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1 Principles revisited.NET: Two libraries: System.Collections System.Collections.Generics Data Structures and Collections.

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Presentation on theme: "1 Principles revisited.NET: Two libraries: System.Collections System.Collections.Generics Data Structures and Collections."— Presentation transcript:

1 1 Principles revisited.NET: Two libraries: System.Collections System.Collections.Generics Data Structures and Collections

2 2 interface: (e.g. IDictionary) Specification class Appl{ ---- IDictionary m; ----- m= new XXXDic(); application class: Hash Table Search Tree ---- ADT Data structure and algorithms Choose and use an adt, e.g. IDictionary Choose and use a data structure, e.g. SortedDicitonary Know about Read and write (use) specifications Data Structures and Collections

3 3 Collections Library System.Collections Data structures in.NET are normally called Collections Are found in namespace System.Collections Compiled into mscorlib.dll assembly Uses object and polymorphism for generic containers. Deprecated! Classes: Array ArrayList Hashtable Stack Queue

4 4 Collection Interfaces System.Collections implements a range of different interfaces in order to provide standard usage of different containers Classes that implements the same interface provides the same services Makes it easier to learn and to use the library Makes it possible to write generic code towards the interface Interfaces: ICollection IEnumerable IEnumerator IList IComparer IComparable

5 5 ArrayList ArrayList stores sequences of elements. duplicate values are ok – position- (index-) based Elements are stored in an resizable array. Implements the IList interface public class ArrayList : IList, IEnumerable,... { // IList services... // additional services int Capacity { get... set... } void TrimToSize() int BinarySearch(object value) int IndexOf (object value, int startIndex) int LastIndexOf (object value, int startIndex)... } control of memory in underlying array searching

6 6 IList Interface IList defineres sequences of elements Access through index public interface IList : ICollection { int Add (object value); void Insert(int index, object value); void Remove (object value); void RemoveAt(int index); void Clear (); bool Contains(object value); int IndexOf (object value); object this[int index] { get; set; } bool IsReadOnly { get; } bool IsFixedSize { get; } } add new elements remove containment testing read/write existing element (see comment) structural properties

7 7 Hashtable Hashtable supports collections of key/value pairs keys must be unique, values holds any data stores object references at key and value GetHashCode method on key determine position in the table. Hashtable ages = new Hashtable(); ages["Ann"] = 27; ages["Bob"] = 32; ages.Add("Tom", 15); ages["Ann"] = 28; int a = (int) ages["Ann"]; create add update retrieve

8 8 Hashtable Traversal Traversal of Hashtable each element is of type DictionaryEntry (struct) data is accessed using the Key and Value properties Hashtable ages = new Hashtable(); ages["Ann"] = 27; ages["Bob"] = 32; ages["Tom"] = 15; foreach (DictionaryEntry entry in ages) { string name = (string) entry.Key; int age = (int) entry.Value;... } enumerate entries get key and value

9 9.NET 2: System.Collections.Generics ICollection IList LinkedList IDictionary List Dictionary SortedDictionary Index able Array-based Balanced search tree Hashtabel (key, value) -pair

10 10 Demos Lists Maps LinkedList in C#

11 How does they work? Array-based list Linked list 11 used Count Free (waste)

12 Dynamic vs. Static Data Structures Array-Based Lists: Fixed (static) size (waste of memory). May be able to grown and shrink (ArrayList), but this is very expensive in running time (O(n)) Provides direct access to elements from index (O(1)) Linked List Implementations: Uses only the necessary space (grows and shrinks as needed). Overhead to references and memory allocation Only sequential access: access by index requires searching (expensive: O(n)) 12

13 Hashing Keys are converted to indices in an array. A hash function, h maps a key to an integer, the hash code. The hash code is divided by the array size and the remainder is used as index If two or more keys gives the same index, we have a collision. 13

14 Chaining The array doesn’t hold the element itself, but a reference to a collection (a linked list for instance) of all colliding elements. On search that list must be traversed 14

15 Efficiency of Hashing Worst case (maximum collisions): retrieve, insert, delete all O(n) Average number of collisions depends on the load factor, λ, not on table size λ = (number of used entries)/(table size) But not on n. Typically (linear probing): numberOfCollisions avg = 1/(1 - λ) Example: 75% of the table entries in use: λ = 0.75: 1/(1-0.75) = 4 collisions in average (independent of the table size). 15

16 When Hashing Is Inefficient Traversing in key order. Find smallest/largest key. Range-search (Find all keys between high and low). Searching on something else than the designated primary key. 16

17 17 (Binary) Search Trees Value based container: The search tree property: For any internal node: the value is greater than the value in the left child For any internal node: the value is less than the value in the right child Note the recursive nature of this definition: It implies that all sub trees themselves are search trees Every operation must ensure that the search tree property is maintained

18 18 Example: A Binary Search Tree Holding Names

19 19 InOrder: Traversal Visits Nodes in Sorted Order

20 20 Efficiency insert retrieve delete All operations depend on the depth of the tree If balanced: O(log n) Most libraries use a balanced version, for instance Red-Black Trees


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