public ListNode mergeKLists(ArrayList<ListNode> lists) {
if (lists.size() == 0) return null;
PriorityQueue<ListNode> q =
new PriorityQueue<ListNode>(
lists.size(),
new Comparator<ListNode>() {
public int compare(ListNode a, ListNode b) {
if (a.val > b.val) return 1;
else if (a.val == b.val) return 0;
else return -1;
}
});
for (ListNode i : lists) if (i != null) q.add(i);
ListNode head = new ListNode(-1);
ListNode pre = head;
while (q.size() != 0) {
ListNode temp = q.poll();
pre.next = temp;
if (temp.next != null) q.add(temp.next);
pre = pre.next;
}
return head.next;
}
public ListNode mergeKLists(ArrayList<ListNode> lists) {
if (lists == null || lists.isEmpty()) return null;
ListNode head = new ListNode(0);
ListNode p = head;
PriorityQueue<ListNode> queue =
new PriorityQueue<ListNode>(
lists.size(),
new Comparator<ListNode>() {
@Override
public int compare(ListNode o1, ListNode o2) {
return o1.val - o2.val;
}
});
for (ListNode n : lists) {
if (n != null) {
queue.offer(n);
}
}
while (!queue.isEmpty()) {
ListNode n = queue.poll();
p.next = n;
p = p.next;
if (n.next != null) {
queue.offer(n.next);
}
}
return head.next;
}
public ListNode removeNthFromEnd(ListNode head, int n) {
// Start typing your Java solution below
// DO NOT write main() function
if (head == null) {
return null;
}
ListNode tail = head;
int i = 0;
for (; i < n && tail != null; ++i) {
tail = tail.next;
}
if (tail == null && i < n) {
return null;
}
ListNode nth = head;
ListNode pHead = new ListNode(0);
pHead.next = head;
ListNode prev = pHead;
while (tail != null) {
prev = nth;
nth = nth.next;
tail = tail.next;
}
// remove nth from end
prev.next = nth.next;
return pHead.next;
}
public ListNode deleteDuplicates(ListNode head) {
if (head == null) {
return null;
}
Set<Integer> valToRemove = new HashSet<Integer>();
ListNode cur = head;
while (cur != null) {
if (cur.next != null && cur.val == cur.next.val) {
valToRemove.add(cur.val);
}
cur = cur.next;
}
ListNode fake = new ListNode(0);
fake.next = head;
cur = fake;
while (cur.next != null) {
if (valToRemove.contains(cur.next.val)) {
cur.next = cur.next.next;
continue;
}
cur = cur.next;
}
return fake.next;
}
public void padList(ListNode head, int len) {
for (int i = 0; i < len; i++) {
ListNode newNode = new ListNode(0);
newNode.next = head;
head = newNode;
}
}
public static ListNode reverseKGroup(ListNode head, int k) {
if (head == null || head.next == null || k < 2) {
return head;
}
LinkedList<ListNode> l = new LinkedList<ListNode>();
int count = 0;
ListNode pre = new ListNode(0);
ListNode temp = pre;
while (head != null) {
if (count++ < k) {
ListNode t = new ListNode(head.val);
l.push(t);
head = head.next;
}
if (count >= k) {
count = 0;
while (!l.isEmpty()) {
temp.next = l.pop();
temp = temp.next;
}
}
}
while (!l.isEmpty()) {
temp.next = l.pollLast();
temp = temp.next;
}
return pre.next;
}
public static ListNode NAfterMMore(ListNode head, int m, int n) {
if (head == null || head.next == null || n == 0) return head;
ListNode p = head, previous = null;
int count = 0;
while (p != null) {
count = 0;
while (count < m) {
count++;
previous = p;
p = p.next;
}
count = 0;
while (count < n && p != null) {
count++;
p = p.next;
}
previous.next = p;
previous = previous.next;
// p = p == null ? null : p.next;
}
return head;
}
public ListNode deleteDuplicates(ListNode a) {
ListNode temp = a;
LinkedHashMap<Integer, Integer> map = new LinkedHashMap<Integer, Integer>();
int i = 0;
while (temp != null) {
if (map.get(temp.val) == null) {
map.put(temp.val, 1);
} else {
map.put(temp.val, map.get(temp.val) + 1);
}
temp = temp.next;
}
System.out.println(map);
Iterator<Integer> it = map.keySet().iterator();
ListNode root = null;
ListNode root1 = null;
while (it.hasNext()) {
int x = it.next();
if (map.get(x) == 1) {
if (root == null) {
root = new ListNode(x);
root1 = root;
} else {
ListNode node = new ListNode(x);
root1.next = node;
root1 = node;
}
}
}
return root;
}
public ListNode mergeList(ListNode head1, ListNode head2) {
if (head1 == null) return head2;
if (head2 == null) return head1;
ListNode dummy = new ListNode(-1);
ListNode p = dummy;
ListNode p1 = head1;
ListNode p2 = head2;
while (p1 != null && p2 != null) {
p.next = p1;
p1 = p1.next;
p = p.next;
p.next = p2;
p2 = p2.next;
p = p.next;
}
if (p1 == null) {
p.next = p2;
}
if (p2 == null) {
p.next = p1;
}
return dummy.next;
}
/* Helpers */
private static InputArgs input() throws IOException {
System.out.println("2.2 Return Kth to Last");
// read K
System.out.print("Please input K: ");
Scanner sc = new Scanner(System.in);
int k = sc.nextInt();
// read number of nodes
System.out.println();
System.out.print("Please input the number of nodes in the linked list: ");
int n = sc.nextInt();
// read linked list
System.out.println();
System.out.print("Please input value of nodes (seperate by space, e.g., 1 2 3): ");
ListNode dummy = new ListNode(0);
ListNode pre = dummy;
for (int i = 0; i < n; i++) {
ListNode cur = new ListNode(sc.nextInt());
pre.next = cur;
pre = cur;
}
return new InputArgs(k, dummy.next);
}
/**
* @param head: The first node of linked list.
* @return: a tree node
*/
public TreeNode sortedListToBST(ListNode head) {
// write your code here
if (head == null) {
return null;
}
ListNode current = head;
int count = 0;
while (current != null) { // 遍历单链表
count++;
current = current.next;
}
ListNode middle = head, prev = null;
for (int i = 0; i < count / 2; i++) {
prev = middle;
middle = middle.next;
}
TreeNode root = new TreeNode(middle.val);
if (middle == head) { // 说明链表长度为1,直接输出
return root;
}
prev.next = null;
root.left = sortedListToBST(head);
root.right = sortedListToBST(middle.next);
return root;
}
public ListNode addTwoNumbers(ListNode l1, ListNode l2) {
addNode = new ListNode(l1.val + l2.val);
ListNode travel = addNode;
ListNode l1Travel = l1;
ListNode l2Travel = l2;
int a;
int b;
int over = 0;
while ((l1Travel.next != null) || (l2Travel.next != null) || over != 0) {
a = l1Travel.next == null ? 0 : l1Travel.next.val;
b = l2Travel.next == null ? 0 : l2Travel.next.val;
over = over + a + b;
travel.next = new ListNode((over) % 10);
travel = travel.next;
over = (over) / 10;
if (l1Travel.next != null) {
l1Travel = l1Travel.next;
}
if (l2Travel.next != null) {
l2Travel = l2Travel.next;
}
}
travel.next = null;
return addNode;
}
public ListNode swapPairs(ListNode head) {
if ((head == null) || (head.next == null)) return head;
ListNode n = head.next;
head.next = swapPairs(head.next.next);
n.next = head;
return n;
}
public ListNode rotateRight(ListNode head, int k) {
// corner case
if (head == null || head.next == null) {
return head;
}
// get length and move one pointer to the end of the list
int count = 1;
ListNode node = head;
while (node != null && node.next != null) {
count++;
node = node.next;
}
k = k % count;
int step = count - k - 1;
ListNode temp = head;
for (int i = 0; i < step; i++) {
temp = temp.next;
}
// System.out.println(right.val);
// System.out.println(right.next);
node.next = head;
// System.out.println(right.next);
// ListNode right = temp.next;
ListNode right = temp.next;
temp.next = null;
return right;
}
public ListNode rotateRight(ListNode head, int k) {
if (head == null || head.next == null || k == 0) return head;
ListNode p = new ListNode(-1);
ListNode p1 = head;
ListNode p2 = head;
ListNode temp = head;
int len = 0;
while (temp != null) {
len++;
temp = temp.next;
}
k %= len;
if (k == 0) return head;
for (int i = 0; i < k; i++) {
p1 = p1.next;
}
while (p1.next != null) {
p1 = p1.next;
p2 = p2.next;
}
p = p2.next;
p1.next = head;
p2.next = null;
return p;
}
public ListNode mergeKLists(ListNode[] lists) {
ListNode sentinel = new ListNode(0);
ListNode current = sentinel;
PriorityQueue<ListNode> heap =
new PriorityQueue<>(
(e1, e2) -> {
if (e1.val > e2.val) {
return 1;
} else if (e1.val < e2.val) {
return -1;
} else {
return 0;
}
});
for (ListNode node : lists) {
if (node != null) {
heap.add(node);
}
}
while (heap.isEmpty() == false) {
ListNode nodeWithMinValue = heap.poll();
current.next = nodeWithMinValue;
nodeWithMinValue = nodeWithMinValue.next;
if (nodeWithMinValue != null) {
heap.add(nodeWithMinValue);
}
}
return sentinel.next;
}
public ListNode mergeTwoLists(ListNode l1, ListNode l2) {
ListNode l1c = l1;
ListNode l2c = l2;
ListNode head = new ListNode(-100);
ListNode r = head;
while (l1c != null && l2c != null) {
if (l1c.val > l2c.val) {
head.next = l2c;
l2c = l2c.next;
head = head.next;
} else {
head.next = l1c;
l1c = l1c.next;
head = head.next;
}
}
if (l1c == null) {
head.next = l2c;
}
if (l2c == null) {
head.next = l1c;
}
return r.next;
}
public static ListNode[] SecondTry(ListNode l1, ListNode l2) {
if (l1 == null || l2 == null) {
return new ListNode[] {l1 == null ? l2 : l1, l1 == null ? l2 : l1};
}
ListNode[] res = new ListNode[2];
ListNode newHead = new ListNode(), head1 = new ListNode(), head2 = new ListNode();
ListNode p = newHead, p1 = l1, p2 = l2;
head1.next = p1;
head2.next = p2;
while (p1 != null && p2 != null) {
p.next = p1;
p = p.next;
head1.next = p1.next;
p1 = p1.next;
p.next = p2;
p = p.next;
head2.next = p2.next;
p2 = p2.next;
}
p.next = null;
res[0] = newHead.next;
res[1] = head2.next;
return res;
}
/**
* @param ListNode head is the head of the linked list
* @return: ListNode head of the linked list
*/
public static ListNode deleteDuplicates(ListNode head) {
// write your code here
if (head == null || head.next == null) {
return head;
}
ListNode curt = new ListNode(0);
ListNode ret = curt;
while (head != null && head.next != null) {
if (head.val != head.next.val) {
curt.next = new ListNode(head.val);
curt = curt.next;
head = head.next;
} else {
while (head.next != null && head.val == head.next.val) {
head = head.next;
}
head = head.next;
}
}
if (head != null) {
curt.next = new ListNode(head.val);
}
return ret.next;
}
private ListNode removeNode(ListNode head, int pos) {
if (pos == 0) {
return head.next;
}
if (pos == 1) {
return head.next;
} else {
int count = 1;
ListNode previous = head;
ListNode next = head.next;
while (next != null && count < pos - 1) {
previous = next;
next = next.next;
count++;
}
if (next == null) {
previous.next = null;
} else {
previous.next = next.next;
}
return head;
}
}
public ListNode deleteDuplicates(ListNode head) {
if (head == null) {
return head;
}
ListNode dummy = new ListNode(0);
dummy.next = head;
ListNode prev = dummy;
boolean dup = false;
while (head != null) {
if (head.next != null && head.val == head.next.val) {
head = head.next;
dup = true;
} else if (head.next == null) {
if (dup) {
prev.next = null;
}
head = head.next;
} else if (head.val != head.next.val) {
if (dup) {
head = head.next;
prev.next = head;
dup = false;
} else {
prev = head;
head = head.next;
}
}
}
return dummy.next;
}
public ListNode mergeTwoLists(ListNode l1, ListNode l2) {
ListNode dummy = new ListNode(0);
ListNode cur = dummy;
while (l1 != null || l2 != null) {
if (l1 != null && l2 != null) {
if (l1.val <= l2.val) {
cur.next = l1;
l1 = l1.next;
} else {
cur.next = l2;
l2 = l2.next;
}
cur = cur.next;
} else if (l1 == null && l2 != null) {
cur.next = l2;
l2 = l2.next;
cur = cur.next;
} else if (l1 != null && l2 == null) {
cur.next = l1;
l1 = l1.next;
cur = cur.next;
}
}
return dummy.next;
}
public static ListNode reverseKNodes(ListNode head, int k) {
// Start with head
ListNode current = head;
// last node after reverse
ListNode prevTail = null;
// first node before reverse
ListNode prevCurrent = head;
while (current != null) {
// loop for reversing K nodes
int count = k;
ListNode tail = null;
while (current != null && count > 0) {
ListNode next = current.getNext();
current.setNext(tail);
tail = current;
current = next;
count--;
}
// reversed K Nodes
if (prevTail != null) {
// Link this set and previous set
prevTail.setNext(tail);
} else {
// We just reversed first set of K nodes, update head point to the Kth Node
head = tail;
}
// save the last node after reverse since we need to connect to the next set.
prevTail = prevCurrent;
// Save the current node, which will become the last node after reverse
prevCurrent = current;
}
return head;
}
// fail to solve the problem
// This is very basic and important!
public ListNode mergeTwoLists(ListNode l1, ListNode l2) {
// only one statement is enough to solve 3 condition
// cause linklist is connected, I don't need to insert rest of the node anymore
if (l1 == null || l2 == null) return l1 == null ? l2 : l1;
// the head node is specil, need seperate initiate.
ListNode head = null;
if (l1.val <= l2.val) {
head = l1;
l1 = l1.next;
} else {
head = l2;
l2 = l2.next;
}
ListNode temp = head;
// in while loop, temp.next = smallvalue; l1 = l1.next; temp = temp.next;
while (l1 != null && l2 != null) {
if (l1.val <= l2.val) {
temp.next = l1;
l1 = l1.next;
} else {
temp.next = l2;
l2 = l2.next;
}
;
temp = temp.next;
}
// finally, we find the non-null node add it to the rear of l3
// cause linklist is connected, I don't need to insert rest of the node anymore
temp.next = l1 == null ? l2 : l1;
return head;
}
public ListNode mergeKLists(ArrayList<ListNode> lists) {
if (lists == null || lists.isEmpty()) return null;
PriorityQueue<ListNode> heap =
new PriorityQueue<ListNode>(
lists.size(),
new Comparator<ListNode>() {
public int compare(ListNode o1, ListNode o2) {
return o1.data > o2.data ? 1 : (o1.data < o2.data ? -1 : 0);
}
});
for (ListNode node : lists) {
if (node != null) {
heap.add(node);
}
}
ListNode head = null, cur = null;
while (!heap.isEmpty()) {
if (head == null) {
head = heap.poll();
cur = head;
} else {
cur.next = heap.poll();
cur = cur.next;
}
if (cur.next != null) {
heap.add(cur.next);
}
}
return head;
}
public void reorderList(ListNode head) {
if (head == null || head.next == null || head.next.next == null) {
return;
}
ListNode oneStep = head;
ListNode twoStep = head;
while (twoStep != null && twoStep.next != null) {
twoStep = twoStep.next.next;
oneStep = oneStep.next;
}
ListNode half = oneStep.next;
oneStep.next = null;
Stack<ListNode> stack = new Stack<ListNode>();
while (half != null) {
stack.push(half);
half = half.next;
}
ListNode tmp = head;
while (head != null) {
ListNode oldRight = head.next;
if (stack.empty()) {
break;
}
head.next = stack.pop();
head.next.next = oldRight;
head = oldRight;
}
head = tmp;
}
public static boolean isPalindrome_good(ListNode head) {
if (head == null || head.next == null) {
return true;
}
ListNode fast = head;
ListNode slow = head;
while (fast.next != null && fast.next.next != null) {
slow = slow.next;
fast = fast.next.next;
}
ListNode newhead = slow.next;
ListNode pre = null;
while (newhead != null) {
ListNode temp = newhead.next;
newhead.next = pre;
pre = newhead;
newhead = temp;
}
while (pre != null) {
if (pre.val != head.val) {
return false;
}
pre = pre.next;
head = head.next;
}
return true;
}
/*
Solution 2
Did not use additional space, each time encounter the first unique value node,
traversal the rest of the list to delete the same value's nodes.
Assumption:
None.
Time complexity: O(n^2)
Space Complexity: O(1)
*/
private static ListNode RemoveDups2(ListNode head) {
if (head == null) return head;
ListNode pre = head;
while (pre != null) {
ListNode pre2 = pre;
ListNode cur = pre.next;
int target = pre.val;
while (cur != null) { // delete the dups in the rest of the list
if (cur.val == target) {
pre2.next = cur.next;
cur = cur.next;
} else {
pre2 = cur;
cur = cur.next;
}
}
// move to next different value's node
pre = pre.next;
}
return head;
}
/**
* @param ListNode l1 is the head of the linked list
* @param ListNode l2 is the head of the linked list
* @return: ListNode head of linked list
*/
public ListNode mergeTwoLists(ListNode l1, ListNode l2) {
// write your code here
if (l1 == null && l2 == null) {
return null;
}
ListNode fakeHead = new ListNode(0);
ListNode curr = fakeHead;
while (l1 != null && l2 != null) {
if (l1.val <= l2.val) {
curr.next = l1;
l1 = l1.next;
} else {
curr.next = l2;
l2 = l2.next;
}
curr = curr.next;
}
if (l1 != null) {
curr.next = l1;
}
if (l2 != null) {
curr.next = l2;
}
return fakeHead.next;
}
public ListNode removeNthFromEnd(ListNode head, int n) {
if (head == null || head.next == null) {
return null;
}
ListNode first = head;
ListNode second = head;
for (int i = 0; i < n; i++) {
first = first.next;
if (first == null) {
return head.next;
}
}
while (first.next != null) {
first = first.next;
second = second.next;
}
second.next = second.next.next;
return head;
}
