2368. Reachable Nodes With Restrictions
Problem Description
In this problem, we are given an undirected tree with n
nodes, where each node is labeled from 0
to n - 1
. A 2D integer array edges
is provided that contains n - 1
pairs of integers, with each pair [ai, bi]
indicating an edge between the nodes ai
and bi
. Alongside this, we have an integer array restricted
that lists restricted nodes which should not be visited.
Our goal is to find the maximum number of nodes that can be reached from node 0
without visiting any of the restricted nodes. It's important to note that node 0
is not a restricted node.
The result should be the count of accessible nodes, including node 0
, keeping in mind the restricted nodes' constraint.
Flowchart Walkthrough
To analyze the approach for LeetCode problem 2368: Reachable Nodes With Restrictions using the Flowchart, let's follow this process:
Is it a graph?
- Yes: The problem represents connections between nodes explicitly, with certain nodes having restrictions on connectivity, effectively forming a graph scenario.
Is it a tree?
- Yes: Despite the restrictions, the graph is still essentially a tree because it starts from a root node (1) and explores other nodes without cycles, adhering to tree properties.
Is the problem related to directed acyclic graphs (DAGs)?
- No: We are dealing with a tree here, which by definition is acyclic but undirected, and our focus is not on directed acyclic structures.
Is the problem related to shortest paths?
- No: The task is about counting the number of reachable nodes, not finding the shortest path to any node.
Does the problem involve connectivity?
- Yes: The goal is to verify the reachability of nodes given certain restrictions, highlighting the problem as a connectivity issue.
Is the graph weighted?
- No: The connections between nodes are either existent or restricted; there’s no weight like cost or distance associated with the edges.
Conclusion: Given that it's an unweighted connectivity problem in a tree-like structure, the flowchart leads us to employ a DFS (Depth-First Search) to explore maximum nodes while respecting the restrictions. DFS is typically efficient for tree structures to visit each node and check conditions or applications like reachability.
Intuition
To solve this problem, we use depth-first search (DFS), which is a standard graph traversal algorithm, to explore the graph starting from node 0
. The graph is represented using an adjacency list, which is a common way to represent graphs in memory.
The key steps involve:
- Constructing an adjacency list from the
edges
array, allowing us to access all connected nodes from a given node easily. - Creating a visited array,
vis
, to keep track of both visited and restricted nodes, marking restricted nodes as visited preemptively so that we don't traverse them during DFS. - Implementing a recursive DFS function that will traverse the graph. For each node
u
that is not visited and not restricted, the function will:- Increase the count of reachable nodes,
ans
, by 1. - Mark the node as visited.
- Recursively call DFS for all adjacent nodes of
u
.
- Increase the count of reachable nodes,
When the DFS function completes, ans
will contain the total count of reachable nodes from node 0
, ensuring that no restricted nodes are counted. This approach guarantees that we explore all possible paths in a depth-first manner while skipping over the restricted nodes and only counting the valid ones.
Learn more about Tree, Depth-First Search, Breadth-First Search and Graph patterns.
Solution Approach
The solution utilizes the Depth-First Search (DFS) algorithm to traverse the tree from node 0
and count the maximum number of reachable nodes without visiting any restricted nodes. Here's how the implementation works:
-
Data Structure: We use a
defaultdict
to create an adjacency listg
that represents the graph. Each key in this dictionary corresponds to a node, and the value is a list of nodes that are connected to it by an edge. This allows us to efficiently access all neighbor nodes of any given node. -
Pre-Marking Restricted Nodes: We create a list
vis
of boolean values to keep track of whether a node has been visited or is restricted. Its length isn
to cover all nodes. Restricted nodes are preemptively marked as visited (i.e.,True
) since we don't want to include them in our count. -
Graph Construction: For each edge provided in the
edges
array, we add the corresponding nodes to the adjacency list of each other. Since the graph represents an undirected tree, if there is an edge betweena
andb
, thenb
needs to be in the adjacency list ofa
and vice versa. -
DFS (Depth-First Search) Function: We define a recursive function
dfs
that takes a nodeu
as an argument. Within this function, we check ifu
is already visited or not. If it hasn't been visited:- We increment the reachable nodes count
ans
by 1. - We mark
u
as visited by settingvis[u]
toTrue
. - We then call
dfs
recursively for all the unvisited neighbor nodes ofu
found in the adjacency listg[u]
. The use of recursion inherently follows a depth-first traversal, going as deep as possible along one branch before backtracking.
- We increment the reachable nodes count
-
Initialization and Invocation: Before invoking the DFS function, we initialize the
ans
variable to0
, which will be used to keep track of the number of reachable nodes. We then calldfs(0)
to start the traversal from node0
. -
Result: After the DFS completes,
ans
gives us the total number of nodes that can be reached from node0
without traversing any restricted nodes, and this value is returned.
In this way, the DFS algorithm, an efficient graph traversal technique, along with an adjacency list representation of the tree, allows us to solve the problem with a concise and effective approach.
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Start EvaluatorExample Walkthrough
Let’s take a small example to illustrate the solution approach described above.
Suppose we have 5 nodes (from 0
to 4
) and n - 1
edges connecting them as follows: edges = [[0, 1], [0, 2], [1, 3], [1, 4]]
. The restricted
list containing the nodes that cannot be visited is restricted = [3]
.
Based on the edges, the tree structure looks like this:
0 / \ 1 2 / \ 3 4
Here, node 3
is restricted and should not be visited.
Now, let’s walk through the steps of the solution approach:
-
Data Structure: We use a
defaultdict(list)
to construct the adjacency listg
representing the graph:g = {0: [1, 2], 1: [0, 3, 4], 2: [0], 3: [1], 4: [1]}
-
Pre-Marking Restricted Nodes: We then create a list
vis
initialized withFalse
values. Since only node3
is restricted,vis
will be:vis = [False, False, False, True, False]
Node
3
is markedTrue
to indicate it's visited/restricted. -
Graph Construction: Our graph
g
has already been constructed from the edges array in step 1. -
DFS (Depth-First Search) Function: We write a recursive function
dfs(u)
that:def dfs(u): if vis[u]: return 0 vis[u] = True count = 1 for neigh in g[u]: count += dfs(neigh) return count
This function will count reachable nodes not previously counted nor restricted.
-
Initialization and Invocation: With
ans = 0
, we calldfs(0)
and begin the DFS traversal. -
Result: We visit node
0
, which isn't in therestricted
list nor visited. Soans
is now1
. Thedfs
goes on to visit nodes1
and2
. Node1
has two children,3
and4
, but since3
is restricted, it only counts4
. After the complete DFS call, theans
value is4
(nodes0
,1
,2
, and4
).
In this example, the ans
value after running the DFS algorithm implies we can reach 4 nodes from node 0
without visiting any restricted nodes. This is consistent with our tree structure, taking into account the restrictions.
Solution Implementation
1from collections import defaultdict
2
3class Solution:
4 def reachableNodes(self, n: int, edges: List[List[int]], restricted: List[int]) -> int:
5 # Create a graph represented as an adjacency list
6 graph = defaultdict(list)
7 # A list to keep track of visited nodes, default to False
8 visited = [False] * n
9
10 # Mark restricted nodes as visited so they won't be traversed
11 for node in restricted:
12 visited[node] = True
13
14 # Construct the graph by adding edges
15 for start, end in edges:
16 graph[start].append(end)
17 graph[end].append(start)
18
19 # Depth-First Search (DFS) function to traverse the graph
20 def dfs(node):
21 nonlocal count_visited
22 # If the node is already visited or restricted, return
23 if visited[node]:
24 return
25
26 # Increase the count of visited (reachable) nodes
27 count_visited += 1
28 # Mark the node as visited
29 visited[node] = True
30
31 # Recursively visit all adjacent nodes
32 for adjacent in graph[node]:
33 dfs(adjacent)
34
35 # Initialize the count of reachable nodes
36 count_visited = 0
37 # Start DFS from the first node
38 dfs(0)
39 # Return the number of reachable nodes
40 return count_visited
41
1class Solution {
2 // Graph represented as an adjacency list
3 private List<Integer>[] graph;
4 // Array to keep track of visited nodes
5 private boolean[] visited;
6 // Counter to keep track of the number of reachable nodes
7 private int numberOfReachableNodes;
8
9 // Method to return the number of reachable nodes
10 public int reachableNodes(int n, int[][] edges, int[] restricted) {
11 // Initialize the graph for each node
12 graph = new List[n];
13 for (int i = 0; i < n; i++) {
14 graph[i] = new ArrayList<>();
15 }
16
17 // Mark restricted nodes as visited so they won't be explored in DFS
18 visited = new boolean[n];
19 for (int restrictedNode : restricted) {
20 visited[restrictedNode] = true;
21 }
22
23 // Build the graph by adding edges
24 for (int[] edge : edges) {
25 int from = edge[0], to = edge[1];
26 graph[from].add(to);
27 graph[to].add(from);
28 }
29
30 // Initialize the count of reachable nodes and start DFS from node 0
31 numberOfReachableNodes = 0;
32 dfs(0);
33
34 // Return the total count of reachable nodes
35 return numberOfReachableNodes;
36 }
37
38 // DFS method to traverse nodes
39 private void dfs(int node) {
40 // If the current node is visited/restricted, do not proceed with DFS
41 if (visited[node]) {
42 return;
43 }
44
45 // Mark the node as visited and increment the reachable nodes counter
46 numberOfReachableNodes++;
47 visited[node] = true;
48
49 // Visit all the neighbors of the current node
50 for (int neighbor : graph[node]) {
51 dfs(neighbor);
52 }
53 }
54}
55
1class Solution {
2public:
3 int nodeCount; // Use a more descriptive name for this variable, which represents the count of reachable nodes.
4
5 int reachableNodes(int n, vector<vector<int>>& edges, vector<int>& restricted) {
6 vector<vector<int>> graph(n); // Use 'graph' to store the adjacency list representation of the graph.
7 // Construct the graph from the given edge list.
8 for (const auto& edge : edges) {
9 int from = edge[0], to = edge[1];
10 graph[from].push_back(to);
11 graph[to].push_back(from);
12 }
13 vector<bool> visited(n, false); // Use 'visited' to mark the visited nodes, initialized to false.
14 // Mark the restricted nodes as visited so they won't be counted.
15 for (int node : restricted) visited[node] = true;
16
17 // Initialize the reachable node count to zero before starting the DFS.
18 nodeCount = 0;
19 // Start depth-first search from node 0.
20 dfs(0, graph, visited);
21 return nodeCount; // Return the count of reachable nodes after the DFS is complete.
22 }
23
24 void dfs(int node, vector<vector<int>>& graph, vector<bool>& visited) {
25 if (visited[node]) {
26 // If the node has been visited or is restricted, return early.
27 return;
28 }
29 // Mark the current node as visited.
30 visited[node] = true;
31 // Increment the count of reachable nodes.
32 nodeCount++;
33 // Iterate over all the neighbors of the current node.
34 for (int neighbor : graph[node]) {
35 // Perform DFS on all non-visited neighbors.
36 dfs(neighbor, graph, visited);
37 }
38 }
39};
40
1function reachableNodes(n: number, edges: number[][], restricted: number[]): number {
2 let nodeCount = 0; // Holds the count of nodes that can be reached
3 const visited = new Array(n).fill(false); // Tracks visited nodes
4 const adjacencyList = new Map<number, number[]>(); // Adjacency list to represent the graph
5
6 // Construct the adjacency list from the edges
7 for (const [start, end] of edges) {
8 // Append the end node to the adjacency list of the start node
9 adjacencyList.set(start, [...(adjacencyList.get(start) ?? []), end]);
10 // Append the start node to the adjacency list of the end node
11 adjacencyList.set(end, [...(adjacencyList.get(end) ?? []), start]);
12 }
13
14 // Depth-First Search function to explore the graph
15 const dfs = (currentNode: number) => {
16 // If the node has been visited or is restricted, stop the search
17 if (restricted.includes(currentNode) || visited[currentNode]) {
18 return;
19 }
20 // Increment node count and mark the node as visited
21 nodeCount++;
22 visited[currentNode] = true;
23
24 // Iterate over all adjacent nodes and explore them
25 for (const neighbor of adjacencyList.get(currentNode) ?? []) {
26 dfs(neighbor);
27 }
28 };
29
30 // Begin the Depth-First Search from node 0
31 dfs(0);
32
33 // Return the total number of nodes that can be reached
34 return nodeCount;
35}
36
Time and Space Complexity
The given Python code defines a Solution
class with a method reachableNodes
to count the number of nodes in an undirected graph that can be reached without visiting any of the restricted nodes. It uses a Depth First Search (DFS) approach.
Time Complexity
The time complexity of the code is primarily determined by the DFS traversal of the graph provided by edges
.
-
The adjacency list for the graph is constructed in linear time relative to the number of edges.
for a, b in edges
loop runs|E|
times, where|E|
is the number of edges. -
The DFS (
dfs
function) visits each vertex only once, because once a vertex has been visited, it is marked as visited (vis[u] = True
). -
Each edge is traversed exactly twice in an undirected graph (once for each direction), during the entire DFS process.
Therefore, the time complexity of the DFS traversal is O(|V| + |E|)
, where |V|
is the number of vertices and |E|
is the number of edges.
Combining the adjacency list construction and the DFS traversal, the total time complexity remains O(|V| + |E|)
since both are dependent on the size of the graph.
Space Complexity
The space complexity is determined by:
- The storage of the graph in the adjacency list
g
, which consumesO(|V| + |E|)
space. - The recursive DFS call stack, which, in the worst case, could hold all vertices if the graph is a linked list shape (each vertex connected to only one other), hence
O(|V|)
in space. - The
vis
array, which takesO(|V|)
space, to keep track of visited nodes, including restricted ones.
Summing this up, the space complexity is O(|V| + |E|)
when considering both the adjacency list and the DFS stack.
Learn more about how to find time and space complexity quickly using problem constraints.
In a binary min heap, the maximum element can be found in:
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