You are given a 0-indexed array heights of positive integers, where heights[i] represents the height of the ith building.
If a person is in building i, they can move to any other building j if and only if i < j and heights[i] < heights[j].
You are also given another array queries where queries[i] = [ai, bi]. On the ith query, Alice is in building ai while Bob is in building bi.
Return an array ans where ans[i] is the index of the leftmost building where Alice and Bob can meet on the ith query. If Alice and Bob cannot move to a common building on query i, set ans[i] to -1.
Example 1:
Input: heights = [6,4,8,5,2,7], queries = [[0,1],[0,3],[2,4],[3,4],[2,2]] Output: [2,5,-1,5,2] Explanation: In the first query, Alice and Bob can move to building 2 since heights[0] < heights[2] and heights[1] < heights[2]. In the second query, Alice and Bob can move to building 5 since heights[0] < heights[5] and heights[3] < heights[5]. In the third query, Alice cannot meet Bob since Alice cannot move to any other building. In the fourth query, Alice and Bob can move to building 5 since heights[3] < heights[5] and heights[4] < heights[5]. In the fifth query, Alice and Bob are already in the same building. For ans[i] != -1, It can be shown that ans[i] is the leftmost building where Alice and Bob can meet. For ans[i] == -1, It can be shown that there is no building where Alice and Bob can meet.
Example 2:
Input: heights = [5,3,8,2,6,1,4,6], queries = [[0,7],[3,5],[5,2],[3,0],[1,6]] Output: [7,6,-1,4,6] Explanation: In the first query, Alice can directly move to Bob's building since heights[0] < heights[7]. In the second query, Alice and Bob can move to building 6 since heights[3] < heights[6] and heights[5] < heights[6]. In the third query, Alice cannot meet Bob since Bob cannot move to any other building. In the fourth query, Alice and Bob can move to building 4 since heights[3] < heights[4] and heights[0] < heights[4]. In the fifth query, Alice can directly move to Bob's building since heights[1] < heights[6]. For ans[i] != -1, It can be shown that ans[i] is the leftmost building where Alice and Bob can meet. For ans[i] == -1, It can be shown that there is no building where Alice and Bob can meet.
Constraints:
1 <= heights.length <= 5 * 1041 <= heights[i] <= 1091 <= queries.length <= 5 * 104queries[i] = [ai, bi]0 <= ai, bi <= heights.length - 1
Companies: Infosys
Related Topics:
Array, Binary Search, Stack, Binary Indexed Tree, Segment Tree, Heap (Priority Queue), Monotonic Stack
Similar Questions:
Hints:
- For each query
[x, y], ifx > y, swapxandy. Now, we can assume thatx <= y. - For each query
[x, y], ifx == yorheights[x] < heights[y], then the answer isysincex ≤ y. - Otherwise, we need to find the smallest index
tsuch thaty < tandheights[x] < heights[t]. Note thatheights[y] <= heights[x], soheights[x] < heights[t]is a sufficient condition. - To find index
tfor each query, sort the queries in descending order ofy. Iterate over the queries while maintaining a monotonic stack which we can binary search over to find indext.
// OJ: https://leetcode.com/problems/find-building-where-alice-and-bob-can-meet
// Author: github.com/lzl124631x
// Time: O(H + QlogQ + QlogH)
// Space: O(Q + H)
class Solution {
public:
vector<int> leftmostBuildingQueries(vector<int>& H, vector<vector<int>>& Q) {
for (int i = 0; i < Q.size(); ++i) {
if (Q[i][0] > Q[i][1]) swap(Q[i][0], Q[i][1]);
Q[i].push_back(i);
}
sort(begin(Q), end(Q), [](auto &a, auto &b) { return a[1] > b[1]; });
map<int, int> m; // height -> left most index. Both are monotonically increasing
vector<int> ans(Q.size(), -1);
int i = H.size() - 1;
auto insert = [&](int h, int i) {
m[h] = i;
for (auto it = m.begin(); it != m.end() && it->first != h; m.erase(it++)); // delete all the keys < `h`, because they have smaller height with greater index, which won't be better than {h, i}.
};
for (auto &q : Q) {
int a = q[0], b = q[1], idx = q[2];
if (a == b) {
ans[idx] = a;
continue;
}
for (; i >= 0 && i >= b; --i) insert(H[i], i);
int goal = H[a] >= H[b] ? H[a] + 1 : H[b];
auto it = m.lower_bound(goal);
if (it != m.end()) ans[idx] = it->second;
}
return ans;
}
};