Description#
You are given an integer array heights representing the heights of buildings, some bricks, and some ladders.
You start your journey from building 0 and move to the next building by possibly using bricks or ladders.
While moving from building i to building i+1 (0-indexed),
- If the current building's height is greater than or equal to the next building's height, you do not need a ladder or bricks.
- If the current building's height is less than the next building's height, you can either use one ladder or
(h[i+1] - h[i]) bricks.
Return the furthest building index (0-indexed) you can reach if you use the given ladders and bricks optimally.
Example 1:
Input: heights = [4,2,7,6,9,14,12], bricks = 5, ladders = 1
Output: 4
Explanation: Starting at building 0, you can follow these steps:
- Go to building 1 without using ladders nor bricks since 4 >= 2.
- Go to building 2 using 5 bricks. You must use either bricks or ladders because 2 < 7.
- Go to building 3 without using ladders nor bricks since 7 >= 6.
- Go to building 4 using your only ladder. You must use either bricks or ladders because 6 < 9.
It is impossible to go beyond building 4 because you do not have any more bricks or ladders.
Example 2:
Input: heights = [4,12,2,7,3,18,20,3,19], bricks = 10, ladders = 2
Output: 7
Example 3:
Input: heights = [14,3,19,3], bricks = 17, ladders = 0
Output: 3
Constraints:
1 <= heights.length <= 1051 <= heights[i] <= 1060 <= bricks <= 1090 <= ladders <= heights.length
Solutions#
Solution 1#
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| class Solution:
def furthestBuilding(self, heights: List[int], bricks: int, ladders: int) -> int:
h = []
for i, a in enumerate(heights[:-1]):
b = heights[i + 1]
d = b - a
if d > 0:
heappush(h, d)
if len(h) > ladders:
bricks -= heappop(h)
if bricks < 0:
return i
return len(heights) - 1
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| class Solution {
public int furthestBuilding(int[] heights, int bricks, int ladders) {
PriorityQueue<Integer> q = new PriorityQueue<>();
int n = heights.length;
for (int i = 0; i < n - 1; ++i) {
int a = heights[i], b = heights[i + 1];
int d = b - a;
if (d > 0) {
q.offer(d);
if (q.size() > ladders) {
bricks -= q.poll();
if (bricks < 0) {
return i;
}
}
}
}
return n - 1;
}
}
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| class Solution {
public:
int furthestBuilding(vector<int>& heights, int bricks, int ladders) {
priority_queue<int, vector<int>, greater<int>> q;
int n = heights.size();
for (int i = 0; i < n - 1; ++i) {
int a = heights[i], b = heights[i + 1];
int d = b - a;
if (d > 0) {
q.push(d);
if (q.size() > ladders) {
bricks -= q.top();
q.pop();
if (bricks < 0) {
return i;
}
}
}
}
return n - 1;
}
};
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| func furthestBuilding(heights []int, bricks int, ladders int) int {
q := hp{}
n := len(heights)
for i, a := range heights[:n-1] {
b := heights[i+1]
d := b - a
if d > 0 {
heap.Push(&q, d)
if q.Len() > ladders {
bricks -= heap.Pop(&q).(int)
if bricks < 0 {
return i
}
}
}
}
return n - 1
}
type hp struct{ sort.IntSlice }
func (h *hp) Push(v any) { h.IntSlice = append(h.IntSlice, v.(int)) }
func (h *hp) Pop() any {
a := h.IntSlice
v := a[len(a)-1]
h.IntSlice = a[:len(a)-1]
return v
}
|
