solution.py

#!/bin/python3

import math
import os
import random
import re
import sys

class SinglyLinkedListNode:
    def __init__(self, node_data):
        self.data = node_data
        self.next = None

class SinglyLinkedList:
    def __init__(self):
        self.head = None
        self.tail = None

    def insert_node(self, node_data):
        node = SinglyLinkedListNode(node_data)

        if not self.head:
            self.head = node
        else:
            self.tail.next = node


        self.tail = node

def print_singly_linked_list(node, sep, fptr):
    while node:
        fptr.write(str(node.data))

        node = node.next

        if node:
            fptr.write(sep)

# Cycle detection Function

def has_cycle(head):

    visited=[]   # List to store already visited nodes
    temp=head
    while temp is not None:     # traversing the linked list
        if temp in visited:     
            return 1            # If node is already present in visited, it indicates presence of a cycle.
        else:
            visited.append(temp)
        temp=temp.next
    return 0

if __name__ == '__main__':
    fptr = open(os.environ['OUTPUT_PATH'], 'w')

    tests = int(input())

    for tests_itr in range(tests):
        index = int(input())

        llist_count = int(input())

        llist = SinglyLinkedList()

        for _ in range(llist_count):
            llist_item = int(input())
            llist.insert_node(llist_item)

        extra = SinglyLinkedListNode(-1);
        temp = llist.head;

        for i in range(llist_count):
            if i == index:
                extra = temp

            if i != llist_count-1:
                temp = temp.next

        temp.next = extra

        result = has_cycle(llist.head)

        fptr.write(str(int(result)) + '\n')

    fptr.close()