There are n
cities numbered from 0
to n-1
. Given the array edges
where edges[i] = [fromi, toi, weighti]
represents a bidirectional and weighted edge between cities fromi
and toi
, and given the integer distanceThreshold
.
Return the city with the smallest number of cities that are reachable through some path and whose distance is at most distanceThreshold
, If there are multiple such cities, return the city with the greatest number.
Notice that the distance of a path connecting cities i and j is equal to the sum of the edges' weights along that path.
Example 1:
Input: n = 4, edges = [[0,1,3],[1,2,1],[1,3,4],[2,3,1]], distanceThreshold = 4
Output: 3
Explanation: The figure above describes the graph.
The neighboring cities at a distanceThreshold = 4 for each city are:
City 0 -> [City 1, City 2]
City 1 -> [City 0, City 2, City 3]
City 2 -> [City 0, City 1, City 3]
City 3 -> [City 1, City 2]
Cities 0 and 3 have 2 neighboring cities at a distanceThreshold = 4, but we have to return city 3 since it has the greatest number.
Example 2:
Input: n = 5, edges = [[0,1,2],[0,4,8],[1,2,3],[1,4,2],[2,3,1],[3,4,1]], distanceThreshold = 2
Output: 0
Explanation: The figure above describes the graph.
The neighboring cities at a distanceThreshold = 2 for each city are:
City 0 -> [City 1]
City 1 -> [City 0, City 4]
City 2 -> [City 3, City 4]
City 3 -> [City 2, City 4]
City 4 -> [City 1, City 2, City 3]
The city 0 has 1 neighboring city at a distanceThreshold = 2.
Constraints:
2 <= n <= 100
1 <= edges.length <= n * (n - 1) / 2
edges[i].length == 3
0 <= fromi < toi < n
1 <= weighti, distanceThreshold <= 10^4
- All pairs
(fromi, toi)
are distinct.
-
Floyd-warshall算法,O(V^3)
class Solution: def findTheCity(self, n: int, edges: List[List[int]], distanceThreshold: int) -> int: # Floyd-warshall dp = [[float('inf') for _ in range(n)] for _ in range(n)] for ed in edges: u, v, weight = ed[0], ed[1], ed[2] dp[u][v] = dp[v][u] = weight for k in range(n): for u in range(n): for v in range(n): dp[u][v] = min(dp[u][v], dp[u][k] + dp[k][v]) ans = -1 min_neighbor = float('inf') for u in range(n): cur_neighbor = 0 for v in range(n): if v != u and dp[u][v] <= distanceThreshold: cur_neighbor += 1 if cur_neighbor <= min_neighbor: min_neighbor = cur_neighbor ans = u return ans