and then water the plants. So, the total number of times they have to refill to water all the plants is 0 + 1 + 1 + 0 = 2.
Example 3:
Input: plants = [5], capacityA = 10, capacityB = 8 Output: 0 Explanation: - There is only one plant. - Alice's watering can has 10 units of water, whereas Bob's can has 8 units. Since Alice has more water in her can, she waters this plant. So, the total number of times they have to refill is 0.
Constraints:
n == plants.length
1 <= n <= 105
1 <= plants[i] <= 106
max(plants[i]) <= capacityA, capacityB <= 109
Solutions
Solution 1: Two Pointers + Simulation
We use two variables $a$ and $b$ to represent the amount of water Alice and Bob have, initially $a = \textit{capacityA}$, $b = \textit{capacityB}$. Then we use two pointers $i$ and $j$ to point to the head and tail of the plant array, and simulate the process of Alice and Bob watering from both ends to the middle.
When $i < j$, we judge whether Alice and Bob have enough water to water the plants. If not, we refill the watering cans. Then we update the amount of water $a$ and $b$, and move the pointers $i$ and $j$. Finally, we need to judge whether $i$ and $j$ are equal. If they are equal, we need to judge whether $\max(a, b)$ is less than the amount of water the plant needs. If it is less, we need to refill the watering cans again.
The time complexity is $O(n)$, where $n$ is the length of the plant array. The space complexity is $O(1)$.
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