MINIMUM TRINN FOR Å NÅ SLUTTEN AV ARRAYET UNDER BEGRENSNINGER

Gitt en matrise som inneholder ett-sifrede tall bare forutsatt at vi står ved første indeks, må vi nå til slutten av matrisen ved å bruke minimum antall trinn, hvor vi i ett trinn kan hoppe til naboindekser eller kan hoppe til en posisjon med samme verdi.
Med andre ord hvis vi er ved indeks i, kan du i ett trinn nå til arr[i-1] eller arr[i+1] eller arr[K] slik at arr[K] = arr[i] (verdien av arr[K] er den samme som arr[i])

Eksempler:

Input : arr[] = {5 4 2 5 0} Output : 2 Explanation : Total 2 step required. We start from 5(0) in first step jump to next 5 and in second step we move to value 0 (End of arr[]). Input : arr[] = [0 1 2 3 4 5 6 7 5 4 3 6 0 1 2 3 4 5 7] Output : 5 Explanation : Total 5 step required. 0(0) -> 0(12) -> 6(11) -> 6(6) -> 7(7) -> (18) (inside parenthesis indices are shown)

Dette problemet kan løses ved hjelp av BFS . Vi kan betrakte den gitte matrisen som uvektet graf der hvert toppunkt har to kanter til neste og forrige matriseelementer og flere kanter til matriseelementer med samme verdier. Nå for rask behandling av tredje type kanter beholder vi 10 vektorer som lagrer alle indekser der sifrene 0 til 9 er tilstede. I eksempelet ovenfor vil vektor som tilsvarer 0 lagre [0 12] 2 indekser der 0 har oppstått i gitt matrise.

En annen boolsk matrise brukes slik at vi ikke besøker samme indeks mer enn én gang. Ettersom vi bruker BFS og BFS, er inntektene nivå for nivå garantert optimale minimumstrinn.

Implementering:

C++

    // C++ program to find minimum jumps to reach end   // of array   #include          using     namespace     std  ;   // Method returns minimum step to reach end of array   int     getMinStepToReachEnd  (  int     arr  []     int     N  )   {      // visit boolean array checks whether current index      // is previously visited      bool     visit  [  N  ];      // distance array stores distance of current      // index from starting index      int     distance  [  N  ];      // digit vector stores indices where a      // particular number resides      vector   <  int  >     digit  [  10  ];      // In starting all index are unvisited      memset  (  visit       false       sizeof  (  visit  ));      // storing indices of each number in digit vector      for     (  int     i     =     1  ;     i      <     N  ;     i  ++  )      digit  [  arr  [  i  ]].  push_back  (  i  );      // for starting index distance will be zero      distance  [  0  ]     =     0  ;      visit  [  0  ]     =     true  ;      // Creating a queue and inserting index 0.      queue   <  int  >     q  ;      q  .  push  (  0  );      // loop until queue in not empty      while  (  !  q  .  empty  ())      {      // Get an item from queue q.      int     idx     =     q  .  front  ();     q  .  pop  ();      // If we reached to last index break from loop      if     (  idx     ==     N  -1  )      break  ;      // Find value of dequeued index      int     d     =     arr  [  idx  ];      // looping for all indices with value as d.      for     (  int     i     =     0  ;     i   <  digit  [  d  ].  size  ();     i  ++  )      {      int     nextidx     =     digit  [  d  ][  i  ];      if     (  !  visit  [  nextidx  ])      {      visit  [  nextidx  ]     =     true  ;      q  .  push  (  nextidx  );      // update the distance of this nextidx      distance  [  nextidx  ]     =     distance  [  idx  ]     +     1  ;      }      }      // clear all indices for digit d because all      // of them are processed      digit  [  d  ].  clear  ();      // checking condition for previous index      if     (  idx  -1     >=     0     &&     !  visit  [  idx     -     1  ])      {      visit  [  idx     -     1  ]     =     true  ;      q  .  push  (  idx     -     1  );      distance  [  idx     -     1  ]     =     distance  [  idx  ]     +     1  ;      }      // checking condition for next index      if     (  idx     +     1      <     N     &&     !  visit  [  idx     +     1  ])      {      visit  [  idx     +     1  ]     =     true  ;      q  .  push  (  idx     +     1  );      distance  [  idx     +     1  ]     =     distance  [  idx  ]     +     1  ;      }      }      // N-1th position has the final result      return     distance  [  N     -     1  ];   }   // driver code to test above methods   int     main  ()   {      int     arr  []     =     {  0       1       2       3       4       5       6       7       5        4       3       6       0       1       2       3       4       5       7  };      int     N     =     sizeof  (  arr  )     /     sizeof  (  int  );      cout      < <     getMinStepToReachEnd  (  arr       N  );      return     0  ;   }

Java

    // Java program to find minimum jumps    // to reach end of array   import     java.util.*  ;   class   GFG   {   // Method returns minimum step    // to reach end of array   static     int     getMinStepToReachEnd  (  int     arr  []           int     N  )   {      // visit boolean array checks whether       // current index is previously visited      boolean     []  visit     =     new     boolean  [  N  ]  ;      // distance array stores distance of       // current index from starting index      int     []  distance     =     new     int  [  N  ]  ;      // digit vector stores indices where a      // particular number resides      Vector   <  Integer  >     []  digit     =     new     Vector  [  10  ]  ;      for  (  int     i     =     0  ;     i      <     10  ;     i  ++  )      digit  [  i  ]     =     new     Vector   <>  ();      // In starting all index are unvisited      for  (  int     i     =     0  ;     i      <     N  ;     i  ++  )      visit  [  i  ]     =     false  ;      // storing indices of each number      // in digit vector      for     (  int     i     =     1  ;     i      <     N  ;     i  ++  )      digit  [  arr  [  i  ]]  .  add  (  i  );      // for starting index distance will be zero      distance  [  0  ]     =     0  ;      visit  [  0  ]     =     true  ;      // Creating a queue and inserting index 0.      Queue   <  Integer  >     q     =     new     LinkedList   <>  ();      q  .  add  (  0  );      // loop until queue in not empty      while  (  !  q  .  isEmpty  ())      {      // Get an item from queue q.      int     idx     =     q  .  peek  ();         q  .  remove  ();      // If we reached to last       // index break from loop      if     (  idx     ==     N     -     1  )      break  ;      // Find value of dequeued index      int     d     =     arr  [  idx  ]  ;      // looping for all indices with value as d.      for     (  int     i     =     0  ;     i      <     digit  [  d  ]  .  size  ();     i  ++  )      {      int     nextidx     =     digit  [  d  ]  .  get  (  i  );      if     (  !  visit  [  nextidx  ]  )      {      visit  [  nextidx  ]     =     true  ;      q  .  add  (  nextidx  );      // update the distance of this nextidx      distance  [  nextidx  ]     =     distance  [  idx  ]     +     1  ;      }      }      // clear all indices for digit d       // because all of them are processed      digit  [  d  ]  .  clear  ();      // checking condition for previous index      if     (  idx     -     1     >=     0     &&     !  visit  [  idx     -     1  ]  )      {      visit  [  idx     -     1  ]     =     true  ;      q  .  add  (  idx     -     1  );      distance  [  idx     -     1  ]     =     distance  [  idx  ]     +     1  ;      }      // checking condition for next index      if     (  idx     +     1      <     N     &&     !  visit  [  idx     +     1  ]  )      {      visit  [  idx     +     1  ]     =     true  ;      q  .  add  (  idx     +     1  );      distance  [  idx     +     1  ]     =     distance  [  idx  ]     +     1  ;      }      }      // N-1th position has the final result      return     distance  [  N     -     1  ]  ;   }   // Driver Code   public     static     void     main  (  String     []  args  )   {      int     arr  []     =     {  0       1       2       3       4       5       6       7       5        4       3       6       0       1       2       3       4       5       7  };      int     N     =     arr  .  length  ;      System  .  out  .  println  (  getMinStepToReachEnd  (  arr       N  ));   }   }   // This code is contributed by 29AjayKumar

Python3

    # Python 3 program to find minimum jumps to reach end# of array   # Method returns minimum step to reach end of array   def   getMinStepToReachEnd  (  arr    N  ):   # visit boolean array checks whether current index   # is previously visited   visit   =   [  False   for   i   in   range  (  N  )]   # distance array stores distance of current   # index from starting index   distance   =   [  0   for   i   in   range  (  N  )]   # digit vector stores indices where a   # particular number resides   digit   =   [[  0   for   i   in   range  (  N  )]   for   j   in   range  (  10  )]   # storing indices of each number in digit vector   for   i   in   range  (  1    N  ):   digit  [  arr  [  i  ]]  .  append  (  i  )   # for starting index distance will be zero   distance  [  0  ]   =   0   visit  [  0  ]   =   True   # Creating a queue and inserting index 0.   q   =   []   q  .  append  (  0  )   # loop until queue in not empty   while  (  len  (  q  )  >   0  ):   # Get an item from queue q.   idx   =   q  [  0  ]   q  .  remove  (  q  [  0  ])   # If we reached to last index break from loop   if   (  idx   ==   N  -  1  ):   break   # Find value of dequeued index   d   =   arr  [  idx  ]   # looping for all indices with value as d.   for   i   in   range  (  len  (  digit  [  d  ])):   nextidx   =   digit  [  d  ][  i  ]   if   (  visit  [  nextidx  ]   ==   False  ):   visit  [  nextidx  ]   =   True   q  .  append  (  nextidx  )   # update the distance of this nextidx   distance  [  nextidx  ]   =   distance  [  idx  ]   +   1   # clear all indices for digit d because all   # of them are processed   # checking condition for previous index   if   (  idx  -  1   >=   0   and   visit  [  idx   -   1  ]   ==   False  ):   visit  [  idx   -   1  ]   =   True   q  .  append  (  idx   -   1  )   distance  [  idx   -   1  ]   =   distance  [  idx  ]   +   1   # checking condition for next index   if   (  idx   +   1    <   N   and   visit  [  idx   +   1  ]   ==   False  ):   visit  [  idx   +   1  ]   =   True   q  .  append  (  idx   +   1  )   distance  [  idx   +   1  ]   =   distance  [  idx  ]   +   1   # N-1th position has the final result   return   distance  [  N   -   1  ]   # driver code to test above methods   if   __name__   ==   '__main__'  :   arr   =   [  0     1     2     3     4     5     6     7     5     4     3     6     0     1     2     3     4     5     7  ]   N   =   len  (  arr  )   print  (  getMinStepToReachEnd  (  arr     N  ))   # This code is contributed by   # Surendra_Gangwar

    // C# program to find minimum jumps    // to reach end of array    using     System  ;   using     System.Collections.Generic  ;   class     GFG   {   // Method returns minimum step    // to reach end of array   static     int     getMinStepToReachEnd  (  int     []  arr           int     N  )   {      // visit boolean array checks whether       // current index is previously visited      bool     []  visit     =     new     bool  [  N  ];      // distance array stores distance of       // current index from starting index      int     []  distance     =     new     int  [  N  ];      // digit vector stores indices where a      // particular number resides      List   <  int  >     []  digit     =     new     List   <  int  >  [  10  ];      for  (  int     i     =     0  ;     i      <     10  ;     i  ++  )      digit  [  i  ]     =     new     List   <  int  >  ();      // In starting all index are unvisited      for  (  int     i     =     0  ;     i      <     N  ;     i  ++  )      visit  [  i  ]     =     false  ;      // storing indices of each number      // in digit vector      for     (  int     i     =     1  ;     i      <     N  ;     i  ++  )      digit  [  arr  [  i  ]].  Add  (  i  );      // for starting index distance will be zero      distance  [  0  ]     =     0  ;      visit  [  0  ]     =     true  ;      // Creating a queue and inserting index 0.      Queue   <  int  >     q     =     new     Queue   <  int  >  ();      q  .  Enqueue  (  0  );      // loop until queue in not empty      while  (  q  .  Count     !=     0  )      {      // Get an item from queue q.      int     idx     =     q  .  Peek  ();         q  .  Dequeue  ();      // If we reached to last       // index break from loop      if     (  idx     ==     N     -     1  )      break  ;      // Find value of dequeued index      int     d     =     arr  [  idx  ];      // looping for all indices with value as d.      for     (  int     i     =     0  ;     i      <     digit  [  d  ].  Count  ;     i  ++  )      {      int     nextidx     =     digit  [  d  ][  i  ];      if     (  !  visit  [  nextidx  ])      {      visit  [  nextidx  ]     =     true  ;      q  .  Enqueue  (  nextidx  );      // update the distance of this nextidx      distance  [  nextidx  ]     =     distance  [  idx  ]     +     1  ;      }      }      // clear all indices for digit d       // because all of them are processed      digit  [  d  ].  Clear  ();      // checking condition for previous index      if     (  idx     -     1     >=     0     &&     !  visit  [  idx     -     1  ])      {      visit  [  idx     -     1  ]     =     true  ;      q  .  Enqueue  (  idx     -     1  );      distance  [  idx     -     1  ]     =     distance  [  idx  ]     +     1  ;      }      // checking condition for next index      if     (  idx     +     1      <     N     &&     !  visit  [  idx     +     1  ])      {      visit  [  idx     +     1  ]     =     true  ;      q  .  Enqueue  (  idx     +     1  );      distance  [  idx     +     1  ]     =     distance  [  idx  ]     +     1  ;      }      }      // N-1th position has the final result      return     distance  [  N     -     1  ];   }   // Driver Code   public     static     void     Main  (  String     []  args  )   {      int     []  arr     =     {  0       1       2       3       4       5       6       7       5        4       3       6       0       1       2       3       4       5       7  };      int     N     =     arr  .  Length  ;      Console  .  WriteLine  (  getMinStepToReachEnd  (  arr       N  ));   }   }   // This code is contributed by PrinciRaj1992

JavaScript

     <  script  >   // Javascript program to find minimum jumps    // to reach end of array   // Method returns minimum step    // to reach end of array   function     getMinStepToReachEnd  (  arr    N  )   {      // visit boolean array checks whether       // current index is previously visited      let     visit     =     new     Array  (  N  );          // distance array stores distance of       // current index from starting index      let     distance     =     new     Array  (  N  );          // digit vector stores indices where a      // particular number resides      let     digit     =     new     Array  (  10  );      for  (  let     i     =     0  ;     i      <     10  ;     i  ++  )      digit  [  i  ]     =     [];          // In starting all index are unvisited      for  (  let     i     =     0  ;     i      <     N  ;     i  ++  )      visit  [  i  ]     =     false  ;          // storing indices of each number      // in digit vector      for     (  let     i     =     1  ;     i      <     N  ;     i  ++  )      digit  [  arr  [  i  ]].  push  (  i  );          // for starting index distance will be zero      distance  [  0  ]     =     0  ;      visit  [  0  ]     =     true  ;          // Creating a queue and inserting index 0.      let     q     =     [];      q  .  push  (  0  );          // loop until queue in not empty      while  (  q  .  length  !=  0  )      {      // Get an item from queue q.      let     idx     =     q  .  shift  ();                 // If we reached to last       // index break from loop      if     (  idx     ==     N     -     1  )      break  ;          // Find value of dequeued index      let     d     =     arr  [  idx  ];          // looping for all indices with value as d.      for     (  let     i     =     0  ;     i      <     digit  [  d  ].  length  ;     i  ++  )      {      let     nextidx     =     digit  [  d  ][  i  ];      if     (  !  visit  [  nextidx  ])      {      visit  [  nextidx  ]     =     true  ;      q  .  push  (  nextidx  );          // update the distance of this nextidx      distance  [  nextidx  ]     =     distance  [  idx  ]     +     1  ;      }      }          // clear all indices for digit d       // because all of them are processed      digit  [  d  ]  =  [];          // checking condition for previous index      if     (  idx     -     1     >=     0     &&     !  visit  [  idx     -     1  ])      {      visit  [  idx     -     1  ]     =     true  ;      q  .  push  (  idx     -     1  );      distance  [  idx     -     1  ]     =     distance  [  idx  ]     +     1  ;      }          // checking condition for next index      if     (  idx     +     1      <     N     &&     !  visit  [  idx     +     1  ])      {      visit  [  idx     +     1  ]     =     true  ;      q  .  push  (  idx     +     1  );      distance  [  idx     +     1  ]     =     distance  [  idx  ]     +     1  ;      }      }          // N-1th position has the final result      return     distance  [  N     -     1  ];   }   // Driver Code   let     arr  =  [  0       1       2       3       4       5       6       7       5        4       3       6       0       1       2       3       4       5       7  ];   let     N     =     arr  .  length  ;   document  .  write  (  getMinStepToReachEnd  (  arr       N  ));      // This code is contributed by rag2127    <  /script>

Produksjon

Tidskompleksitet: O(N) hvor N er antall elementer i matrisen.

Romkompleksitet: O(N) hvor N er antall elementer i matrisen. Vi bruker en avstands- og besøksarray av størrelse N og en kø i størrelse N for å lagre indeksene til arrayet.

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