Vzhľadom na a ray arr[] z veľkosť n úlohou je nájsť najdlhšia podsekvencia také, že absolútny rozdiel medzi susedné prvky je 1.
Príklady:
Vstup: arr[] = [10 9 4 5 4 8 6]
výstup: 3
Vysvetlenie: Tri možné podsekvencie dĺžky 3 sú [10 9 8] [4 5 4] a [4 5 6], kde susedné prvky majú absolútny rozdiel 1. Nebolo možné vytvoriť platnú podsekvenciu väčšej dĺžky.
Vstup: arr[] = [1 2 3 4 5]
výstup: 5
Vysvetlenie: Všetky prvky môžu byť zahrnuté do platnej podsekvencie.
Použitie rekurzie - O(2^n) čas a O(n) priestor
C++Pre rekurzívny prístup zvážime dva prípady v každom kroku:
- Ak prvok spĺňa podmienku ( absolútny rozdiel medzi susednými prvkami je 1) my zahŕňajú v nasledujúcom poradí a prejdite na ďalšie prvok.
- inak my preskočiť na prúd prvok a prejdite na ďalší.
Matematicky recidívny vzťah bude vyzerať nasledovne:
base64 dekódovať v js
- longestSubseq(arr idx prev) = max(longestSubseq(arr idx + 1 prev) 1 + longestSubseq (arr idx + 1 idx))
Základný prípad:
- Kedy idx == arr.size() máme dosiahnuté koniec poľa tak vrátiť 0 (keďže nie je možné zahrnúť žiadne ďalšie prvky).
// C++ program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion. #include
// Java program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion. import java.util.ArrayList; class GfG { // Helper function to recursively find the subsequence static int subseqHelper(int idx int prev ArrayList<Integer> arr) { // Base case: if index reaches the end of the array if (idx == arr.size()) { return 0; } // Skip the current element and move to the next index int noTake = subseqHelper(idx + 1 prev arr); // Take the current element if the condition is met int take = 0; if (prev == -1 || Math.abs(arr.get(idx) - arr.get(prev)) == 1) { take = 1 + subseqHelper(idx + 1 idx arr); } // Return the maximum of the two options return Math.max(take noTake); } // Function to find the longest subsequence static int longestSubseq(ArrayList<Integer> arr) { // Start recursion from index 0 // with no previous element return subseqHelper(0 -1 arr); } public static void main(String[] args) { ArrayList<Integer> arr = new ArrayList<>(); arr.add(10); arr.add(9); arr.add(4); arr.add(5); arr.add(4); arr.add(8); arr.add(6); System.out.println(longestSubseq(arr)); } }
# Python program to find the longest subsequence such that # the difference between adjacent elements is one using # recursion. def subseq_helper(idx prev arr): # Base case: if index reaches the end of the array if idx == len(arr): return 0 # Skip the current element and move to the next index no_take = subseq_helper(idx + 1 prev arr) # Take the current element if the condition is met take = 0 if prev == -1 or abs(arr[idx] - arr[prev]) == 1: take = 1 + subseq_helper(idx + 1 idx arr) # Return the maximum of the two options return max(take no_take) def longest_subseq(arr): # Start recursion from index 0 # with no previous element return subseq_helper(0 -1 arr) if __name__ == '__main__': arr = [10 9 4 5 4 8 6] print(longest_subseq(arr))
// C# program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion. using System; using System.Collections.Generic; class GfG { // Helper function to recursively find the subsequence static int SubseqHelper(int idx int prev List<int> arr) { // Base case: if index reaches the end of the array if (idx == arr.Count) { return 0; } // Skip the current element and move to the next index int noTake = SubseqHelper(idx + 1 prev arr); // Take the current element if the condition is met int take = 0; if (prev == -1 || Math.Abs(arr[idx] - arr[prev]) == 1) { take = 1 + SubseqHelper(idx + 1 idx arr); } // Return the maximum of the two options return Math.Max(take noTake); } // Function to find the longest subsequence static int LongestSubseq(List<int> arr) { // Start recursion from index 0 // with no previous element return SubseqHelper(0 -1 arr); } static void Main(string[] args) { List<int> arr = new List<int> { 10 9 4 5 4 8 6 }; Console.WriteLine(LongestSubseq(arr)); } }
// JavaScript program to find the longest subsequence // such that the difference between adjacent elements // is one using recursion. function subseqHelper(idx prev arr) { // Base case: if index reaches the end of the array if (idx === arr.length) { return 0; } // Skip the current element and move to the next index let noTake = subseqHelper(idx + 1 prev arr); // Take the current element if the condition is met let take = 0; if (prev === -1 || Math.abs(arr[idx] - arr[prev]) === 1) { take = 1 + subseqHelper(idx + 1 idx arr); } // Return the maximum of the two options return Math.max(take noTake); } function longestSubseq(arr) { // Start recursion from index 0 // with no previous element return subseqHelper(0 -1 arr); } const arr = [10 9 4 5 4 8 6]; console.log(longestSubseq(arr));
Výstup
3
Používanie zhora nadol DP (memoization ) - O(n^2) Čas a O(n^2) Priestor
Ak si pozorne všimneme, môžeme pozorovať, že vyššie uvedené rekurzívne riešenie má nasledujúce dve vlastnosti Dynamické programovanie :
1. Optimálna spodná štruktúra: Riešenie na nájdenie najdlhšej podsekvencie tak, že rozdiel medzi susednými prvkami je možné odvodiť z optimálnych riešení menších čiastkových problémov. Konkrétne pre akúkoľvek danosť idx (aktuálny index) a predch (predchádzajúci index v podsekvencii) môžeme rekurzívny vzťah vyjadriť takto:
- subseqHelper(idx predchádzajúce) = max(subseqHelper(idx + 1 predchádzajúce) 1 + subseqHelper(idx + 1 idx))
2. Prekrývajúce sa čiastkové problémy: Pri realizácii a rekurzívne prístup k riešeniu problému pozorujeme, že mnohé podproblémy sa počítajú viackrát. Napríklad pri výpočte subseqHelper(0 -1) pre pole arr = [10 9 4 5] podproblém subseqHelper(2 -1) možno vypočítať viacnásobný krát. Aby sme sa vyhli tomuto opakovaniu, používame memoizáciu na ukladanie výsledkov predtým vypočítaných čiastkových problémov.
Rekurzívne riešenie zahŕňa dve parametre:
- idx (aktuálny index v poli).
- predch (index posledného zahrnutého prvku v podsekvencii).
Musíme sledovať oba parametre tak vytvoríme a 2D pole poznámky z veľkosť (n) x (n+1) . Inicializujeme 2D pole poznámky s -1 čo znamená, že ešte neboli vypočítané žiadne čiastkové problémy. Pred výpočtom výsledku skontrolujeme, či je hodnota at memo[idx][prev+1] je -1. Ak áno, vypočítame a obchod výsledok. V opačnom prípade vrátime uložený výsledok.
C++// C++ program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion with memoization. #include
// Java program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion with memoization. import java.util.ArrayList; import java.util.Arrays; class GfG { // Helper function to recursively find the subsequence static int subseqHelper(int idx int prev ArrayList<Integer> arr int[][] memo) { // Base case: if index reaches the end of the array if (idx == arr.size()) { return 0; } // Check if the result is already computed if (memo[idx][prev + 1] != -1) { return memo[idx][prev + 1]; } // Skip the current element and move to the next index int noTake = subseqHelper(idx + 1 prev arr memo); // Take the current element if the condition is met int take = 0; if (prev == -1 || Math.abs(arr.get(idx) - arr.get(prev)) == 1) { take = 1 + subseqHelper(idx + 1 idx arr memo); } // Store the result in the memo table memo[idx][prev + 1] = Math.max(take noTake); // Return the stored result return memo[idx][prev + 1]; } // Function to find the longest subsequence static int longestSubseq(ArrayList<Integer> arr) { int n = arr.size(); // Create a memoization table initialized to -1 int[][] memo = new int[n][n + 1]; for (int[] row : memo) { Arrays.fill(row -1); } // Start recursion from index 0 // with no previous element return subseqHelper(0 -1 arr memo); } public static void main(String[] args) { ArrayList<Integer> arr = new ArrayList<>(); arr.add(10); arr.add(9); arr.add(4); arr.add(5); arr.add(4); arr.add(8); arr.add(6); System.out.println(longestSubseq(arr)); } }
# Python program to find the longest subsequence such that # the difference between adjacent elements is one using # recursion with memoization. def subseq_helper(idx prev arr memo): # Base case: if index reaches the end of the array if idx == len(arr): return 0 # Check if the result is already computed if memo[idx][prev + 1] != -1: return memo[idx][prev + 1] # Skip the current element and move to the next index no_take = subseq_helper(idx + 1 prev arr memo) # Take the current element if the condition is met take = 0 if prev == -1 or abs(arr[idx] - arr[prev]) == 1: take = 1 + subseq_helper(idx + 1 idx arr memo) # Store the result in the memo table memo[idx][prev + 1] = max(take no_take) # Return the stored result return memo[idx][prev + 1] def longest_subseq(arr): n = len(arr) # Create a memoization table initialized to -1 memo = [[-1 for _ in range(n + 1)] for _ in range(n)] # Start recursion from index 0 with # no previous element return subseq_helper(0 -1 arr memo) if __name__ == '__main__': arr = [10 9 4 5 4 8 6] print(longest_subseq(arr))
// C# program to find the longest subsequence such that // the difference between adjacent elements is one using // recursion with memoization. using System; using System.Collections.Generic; class GfG { // Helper function to recursively find the subsequence static int SubseqHelper(int idx int prev List<int> arr int[] memo) { // Base case: if index reaches the end of the array if (idx == arr.Count) { return 0; } // Check if the result is already computed if (memo[idx prev + 1] != -1) { return memo[idx prev + 1]; } // Skip the current element and move to the next index int noTake = SubseqHelper(idx + 1 prev arr memo); // Take the current element if the condition is met int take = 0; if (prev == -1 || Math.Abs(arr[idx] - arr[prev]) == 1) { take = 1 + SubseqHelper(idx + 1 idx arr memo); } // Store the result in the memoization table memo[idx prev + 1] = Math.Max(take noTake); // Return the stored result return memo[idx prev + 1]; } // Function to find the longest subsequence static int LongestSubseq(List<int> arr) { int n = arr.Count; // Create a memoization table initialized to -1 int[] memo = new int[n n + 1]; for (int i = 0; i < n; i++) { for (int j = 0; j <= n; j++) { memo[i j] = -1; } } // Start recursion from index 0 with no previous element return SubseqHelper(0 -1 arr memo); } static void Main(string[] args) { List<int> arr = new List<int> { 10 9 4 5 4 8 6 }; Console.WriteLine(LongestSubseq(arr)); } }
// JavaScript program to find the longest subsequence // such that the difference between adjacent elements // is one using recursion with memoization. function subseqHelper(idx prev arr memo) { // Base case: if index reaches the end of the array if (idx === arr.length) { return 0; } // Check if the result is already computed if (memo[idx][prev + 1] !== -1) { return memo[idx][prev + 1]; } // Skip the current element and move to the next index let noTake = subseqHelper(idx + 1 prev arr memo); // Take the current element if the condition is met let take = 0; if (prev === -1 || Math.abs(arr[idx] - arr[prev]) === 1) { take = 1 + subseqHelper(idx + 1 idx arr memo); } // Store the result in the memoization table memo[idx][prev + 1] = Math.max(take noTake); // Return the stored result return memo[idx][prev + 1]; } function longestSubseq(arr) { let n = arr.length; // Create a memoization table initialized to -1 let memo = Array.from({ length: n } () => Array(n + 1).fill(-1)); // Start recursion from index 0 with no previous element return subseqHelper(0 -1 arr memo); } const arr = [10 9 4 5 4 8 6]; console.log(longestSubseq(arr));
Výstup
3
Použitie DP zdola nahor (tabuľka) – O(n) Čas a O(n) Priestor
Prístup je podobný ako rekurzívne ale namiesto rekurzívneho rozdelenia problému iteračne zostavujeme riešenie v a spôsobom zdola nahor.
Namiesto použitia rekurzie využívame a hashmap dynamická programovacia tabuľka (dp) uložiť dĺžky z najdlhších podsekvencií. To nám pomáha efektívne vypočítať a aktualizovať podsekvencia dĺžky pre všetky možné hodnoty prvkov poľa.
C++Vzťah dynamického programovania:
dp[x] predstavuje dĺžka najdlhšej podsekvencie končiacej prvkom x.
Pre každý prvok arr[i] v poli: Ak arr[i] + 1 alebo arr[i] - 1 existuje v dp:
- dp[arr[i]] = 1 + max(dp[arr[i] + 1] dp[arr[i] - 1]);
To znamená, že môžeme rozšíriť podsekvencie končiace na arr[i] + 1 alebo arr[i] - 1 podľa vrátane arr[i].
V opačnom prípade začnite novú podsekvenciu:
- dp[arr[i]] = 1;
// C++ program to find the longest subsequence such that // the difference between adjacent elements is one using // Tabulation. #include
// Java code to find the longest subsequence such that // the difference between adjacent elements // is one using Tabulation. import java.util.HashMap; import java.util.ArrayList; class GfG { static int longestSubseq(ArrayList<Integer> arr) { int n = arr.size(); // Base case: if the array has only one element if (n == 1) { return 1; } // Map to store the length of the longest subsequence HashMap<Integer Integer> dp = new HashMap<>(); int ans = 1; // Loop through the array to fill the map // with subsequence lengths for (int i = 0; i < n; ++i) { // Check if the current element is adjacent // to another subsequence if (dp.containsKey(arr.get(i) + 1) || dp.containsKey(arr.get(i) - 1)) { dp.put(arr.get(i) 1 + Math.max(dp.getOrDefault(arr.get(i) + 1 0) dp.getOrDefault(arr.get(i) - 1 0))); } else { dp.put(arr.get(i) 1); } // Update the result with the maximum // subsequence length ans = Math.max(ans dp.get(arr.get(i))); } return ans; } public static void main(String[] args) { ArrayList<Integer> arr = new ArrayList<>(); arr.add(10); arr.add(9); arr.add(4); arr.add(5); arr.add(4); arr.add(8); arr.add(6); System.out.println(longestSubseq(arr)); } }
# Python code to find the longest subsequence such that # the difference between adjacent elements is # one using Tabulation. def longestSubseq(arr): n = len(arr) # Base case: if the array has only one element if n == 1: return 1 # Dictionary to store the length of the # longest subsequence dp = {} ans = 1 for i in range(n): # Check if the current element is adjacent to # another subsequence if arr[i] + 1 in dp or arr[i] - 1 in dp: dp[arr[i]] = 1 + max(dp.get(arr[i] + 1 0) dp.get(arr[i] - 1 0)) else: dp[arr[i]] = 1 # Update the result with the maximum # subsequence length ans = max(ans dp[arr[i]]) return ans if __name__ == '__main__': arr = [10 9 4 5 4 8 6] print(longestSubseq(arr))
// C# code to find the longest subsequence such that // the difference between adjacent elements // is one using Tabulation. using System; using System.Collections.Generic; class GfG { static int longestSubseq(List<int> arr) { int n = arr.Count; // Base case: if the array has only one element if (n == 1) { return 1; } // Map to store the length of the longest subsequence Dictionary<int int> dp = new Dictionary<int int>(); int ans = 1; // Loop through the array to fill the map with // subsequence lengths for (int i = 0; i < n; ++i) { // Check if the current element is adjacent to // another subsequence if (dp.ContainsKey(arr[i] + 1) || dp.ContainsKey(arr[i] - 1)) { dp[arr[i]] = 1 + Math.Max(dp.GetValueOrDefault(arr[i] + 1 0) dp.GetValueOrDefault(arr[i] - 1 0)); } else { dp[arr[i]] = 1; } // Update the result with the maximum // subsequence length ans = Math.Max(ans dp[arr[i]]); } return ans; } static void Main(string[] args) { List<int> arr = new List<int> { 10 9 4 5 4 8 6 }; Console.WriteLine(longestSubseq(arr)); } }
// Function to find the longest subsequence such that // the difference between adjacent elements // is one using Tabulation. function longestSubseq(arr) { const n = arr.length; // Base case: if the array has only one element if (n === 1) { return 1; } // Object to store the length of the // longest subsequence let dp = {}; let ans = 1; // Loop through the array to fill the object // with subsequence lengths for (let i = 0; i < n; i++) { // Check if the current element is adjacent to // another subsequence if ((arr[i] + 1) in dp || (arr[i] - 1) in dp) { dp[arr[i]] = 1 + Math.max(dp[arr[i] + 1] || 0 dp[arr[i] - 1] || 0); } else { dp[arr[i]] = 1; } // Update the result with the maximum // subsequence length ans = Math.max(ans dp[arr[i]]); } return ans; } const arr = [10 9 4 5 4 8 6]; console.log(longestSubseq(arr));
Výstup
3Vytvoriť kvíz