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存在一个由 n 个节点组成的无向连通图,图中的节点按从 0 到 n - 1 编号。
给你一个数组 graph 表示这个图。其中,graph[i] 是一个列表,由所有与节点 i 直接相连的节点组成。
返回能够访问所有节点的最短路径的长度。你可以在任一节点开始和停止,也可以多次重访节点,并且可以重用边。
示例 1:
输入:graph = [[1,2,3],[0],[0],[0]] 输出:4 解释:一种可能的路径为 [1,0,2,0,3]
示例 2:
输入:graph = [[1],[0,2,4],[1,3,4],[2],[1,2]] 输出:4 解释:一种可能的路径为 [0,1,4,2,3]
提示:
n == graph.length1 <= n <= 120 <= graph[i].length < ngraph[i] 不包含 i
graph[a] 包含 b ,那么 graph[b] 也包含 a
因为每条边权值一样,所以用 BFS 就能得出最短路径,过程中可以用状态压缩记录节点的访问情况。另外,同一个节点 u 以及对应的节点访问情况需要保证只被搜索过一次,因此可以用 vis(u, state) 表示是否已经被搜索过,防止无效的重复搜索。
本题也属于 BFS 最小步数模型,可以使用 A* 算法优化搜索。
A* 算法主要思想如下:
(dist[state] + f(state), state),dist[state] 表示从起点到当前 state 的距离,f(state) 表示从当前 state 到终点的估计距离,这两个距离之和作为堆排序的依据;f(state) 是估价函数,并且估价函数要满足 f(state) <= g(state),其中 g(state) 表示 state 到终点的真实距离;class Solution:
def shortestPathLength(self, graph: List[List[int]]) -> int:
n = len(graph)
dst = -1 ^ (-1 << n)
q = deque()
vis = [[False] * (1 << n) for _ in range(n)]
for i in range(n):
q.append((i, 1 << i, 0))
vis[i][1 << i] = True
while q:
u, state, dis = q.popleft()
for v in graph[u]:
nxt = state | (1 << v)
if nxt == dst:
return dis + 1
if not vis[v][nxt]:
q.append((v, nxt, dis + 1))
vis[v][nxt] = True
return 0
A* 算法:
class Solution:
def shortestPathLength(self, graph: List[List[int]]) -> int:
n = len(graph)
def f(state):
return sum(((state >> i) & 1) == 0 for i in range(n))
q = []
dist = [[inf] * (1 << n) for _ in range(n)]
for i in range(n):
heappush(q, (f(1 << i), i, 1 << i))
dist[i][1 << i] = 0
while q:
_, u, state = heappop(q)
if state == (1 << n) - 1:
return dist[u][state]
for v in graph[u]:
nxt = state | (1 << v)
if dist[v][nxt] > dist[u][state] + 1:
dist[v][nxt] = dist[u][state] + 1
heappush(q, (dist[v][nxt] + f(nxt), v, nxt))
return 0
class Solution {
public int shortestPathLength(int[][] graph) {
int n = graph.length;
int dst = -1 ^ (-1 << n);
Queue<Tuple> queue = new ArrayDeque<>();
boolean[][] vis = new boolean[n][1 << n];
for (int i = 0; i < n; i++) {
queue.offer(new Tuple(i, 1 << i, 0));
vis[i][1 << i] = true;
}
while (!queue.isEmpty()) {
Tuple t = queue.poll();
int u = t.u, state = t.state, dis = t.dis;
for (int v : graph[u]) {
int next = state | (1 << v);
if (next == dst) {
return dis + 1;
}
if (!vis[v][next]) {
queue.offer(new Tuple(v, next, dis + 1));
vis[v][next] = true;
}
}
}
return 0;
}
private static class Tuple {
int u;
int state;
int dis;
public Tuple(int u, int state, int dis) {
this.u = u;
this.state = state;
this.dis = dis;
}
}
}
A* 算法:
class Solution {
private int n;
public int shortestPathLength(int[][] graph) {
n = graph.length;
int[][] dist = new int[n][1 << n];
for (int i = 0; i < n; ++i) {
Arrays.fill(dist[i], Integer.MAX_VALUE);
}
PriorityQueue<int[]> q = new PriorityQueue<>(Comparator.comparingInt(a -> a[0]));
for (int i = 0; i < n; ++i) {
q.offer(new int[] {f(1 << i), i, 1 << i});
dist[i][1 << i] = 0;
}
while (!q.isEmpty()) {
int[] p = q.poll();
int u = p[1], state = p[2];
if (state == (1 << n) - 1) {
return dist[u][state];
}
for (int v : graph[u]) {
int nxt = state | (1 << v);
if (dist[v][nxt] > dist[u][state] + 1) {
dist[v][nxt] = dist[u][state] + 1;
q.offer(new int[] {dist[v][nxt] + f(nxt), v, nxt});
}
}
}
return 0;
}
private int f(int state) {
int ans = 0;
for (int i = 0; i < n; ++i) {
if (((state >> i) & 1) == 0) {
++ans;
}
}
return ans;
}
}
type tuple struct {
u int
state int
dis int
}
func shortestPathLength(graph [][]int) int {
n := len(graph)
dst := -1 ^ (-1 << n)
q := make([]tuple, 0)
vis := make([][]bool, n)
for i := 0; i < n; i++ {
vis[i] = make([]bool, 1<<n)
q = append(q, tuple{i, 1 << i, 0})
vis[i][1<<i] = true
}
for len(q) > 0 {
t := q[0]
q = q[1:]
cur, state, dis := t.u, t.state, t.dis
for _, v := range graph[cur] {
next := state | (1 << v)
if next == dst {
return dis + 1
}
if !vis[v][next] {
q = append(q, tuple{v, next, dis + 1})
vis[v][next] = true
}
}
}
return 0
}
class Solution {
public:
int shortestPathLength(vector<vector<int>>& graph) {
int n = graph.size();
queue<tuple<int, int, int>> q;
vector<vector<bool>> vis(n, vector<bool>(1 << n));
for (int i = 0; i < n; ++i) {
q.emplace(i, 1 << i, 0);
vis[i][1 << i] = true;
}
while (!q.empty()) {
auto [u, state, dist] = q.front();
q.pop();
if (state == (1 << n) - 1) return dist;
for (int& v : graph[u]) {
int nxt = state | (1 << v);
if (!vis[v][nxt]) {
q.emplace(v, nxt, dist + 1);
vis[v][nxt] = true;
}
}
}
return 0;
}
};
A* 算法:
class Solution {
public:
int n;
int shortestPathLength(vector<vector<int>>& graph) {
n = graph.size();
priority_queue<tuple<int, int, int>, vector<tuple<int, int, int>>, greater<tuple<int, int, int>>> q;
vector<vector<int>> dist(n, vector<int>(1 << n, INT_MAX));
for (int i = 0; i < n; ++i)
{
q.push({f(1 << i), i, 1 << i});
dist[i][1 << i] = 0;
}
while (!q.empty())
{
auto [_, u, state] = q.top();
q.pop();
if (state == (1 << n) - 1) return dist[u][state];
for (int v : graph[u])
{
int nxt = state | (1 << v);
if (dist[v][nxt] > dist[u][state] + 1)
{
dist[v][nxt] = dist[u][state] + 1;
q.push({dist[v][nxt] + f(nxt), v, nxt});
}
}
}
return 0;
}
int f(int state) {
int ans = 0;
for (int i = 0; i < n; ++i)
if (((state >> i) & 1) == 0)
++ans;
return ans;
}
};
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