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Langste pad in een gerichte acyclische grafiek | Stel 2 in

Gegeven een Weighted Directed Acyclic Graph (DAG) en een bronhoekpunt daarin, vind je de langste afstanden van het bronpunt tot alle andere hoekpunten in de gegeven grafiek.

We hebben al besproken hoe we het kunnen vinden Langste pad in gerichte acyclische grafiek (DAG) in Set 1. In dit bericht zullen we een andere interessante oplossing bespreken om het langste pad van DAG te vinden dat een algoritme gebruikt voor het vinden Kortste pad in een DAG .

Het idee is om negeer de gewichten van het pad en vind het kortste pad in de grafiek . Een langste pad tussen twee gegeven hoekpunten s en t in een gewogen grafiek G is hetzelfde als een kortste pad in een grafiek G' afgeleid van G door elk gewicht in zijn negatie te veranderen. Dus als de kortste paden in G' gevonden kunnen worden, dan kunnen de langste paden ook in G gevonden worden. 
Hieronder vindt u het stapsgewijze proces voor het vinden van de langste paden -

We veranderen het gewicht van elke rand van een bepaalde grafiek in de negatie ervan en initialiseren de afstanden tot alle hoekpunten als oneindig en de afstand tot de bron als 0. Vervolgens vinden we een topologische sortering van de grafiek die een lineaire ordening van de grafiek vertegenwoordigt. Wanneer we een hoekpunt u in topologische volgorde beschouwen, is het gegarandeerd dat we elke binnenkomende rand ervan hebben overwogen. dat wil zeggen dat we het kortste pad naar dat hoekpunt al hebben gevonden en we kunnen die informatie gebruiken om het kortere pad van alle aangrenzende hoekpunten bij te werken. Zodra we de topologische volgorde hebben, verwerken we één voor één alle hoekpunten in topologische volgorde. Voor elk hoekpunt dat wordt verwerkt, werken we de afstanden van het aangrenzende hoekpunt bij met behulp van de kortste afstand van het huidige hoekpunt tot het bronpunt en het randgewicht ervan. d.w.z.  

for every adjacent vertex v of every vertex u in topological order if (dist[v] > dist[u] + weight(u v)) dist[v] = dist[u] + weight(u v)

Zodra we alle kortste paden vanaf het bronpunt hebben gevonden, zijn de langste paden slechts een ontkenning van de kortste paden.

Hieronder vindt u de implementatie van de bovenstaande aanpak:

C++ 
   // A C++ program to find single source longest distances   // in a DAG   #include          using     namespace     std  ;   // Graph is represented using adjacency list. Every node of   // adjacency list contains vertex number of the vertex to   // which edge connects. It also contains weight of the edge   class     AdjListNode   {      int     v  ;      int     weight  ;   public  :      AdjListNode  (  int     _v       int     _w  )      {      v     =     _v  ;      weight     =     _w  ;      }      int     getV  ()      {      return     v  ;      }      int     getWeight  ()      {      return     weight  ;      }   };   // Graph class represents a directed graph using adjacency   // list representation   class     Graph   {      int     V  ;     // No. of vertices      // Pointer to an array containing adjacency lists      list   <  AdjListNode  >*     adj  ;      // This function uses DFS      void     longestPathUtil  (  int       vector   <  bool  >     &       stack   <  int  >     &  );   public  :      Graph  (  int  );     // Constructor      ~  Graph  ();     // Destructor      // function to add an edge to graph      void     addEdge  (  int       int       int  );      void     longestPath  (  int  );   };   Graph  ::  Graph  (  int     V  )     // Constructor   {      this  ->  V     =     V  ;      adj     =     new     list   <  AdjListNode  >  [  V  ];   }   Graph  ::~  Graph  ()     // Destructor   {      delete  []     adj  ;   }   void     Graph  ::  addEdge  (  int     u       int     v       int     weight  )   {      AdjListNode     node  (  v       weight  );      adj  [  u  ].  push_back  (  node  );     // Add v to u's list   }   // A recursive function used by longestPath. See below   // link for details.   // https://www.geeksforgeeks.org/dsa/topological-sorting/   void     Graph  ::  longestPathUtil  (  int     v       vector   <  bool  >     &  visited        stack   <  int  >     &  Stack  )   {      // Mark the current node as visited      visited  [  v  ]     =     true  ;      // Recur for all the vertices adjacent to this vertex      for     (  AdjListNode     node     :     adj  [  v  ])      {      if     (  !  visited  [  node  .  getV  ()])      longestPathUtil  (  node  .  getV  ()     visited       Stack  );      }      // Push current vertex to stack which stores topological      // sort      Stack  .  push  (  v  );   }   // The function do Topological Sort and finds longest   // distances from given source vertex   void     Graph  ::  longestPath  (  int     s  )   {      // Initialize distances to all vertices as infinite and      // distance to source as 0      int     dist  [  V  ];      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      dist  [  i  ]     =     INT_MAX  ;      dist  [  s  ]     =     0  ;      stack   <  int  >     Stack  ;      // Mark all the vertices as not visited      vector   <  bool  >     visited  (  V       false  );      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      if     (  visited  [  i  ]     ==     false  )      longestPathUtil  (  i       visited       Stack  );      // Process vertices in topological order      while     (  !  Stack  .  empty  ())      {      // Get the next vertex from topological order      int     u     =     Stack  .  top  ();      Stack  .  pop  ();      if     (  dist  [  u  ]     !=     INT_MAX  )      {      // Update distances of all adjacent vertices      // (edge from u -> v exists)      for     (  AdjListNode     v     :     adj  [  u  ])      {      // consider negative weight of edges and      // find shortest path      if     (  dist  [  v  .  getV  ()]     >     dist  [  u  ]     +     v  .  getWeight  ()     *     -1  )      dist  [  v  .  getV  ()]     =     dist  [  u  ]     +     v  .  getWeight  ()     *     -1  ;      }      }      }      // Print the calculated longest distances      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      {      if     (  dist  [  i  ]     ==     INT_MAX  )      cout      < <     'INT_MIN '  ;      else      cout      < <     (  dist  [  i  ]     *     -1  )      < <     ' '  ;      }   }   // Driver code   int     main  ()   {      Graph     g  (  6  );      g  .  addEdge  (  0       1       5  );      g  .  addEdge  (  0       2       3  );      g  .  addEdge  (  1       3       6  );      g  .  addEdge  (  1       2       2  );      g  .  addEdge  (  2       4       4  );      g  .  addEdge  (  2       5       2  );      g  .  addEdge  (  2       3       7  );      g  .  addEdge  (  3       5       1  );      g  .  addEdge  (  3       4       -1  );      g  .  addEdge  (  4       5       -2  );      int     s     =     1  ;      cout      < <     'Following are longest distances from '       < <     'source vertex '      < <     s      < <     '   n  '  ;      g  .  longestPath  (  s  );      return     0  ;   }
Python3 
   # A Python3 program to find single source    # longest distances in a DAG   import   sys   def   addEdge  (  u     v     w  ):   global   adj   adj  [  u  ]  .  append  ([  v     w  ])   # A recursive function used by longestPath.    # See below link for details.   # https:#www.geeksforgeeks.org/topological-sorting/   def   longestPathUtil  (  v  ):   global   visited     adj    Stack   visited  [  v  ]   =   1   # Recur for all the vertices adjacent   # to this vertex   for   node   in   adj  [  v  ]:   if   (  not   visited  [  node  [  0  ]]):   longestPathUtil  (  node  [  0  ])   # Push current vertex to stack which    # stores topological sort   Stack  .  append  (  v  )   # The function do Topological Sort and finds   # longest distances from given source vertex   def   longestPath  (  s  ):   # Initialize distances to all vertices    # as infinite and   global   visited     Stack     adj    V   dist   =   [  sys  .  maxsize   for   i   in   range  (  V  )]   # for (i = 0 i  < V i++)   # dist[i] = INT_MAX   dist  [  s  ]   =   0   for   i   in   range  (  V  ):   if   (  visited  [  i  ]   ==   0  ):   longestPathUtil  (  i  )   # print(Stack)   while   (  len  (  Stack  )   >   0  ):   # Get the next vertex from topological order   u   =   Stack  [  -  1  ]   del   Stack  [  -  1  ]   if   (  dist  [  u  ]   !=   sys  .  maxsize  ):   # Update distances of all adjacent vertices   # (edge from u -> v exists)   for   v   in   adj  [  u  ]:   # Consider negative weight of edges and   # find shortest path   if   (  dist  [  v  [  0  ]]   >   dist  [  u  ]   +   v  [  1  ]   *   -  1  ):   dist  [  v  [  0  ]]   =   dist  [  u  ]   +   v  [  1  ]   *   -  1   # Print the calculated longest distances   for   i   in   range  (  V  ):   if   (  dist  [  i  ]   ==   sys  .  maxsize  ):   print  (  'INT_MIN '     end   =   ' '  )   else  :   print  (  dist  [  i  ]   *   (  -  1  )   end   =   ' '  )   # Driver code   if   __name__   ==   '__main__'  :   V   =   6   visited   =   [  0   for   i   in   range  (  7  )]   Stack   =   []   adj   =   [[]   for   i   in   range  (  7  )]   addEdge  (  0     1     5  )   addEdge  (  0     2     3  )   addEdge  (  1     3     6  )   addEdge  (  1     2     2  )   addEdge  (  2     4     4  )   addEdge  (  2     5     2  )   addEdge  (  2     3     7  )   addEdge  (  3     5     1  )   addEdge  (  3     4     -  1  )   addEdge  (  4     5     -  2  )   s   =   1   print  (  'Following are longest distances from source vertex'     s  )   longestPath  (  s  )   # This code is contributed by mohit kumar 29
C# 
   // C# program to find single source longest distances   // in a DAG   using     System  ;   using     System.Collections.Generic  ;   // Graph is represented using adjacency list. Every node of   // adjacency list contains vertex number of the vertex to   // which edge connects. It also contains weight of the edge   class     AdjListNode     {      private     int     v  ;      private     int     weight  ;      public     AdjListNode  (  int     _v       int     _w  )      {      v     =     _v  ;      weight     =     _w  ;      }      public     int     getV  ()     {     return     v  ;     }      public     int     getWeight  ()     {     return     weight  ;     }   }   // Graph class represents a directed graph using adjacency   // list representation   class     Graph     {      private     int     V  ;     // No. of vertices      // Pointer to an array containing adjacency lists      private     List   <  AdjListNode  >  []     adj  ;      public     Graph  (  int     v  )     // Constructor      {      V     =     v  ;      adj     =     new     List   <  AdjListNode  >  [     v     ];      for     (  int     i     =     0  ;     i      <     v  ;     i  ++  )      adj  [  i  ]     =     new     List   <  AdjListNode  >  ();      }      public     void     AddEdge  (  int     u       int     v       int     weight  )      {      AdjListNode     node     =     new     AdjListNode  (  v       weight  );      adj  [  u  ].  Add  (  node  );     // Add v to u's list      }      // A recursive function used by longestPath. See below      // link for details.      // https://www.geeksforgeeks.org/dsa/topological-sorting/      private     void     LongestPathUtil  (  int     v       bool  []     visited        Stack   <  int  >     stack  )      {      // Mark the current node as visited      visited  [  v  ]     =     true  ;      // Recur for all the vertices adjacent to this      // vertex      foreach  (  AdjListNode     node     in     adj  [  v  ])      {      if     (  !  visited  [  node  .  getV  ()])      LongestPathUtil  (  node  .  getV  ()     visited        stack  );      }      // Push current vertex to stack which stores      // topological sort      stack  .  Push  (  v  );      }      // The function do Topological Sort and finds longest      // distances from given source vertex      public     void     LongestPath  (  int     s  )      {          // Initialize distances to all vertices as infinite      // and distance to source as 0      int  []     dist     =     new     int  [  V  ];      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      dist  [  i  ]     =     Int32  .  MaxValue  ;      dist  [  s  ]     =     0  ;      Stack   <  int  >     stack     =     new     Stack   <  int  >  ();      // Mark all the vertices as not visited      bool  []     visited     =     new     bool  [  V  ];      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )     {      if     (  visited  [  i  ]     ==     false  )      LongestPathUtil  (  i       visited       stack  );      }      // Process vertices in topological order      while     (  stack  .  Count     >     0  )     {      // Get the next vertex from topological order      int     u     =     stack  .  Pop  ();      if     (  dist  [  u  ]     !=     Int32  .  MaxValue  )     {      // Update distances of all adjacent vertices      // (edge from u -> v exists)      foreach  (  AdjListNode     v     in     adj  [  u  ])      {      // consider negative weight of edges and      // find shortest path      if     (  dist  [  v  .  getV  ()]      >     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  )      dist  [  v  .  getV  ()]      =     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  ;      }      }      }      // Print the calculated longest distances      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )     {      if     (  dist  [  i  ]     ==     Int32  .  MaxValue  )      Console  .  Write  (  'INT_MIN '  );      else      Console  .  Write  (  '{0} '       dist  [  i  ]     *     -  1  );      }      Console  .  WriteLine  ();      }   }   public     class     GFG     {      // Driver code      static     void     Main  (  string  []     args  )      {      Graph     g     =     new     Graph  (  6  );      g  .  AddEdge  (  0       1       5  );      g  .  AddEdge  (  0       2       3  );      g  .  AddEdge  (  1       3       6  );      g  .  AddEdge  (  1       2       2  );      g  .  AddEdge  (  2       4       4  );      g  .  AddEdge  (  2       5       2  );      g  .  AddEdge  (  2       3       7  );      g  .  AddEdge  (  3       5       1  );      g  .  AddEdge  (  3       4       -  1  );      g  .  AddEdge  (  4       5       -  2  );      int     s     =     1  ;      Console  .  WriteLine  (      'Following are longest distances from source vertex {0} '        s  );      g  .  LongestPath  (  s  );      }   }   // This code is contributed by cavi4762.
Java 
   // A Java program to find single source longest distances   // in a DAG   import     java.util.*  ;   // Graph is represented using adjacency list. Every   // node of adjacency list contains vertex number of   // the vertex to which edge connects. It also   // contains weight of the edge   class   AdjListNode     {      private     int     v  ;      private     int     weight  ;      AdjListNode  (  int     _v       int     _w  )      {      v     =     _v  ;      weight     =     _w  ;      }      int     getV  ()     {     return     v  ;     }      int     getWeight  ()     {     return     weight  ;     }   }   // Class to represent a graph using adjacency list   // representation   public     class   GFG     {      int     V  ;     // No. of vertices'      // Pointer to an array containing adjacency lists      ArrayList   <  AdjListNode  >[]     adj  ;      @SuppressWarnings  (  'unchecked'  )      GFG  (  int     V  )     // Constructor      {      this  .  V     =     V  ;      adj     =     new     ArrayList  [  V  ]  ;      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )     {      adj  [  i  ]     =     new     ArrayList   <>  ();      }      }      void     addEdge  (  int     u       int     v       int     weight  )      {      AdjListNode     node     =     new     AdjListNode  (  v       weight  );      adj  [  u  ]  .  add  (  node  );     // Add v to u's list      }      // A recursive function used by longestPath. See      // below link for details https://      // www.geeksforgeeks.org/topological-sorting/      void     topologicalSortUtil  (  int     v       boolean     visited  []        Stack   <  Integer  >     stack  )      {      // Mark the current node as visited      visited  [  v  ]     =     true  ;      // Recur for all the vertices adjacent to this      // vertex      for     (  int     i     =     0  ;     i      <     adj  [  v  ]  .  size  ();     i  ++  )     {      AdjListNode     node     =     adj  [  v  ]  .  get  (  i  );      if     (  !  visited  [  node  .  getV  ()  ]  )      topologicalSortUtil  (  node  .  getV  ()     visited        stack  );      }      // Push current vertex to stack which stores      // topological sort      stack  .  push  (  v  );      }      // The function to find Smallest distances from a      // given vertex. It uses recursive      // topologicalSortUtil() to get topological sorting.      void     longestPath  (  int     s  )      {      Stack   <  Integer  >     stack     =     new     Stack   <  Integer  >  ();      int     dist  []     =     new     int  [  V  ]  ;      // Mark all the vertices as not visited      boolean     visited  []     =     new     boolean  [  V  ]  ;      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      visited  [  i  ]     =     false  ;      // Call the recursive helper function to store      // Topological Sort starting from all vertices      // one by one      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      if     (  visited  [  i  ]     ==     false  )      topologicalSortUtil  (  i       visited       stack  );      // Initialize distances to all vertices as      // infinite and distance to source as 0      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      dist  [  i  ]     =     Integer  .  MAX_VALUE  ;      dist  [  s  ]     =     0  ;      // Process vertices in topological order      while     (  stack  .  isEmpty  ()     ==     false  )     {      // Get the next vertex from topological      // order      int     u     =     stack  .  peek  ();      stack  .  pop  ();      // Update distances of all adjacent vertices      if     (  dist  [  u  ]     !=     Integer  .  MAX_VALUE  )     {      for     (  AdjListNode     v     :     adj  [  u  ]  )     {      if     (  dist  [  v  .  getV  ()  ]      >     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  )      dist  [  v  .  getV  ()  ]      =     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  ;      }      }      }      // Print the calculated longest distances      for     (  int     i     =     0  ;     i      <     V  ;     i  ++  )      if     (  dist  [  i  ]     ==     Integer  .  MAX_VALUE  )      System  .  out  .  print  (  'INF '  );      else      System  .  out  .  print  (  dist  [  i  ]     *     -  1     +     ' '  );      }      // Driver program to test above functions      public     static     void     main  (  String     args  []  )      {      // Create a graph given in the above diagram.      // Here vertex numbers are 0 1 2 3 4 5 with      // following mappings:      // 0=r 1=s 2=t 3=x 4=y 5=z      GFG     g     =     new     GFG  (  6  );      g  .  addEdge  (  0       1       5  );      g  .  addEdge  (  0       2       3  );      g  .  addEdge  (  1       3       6  );      g  .  addEdge  (  1       2       2  );      g  .  addEdge  (  2       4       4  );      g  .  addEdge  (  2       5       2  );      g  .  addEdge  (  2       3       7  );      g  .  addEdge  (  3       5       1  );      g  .  addEdge  (  3       4       -  1  );      g  .  addEdge  (  4       5       -  2  );      int     s     =     1  ;      System  .  out  .  print  (      'Following are longest distances from source vertex '      +     s     +     ' n'  );      g  .  longestPath  (  s  );      }   }   // This code is contributed by Prithi_Dey
JavaScript 
   class     AdjListNode     {      constructor  (  v       weight  )     {      this  .  v     =     v  ;      this  .  weight     =     weight  ;      }      getV  ()     {     return     this  .  v  ;     }      getWeight  ()     {     return     this  .  weight  ;     }   }   class     GFG     {      constructor  (  V  )     {      this  .  V     =     V  ;      this  .  adj     =     new     Array  (  V  );      for     (  let     i     =     0  ;     i      <     V  ;     i  ++  )     {      this  .  adj  [  i  ]     =     new     Array  ();      }      }      addEdge  (  u       v       weight  )     {      let     node     =     new     AdjListNode  (  v       weight  );      this  .  adj  [  u  ].  push  (  node  );      }      topologicalSortUtil  (  v       visited       stack  )     {      visited  [  v  ]     =     true  ;      for     (  let     i     =     0  ;     i      <     this  .  adj  [  v  ].  length  ;     i  ++  )     {      let     node     =     this  .  adj  [  v  ][  i  ];      if     (  !  visited  [  node  .  getV  ()])     {      this  .  topologicalSortUtil  (  node  .  getV  ()     visited       stack  );      }      }      stack  .  push  (  v  );      }      longestPath  (  s  )     {      let     stack     =     new     Array  ();      let     dist     =     new     Array  (  this  .  V  );      let     visited     =     new     Array  (  this  .  V  );      for     (  let     i     =     0  ;     i      <     this  .  V  ;     i  ++  )     {      visited  [  i  ]     =     false  ;      }      for     (  let     i     =     0  ;     i      <     this  .  V  ;     i  ++  )     {      if     (  !  visited  [  i  ])     {      this  .  topologicalSortUtil  (  i       visited       stack  );      }      }      for     (  let     i     =     0  ;     i      <     this  .  V  ;     i  ++  )     {      dist  [  i  ]     =     Number  .  MAX_SAFE_INTEGER  ;      }              dist  [  s  ]     =     0  ;      let     u     =     stack  .  pop  ();      while     (  stack  .  length     >     0  )     {      u     =     stack  .  pop  ();      if     (  dist  [  u  ]     !==     Number  .  MAX_SAFE_INTEGER  )     {      for     (  let     v     of     this  .  adj  [  u  ])     {      if     (  dist  [  v  .  getV  ()]     >     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  )     {      dist  [  v  .  getV  ()]     =     dist  [  u  ]     +     v  .  getWeight  ()     *     -  1  ;      }      }      }   }              for     (  let     i     =     0  ;     i      <     this  .  V  ;     i  ++  )     {      if     (  dist  [  i  ]     ===     Number  .  MAX_SAFE_INTEGER  )     {      console  .  log  (  'INF'  );      }      else     {      console  .  log  (  dist  [  i  ]     *     -  1  );      }      }      }   }   let     g     =     new     GFG  (  6  );   g  .  addEdge  (  0       1       5  );   g  .  addEdge  (  0       2       3  );   g  .  addEdge  (  1       3       6  );   g  .  addEdge  (  1       2       2  );   g  .  addEdge  (  2       4       4  );   g  .  addEdge  (  2       5       2  );   g  .  addEdge  (  2       3       7  );   g  .  addEdge  (  3       5       1  );   g  .  addEdge  (  3       4       -  1  );   g  .  addEdge  (  4       5       -  2  );   console  .  log  (  'Longest distances from the vertex 1 : '  );   g  .  longestPath  (  1  );   //this code is contributed by devendra

Uitvoer 
Following are longest distances from source vertex 1 INT_MIN 0 2 9 8 10

Tijdcomplexiteit : Tijdscomplexiteit van topologische sortering is O(V+E). Nadat de topologische volgorde is gevonden, verwerkt het algoritme alle hoekpunten en voert het voor elk hoekpunt een lus uit voor alle aangrenzende hoekpunten. Omdat het totale aantal aangrenzende hoekpunten in een grafiek O(E) is, loopt de binnenste lus O(V + E) keer. Daarom is de totale tijdscomplexiteit van dit algoritme O(V + E).

Ruimtecomplexiteit:
De ruimtecomplexiteit van het bovenstaande algoritme is O(V). We slaan de uitvoerarray en een stapel op voor topologische sortering.


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