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📜  由相同元素组成的最长子数组的长度最多增加K个减量

📅  最后修改于: 2021-04-17 12:44:29             🧑  作者: Mango

给定大小为N且整数K的数组arr [] ,任务是找到由相同元素组成的最长子数组的长度,该长度可以通过将数组元素最多K1来获得。

例子:

方法:可以使用段树和二进制搜索技术解决该问题。这个想法是使用以下观察:

请按照以下步骤解决以上问题:

  1. 初始化段树以计算数组的子数组中的最小元素,并初始化前缀和数组以计算子数组的和元素。
  2. 遍历数组arr [] 。对于i元素,请执行以下操作:
    • 初始化两个变量,即start = iend = N – 1并在[start,end]范围内应用二进制搜索以检查子数组{arr [start],…,arr [end]}的所有元素是否都可以通过从上述观察中最多减少K个运算,可以使相等或不相等。
    • 如果子数组{arr [start],…,arr [end]}的所有元素可以通过最多减少K个操作而相等,则更新start =(start + end)/ 2 +1
    • 否则,更新结束=(开始+结束)/ 2 – 1
  3. 最后,打印从上述操作获得的最长子数组的长度。

下面是上述方法的实现:

C++
// C++ program to implement
// the above appraoch
 
#include 
using namespace std;
 
// Function to construct Segment Tree
// to return the minimum element in a range
int build(int tree[], int* A, int start,
          int end, int node)
{
    // If leaf nodes of
    // the tree are found
    if (start == end) {
 
        // Update the value in segment
        // tree from given array
        tree[node] = A[start];
 
        return tree[node];
    }
 
    // Divide left and right subtree
    int mid = (start + end) / 2;
 
    // Stores smallest element in
    // subarray { arr[start], arr[mid] }
    int X = build(tree, A, start, mid,
                  2 * node + 1);
 
    // Stores smallest element in
    // subarray { arr[mid + 1], arr[end] }
    int Y = build(tree, A, mid + 1,
                  end, 2 * node + 2);
 
    // Stores smallest element in
    // subarray { arr[start], arr[end] }
    return tree[node] = min(X, Y);
}
 
// Function to find the smallest
// element present in a subarray
int query(int tree[], int start, int end,
          int l, int r, int node)
{
    // If elements of the subarray
    // are not in the range [l, r]
    if (start > r || end < l)
        return INT_MAX;
 
    // If all the elements of the
    // subarray are in the range [l, r]
    if (start >= l && end <= r)
        return tree[node];
 
    // Divide tree into left
    // and right subtree
    int mid = (start + end) / 2;
 
    // Stores smallest element
    // in left subtree
    int X = query(tree, start, mid, l,
                  r, 2 * node + 1);
 
    // Stores smallest element in
    // right subtree
    int Y = query(tree, mid + 1, end, l,
                  r, 2 * node + 2);
 
    return min(X, Y);
}
 
// Function that find length of longest
// subarray with all equal elements in
// atmost K decrements
int longestSubArray(int* A, int N, int K)
{
    // Stores length of longest subarray
    // with all equal elements in atmost
    // K decrements.
    int res = 1;
 
    // Store the prefix sum array
    int preSum[N + 1];
 
    // Calculate the prefix sum array
    preSum[0] = A[0];
    for (int i = 0; i < N; i++)
        preSum[i + 1] = preSum[i] + A[i];
 
    int tree[4 * N + 5];
 
    // Build the segment tree
    // for range min query
    build(tree, A, 0, N - 1, 0);
 
    // Traverse the array
    for (int i = 0; i < N; i++) {
 
        // Stores start index
        // of the subarray
        int start = i;
 
        // Stores end index
        // of the subarray
        int end = N - 1;
 
        int mid;
 
        // Stores end index of
        // the longest subarray
        int max_index = i;
 
        // Performing the binary search
        // to find the endpoint
        // for the selected range
        while (start <= end) {
 
            // Find the mid for binary search
            mid = (start + end) / 2;
 
            // Find the smallest element in
            // range [i, mid] using Segment Tree
            int min_element
                = query(tree, 0, N - 1, i, mid, 0);
 
            // Stores total sum of subarray
            // after K decrements
            int expected_sum
                = (mid - i + 1) * min_element;
 
            // Stores sum of elements of
            // subarray before K decrements
            int actual_sum
                = preSum[mid + 1] - preSum[i];
 
            // If subarray found with
            // all equal elements
            if (actual_sum - expected_sum <= K) {
 
                // Update start
                start = mid + 1;
 
                // Update max_index
                max_index = max(max_index, mid);
            }
 
            // If false, it means that
            // the selected range is invalid
            else {
 
                // Update end
                end = mid - 1;
            }
        }
 
        // Store the length of longest subarray
        res = max(res, max_index - i + 1);
    }
 
    // Return result
    return res;
}
 
// Driver Code
int main()
{
    int arr[] = { 1, 7, 3, 4, 5, 6 };
    int k = 6;
    int n = 6;
    cout << longestSubArray(arr, n, k);
 
    return 0;
}


Java
// Java program to implement
// the above appraoch
import java.util.*;
  
class GFG{
 
// Function to construct Segment Tree
// to return the minimum element in a range
static int build(int tree[], int[] A, int start,
                 int end, int node)
{
     
    // If leaf nodes of
    // the tree are found
    if (start == end)
    {
         
        // Update the value in segment
        // tree from given array
        tree[node] = A[start];
  
        return tree[node];
    }
  
    // Divide left and right subtree
    int mid = (start + end) / 2;
  
    // Stores smallest element in
    // subarray { arr[start], arr[mid] }
    int X = build(tree, A, start, mid,
                  2 * node + 1);
  
    // Stores smallest element in
    // subarray { arr[mid + 1], arr[end] }
    int Y = build(tree, A, mid + 1,
                 end, 2 * node + 2);
  
    // Stores smallest element in
    // subarray { arr[start], arr[end] }
    return (tree[node] = Math.min(X, Y));
}
  
// Function to find the smallest
// element present in a subarray
static int query(int tree[], int start, int end,
                 int l, int r, int node)
{
     
    // If elements of the subarray
    // are not in the range [l, r]
    if (start > r || end < l)
        return Integer.MAX_VALUE;
  
    // If all the elements of the
    // subarray are in the range [l, r]
    if (start >= l && end <= r)
        return tree[node];
  
    // Divide tree into left
    // and right subtree
    int mid = (start + end) / 2;
  
    // Stores smallest element
    // in left subtree
    int X = query(tree, start, mid, l,
                  r, 2 * node + 1);
  
    // Stores smallest element in
    // right subtree
    int Y = query(tree, mid + 1, end, l,
                  r, 2 * node + 2);
  
    return Math.min(X, Y);
}
  
// Function that find length of longest
// subarray with all equal elements in
// atmost K decrements
static int longestSubArray(int[] A, int N, int K)
{
     
    // Stores length of longest subarray
    // with all equal elements in atmost
    // K decrements.
    int res = 1;
  
    // Store the prefix sum array
    int preSum[] = new int[N + 1];
  
    // Calculate the prefix sum array
    preSum[0] = A[0];
    for(int i = 0; i < N; i++)
        preSum[i + 1] = preSum[i] + A[i];
  
    int tree[] = new int[4 * N + 5];
  
    // Build the segment tree
    // for range min query
    build(tree, A, 0, N - 1, 0);
  
    // Traverse the array
    for(int i = 0; i < N; i++)
    {
         
        // Stores start index
        // of the subarray
        int start = i;
  
        // Stores end index
        // of the subarray
        int end = N - 1;
  
        int mid;
  
        // Stores end index of
        // the longest subarray
        int max_index = i;
  
        // Performing the binary search
        // to find the endpoint
        // for the selected range
        while (start <= end)
        {
             
            // Find the mid for binary search
            mid = (start + end) / 2;
  
            // Find the smallest element in
            // range [i, mid] using Segment Tree
            int min_element = query(tree, 0, N - 1,
                                    i, mid, 0);
  
            // Stores total sum of subarray
            // after K decrements
            int expected_sum = (mid - i + 1) *
                                min_element;
  
            // Stores sum of elements of
            // subarray before K decrements
            int actual_sum = preSum[mid + 1] -
                             preSum[i];
  
            // If subarray found with
            // all equal elements
            if (actual_sum - expected_sum <= K)
            {
                 
                // Update start
                start = mid + 1;
  
                // Update max_index
                max_index = Math.max(max_index, mid);
            }
  
            // If false, it means that
            // the selected range is invalid
            else
            {
                 
                // Update end
                end = mid - 1;
            }
        }
  
        // Store the length of longest subarray
        res = Math.max(res, max_index - i + 1);
    }
  
    // Return result
    return res;
}
  
// Driver Code
static public void main(String args[])
{
    int arr[] = { 1, 7, 3, 4, 5, 6 };
    int k = 6;
    int n = 6;
     
    System.out.print(longestSubArray(arr, n, k));
}
}
 
// This code is contributed by sanjoy_62


Python3
# Python3 program to implement
# the above appraoch
import sys
 
# Function to construct Segment Tree
# to return the minimum element in a range
def build(tree, A, start, end, node):
     
    # If leaf nodes of
    # the tree are found
    if (start == end):
         
        # Update the value in segment
        # tree from given array
        tree[node] = A[start]
  
        return tree[node]
     
    # Divide left and right subtree
    mid = (int)((start + end) / 2)
  
    # Stores smallest element in
    # subarray : arr[start], arr[mid]
    X = build(tree, A, start, mid,
              2 * node + 1)
 
    # Stores smallest element in
    # subarray : arr[mid + 1], arr[end]
    Y = build(tree, A, mid + 1,
             end, 2 * node + 2)
  
    # Stores smallest element in
    # subarray : arr[start], arr[end]
    return (tree[node] == min(X, Y))
 
# Function to find the smallest
# element present in a subarray
def query(tree, start, end, l, r, node):
               
    # If elements of the subarray
    # are not in the range [l, r]
    if (start > r or end < l) :
        return sys.maxsize
  
    # If all the elements of the
    # subarray are in the range [l, r]
    if (start >= l and end <= r):
        return tree[node]
  
    # Divide tree into left
    # and right subtree
    mid = (int)((start + end) / 2)
  
    # Stores smallest element
    # in left subtree
    X = query(tree, start, mid, l,
              r, 2 * node + 1)
  
    # Stores smallest element in
    # right subtree
    Y = query(tree, mid + 1, end, l,
            r, 2 * node + 2)
  
    return min(X, Y)
 
# Function that find length of longest
# subarray with all equal elements in
# atmost K decrements
def longestSubArray(A, N, K):
     
    # Stores length of longest subarray
    # with all equal elements in atmost
    # K decrements.
    res = 1
  
    # Store the prefix sum array
    preSum = [0] * (N + 1)
  
    # Calculate the prefix sum array
    preSum[0] = A[0]
    for i in range(N):
        preSum[i + 1] = preSum[i] + A[i]
  
    tree = [0] * (4 * N + 5)
  
    # Build the segment tree
    # for range min query
    build(tree, A, 0, N - 1, 0)
  
    # Traverse the array
    for i in range(N):
  
        # Stores start index
        # of the subarray
        start = i
  
        # Stores end index
        # of the subarray
        end = N - 1
  
        # Stores end index of
        # the longest subarray
        max_index = i
  
        # Performing the binary search
        # to find the endpoint
        # for the selected range
        while (start <= end):
  
            # Find the mid for binary search
            mid = (int)((start + end) / 2)
  
            # Find the smallest element in
            # range [i, mid] using Segment Tree
            min_element = query(tree, 0, N - 1, i, mid, 0)
  
            # Stores total sum of subarray
            # after K decrements
            expected_sum = (mid - i + 1) * min_element
  
            # Stores sum of elements of
            # subarray before K decrements
            actual_sum = preSum[mid + 1] - preSum[i]
  
            # If subarray found with
            # all equal elements
            if (actual_sum - expected_sum <= K):
                 
                # Update start
                start = mid + 1
  
                # Update max_index
                max_index = max(max_index, mid)
             
            # If false, it means that
            # the selected range is invalid
            else:
  
                # Update end
                end = mid - 1
             
        # Store the length of longest subarray
        res = max(res, max_index - i + 2)
 
    # Return result
    return res
 
# Driver Code
arr = [ 1, 7, 3, 4, 5, 6 ]
k = 6
n = 6
 
print(longestSubArray(arr, n, k))
 
# This code is contributed by splevel62


C#
// C# program to implement
// the above appraoch
using System;
  
class GFG{
      
// Function to construct Segment Tree
// to return the minimum element in a range
static int build(int[] tree, int[] A, int start,
                 int end, int node)
{
     
    // If leaf nodes of
    // the tree are found
    if (start == end)
    {
         
        // Update the value in segment
        // tree from given array
        tree[node] = A[start];
   
        return tree[node];
    }
   
    // Divide left and right subtree
    int mid = (start + end) / 2;
   
    // Stores smallest element in
    // subarray { arr[start], arr[mid] }
    int X = build(tree, A, start, mid,
                  2 * node + 1);
   
    // Stores smallest element in
    // subarray { arr[mid + 1], arr[end] }
    int Y = build(tree, A, mid + 1,
                  end, 2 * node + 2);
   
    // Stores smallest element in
    // subarray { arr[start], arr[end] }
    return (tree[node] = Math.Min(X, Y));
}
   
// Function to find the smallest
// element present in a subarray
static int query(int[] tree, int start, int end,
                 int l, int r, int node)
{
      
    // If elements of the subarray
    // are not in the range [l, r]
    if (start > r || end < l)
        return Int32.MaxValue;
   
    // If all the elements of the
    // subarray are in the range [l, r]
    if (start >= l && end <= r)
        return tree[node];
   
    // Divide tree into left
    // and right subtree
    int mid = (start + end) / 2;
   
    // Stores smallest element
    // in left subtree
    int X = query(tree, start, mid, l,
                  r, 2 * node + 1);
   
    // Stores smallest element in
    // right subtree
    int Y = query(tree, mid + 1, end, l,
                  r, 2 * node + 2);
   
    return Math.Min(X, Y);
}
   
// Function that find length of longest
// subarray with all equal elements in
// atmost K decrements
static int longestSubArray(int[] A, int N, int K)
{
      
    // Stores length of longest subarray
    // with all equal elements in atmost
    // K decrements.
    int res = 1;
   
    // Store the prefix sum array
    int[] preSum = new int[N + 1];
   
    // Calculate the prefix sum array
    preSum[0] = A[0];
    for(int i = 0; i < N; i++)
        preSum[i + 1] = preSum[i] + A[i];
   
    int[] tree = new int[4 * N + 5];
   
    // Build the segment tree
    // for range min query
    build(tree, A, 0, N - 1, 0);
   
    // Traverse the array
    for(int i = 0; i < N; i++)
    {
          
        // Stores start index
        // of the subarray
        int start = i;
   
        // Stores end index
        // of the subarray
        int end = N - 1;
   
        int mid;
   
        // Stores end index of
        // the longest subarray
        int max_index = i;
   
        // Performing the binary search
        // to find the endpoint
        // for the selected range
        while (start <= end)
        {
              
            // Find the mid for binary search
            mid = (start + end) / 2;
   
            // Find the smallest element in
            // range [i, mid] using Segment Tree
            int min_element = query(tree, 0, N - 1,
                                    i, mid, 0);
   
            // Stores total sum of subarray
            // after K decrements
            int expected_sum = (mid - i + 1) *
                                min_element;
   
            // Stores sum of elements of
            // subarray before K decrements
            int actual_sum = preSum[mid + 1] -
                             preSum[i];
   
            // If subarray found with
            // all equal elements
            if (actual_sum - expected_sum <= K)
            {
                  
                // Update start
                start = mid + 1;
   
                // Update max_index
                max_index = Math.Max(max_index, mid);
            }
   
            // If false, it means that
            // the selected range is invalid
            else
            {
                  
                // Update end
                end = mid - 1;
            }
        }
   
        // Store the length of longest subarray
        res = Math.Max(res, max_index - i + 1);
    }
   
    // Return result
    return res;
}
  
// Driver Code
static void Main()
{
    int[] arr = { 1, 7, 3, 4, 5, 6 };
    int k = 6;
    int n = 6;
      
    Console.WriteLine(longestSubArray(arr, n, k));
}
}
 
// This code is contributed by susmitakundugoaldanga


输出:
4

时间复杂度: O(N *(log(N)) 2 )
辅助空间:O(N)