Given an array arr[] of N positive integers. The task is to find the length of the shortest sub-sequence such that the GCD of the subsequence is 1. If none of the sub-sequence has GCD 1, then print “-1“.
Examples:
Input: arr[] = {2, 6, 12, 3}
Output: 2
Explanation:
The GCD of 2, 3 = 1, which is the smallest length of subsequence like 2.Input: arr[] = {2, 4}
Output: -1
Explanation:
GCD of 2, 4 = 2
Naive Approach: The idea is to generate all possible subsequences of the given array and print the length of that subsequence whose GCD is unity and has a minimum length. If none of the sub-sequences has GCD 1, then print “-1“.
Time Complexity: O(2N)
Auxiliary Space: O(1)
Another Approach: Using the Dynamic programming Tabulation method
We use a 2D matrix to store the previous computation of sub-problems and find the actual answer.
Implementation steps :
- Create a table to store the solution of the subproblems.
- Initialize the table with base cases
- Fill up the table iteratively
- Return the final solution
Implementation:
// C++ program for the above approach #include <bits/stdc++.h> using namespace std;
int findMinimumLength(vector< int >& a)
{ int n = a.size();
vector<vector< int > > dp(n, vector< int >(n, 0));
// Calculate the GCD of all elements in the sequence
int gcd = a[0];
for ( int i = 1; i < n; i++) {
gcd = __gcd(gcd, a[i]);
}
// If the GCD is not 1, it's impossible to form a
// subsequence with GCD 1
if (gcd != 1) {
return -1;
}
// Initialize the diagonal of the dp table to 1
for ( int i = 0; i < n; i++) {
dp[i][i] = 1;
}
// Calculate the dp table
for ( int len = 2; len <= n; len++) {
for ( int i = 0; i < n - len + 1; i++) {
int j = i + len - 1;
int g = __gcd(a[i], a[j]);
if (g == 1) {
dp[i][j] = 2;
}
else {
dp[i][j] = INT_MAX;
for ( int k = i; k < j; k++) {
dp[i][j] = min(dp[i][j],
dp[i][k] + dp[k + 1][j]);
}
}
}
}
return dp[0][n - 1];
} // Driver Code int main()
{ vector< int > a = { 2, 6, 12, 3 };
// function call
int ans = findMinimumLength(a);
if (ans == -1) {
cout << -1 << endl;
}
else {
cout << ans << endl;
}
return 0;
} // this code is contributed by bhardwajji |
import java.util.*;
public class Main {
public static int
findMinimumLength(ArrayList<Integer> a)
{
int n = a.size();
int [][] dp = new int [n][n];
// Calculate the GCD of all elements in the sequence
int gcd = a.get( 0 );
for ( int i = 1 ; i < n; i++) {
gcd = gcd(gcd, a.get(i));
}
// If the GCD is not 1, it's impossible to form a
// subsequence with GCD 1
if (gcd != 1 ) {
return - 1 ;
}
// Initialize the diagonal of the dp table to 1
for ( int i = 0 ; i < n; i++) {
dp[i][i] = 1 ;
}
// Calculate the dp table
for ( int len = 2 ; len <= n; len++) {
for ( int i = 0 ; i < n - len + 1 ; i++) {
int j = i + len - 1 ;
int g = gcd(a.get(i), a.get(j));
if (g == 1 ) {
dp[i][j] = 2 ;
}
else {
dp[i][j] = Integer.MAX_VALUE;
for ( int k = i; k < j; k++) {
dp[i][j] = Math.min(
dp[i][j],
dp[i][k] + dp[k + 1 ][j]);
}
}
}
}
return dp[ 0 ][n - 1 ];
}
public static int gcd( int a, int b)
{
if (b == 0 ) {
return a;
}
else {
return gcd(b, a % b);
}
}
public static void main(String[] args)
{
ArrayList<Integer> a
= new ArrayList<>(Arrays.asList( 2 , 6 , 12 , 3 ));
// function call
int ans = findMinimumLength(a);
if (ans == - 1 ) {
System.out.println(- 1 );
}
else {
System.out.println(ans);
}
}
} // This code is contributed by user_dtewbxkn77n |
# Python program for the above approach import math
def findMinimumLength(a):
n = len (a)
dp = [[ 0 ] * n for _ in range (n)]
# Calculate the GCD of all elements in the sequence
gcd = a[ 0 ]
for i in range ( 1 , n):
gcd = math.gcd(gcd, a[i])
# If the GCD is not 1, it's impossible to form a subsequence with GCD 1
if gcd ! = 1 :
return - 1
# Initialize the diagonal of the dp table to 1
for i in range (n):
dp[i][i] = 1
# Calculate the dp table
for length in range ( 2 , n + 1 ):
for i in range (n - length + 1 ):
j = i + length - 1
g = math.gcd(a[i], a[j])
if g = = 1 :
dp[i][j] = 2
else :
dp[i][j] = float ( 'inf' )
for k in range (i, j):
dp[i][j] = min (dp[i][j], dp[i][k] + dp[k + 1 ][j])
return dp[ 0 ][n - 1 ]
# Driver Code a = [ 2 , 6 , 12 , 3 ]
ans = findMinimumLength(a)
if ans = = - 1 :
print ( - 1 )
else :
print (ans)
# Contributed by adityasha4x71 |
function findMinimumLength(a) {
const n = a.length;
const dp = Array.from({
length: n
}, () => new Array(n).fill(0));
// Calculate the GCD of all elements in the sequence
let gcd = a[0];
for (let i = 1; i < n; i++) {
gcd = gcdFunc(gcd, a[i]);
}
// If the GCD is not 1, it's impossible to form a subsequence with GCD 1
if (gcd !== 1) {
return -1;
}
// Initialize the diagonal of the dp table to 1
for (let i = 0; i < n; i++) {
dp[i][i] = 1;
}
// Calculate the dp table
for (let len = 2; len <= n; len++) {
for (let i = 0; i < n - len + 1; i++) {
const j = i + len - 1;
const g = gcdFunc(a[i], a[j]);
if (g === 1) {
dp[i][j] = 2;
} else {
dp[i][j] = Infinity;
for (let k = i; k < j; k++) {
dp[i][j] = Math.min(dp[i][j], dp[i][k] + dp[k + 1][j]);
}
}
}
}
return dp[0][n - 1];
} function gcdFunc(a, b) {
if (b === 0) {
return a;
} else {
return gcdFunc(b, a % b);
}
} const a = [2, 6, 12, 3]; const ans = findMinimumLength(a); if (ans === -1) {
console.log(-1);
} else {
console.log(ans);
} |
using System;
using System.Collections.Generic;
using System.Linq;
class Program {
static int FindMinimumLength(List< int > a)
{
int n = a.Count;
int [, ] dp = new int [n, n];
// Calculate the GCD of all elements in the sequence
int gcd = a[0];
for ( int i = 1; i < n; i++) {
gcd = Gcd(gcd, a[i]);
}
// If the GCD is not 1, it's impossible to form a
// subsequence with GCD 1
if (gcd != 1) {
return -1;
}
// Initialize the diagonal of the dp table to 1
for ( int i = 0; i < n; i++) {
dp[i, i] = 1;
}
// Calculate the dp table
for ( int len = 2; len <= n; len++) {
for ( int i = 0; i < n - len + 1; i++) {
int j = i + len - 1;
int g = Gcd(a[i], a[j]);
if (g == 1) {
dp[i, j] = 2;
}
else {
dp[i, j] = int .MaxValue;
for ( int k = i; k < j; k++) {
dp[i, j] = Math.Min(
dp[i, j],
dp[i, k] + dp[k + 1, j]);
}
}
}
}
return dp[0, n - 1];
}
static int Gcd( int a, int b)
{
if (a == 0) {
return b;
}
return Gcd(b % a, a);
}
static void Main( string [] args)
{
List< int > a = new List< int >() { 2, 6, 12, 3 };
// function call
int ans = FindMinimumLength(a);
if (ans == -1) {
Console.WriteLine(-1);
}
else {
Console.WriteLine(ans);
}
}
} |
2
Time Complexity: O(n^3)
Auxiliary Space: O(n^2)
Efficient Approach: There are 2 key observations for solving this problem:
- Two numbers will have their GCD equal to one only when their prime factors are different.
- Any positive number which is less than 109 can have a maximum of 9 prime factors.
For Example 2×3×5×7×11×13×17×19×23 = 22, 30, 92, 870. If we multiply this number by the next prime number, which is 29, it will be greater than 10^9.
Follow the steps below to solve the problem:
-
Express the numbers as the product of its prime factors. Since we have a maximum of 9 prime factors, we can use the concept of Bitmask to store the state of the number.
For Example, prime factors of 12 are 2 and 3. This can be expressed in binary as 11 (Ignoring the preceding zeroes), meaning two prime factors are there for this number. - For every number in the input array, check if any other number has the corresponding bit set or not. This could be achieved using Bitwise AND operation. The resultant of this operation is another state of our solution space.
- Now use the concept of Dynamic Programming to memorize the states. The idea is to use an array to store the states of the solution space. This works since only 9 bits could be set a time, and an array of size 1024 could capture all the states of the solution space.
- Every state uses dynamic programming to store the shortest way to reach that state.
- If the Bitwise AND of any two states is equal to 0, then the GCD is equal to one, i.e., if there is a possibility to reach state 0 from the current state, then it will have the minimum length sub-sequence and print that length otherwise print “-1”.
Below is the implementation of the above approach:
// C++ program for the above approach #include <bits/stdc++.h> using namespace std;
// Function that finds the prime // factors of a number vector< int > findPrimeFactors( int n)
{ // To store the prime factor
vector< int > primeFactors(9, 0);
int j = 0;
// 2s that divide n
if (n % 2 == 0) {
primeFactors[j++] = 2;
while (n % 2 == 0)
n >>= 1;
}
// N must be odd at this point
// Skip one element
for ( int i = 3;
i * i <= n; i += 2) {
if (n % i == 0) {
// Update the prime factor
primeFactors[j++] = i;
while (n % i == 0)
n /= i;
}
}
// If n is a prime number
// greater than 2
if (n > 2)
primeFactors[j++] = n;
vector< int > PrimeFactors(j);
for ( int i = 0; i < j; i++)
{
PrimeFactors[i] = primeFactors[i];
}
return PrimeFactors;
} // Function that finds the shortest // subsequence void findShortestSubsequence(vector< int > &dp, vector< int > a,
int index, vector< int > primeFactors)
{ int n = a.size();
for ( int j = index; j < n; j++) {
int bitmask = 0;
for ( int p = 0;
p < primeFactors.size(); p++) {
// Check if the prime factor
// of first number, is also
// the prime factor of the
// rest numbers in array
if ((a[j] % primeFactors[p]) == 0) {
// Set corresponding bit
// of prime factor to 1,
// it means both these
// numbers have the
// same prime factor
bitmask ^= (1 << p);
}
}
for ( int i = 0; i < dp.size(); i++) {
// If no states encountered
// so far continue for this
// combination of bits
if (dp[i] == n + 1)
continue ;
// Update this state with
// minimum ways to reach
// this state
dp[bitmask & i]
= min(dp[bitmask & i],
dp[i] + 1);
}
}
} // Function that print the minimum // length of subsequence void printMinimumLength(vector< int > a)
{ int Min = a.size() + 1;
for ( int i = 0; i < a.size() - 1; i++) {
// Find the prime factors of
// the first number
vector< int > primeFactors
= findPrimeFactors(a[i]);
int n = primeFactors.size();
// Initialize the array with
// maximum steps, size of the
// array + 1 for instance
vector< int > dp(1 << n, a.size() + 1);
// Express the prime factors
// in bit representation
// Total number of set bits is
// equal to the total number
// of prime factors
int setBits = (1 << n) - 1;
// Indicates there is one
// way to reach the number
// under consideration
dp[setBits] = 1;
findShortestSubsequence(dp, a, i + 1,
primeFactors);
// State 0 corresponds
// to gcd of 1
Min = min(dp[0], Min);
}
// If not found such subsequence
// then print "-1"
if (Min == (a.size() + 1))
cout << -1 << endl;
// Else print the length
else
cout << Min << endl;
} // Driver code int main()
{ // Given array arr[]
vector< int > arr = { 2, 6, 12, 3 };
// Function Call
printMinimumLength(arr);
return 0;
} // This code is contributed by divyeshrabadiya07 |
// Java program for the above approach import java.io.*;
import java.util.*;
class GFG {
// Function that finds the prime
// factors of a number
private static int [] findPrimeFactors( int n)
{
// To store the prime factor
int [] primeFactors = new int [ 9 ];
int j = 0 ;
// 2s that divide n
if (n % 2 == 0 ) {
primeFactors[j++] = 2 ;
while (n % 2 == 0 )
n >>= 1 ;
}
// N must be odd at this point
// Skip one element
for ( int i = 3 ;
i * i <= n; i += 2 ) {
if (n % i == 0 ) {
// Update the prime factor
primeFactors[j++] = i;
while (n % i == 0 )
n /= i;
}
}
// If n is a prime number
// greater than 2
if (n > 2 )
primeFactors[j++] = n;
return Arrays.copyOfRange(primeFactors, 0 , j);
}
// Function that finds the shortest
// subsequence
private static void
findShortestSubsequence( int [] dp, int [] a,
int index,
int [] primeFactors)
{
int n = a.length;
for ( int j = index; j < n; j++) {
int bitmask = 0 ;
for ( int p = 0 ;
p < primeFactors.length; p++) {
// Check if the prime factor
// of first number, is also
// the prime factor of the
// rest numbers in array
if (a[j] % primeFactors[p] == 0 ) {
// Set corresponding bit
// of prime factor to 1,
// it means both these
// numbers have the
// same prime factor
bitmask ^= ( 1 << p);
}
}
for ( int i = 0 ;
i < dp.length; i++) {
// If no states encountered
// so far continue for this
// combination of bits
if (dp[i] == n + 1 )
continue ;
// Update this state with
// minimum ways to reach
// this state
dp[bitmask & i]
= Math.min(dp[bitmask & i],
dp[i] + 1 );
}
}
}
// Function that print the minimum
// length of subsequence
private static void
printMinimumLength( int [] a)
{
int min = a.length + 1 ;
for ( int i = 0 ;
i < a.length - 1 ; i++) {
// Find the prime factors of
// the first number
int [] primeFactors
= findPrimeFactors(a[i]);
int n = primeFactors.length;
int [] dp = new int [ 1 << n];
// Initialize the array with
// maximum steps, size of the
// array + 1 for instance
Arrays.fill(dp, a.length + 1 );
// Express the prime factors
// in bit representation
// Total number of set bits is
// equal to the total number
// of prime factors
int setBits = ( 1 << n) - 1 ;
// Indicates there is one
// way to reach the number
// under consideration
dp[setBits] = 1 ;
findShortestSubsequence(dp, a, i + 1 ,
primeFactors);
// State 0 corresponds
// to gcd of 1
min = Math.min(dp[ 0 ], min);
}
// If not found such subsequence
// then print "-1"
if (min == a.length + 1 )
System.out.println(- 1 );
// Else print the length
else
System.out.println(min);
}
// Driver Code
public static void main(String[] args)
{
// Given array arr[]
int [] arr = { 2 , 6 , 12 , 3 };
// Function Call
printMinimumLength(arr);
}
} |
# Python3 program for the above approach # Function that finds the prime # factors of a number def findPrimeFactors(n):
# To store the prime factor
primeFactors = [ 0 for i in range ( 9 )]
j = 0
# 2s that divide n
if (n % 2 = = 0 ):
primeFactors[j] = 2
j + = 1
while (n % 2 = = 0 ):
n >> = 1
# N must be odd at this point
# Skip one element
i = 3
while (i * i < = n):
if (n % i = = 0 ):
# Update the prime factor
primeFactors[j] = i
j + = 1
while (n % i = = 0 ):
n / / = i
i + = 2
# If n is a prime number
# greater than 2
if (n > 2 ):
primeFactors[j] = n
j + = 1
for i in range ( 0 , j + 1 ):
primeFactors[i] = 0
return primeFactors
# Function that finds the shortest # subsequence def findShortestSubsequence(dp, a, index,
primeFactors):
n = len (a)
for j in range (index, n):
bitmask = 0
for p in range ( len (primeFactors)):
# Check if the prime factor
# of first number, is also
# the prime factor of the
# rest numbers in array
if (primeFactors[p] ! = 0 and
a[j] % primeFactors[p] = = 0 ):
# Set corresponding bit
# of prime factor to 1,
# it means both these
# numbers have the
# same prime factor
bitmask ^ = ( 1 << p)
for i in range ( len (dp)):
# If no states encountered
# so far continue for this
# combination of bits
if (dp[i] = = n + 1 ):
continue
# Update this state with
# minimum ways to reach
# this state
dp[bitmask & i] = min (dp[bitmask & i],
dp[i] + 1 )
# Function that print the minimum # length of subsequence def printMinimumLength(a):
mn = len (a) + 1
for i in range ( len (a) - 1 ):
# Find the prime factors of
# the first number
primeFactors = findPrimeFactors(a[i])
n = len (primeFactors)
dp = [ 0 for i in range ( 1 << n)]
# Initialize the array with
# maximum steps, size of the
# array + 1 for instance
dp = [ len (a) + 1 for i in range ( len (dp))]
# Express the prime factors
# in bit representation
# Total number of set bits is
# equal to the total number
# of prime factors
setBits = ( 1 << n) - 1
# Indicates there is one
# way to reach the number
# under consideration
dp[setBits] = 1
findShortestSubsequence(dp, a, i + 1 ,
primeFactors)
# State 0 corresponds
# to gcd of 1
mn = min (dp[ 0 ], mn)
# If not found such subsequence
# then print "-1"
if (mn = = len (a) + 1 ):
print ( - 1 )
# Else print the length
else :
print (mn)
# Driver Code if __name__ = = '__main__' :
# Given array arr[]
arr = [ 2 , 6 , 12 , 3 ]
# Function Call
printMinimumLength(arr)
# This code is contributed by bgangwar59 |
<script> // Javascript program for the above approach // Function that finds the prime // factors of a number function findPrimeFactors(n)
{ // To store the prime factor
let primeFactors = new Array(9).fill(0);
let j = 0;
// 2s that divide n
if (n % 2 == 0) {
primeFactors[j++] = 2;
while (n % 2 == 0)
n >>= 1;
}
// N must be odd at this point
// Skip one element
for (let i = 3;
i * i <= n; i += 2) {
if (n % i == 0) {
// Update the prime factor
primeFactors[j++] = i;
while (n % i == 0)
n /= i;
}
}
// If n is a prime number
// greater than 2
if (n > 2)
primeFactors[j++] = n;
let PrimeFactors = new Array(j);
for (let i = 0; i < j; i++)
{
PrimeFactors[i] = primeFactors[i];
}
return PrimeFactors;
} // Function that finds the shortest // subsequence function findShortestSubsequence(dp, a, index, primeFactors)
{ let n = a.length;
for (let j = index; j < n; j++) {
let bitmask = 0;
for (let p = 0;
p < primeFactors.length; p++) {
// Check if the prime factor
// of first number, is also
// the prime factor of the
// rest numbers in array
if ((a[j] % primeFactors[p]) == 0) {
// Set corresponding bit
// of prime factor to 1,
// it means both these
// numbers have the
// same prime factor
bitmask ^= (1 << p);
}
}
for (let i = 0; i < dp.length; i++) {
// If no states encountered
// so far continue for this
// combination of bits
if (dp[i] == n + 1)
continue ;
// Update this state with
// minimum ways to reach
// this state
dp[bitmask & i]
= Math.min(dp[bitmask & i], dp[i] + 1);
}
}
} // Function that print the minimum // length of subsequence function prletMinimumLength(a)
{ let Min = a.length + 1;
for (let i = 0; i < a.length - 1; i++) {
// Find the prime factors of
// the first number
let primeFactors = findPrimeFactors(a[i]);
let n = primeFactors.length;
// Initialize the array with
// maximum steps, size of the
// array + 1 for instance
let dp = new Array(1 << n);
for (let i = 0; i < dp.length; i++){
dp[i] = a.length + 1
}
// Express the prime factors
// in bit representation
// Total number of set bits is
// equal to the total number
// of prime factors
let setBits = (1 << n) - 1;
// Indicates there is one
// way to reach the number
// under consideration
dp[setBits] = 1;
findShortestSubsequence(dp, a, i + 1,
primeFactors);
// State 0 corresponds
// to gcd of 1
Min = Math.min(dp[0], Min);
}
// If not found such subsequence
// then print "-1"
if (Min == (a.length + 1))
document.write(-1 + "<br>" );
// Else print the length
else
document.write(Min + "<br>" );
} // Driver code // Given array arr[]
let arr = [ 2, 6, 12, 3 ];
// Function Call
prletMinimumLength(arr);
// This code is contributed by _saurabh_jaiswal </script> |
// C# program for // the above approach using System;
class GFG{
// Function that finds the prime // factors of a number private static int [] findPrimeFactors( int n)
{ // To store the prime factor
int [] primeFactors = new int [9];
int j = 0;
// 2s that divide n
if (n % 2 == 0)
{
primeFactors[j++] = 2;
while (n % 2 == 0)
n >>= 1;
}
// N must be odd at this point
// Skip one element
for ( int i = 3;
i * i <= n; i += 2)
{
if (n % i == 0)
{
// Update the prime factor
primeFactors[j++] = i;
while (n % i == 0)
n /= i;
}
}
// If n is a prime number
// greater than 2
if (n > 2)
primeFactors[j++] = n;
int []temp = new int [j];
Array.Copy(primeFactors, temp, j);
return temp;
} // Function that finds the shortest // subsequence private static void findShortestSubsequence( int [] dp, int [] a,
int index,
int [] primeFactors)
{ int n = a.Length;
for ( int j = index; j < n; j++)
{
int bitmask = 0;
for ( int p = 0;
p < primeFactors.Length; p++)
{
// Check if the prime factor
// of first number, is also
// the prime factor of the
// rest numbers in array
if (a[j] % primeFactors[p] == 0)
{
// Set corresponding bit
// of prime factor to 1,
// it means both these
// numbers have the
// same prime factor
bitmask ^= (1 << p);
}
}
for ( int i = 0;
i < dp.Length; i++)
{
// If no states encountered
// so far continue for this
// combination of bits
if (dp[i] == n + 1)
continue ;
// Update this state with
// minimum ways to reach
// this state
dp[bitmask & i] = Math.Min(dp[bitmask & i],
dp[i] + 1);
}
}
} // Function that print the minimum // length of subsequence private static void printMinimumLength( int [] a)
{ int min = a.Length + 1;
for ( int i = 0;
i < a.Length - 1; i++)
{
// Find the prime factors of
// the first number
int [] primeFactors = findPrimeFactors(a[i]);
int n = primeFactors.Length;
int [] dp = new int [1 << n];
// Initialize the array with
// maximum steps, size of the
// array + 1 for instance
for (i = 0; i < dp.Length; i++)
dp[i] = a.Length + 1;
// Express the prime factors
// in bit representation
// Total number of set bits is
// equal to the total number
// of prime factors
int setBits = (1 << n) - 1;
// Indicates there is one
// way to reach the number
// under consideration
dp[setBits] = 1;
findShortestSubsequence(dp, a, i + 1,
primeFactors);
// State 0 corresponds
// to gcd of 1
min = Math.Min(dp[0], min);
}
// If not found such subsequence
// then print "-1"
if (min == a.Length + 1)
Console.WriteLine(-1);
// Else print the length
else
Console.WriteLine(min);
} // Driver Code public static void Main(String[] args)
{ // Given array []arr
int [] arr = {2, 6, 12, 3};
// Function Call
printMinimumLength(arr);
} } // This code is contributed by Rajput-Ji |
2
Time Complexity: O(N2)
Auxiliary Space: O(2^k) where k is the number of factors of array elements.