Klona en oriktad graf
Prova det på GfG Practice 
Produktion
Produktion
Givet a ansluten oriktad graf representeras av angränsande lista adjList[][] med n noder och m kanter där varje nod har en distinkt etikett från 0 till n-1 och varje adj[i] representerar listan över hörn kopplade till vertex i.
Skapa en klona av grafen där varje nod i grafen innehåller ett heltal val och en array ( grannar ) av noder som innehåller noder som ligger intill den aktuella noden.
klass Nod {
val: heltal
grannar: Lista[Node]
}
Din uppgift är att klona den givna grafen och returnera en referens till den klonade grafen.
Notera: Om du returnerar en korrekt kopia av den givna grafen blir resultatet sann; Annars kommer den att skrivas ut falskt om kopian är felaktig.
Exempel
Input: n = 4 adjList[][] = [[1 2] [0 2] [0 1 3] [2]]
Produktion: sann
Förklaring:
Eftersom den klonade grafen är identisk med originalet blir utdata sann.Input: n = 3 adjList[][] = [[1 2] [0] [0]]
Produktion: sann
Förklaring:
Eftersom den klonade grafen är identisk med originalet blir utdata sann.
Innehållsförteckning
- Varför behöver vi spåra de besökta/klonade noderna?
- Hur håller man reda på de besökta/klonade noderna?
- Hur ansluter man klonnoder?
- Hur kontrollerar man om den klonade grafen är korrekt?
- [Tillvägagångssätt 1] Använda BFS-traversal - O(V+E) Tid och O(V) Space
- [Approach 2] Användning av DFS-traversal - O(V+E) Tid och O(V) Space
Varför behöver vi spåra de besökta/klonade noderna?
Vi måste spåra besökta eller klonade noder för att undvika oändlig rekursion och överflödigt arbete när vi klonar en graf. Eftersom grafer kan innehålla cykler (där en nod kan peka tillbaka till en tidigare besökt nod) utan att hålla reda på de noder som vi redan har klonat skulle kloningsfunktionen oändligt återbesöka samma noder, vilket resulterade i ett stackspill eller felaktig duplicering.
Hur håller man reda på de besökta/klonade noderna?
En HashMap/Map krävs för att underhålla alla noder som redan har skapats. Nyckelbutiker : Referens/adress till den ursprungliga noden Värdebutiker : Referens/adress till klonad nod En kopia av alla grafnoder har gjorts.
Hur ansluter man klonnoder?
När du besöker de angränsande hörnen av en nod i få motsvarande klonade nod för dig låt oss kalla det I besök nu alla närliggande noder för i och för varje granne hitta motsvarande klonnod (om den inte hittas skapa en) och tryck sedan in i den angränsande vektorn för I nod.
Hur kontrollerar man om den klonade grafen är korrekt?
Utför en BFS-traversering på den ursprungliga grafen före kloning och sedan igen på den klonade grafen efter att kloningen är klar. Under varje genomgång skriv ut värdet för varje nod tillsammans med dess adress (eller referens). För att verifiera riktigheten av kloningen, jämför ordningen på besökta noder i båda genomgångarna. Om nodvärdena visas i samma ordning men deras adresser (eller referenser) skiljer sig åt bekräftar det att grafen har klonats på ett framgångsrikt och korrekt sätt.
Utforska hur klona en oriktad graf inklusive grafer med flera anslutna komponenter använder BFS eller DFS för att säkerställa en fullständig djup kopia av alla noder och kanter.
[Tillvägagångssätt 1] Använda BFS-traversal - O(V+E) Tid och O(V) Space
C++I BFS-metoden klonas grafen iterativt med hjälp av en kö. Vi börjar med att klona den initiala noden och placera den i kön. När vi bearbetar varje nod från kön besöker vi dess grannar. Om en granne inte har klonats ännu skapar vi en klon som lagrar den på en karta och ställer den i kö för senare bearbetning. Vi lägger sedan till klonen av grannen till den aktuella nodens klonlista över grannar. Denna process fortsätter nivå för nivå och säkerställer att alla noder besöks i bredd-första ordning. BFS är särskilt användbart för att undvika djup rekursion och hantera stora eller breda grafer effektivt.
#include #include #include #include using namespace std ; // Definition for a Node struct Node { int val ; vector < Node *> neighbors ; }; // Clone the graph Node * cloneGraph ( Node * node ) { if ( ! node ) return nullptr ; map < Node * Node *> mp ; queue < Node *> q ; // Clone the source node Node * clone = new Node (); clone -> val = node -> val ; mp [ node ] = clone ; q . push ( node ); while ( ! q . empty ()) { Node * u = q . front (); q . pop (); for ( auto neighbor : u -> neighbors ) { // Clone neighbor if not already cloned if ( mp . find ( neighbor ) == mp . end ()) { Node * neighborClone = new Node (); neighborClone -> val = neighbor -> val ; mp [ neighbor ] = neighborClone ; q . push ( neighbor ); } // Link clone of neighbor to clone of current node mp [ u ] -> neighbors . push_back ( mp [ neighbor ]); } } return mp [ node ]; } // Build graph Node * buildGraph () { Node * node1 = new Node (); node1 -> val = 0 ; Node * node2 = new Node (); node2 -> val = 1 ; Node * node3 = new Node (); node3 -> val = 2 ; Node * node4 = new Node (); node4 -> val = 3 ; node1 -> neighbors = { node2 node3 }; node2 -> neighbors = { node1 node3 }; node3 -> neighbors = { node1 node2 node4 }; node4 -> neighbors = { node3 }; return node1 ; } // Compare two graphs for structural and value equality bool compareGraphs ( Node * node1 Node * node2 map < Node * Node *>& visited ) { if ( ! node1 || ! node2 ) return node1 == node2 ; if ( node1 -> val != node2 -> val || node1 == node2 ) return false ; visited [ node1 ] = node2 ; if ( node1 -> neighbors . size () != node2 -> neighbors . size ()) return false ; for ( size_t i = 0 ; i < node1 -> neighbors . size (); ++ i ) { Node * n1 = node1 -> neighbors [ i ]; Node * n2 = node2 -> neighbors [ i ]; if ( visited . count ( n1 )) { if ( visited [ n1 ] != n2 ) return false ; } else { if ( ! compareGraphs ( n1 n2 visited )) return false ; } } return true ; } // Driver Code int main () { Node * original = buildGraph (); Node * cloned = cloneGraph ( original ); map < Node * Node *> visited ; cout < < ( compareGraphs ( original cloned visited ) ? 'true' : 'false' ) < < endl ; return 0 ; }
Java import java.util.* ; // Definition for a Node class Node { public int val ; public ArrayList < Node > neighbors ; public Node () { neighbors = new ArrayList <> (); } public Node ( int val ) { this . val = val ; neighbors = new ArrayList <> (); } } public class GfG { // Clone the graph public static Node cloneGraph ( Node node ) { if ( node == null ) return null ; Map < Node Node > mp = new HashMap <> (); Queue < Node > q = new LinkedList <> (); // Clone the starting node Node clone = new Node ( node . val ); mp . put ( node clone ); q . offer ( node ); while ( ! q . isEmpty ()) { Node current = q . poll (); for ( Node neighbor : current . neighbors ) { // Clone neighbor if it hasn't been cloned yet if ( ! mp . containsKey ( neighbor )) { mp . put ( neighbor new Node ( neighbor . val )); q . offer ( neighbor ); } // Add the clone of the neighbor to the current node's clone mp . get ( current ). neighbors . add ( mp . get ( neighbor )); } } return mp . get ( node ); } // Build graph public static Node buildGraph () { Node node1 = new Node ( 0 ); Node node2 = new Node ( 1 ); Node node3 = new Node ( 2 ); Node node4 = new Node ( 3 ); node1 . neighbors . addAll ( new ArrayList <> ( Arrays . asList ( node2 node3 ))); node2 . neighbors . addAll ( new ArrayList <> ( Arrays . asList ( node1 node3 ))); node3 . neighbors . addAll ( new ArrayList <> ( Arrays . asList ( node1 node2 node4 ))); node4 . neighbors . addAll ( new ArrayList <> ( Arrays . asList ( node3 ))); return node1 ; } // Compare two graphs for structure and value public static boolean compareGraphs ( Node n1 Node n2 HashMap < Node Node > visited ) { if ( n1 == null || n2 == null ) return n1 == n2 ; if ( n1 . val != n2 . val || n1 == n2 ) return false ; visited . put ( n1 n2 ); if ( n1 . neighbors . size () != n2 . neighbors . size ()) return false ; for ( int i = 0 ; i < n1 . neighbors . size (); i ++ ) { Node neighbor1 = n1 . neighbors . get ( i ); Node neighbor2 = n2 . neighbors . get ( i ); if ( visited . containsKey ( neighbor1 )) { if ( visited . get ( neighbor1 ) != neighbor2 ) return false ; } else { if ( ! compareGraphs ( neighbor1 neighbor2 visited )) return false ; } } return true ; } public static void main ( String [] args ) { Node original = buildGraph (); Node cloned = cloneGraph ( original ); boolean isEqual = compareGraphs ( original cloned new HashMap <> ()); System . out . println ( isEqual ? 'true' : 'false' ); } }
Python from collections import deque # Definition for a Node class Node : def __init__ ( self val = 0 ): self . val = val self . neighbors = [] # Clone the graph def cloneGraph ( node ): if not node : return None # Map to hold original nodes as keys and their clones as values mp = {} # Initialize BFS queue q = deque ([ node ]) # Clone the starting node mp [ node ] = Node ( node . val ) while q : current = q . popleft () for neighbor in current . neighbors : # If neighbor not cloned yet if neighbor not in mp : mp [ neighbor ] = Node ( neighbor . val ) q . append ( neighbor ) # Link clone of neighbor to the clone of the current node mp [ current ] . neighbors . append ( mp [ neighbor ]) return mp [ node ] # Build graph def buildGraph (): node1 = Node ( 0 ) node2 = Node ( 1 ) node3 = Node ( 2 ) node4 = Node ( 3 ) node1 . neighbors = [ node2 node3 ] node2 . neighbors = [ node1 node3 ] node3 . neighbors = [ node1 node2 node4 ] node4 . neighbors = [ node3 ] return node1 # Compare two graphs structurally and by values def compareGraphs ( n1 n2 visited ): if not n1 or not n2 : return n1 == n2 if n1 . val != n2 . val or n1 is n2 : return False visited [ n1 ] = n2 if len ( n1 . neighbors ) != len ( n2 . neighbors ): return False for i in range ( len ( n1 . neighbors )): neighbor1 = n1 . neighbors [ i ] neighbor2 = n2 . neighbors [ i ] if neighbor1 in visited : if visited [ neighbor1 ] != neighbor2 : return False else : if not compareGraphs ( neighbor1 neighbor2 visited ): return False return True # Driver if __name__ == '__main__' : original = buildGraph () cloned = cloneGraph ( original ) result = compareGraphs ( original cloned {}) print ( 'true' if result else 'false' )
C# using System ; using System.Collections.Generic ; // Definition for a Node public class Node { public int val ; public List < Node > neighbors ; public Node () { neighbors = new List < Node > (); } public Node ( int val ) { this . val = val ; neighbors = new List < Node > (); } } class GfG { // Clone the graph public static Node CloneGraph ( Node node ) { if ( node == null ) return null ; var mp = new Dictionary < Node Node > (); var q = new Queue < Node > (); // Clone the starting node var clone = new Node ( node . val ); mp [ node ] = clone ; q . Enqueue ( node ); while ( q . Count > 0 ) { var current = q . Dequeue (); foreach ( var neighbor in current . neighbors ) { // If neighbor not cloned clone it and enqueue if ( ! mp . ContainsKey ( neighbor )) { mp [ neighbor ] = new Node ( neighbor . val ); q . Enqueue ( neighbor ); } // Add clone of neighbor to clone of current mp [ current ]. neighbors . Add ( mp [ neighbor ]); } } return mp [ node ]; } // Build graph public static Node BuildGraph () { var node1 = new Node ( 0 ); var node2 = new Node ( 1 ); var node3 = new Node ( 2 ); var node4 = new Node ( 3 ); node1 . neighbors . AddRange ( new [] { node2 node3 }); node2 . neighbors . AddRange ( new [] { node1 node3 }); node3 . neighbors . AddRange ( new [] { node1 node2 node4 }); node4 . neighbors . AddRange ( new [] { node3 }); return node1 ; } // Compare two graphs for structure and value public static bool CompareGraphs ( Node n1 Node n2 Dictionary < Node Node > visited ) { if ( n1 == null || n2 == null ) return n1 == n2 ; if ( n1 . val != n2 . val || ReferenceEquals ( n1 n2 )) return false ; visited [ n1 ] = n2 ; if ( n1 . neighbors . Count != n2 . neighbors . Count ) return false ; for ( int i = 0 ; i < n1 . neighbors . Count ; i ++ ) { var neighbor1 = n1 . neighbors [ i ]; var neighbor2 = n2 . neighbors [ i ]; if ( visited . ContainsKey ( neighbor1 )) { if ( ! ReferenceEquals ( visited [ neighbor1 ] neighbor2 )) return false ; } else { if ( ! CompareGraphs ( neighbor1 neighbor2 visited )) return false ; } } return true ; } public static void Main () { var original = BuildGraph (); var cloned = CloneGraph ( original ); var visited = new Dictionary < Node Node > (); Console . WriteLine ( CompareGraphs ( original cloned visited ) ? 'true' : 'false' ); } }
JavaScript // Definition for a Node class Node { constructor ( val = 0 ) { this . val = val ; this . neighbors = []; } } // Clone the graph function cloneGraph ( node ) { if ( ! node ) return null ; const mp = new Map (); const q = [ node ]; // Clone the initial node mp . set ( node new Node ( node . val )); while ( q . length > 0 ) { const current = q . shift (); for ( const neighbor of current . neighbors ) { if ( ! mp . has ( neighbor )) { mp . set ( neighbor new Node ( neighbor . val )); q . push ( neighbor ); } // Link clone of neighbor to clone of current mp . get ( current ). neighbors . push ( mp . get ( neighbor )); } } return mp . get ( node ); } // Build graph function buildGraph () { const node1 = new Node ( 0 ); const node2 = new Node ( 1 ); const node3 = new Node ( 2 ); const node4 = new Node ( 3 ); node1 . neighbors = [ node2 node3 ]; node2 . neighbors = [ node1 node3 ]; node3 . neighbors = [ node1 node2 node4 ]; node4 . neighbors = [ node3 ]; return node1 ; } // Compare two graphs structurally and by value function compareGraphs ( n1 n2 visited = new Map ()) { if ( ! n1 || ! n2 ) return n1 === n2 ; if ( n1 . val !== n2 . val || n1 === n2 ) return false ; visited . set ( n1 n2 ); if ( n1 . neighbors . length !== n2 . neighbors . length ) return false ; for ( let i = 0 ; i < n1 . neighbors . length ; i ++ ) { const neighbor1 = n1 . neighbors [ i ]; const neighbor2 = n2 . neighbors [ i ]; if ( visited . has ( neighbor1 )) { if ( visited . get ( neighbor1 ) !== neighbor2 ) return false ; } else { if ( ! compareGraphs ( neighbor1 neighbor2 visited )) return false ; } } return true ; } // Driver const original = buildGraph (); const cloned = cloneGraph ( original ); const result = compareGraphs ( original cloned ); console . log ( result ? 'true' : 'false' );
Produktion
true
[Approach 2] Användning av DFS-traversal - O(V+E) Tid och O(V) Space
C++I DFS-metoden klonas grafen med hjälp av rekursion. Vi utgår från den givna noden och utforskar så långt som möjligt längs varje gren innan vi backar. En karta (eller ordbok) används för att hålla reda på redan klonade noder för att undvika att behandla samma nod flera gånger och för att hantera cykler. När vi stöter på en nod för första gången skapar vi en klon av den och lagrar den på kartan. Sedan klonar vi den rekursivt för varje granne till den noden och lägger till den klonade grannen till den aktuella nodens klon. Detta säkerställer att alla noder besöks djupt innan de återvänder och att grafstrukturen är troget kopierad.
#include #include #include #include using namespace std ; // Definition for a Node struct Node { int val ; vector < Node *> neighbors ; }; // Map to hold original node to its copy unordered_map < Node * Node *> copies ; // Function to clone the graph Node * cloneGraph ( Node * node ) { // If the node is NULL return NULL if ( ! node ) return NULL ; // If node is not yet cloned clone it if ( copies . find ( node ) == copies . end ()) { Node * clone = new Node (); clone -> val = node -> val ; copies [ node ] = clone ; // Recursively clone neighbors for ( Node * neighbor : node -> neighbors ) { clone -> neighbors . push_back ( cloneGraph ( neighbor )); } } // Return the clone return copies [ node ]; } // Build graph Node * buildGraph () { Node * node1 = new Node (); node1 -> val = 0 ; Node * node2 = new Node (); node2 -> val = 1 ; Node * node3 = new Node (); node3 -> val = 2 ; Node * node4 = new Node (); node4 -> val = 3 ; node1 -> neighbors = { node2 node3 }; node2 -> neighbors = { node1 node3 }; node3 -> neighbors = { node1 node2 node4 }; node4 -> neighbors = { node3 }; return node1 ; } // Compare two graphs for structural and value equality bool compareGraphs ( Node * node1 Node * node2 map < Node * Node *>& visited ) { if ( ! node1 || ! node2 ) return node1 == node2 ; if ( node1 -> val != node2 -> val || node1 == node2 ) return false ; visited [ node1 ] = node2 ; if ( node1 -> neighbors . size () != node2 -> neighbors . size ()) return false ; for ( size_t i = 0 ; i < node1 -> neighbors . size (); ++ i ) { Node * n1 = node1 -> neighbors [ i ]; Node * n2 = node2 -> neighbors [ i ]; if ( visited . count ( n1 )) { if ( visited [ n1 ] != n2 ) return false ; } else { if ( ! compareGraphs ( n1 n2 visited )) return false ; } } return true ; } // Driver Code int main () { Node * original = buildGraph (); // Clone the graph Node * cloned = cloneGraph ( original ); // Compare original and cloned graph map < Node * Node *> visited ; cout < < ( compareGraphs ( original cloned visited ) ? 'true' : 'false' ) < < endl ; return 0 ; }
Java import java.util.* ; // Definition for a Node class Node { int val ; ArrayList < Node > neighbors ; Node () { neighbors = new ArrayList <> (); } Node ( int val ) { this . val = val ; neighbors = new ArrayList <> (); } } public class GfG { // Map to hold original node to its copy static HashMap < Node Node > copies = new HashMap <> (); // Function to clone the graph using DFS public static Node cloneGraph ( Node node ) { // If the node is NULL return NULL if ( node == null ) return null ; // If node is not yet cloned clone it if ( ! copies . containsKey ( node )) { Node clone = new Node ( node . val ); copies . put ( node clone ); // Recursively clone neighbors for ( Node neighbor : node . neighbors ) { clone . neighbors . add ( cloneGraph ( neighbor )); } } // Return the clone return copies . get ( node ); } // Build graph public static Node buildGraph () { Node node1 = new Node ( 0 ); Node node2 = new Node ( 1 ); Node node3 = new Node ( 2 ); Node node4 = new Node ( 3 ); node1 . neighbors . addAll ( Arrays . asList ( node2 node3 )); node2 . neighbors . addAll ( Arrays . asList ( node1 node3 )); node3 . neighbors . addAll ( Arrays . asList ( node1 node2 node4 )); node4 . neighbors . addAll ( Arrays . asList ( node3 )); return node1 ; } // Compare two graphs for structural and value equality public static boolean compareGraphs ( Node node1 Node node2 HashMap < Node Node > visited ) { if ( node1 == null || node2 == null ) return node1 == node2 ; if ( node1 . val != node2 . val || node1 == node2 ) return false ; visited . put ( node1 node2 ); if ( node1 . neighbors . size () != node2 . neighbors . size ()) return false ; for ( int i = 0 ; i < node1 . neighbors . size (); i ++ ) { Node n1 = node1 . neighbors . get ( i ); Node n2 = node2 . neighbors . get ( i ); if ( visited . containsKey ( n1 )) { if ( visited . get ( n1 ) != n2 ) return false ; } else { if ( ! compareGraphs ( n1 n2 visited )) return false ; } } return true ; } // Driver Code public static void main ( String [] args ) { Node original = buildGraph (); // Clone the graph Node cloned = cloneGraph ( original ); // Compare original and cloned graph boolean result = compareGraphs ( original cloned new HashMap <> ()); System . out . println ( result ? 'true' : 'false' ); } }
Python # Definition for a Node class Node : def __init__ ( self val = 0 neighbors = None ): self . val = val self . neighbors = neighbors if neighbors is not None else [] # Map to hold original node to its copy copies = {} # Function to clone the graph def cloneGraph ( node ): # If the node is None return None if not node : return None # If node is not yet cloned clone it if node not in copies : # Create a clone of the node clone = Node ( node . val ) copies [ node ] = clone # Recursively clone neighbors for neighbor in node . neighbors : clone . neighbors . append ( cloneGraph ( neighbor )) # Return the clone return copies [ node ] def buildGraph (): node1 = Node ( 0 ) node2 = Node ( 1 ) node3 = Node ( 2 ) node4 = Node ( 3 ) node1 . neighbors = [ node2 node3 ] node2 . neighbors = [ node1 node3 ] node3 . neighbors = [ node1 node2 node4 ] node4 . neighbors = [ node3 ] return node1 # Compare two graphs for structural and value equality def compareGraphs ( node1 node2 visited ): if not node1 or not node2 : return node1 == node2 if node1 . val != node2 . val or node1 is node2 : return False visited [ node1 ] = node2 if len ( node1 . neighbors ) != len ( node2 . neighbors ): return False for i in range ( len ( node1 . neighbors )): n1 = node1 . neighbors [ i ] n2 = node2 . neighbors [ i ] if n1 in visited : if visited [ n1 ] != n2 : return False else : if not compareGraphs ( n1 n2 visited ): return False return True # Driver Code if __name__ == '__main__' : original = buildGraph () # Clone the graph using DFS cloned = cloneGraph ( original ) # Compare original and cloned graph visited = {} print ( 'true' if compareGraphs ( original cloned visited ) else 'false' )
C# using System ; using System.Collections.Generic ; public class Node { public int val ; public List < Node > neighbors ; public Node () { val = 0 ; neighbors = new List < Node > (); } public Node ( int _val ) { val = _val ; neighbors = new List < Node > (); } } class GfG { // Dictionary to hold original node to its copy static Dictionary < Node Node > copies = new Dictionary < Node Node > (); // Function to clone the graph using DFS public static Node CloneGraph ( Node node ) { // If the node is NULL return NULL if ( node == null ) return null ; // If node is not yet cloned clone it if ( ! copies . ContainsKey ( node )) { Node clone = new Node ( node . val ); copies [ node ] = clone ; // Recursively clone neighbors foreach ( Node neighbor in node . neighbors ) { clone . neighbors . Add ( CloneGraph ( neighbor )); } } // Return the clone return copies [ node ]; } // Build graph public static Node BuildGraph () { Node node1 = new Node ( 0 ); Node node2 = new Node ( 1 ); Node node3 = new Node ( 2 ); Node node4 = new Node ( 3 ); node1 . neighbors . Add ( node2 ); node1 . neighbors . Add ( node3 ); node2 . neighbors . Add ( node1 ); node2 . neighbors . Add ( node3 ); node3 . neighbors . Add ( node1 ); node3 . neighbors . Add ( node2 ); node3 . neighbors . Add ( node4 ); node4 . neighbors . Add ( node3 ); return node1 ; } // Compare two graphs for structural and value equality public static bool CompareGraphs ( Node node1 Node node2 Dictionary < Node Node > visited ) { if ( node1 == null || node2 == null ) return node1 == node2 ; if ( node1 . val != node2 . val || node1 == node2 ) return false ; visited [ node1 ] = node2 ; if ( node1 . neighbors . Count != node2 . neighbors . Count ) return false ; for ( int i = 0 ; i < node1 . neighbors . Count ; i ++ ) { Node n1 = node1 . neighbors [ i ]; Node n2 = node2 . neighbors [ i ]; if ( visited . ContainsKey ( n1 )) { if ( visited [ n1 ] != n2 ) return false ; } else { if ( ! CompareGraphs ( n1 n2 visited )) return false ; } } return true ; } // Driver Code public static void Main () { Node original = BuildGraph (); // Clone the graph using DFS Node cloned = CloneGraph ( original ); // Compare original and cloned graph bool isEqual = CompareGraphs ( original cloned new Dictionary < Node Node > ()); Console . WriteLine ( isEqual ? 'true' : 'false' ); } }
JavaScript // Definition for a Node class Node { constructor ( val = 0 ) { this . val = val ; this . neighbors = []; } } // Map to hold original node to its copy const copies = new Map (); // Function to clone the graph using DFS function cloneGraph ( node ) { // If the node is NULL return NULL if ( node === null ) return null ; // If node is not yet cloned clone it if ( ! copies . has ( node )) { const clone = new Node ( node . val ); copies . set ( node clone ); // Recursively clone neighbors for ( let neighbor of node . neighbors ) { clone . neighbors . push ( cloneGraph ( neighbor )); } } // Return the clone return copies . get ( node ); } // Build graph function buildGraph () { const node1 = new Node ( 0 ); const node2 = new Node ( 1 ); const node3 = new Node ( 2 ); const node4 = new Node ( 3 ); node1 . neighbors . push ( node2 node3 ); node2 . neighbors . push ( node1 node3 ); node3 . neighbors . push ( node1 node2 node4 ); node4 . neighbors . push ( node3 ); return node1 ; } // Compare two graphs for structural and value equality function compareGraphs ( node1 node2 visited = new Map ()) { if ( ! node1 || ! node2 ) return node1 === node2 ; if ( node1 . val !== node2 . val || node1 === node2 ) return false ; visited . set ( node1 node2 ); if ( node1 . neighbors . length !== node2 . neighbors . length ) return false ; for ( let i = 0 ; i < node1 . neighbors . length ; i ++ ) { const n1 = node1 . neighbors [ i ]; const n2 = node2 . neighbors [ i ]; if ( visited . has ( n1 )) { if ( visited . get ( n1 ) !== n2 ) return false ; } else { if ( ! compareGraphs ( n1 n2 visited )) return false ; } } return true ; } // Driver Code const original = buildGraph (); // Clone the graph using DFS const cloned = cloneGraph ( original ); // Compare original and cloned graph console . log ( compareGraphs ( original cloned ) ? 'true' : 'false' );
Produktion
true
