Lecture 6 Feb 8, 2012 Goals: Linked list (Chapter 3) list class in STL (section 3.3) implementing...
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Transcript of Lecture 6 Feb 8, 2012 Goals: Linked list (Chapter 3) list class in STL (section 3.3) implementing...
Lecture 6 Feb 8, 2012
Goals:
• Linked list (Chapter 3)
• list class in STL (section 3.3)
• implementing with linked lists
Overview of list vs. array
• list can be incrementally grown. (dynamic array resizing is expensive.)
• inserting next to a given node takes constant time. (In arrays, this takes O(n) time where n = size of the array.)
• searching for a given key even in a sorted list takes O(n) time. (in sorted array, it takes O(log n) time by binary search.)
• accessing the k-th node takes O(k) time. (in array, this takes O(1) time.)
Abstract Data Type (ADT)o List ADT insert, find, delete (primary operations) successor, merge, reverse, …
(secondary)
o Variations of linked listso Circular listso Doubly linked lists
Review of ADT
Some list functionsConsider the standard singly-linked list class:
class list { private: Node* first; public: list(int k) { first = new Node(k);} void insert(int k, int posn); // insert k at posn Node* find(int k); // return first node containing k void delete(int k); // remove first node containing k int length(); // return the length of the list void delete_after(Node* n);// remove node after n, if it // exists void get_key(int posn); // return key in a given position void print_list(); // print the list . . . . . . . .}
Etc.
Other functions: delete a key in a position.
Implementing some of the functions
void insert(int k, int posn) { // insert k at a given position // write recursively.
}
Implementing some of the functions
void insert(int k, int posn) { // insert k at a given position // write recursively. if (posn < 1 || posn > length()) return; // wrong value of posn; ignore if (posn == 1) { list temp = new list(k); temp->next = first; first = temp; } else first->next = first->next.insert(k, posn-1);
}
Reverse the list
We want to reverse the list using the existing nodes of the list, i.e., without creating new nodes.
Reverse the list
We want to reverse the list using the existing node of the list, i.e., without creating new nodes.
void reverse() { if (head == NULL || head -> next == NULL) return; Node* p = head; Node* q = p-> next; p->next = NULL; while (q != NULL) { Node* temp = q -> next; q->next = p; p = q; q = temp; } head = p; }
Remove negative items from the list
Example: List: -3, 4, 5, -2, 11 becomes 4, 5, 11
We will write this one recursively.
Remove negative items from the list
Example: List: -3, 4, 5, -2, 11 becomes 4, 5, 11
We will write this one recursively.
void remove_negative() {// removes all the negative items from a list// Example input: -4 5 6 -2 8; output: 5 6 8 if (head == NULL) return; else if (head->key >= 0) {
List nList = List(head->next);nList.remove_negative();
head->next = nList.head; } else {
List nList = List(head->next); nList.remove_negative(); head = nList.head; } }
Generating all subsets of a given list
Generate all the subsets of a given set of numbers.
Thus, if the input is {1, 2, 4} the output is:
{}{1}{2}{4}{1, 2}{1, 4}{2, 4}{1, 2, 4}
Our program treats all the input symbols as distinct so a pre-condition is: the input array elements are distinct.
Data structure used
Array or vector of lists:
Each member of the vector is a pointer to a list containing one of the subsets.
null2
4 2
4
A 0
1
2
3
build(A, j) will generate all the subsets of the set {A[0], A[1], … , A[j – 1]}.
Thus, if A = [2, 4, 6, 1], then build(A, 1) will generate all the subsets of {2}, build(A, 2) will generate all the subsets of {2, 4} etc.
build(A, 1) returns:
null
2 null
build(A, 2)Returns:
null2
4 2
4
set(A,k) calls set(A, k – 1).
Make a copy of set(A,k-1). Call this temp. Insert A[k-1] into each set in temp.
Then merge set(A,k-1) and temp and make it the current collection.
Example: A = {1, 3, 2}. Suppose k = 2.
Build(A,2) returns the collection of lists [ ], [1], [3], [1, 3]. Now inserting 2 into each of the lists gives [2], [2,1], [2,3], [2,1,3].
Merging the two lists we get:
[ ], [1], [3], [1, 3], [2], [2,1], [2,3], [2,1,3].This is the set of all subsets of {1, 3, 2}.
Constructor written recursively
set(vector<int> A, int k) {if (k == 0) { List temp = new List(); A.push_back(temp); }else {set(vector<int> A, k-1); set temp = copy(B);merge(temp); }}
Constructors for set and List
set(int n) { size = n; for (int j=0; j < n; ++j) mems[j] = null;}
public:List() { first = 0;}
Main function for subsets construction
int main() { int s; cout << "Enter the size of the set." << endl; cin >> s; vector<int> a(s); cout << "Enter the elements of the set." << endl; for (int j=0; j < s; ++j) cin >> a[j]; set(a,s).print();}