Singly Linked Lists
24
Singly Linked Lists • Representation • Space Analysis • Creation and Insertion • Traversal • Search • Deletion
description
Singly Linked Lists. Representation Space Analysis Creation and Insertion Traversal Search Deletion. list. head. tail. Representation. We are using a representation in which a linked list has both head and tail references. public class MyLinkedList{ protected Element head; - PowerPoint PPT Presentation
Transcript of Singly Linked Lists
Singly Linked Lists
• Representation
• Space Analysis
• Creation and Insertion
• Traversal
• Search
• Deletion
Representation
• We are using a representation in which a linked list has both head and tail references .
list headtail
public class MyLinkedList{ protected Element head; protected Element tail; public final class Element{ Object data;
Element next;Element(Object obj, Element element){ data = obj; next = element;}
public Object getData(){return data;}public Element getNext(){return next;}
}}
Representation: Space Analysis
• Now, we can take a look at the space requirements:
S(n) = sizeof(MyLinkedList) + n sizeof(MyLinkedList.Element) = 2 sizeof(MyLinkedList.Element ref) + n [sizeof(Object ref) +
sizeof(MyLinkedList.Element ref)] = (n + 2) sizeof(MyLinkedList.Element ref) + n sizeof(Object ref)
Space RequireExplanation
sizeof(MyLinkedList)
The list reference has two fields: head (type: Element) and tail (type: Element) = 2 sizeof(MyLinkedList.Element ref)
nsizeof(MyLinkedList.Element)
The list has n elements of type Element. Each element has two fields-- data (type Object) and next (type Element).
List Creation and Insertion
• An empty list is created as follows:
• Once created, elements can be inserted into the list using either the append or prepend methods
• Also if we have reference to a node (an element), we can use insertAfter or InsertBefore of the Element class.
head
tail
MyLinkedList list = new MyLinkedList;()
for (int k = 0; k < 10; k++) list.append(new Integer(k));
public void append(Object obj){ Element element = new Element(obj, null); if(head == null) head = element; else tail.next = element; tail = element;}
Insertion at the end (Append)
Complexity is O(1)
public void prepend(Object obj) { Element element = new Element(obj, head); if(head == null) tail = element; head = element;}
Insertion at the beginning (Prepend)
Complexity is O(1)
Insertion before and after an elementpublic void insertBefore(Object obj) { Element element = new Element(obj, this); if(this == head) { head = element; return; } Element previous = head; while (previous.next != this) { previous = previous.next; } previous.next = element;}
Complexity is
public void insertAfter(Object obj) { next = new Element(obj, next); if(this == tail) tail = next;}
Complexity is O(1)
O(n)
TraversalTo move a reference e from one node to the next:
Example: Count the number of nodes in a linked list.
public int countNodes(){ int count = 0; Element e = head; while(e != null){ count++;
e = e.next; } return count;}
e = e.next;
Complexity is O(n)
Searching• To search for an element, we traverse from head until
we locate the object.Example: Count the number of nodes with data field
equal to a given object.
public int countNodes(Object obj){ int count = 0; Element e = head; while(e != null){ if(e.data.equals(obj)) count++;
e = e.next; } return count;}
Complexity is.…
public void extract(Object obj) { Element element = head; Element previous = null; while(element != null && ! element.data.equals(obj)) { previous = element; element = element.next; }
if(element == null) throw new IllegalArgumentException("item not found"); if(element == head) head = element.next; else previous.next = element.next; if(element == tail) tail = previous;}
Deletion• To delete an element, we use either the extract method of
MyLinkedList or that of the Element inner class.
Complexity is…
Deletion - Difference between the MyLinkedList and the Element extracts
• To delete an element, we use either the extract method of MyLinkedList or that of the Element inner class.
try{ list.extract(obj1);} catch(IllegalArgumentException e){ System.out.println("Element not found");}
MyLinkedList.Element e = list.find(obj1);if(e != null) e.extract();else System.out.println("Element not found");
Deletion – Deleting First and Last Element
public void extractFirst() { if(head == null) throw new IllegalArgumentException("item not found"); head = head.next; if(head == null) tail = null;}
public void extractLast() { if(tail == null) throw new IllegalArgumentException("item not found"); if (head == tail) head = tail = null; else { Element previous = head; while (previous.next != tail) previous = previous.next; previous.next = null; tail = previous; }}
Complexity is…
Complexity is…
Exercises
• For the MyLinkedList class, Implement each of the following methods:– String toString()– Element find(Object obj)– void insertAt(int n) //counting the nodes from 1.
State the complexity of each method.
• Which methods are affected if we do not use the tail reference in MyLinkedList class.
Doubly Linked Lists
• Representation
• Space Analysis
• Creation and Insertion
• Traversal
• Deletion
Representation
public class DoublyLinkedList{ protected Element head, tail; //. . . public class Element { Object data; Element next, previous; Element(Object obj, Element next, Element previous){ data = obj; this.next = next; this.previous = previous; } public Object getData(){return data;} public Element getNext(){return next;} public Element getPrevious(){return previous;} // . . . }}
list head
tail
Doubly Linked Lists : Space Analysis
• The space requirements of our representation of the doubly linked lists is as follows: S(n) = sizeof(DoublyLinkedList) + n sizeof(DoublyLinkedList.Element) = 2 sizeof(DoublyLinkedList.Element ref) + n [sizeof(Object ref)
+ 2 sizeof(DoublyLinkedList.Element ref)] = (2n + 2) sizeof(DoublyLinkedList.Element ref) + n sizeof(Object ref)
Required spaceExplanationsizeof(DoublyLinkedList)The list reference has two fields:
head (type: Element) and tail (type: Element) = 2 sizeof(DoublyLinkedList.Element ref)
n sizeof(DoublyLinkedList.Element)
The list has n elements of type Element. Each element has three fields-- previous (type Element), data (type Object), and next (type Element)
List Creation and Insertion
• An empty doubly linked list is created as follows:DoublyLinkedList list = new DoublyLinkedList();
• Like singly link list, once created, elements can be inserted into the list using either the append or prepend methods
for (int k = 0; k < 10; k++) list.append(new Int(k));
• Also if we have reference to a node (an element), we can use insertAfter or InsertBefore of the Element class..
b(
head
tail
Insertion at the end (append)public void append(Object obj){ Element element = new Element(obj, null, tail); if(head == null) head = tail = element; else { tail.next = element; tail = element; }}
Complexity is…
Insertion at the beginning (prepend)public void prepend(Object obj){ Element element = new Element(obj, head, null); if(head == null) head = tail = element; else { head.previous = element; head = element; } }
Complexity is…
Insertion before an element• Inserting before the current node (this) that is neither the first
nor the last node:
Complexity is…
Element element = new Element(obj, this, this.previous);this.previous.next = element;this.previous = element;
TraversalFor DoublyLinked list, traversal can be done in either direction. Forward, starting from head, or backward starting from tail.
Example: Count the number of nodes in a linked list.
Element e = head;while (e != null) { //do something e = e.next;}
Element e = tail;while (e != null) { //do something e = e.previous;}
public int countNodes(){ int count = 0; Element e = head; while(e != null){ count++; e = e.next; } return count;}
Complexity is…
public int sumLastNnodes(int n){ if(n <= 0)
throw new IllegalArgumentException("Wrong: " + n); if(head == null)
throw new ListEmptyException();
int count = 0, sum = 0; Element e = tail; while(e != null && count < n){
sum += ((Integer)e.data).intValue(); count++; e = e.previous;
} if(count < n)
throw new IllegalArgumentException(“No. of nodes < "+n); return sum; }
TraversalExample: The following computes the sum of the last n nodes:
Complexity is…
Deletion• To delete an element, we use either the extract method of
DoublyLinkedList or that of the Element inner class. public void extract(Object obj){ Element element = head; while((element != null) && (!element.data.equals(obj)))
element = element.next; if(element == null) throw new IllegalArgumentException("item not found"); if(element == head) { head = element.next; if(element.next != null) element.next.previous = null; }else{ element.previous.next = element.next; if(element.next != null) element.next.previous = element.previous; } if(element == tail) tail = element.previous;}
Complexity is…
Exercises
• For the DoublyLinkedList class, Implement each of the following methods and state its complexity.– String toString()– Element find(Object obj)– void ExtractLast()– void ExtractFirst()– void ExtractLastN(int n)
• For the DoublyLinkedList.Element inner class, implement each of the following methods and state its complexity.– void insertBefore()– void insertAfter()– void extract()
• What are the methods of DoublyLinkedList and its Element inner class are more efficient than those of MyLinkedList class?
