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Program to generate an array having convolution of two given arrays

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Given two arrays A[] and B[] consisting of N and M integers respectively, the task is to construct a convolution array C[] of size (N + M – 1)

The convolution of 2 arrays is defined as C[i + j] = ?(a[i] * b[j]) for every i and j

Note: If the value for any index becomes very large, then print it to modulo 998244353.

Examples:

Input: A[] = {1, 2, 3, 4}, B[] = {5, 6, 7, 8, 9}
Output: {5, 16, 34, 60, 70, 70, 59, 36}
Explanation:
Size of array, C[] = N + M – 1 = 8.
C[0] = A[0] * B[0] = 1 * 5 = 5
C[1] = A[0] * B[1] + A[1] * B[0] = 1 * 6 + 2 * 5 = 16
C[2] = A[0] * B[2] + A[1] * B[1] + A[2] * B[0] = 1 * 7 + 2 * 6 + 3 * 5 = 34
Similarly, C[3] = 60, C[4] = 70, C[5] = 70, C[6] = 59, C[7] = 36.

Input: A[] = {10000000}, B[] = {10000000}
Output: {871938225}
Explanation:
Size of array, C[] = N + M – 1 = 1.
C[0] = A[0] * B[0] = (10000000 * 10000000) % 998244353 = 871938225

Naive Approach: In the convolution array, each term C[i + j] = (a[i] * b[j]) % 998244353. Therefore, the simplest approach is to iterate over both the arrays A[] and B[] using two nested loops to find the resulting convoluted array C[].

Below is the implementation of the above approach:

C++




// C++ program for the above approach
#include <bits/stdc++.h>
using namespace std;
constexpr int MOD = 998244353;
 
// Function to generate a convolution
// array of two given arrays
void findConvolution(const vector<int>& a,
                     const vector<int>& b)
{
    // Stores the size of arrays
    int n = a.size(), m = b.size();
 
    // Stores the final array
    vector<long long> c(n + m - 1);
 
    // Traverse the two given arrays
    for (int i = 0; i < n; ++i) {
        for (int j = 0; j < m; ++j) {
           
              // Update the convolution array
            c[i + j] += 1LL*(a[i] * b[j]) % MOD;
        }
    }
 
    // Print the convolution array c[]
    for (int k = 0; k < c.size(); ++k) {
        c[k] %= MOD;
        cout << c[k] << " ";
    }
}
 
// Driver Code
int main()
{
    vector<int> A = { 1, 2, 3, 4 };
    vector<int> B = { 5, 6, 7, 8, 9 };
   
    findConvolution(A, B);
 
    return 0;
}


Java




// Java program for the above approach
import java.util.*;
 
class GFG{
 
static int MOD = 998244353;
 
// Function to generate a convolution
// array of two given arrays
static void findConvolution(int[] a,
                            int[] b)
{
     
    // Stores the size of arrays
    int n = a.length, m = b.length;
 
    // Stores the final array
    int[] c = new int[(n + m - 1)];
 
    // Traverse the two given arrays
    for(int i = 0; i < n; ++i)
    {
        for(int j = 0; j < m; ++j)
        {
             
            // Update the convolution array
            c[i + j] += (a[i] * b[j]) % MOD;
        }
    }
 
    // Print the convolution array c[]
    for(int k = 0; k < c.length; ++k)
    {
        c[k] %= MOD;
        System.out.print(c[k] + " ");
    }
}
 
// Driver Code
public static void main(String args[])
{
    int[] A = { 1, 2, 3, 4 };
    int[] B = { 5, 6, 7, 8, 9 };
   
    findConvolution(A, B);}
}
 
// This code is contributed by souravghosh0416


Python3




# Python3 program for the above approach
MOD = 998244353
 
# Function to generate a convolution
# array of two given arrays
def findConvolution(a, b):
     
    global MOD
     
    # Stores the size of arrays
    n, m = len(a), len(b)
 
    # Stores the final array
    c = [0] * (n + m - 1)
 
    # Traverse the two given arrays
    for i in range(n):
        for j in range(m):
             
            # Update the convolution array
            c[i + j] += (a[i] * b[j]) % MOD
 
    # Print the convolution array c[]
    for k in range(len(c)):
        c[k] %= MOD
        print(c[k], end = " ")
 
# Driver Code
if __name__ == '__main__':
     
    A = [1, 2, 3, 4]
    B = [5, 6, 7, 8, 9]
     
    findConvolution(A, B)
 
# This code is contributed by mohit kumar 29


C#




// C# program for the above approach
using System;
 
class GFG
{
 static int MOD = 998244353;
 
// Function to generate a convolution
// array of two given arrays
static void findConvolution(int[] a,
                    int[] b)
{
   
    // Stores the size of arrays
    int n = a.Length, m = b.Length;
 
    // Stores the final array
    int[] c = new int[(n + m - 1)];
 
    // Traverse the two given arrays
    for (int i = 0; i < n; ++i) {
        for (int j = 0; j < m; ++j) {
           
              // Update the convolution array
            c[i + j] += (a[i] * b[j]) % MOD;
        }
    }
 
    // Print the convolution array c[]
    for (int k = 0; k < c.Length; ++k) {
        c[k] %= MOD;
        Console.Write(c[k] + " ");
    }
}
 
// Driver Code
public static void Main(String[] args)
{
    int[] A = { 1, 2, 3, 4 };
    int[] B = { 5, 6, 7, 8, 9 };
   
    findConvolution(A, B);
}
}
 
// This code is contributed by code_hunt.


Javascript




<script>
 
// Javascript program for the above approach
 
let MOD = 998244353;
  
// Function to generate a convolution
// array of two given arrays
function findConvolution(a, b)
{
      
    // Stores the size of arrays
    let n = a.length, m = b.length;
  
    // Stores the final array
    let c = [];
    for(let i = 0; i < n + m - 1; ++i)
    {
        c[i] = 0;
    }
  
    // Traverse the two given arrays
    for(let i = 0; i < n; ++i)
    {
        for(let j = 0; j < m; ++j)
        {
              
            // Update the convolution array
            c[i + j] += (a[i] * b[j]) % MOD;
        }
    }
  
    // Print the convolution array c[]
    for(let k = 0; k < c.length; ++k)
    {
        c[k] %= MOD;
        document.write(c[k] + " ");
    }
}
 
// Driver Code
 
    let A = [ 1, 2, 3, 4 ];
    let B = [ 5, 6, 7, 8, 9 ];
    
    findConvolution(A, B);
 
</script>


Output: 

5 16 34 60 70 70 59 36

 

Time Complexity: O(N*M)
Auxiliary Space: O(N+M)

Efficient Approach: To optimize the above approach, the idea is to use the Number-Theoretic Transform (NTT) which is similar to Fast Fourier transform (FFT) for polynomial multiplication, which can work under modulo operations. The problem can be solved by using the same concept of iterative FFT to perform NTT on the given arrays as the same properties hold for the Nth roots of unity in modular arithmetic

Below is the implementation of the above approach:

C++




// C++ program for the above approach
#include <bits/stdc++.h>
using namespace std;
 
#define ll long long
 
const ll mod = 998244353, maxn = 3e6;
ll a[maxn], b[maxn];
 
// Iterative FFT function to compute
// the DFT of given coefficient vector
void fft(ll w0, ll n, ll* a)
{
    // Do bit reversal of the given array
    for (ll i = 0, j = 0; i < n; i++) {
 
        // Swap a[i] and a[j]
        if (i < j)
            swap(a[i], a[j]);
 
        // Right Shift N by 1
        ll bit = n >> 1;
 
        for (; j & bit; bit >>= 1)
            j ^= bit;
        j ^= bit;
    }
 
    // Perform the iterative FFT
    for (ll len = 2; len <= n; len <<= 1) {
 
        ll wlen = w0;
        for (ll aux = n; aux > len; aux >>= 1) {
            wlen = wlen * wlen % mod;
        }
 
        for (ll bat = 0; bat + len <= n; bat += len) {
 
            for (ll i = bat, w = 1; i < bat + len / 2;
                 i++, w = w * wlen % mod) {
 
                ll u = a[i], v = w * a[i + len / 2] % mod;
 
                // Update the value of a[i]
                a[i] = (u + v) % mod,
 
                // Update the value
                // of a[i + len/2]
                    a[i + len / 2]
                    = ((u - v) % mod + mod) % mod;
            }
        }
    }
}
 
// Function to find (a ^ x) % mod
ll binpow(ll a, ll x)
{
    // Stores the result of a ^ x
    ll ans = 1;
 
    // Iterate over the value of x
    for (; x; x /= 2, a = a * a % mod) {
 
        // If x is odd
        if (x & 1)
            ans = ans * a % mod;
    }
 
    // Return the resultant value
    return ans;
}
 
// Function to find the
// inverse of a % mod
ll inv(ll a) { return binpow(a, mod - 2); }
 
// Function to find the
// convolution of two arrays
void findConvolution(ll a[], ll b[], ll n, ll m)
{
    // Stores the first power of 2
    // greater than or equal to n + m
    ll _n = 1ll << 64 - __builtin_clzll(n + m);
 
    // Stores the primitive root
    ll w = 15311432;
    for (ll aux = 1 << 23; aux > _n; aux >>= 1)
        w = w * w % mod;
 
    // Convert arrays a[] and
    // b[] to point value form
    fft(w, _n, a);
    fft(w, _n, b);
 
    // Perform multiplication
    for (ll i = 0; i < _n; i++)
        a[i] = a[i] * b[i] % mod;
 
    // Perform inverse fft to
    // recover final array
    fft(inv(w), _n, a);
    for (ll i = 0; i < _n; i++)
        a[i] = a[i] * inv(_n) % mod;
 
    // Print the convolution
    for (ll i = 0; i < n + m - 1; i++)
        cout << a[i] << " ";
}
 
// Driver Code
int main()
{
    // Given size of the arrays
    ll N = 4, M = 5;
 
    // Fill the arrays
    for (ll i = 0; i < N; i++)
        a[i] = i + 1;
 
    for (ll i = 0; i < M; i++)
        b[i] = 5 + i;
 
    findConvolution(a, b, N, M);
 
    return 0;
}


Java




import java.math.BigInteger;
 
public class GFG {
    public static final long mod = 998244353;
    public static final int maxn = 3000000;
 
    public static long[] a = new long[maxn];
    public static long[] b = new long[maxn];
 
    // Function to find the next power of 2 using
    // bit masking
    public static int nextPowerOf2(int n)
    {
        // if n is a power of two simply return it
        if ((n & (n - 1)) == 0)
            return n;
        // else set only the left bit of most significant
        // bit as in Java right shift is filled with most
        // significant bit we consider
        return 0x40000000
            >> (Integer.numberOfLeadingZeros(n) - 2);
    }
 
    // Iterative fft function to compute
    // the DFT of given coefficient vector
    public static void fft(long w0, long n, long[] a)
    {
        // Do bit reversal of the given array
        for (long i = 0, j = 0; i < n; i++) {
            // Swap a[i] and a[j]
            if (i < j) {
                long temp = a[(int)i];
                a[(int)i] = a[(int)j];
                a[(int)j] = temp;
            }
 
            // Right Shift N by 1
            long bit = n >> 1;
            for (; (j & bit) != 0; bit >>= 1)
                j ^= bit;
            j ^= bit;
        }
 
        // Perform the iterative fft
        for (long len = 2; len <= n; len <<= 1) {
            long wlen = w0;
            for (long aux = n; aux > len; aux >>= 1) {
                wlen = wlen * wlen % mod;
            }
 
            for (long bat = 0; bat + len <= n; bat += len) {
                for (long i = bat, w = 1; i < bat + len / 2;
                     i++, w = w * wlen % mod) {
                    long u = a[(int)i],
                         v
                         = w * a[(int)(i + len / 2)] % mod;
 
                    // Update the value of a[i]
                    a[(int)i] = (u + v) % mod;
 
                    // Update the value
                    // of a[i + len/2]
                    a[(int)(i + len / 2)]
                        = ((u - v) % mod + mod) % mod;
                }
            }
        }
    }
 
    // Function to find (a ^ x) % mod
    public static long binpow(long a, long x)
    {
        // Stores the result of a ^ x
        long ans = 1;
 
        // Iterate over the value of x
        for (; x != 0; x /= 2, a = a * a % mod) {
            // If x is odd
            if ((x & 1) != 0)
                ans = ans * a % mod;
        }
 
        // Return the resultant value
        return ans;
    }
 
    // Function to find the
    // inverse of a % mod
    public static long inv(long a)
    {
        return binpow(a, mod - 2);
    }
 
    // Function to find the
    // convolution of two arrays
    static void FindConvolution(long[] a, long[] b, int n,
                                int m)
    {
        // Stores the first power of 2
        // greater than or equal to n + m
        int _n = nextPowerOf2(n + m);
 
        // Stores the primitive root
        long w = 15311432;
        for (int aux = 1 << 23; aux > _n; aux >>= 1)
            w = w * w % mod;
 
        // Convert arrays a[] and b[] to point value form
        fft(w, _n, a);
        fft(w, _n, b);
 
        // Perform multiplication
        for (int i = 0; i < _n; i++)
            a[i] = a[i] * b[i] % mod;
 
        // Perform inverse fft to recover final array
        fft(inv(w), _n, a);
 
        for (int i = 0; i < _n; i++)
            a[i] = a[i] * inv(_n) % mod;
 
        for (int i = 0; i < n + m - 1; i++)
            System.out.print(a[i] + " ");
    }
 
    public static void main(String[] args)
    {
        // Given size of the arrays
        int N = 4, M = 5;
 
        // Fill the arrays
        for (int i = 0; i < N; i++)
            a[i] = i + 1;
 
        for (int i = 0; i < M; i++)
            b[i] = 5 + i;
 
        FindConvolution(a, b, N, M);
    }
}


C#




using System;
using System.Numerics;
using System.Collections.Generic;
 
public class GFG {
  public const long mod = 998244353;
  public const int maxn = 3000000;
 
  public static long[] a = new long[maxn];
  public static long[] b = new long[maxn];
 
  static int nextPowerOf2(int N)
  {
 
    // if N is a power of two simply return it
    if ((N & (N - 1)) == 0)
      return N;
 
    // else set only the left bit of most significant
    // bit
    return Convert.ToInt32(
      "1"
      + new string('0',
                   Convert.ToString(N, 2).Length),
      2);
  }
  // Iterative fft function to compute
  // the DFT of given coefficient vector
  public static void fft(long w0, long n, long[] a)
  {
    // Do bit reversal of the given array
    for (long i = 0, j = 0; i < n; i++) {
      // Swap a[i] and a[j]
      if (i < j) {
        long temp = a[i];
        a[i] = a[j];
        a[j] = temp;
      }
 
      // Right Shift N by 1
      long bit = n >> 1;
      for (; (j & bit) != 0; bit >>= 1)
        j ^= bit;
      j ^= bit;
    }
 
    // Perform the iterative fft
    for (long len = 2; len <= n; len <<= 1) {
      long wlen = w0;
      for (long aux = n; aux > len; aux >>= 1) {
        wlen = wlen * wlen % mod;
      }
 
      for (long bat = 0; bat + len <= n; bat += len) {
        for (long i = bat, w = 1; i < bat + len / 2;
             i++, w = w * wlen % mod) {
          long u = a[i],
          v = w * a[i + len / 2] % mod;
 
          // Update the value of a[i]
          a[i] = (u + v) % mod;
 
          // Update the value
          // of a[i + len/2]
          a[i + len / 2]
            = ((u - v) % mod + mod) % mod;
        }
      }
    }
  }
 
  // Function to find (a ^ x) % mod
  public static long binpow(long a, long x)
  {
    // Stores the result of a ^ x
    long ans = 1;
 
    // Iterate over the value of x
    for (; x != 0; x /= 2, a = a * a % mod) {
      // If x is odd
      if ((x & 1) != 0)
        ans = ans * a % mod;
    }
 
    // Return the resultant value
    return ans;
  }
 
  // Function to find the
  // inverse of a % mod
  public static long inv(long a)
  {
    return binpow(a, mod - 2);
  }
 
  // Function to find the
  // convolution of two arrays
  // Function to find the convolution of two arrays
  static void FindConvolution(long[] a, long[] b, int n,
                              int m)
  {
    // Stores the first power of 2
    // greater than or equal to n + m
    int _n = nextPowerOf2(n + m);
 
    // Stores the primitive root
    long w = 15311432;
    for (int aux = 1 << 23; aux > _n; aux >>= 1)
      w = w * w % mod;
 
    // Convert arrays a[] and b[] to point value form
    fft(w, _n, a);
    fft(w, _n, b);
 
    // Perform multiplication
    for (int i = 0; i < _n; i++)
      a[i] = a[i] * b[i] % mod;
 
    // Perform inverse fft to recover final array
    fft(inv(w), _n, a);
 
    for (int i = 0; i < _n; i++)
      a[i] = a[i] * inv(_n) % mod;
 
    for (int i = 0; i < n + m - 1; i++)
      Console.Write(a[i] + " ");
  }
 
  public static void Main(string[] args)
  {
    // Given size of the arrays
    int N = 4, M = 5;
 
    // Fill the arrays
    for (int i = 0; i < N; i++)
      a[i] = i + 1;
 
    for (int i = 0; i < M; i++)
      b[i] = 5 + i;
 
    FindConvolution(a, b, N, M);
  }
}


Output: 

5 16 34 60 70 70 59 36

 

Time Complexity: O(N*log(N))
Auxiliary Space: O(N + M)

 



Last Updated : 17 Apr, 2023
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