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CSCE 210 Data Structures and Algorithms

CSCE 210 Data Structures and Algorithms. Prof. Amr Goneid AUC Part 1. Data Modeling and ADTs. Data Modeling and ADTs. Data Modeling Abstract Data types (ADTs) A Classification of Abstract Structures Another Classification Special Data Structures OOP and Classes Examples on Modeling.

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CSCE 210 Data Structures and Algorithms

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  1. CSCE 210Data Structures and Algorithms Prof. Amr Goneid AUC Part 1. Data Modeling and ADTs Prof. Amr Goneid, AUC

  2. Data Modeling and ADTs • Data Modeling • Abstract Data types (ADTs) • A Classification of Abstract Structures • Another Classification • Special Data Structures • OOP and Classes • Examples on Modeling Prof. Amr Goneid, AUC

  3. 1. Data Modeling • Real-world applications need to be reduced to a small number of existing problems (top-down design) • Real-world data need to be described in an abstract way in terms of fundamental structures Prof. Amr Goneid, AUC

  4. Data Modeling • The collection of data in some organization is called a “Data Structure” • The sequences of operations to be done on the data are called “Algorithms” Prof. Amr Goneid, AUC

  5. Data Modeling • The word Algorithm comes from the name of Abu Ja’afar Mohamed ibn Musa Al Khowarizmi (c. 825 A.D.) • An Algorithm is a procedure to do a certain task • An Algorithm is supposed to solve a general, well-specified problem Prof. Amr Goneid, AUC

  6. Data Modeling • Areal-world application is basically Data Structures + Algorithms Prof. Amr Goneid, AUC

  7. Data Modeling • Data and the Operations on that data are parts of an object that cannot be separated. • These two faces of an object are linked. Neither can be carried out independently of the other. Prof. Amr Goneid, AUC

  8. The Data Cone Real-world Data ADTs Data Structures Fundamental Data Types Prof. Amr Goneid, AUC

  9. 2. Abstract Data Types (ADTs) • The most important attribute of data is its type. • Type implies certain operation. It also prohibits other operations. • For example, + - * / are allowed for types int and double, but the modulus (%) is allowed for int and prohibited for double. • When a certain data organization + its operations are not available in the language, we build it as a new data type. To be useful to many applications, we build it as an Abstract Data Type. Prof. Amr Goneid, AUC

  10. Abstract Data Types (ADTs) • An ADT represents the logical or conceptual level of the data. • It consists of: • A collection of data items in some Data Structure • Operations (algorithms) on the data items • For example, a Stack supports retrieval in LIFO (Last In First Out) order. Basic operations are push and pop. It can be implemented using arrays (static or dynamic) or linked lists Prof. Amr Goneid, AUC

  11. Abstract Data Types (ADTs) • The Data Structure used in implementing an ADT is usually dependent on the language. • In contrast, the definition of the ADT is separated from its implementation (Data Abstraction). • (e.g. ADT Stack can be implemented using a static array, a dynamic array or a linked list. • An ADT can be used in more than one application. Prof. Amr Goneid, AUC

  12. Using ADT’s ADT ADT ADT ADT ADT Application Application Application Standard Types/Libraries User Built ADT’s Prof. Amr Goneid, AUC

  13. 3. A Classification of Abstract Structures According to the relationship between members Abstract Structures Sets Linear Trees Graphs Prof. Amr Goneid, AUC

  14. Sets • Order of elements does not matter. Only that they are members of the same set ({1,3,4} is identical to {1,4,3}). • Can be implemented using arrays or linked lists. • Used in problems seeking: • groups • collection • selection • packaging Prof. Amr Goneid, AUC

  15. Linear Structures • Sequential, one-to-one relationship. Examples: Tables, Stacks, Queues, Strings and Permutations. • Can be implemented using arrays and linked lists (structs and pointers). • Used in problems dealing with: • Searching, Sorting, stacking, waiting lines. • Text processing, character sequences, patterns • Arrangements, ordering, tours, sequences. Prof. Amr Goneid, AUC

  16. Trees • Non-Linear, hierarchical one-to-many. Examples: Binary Trees, Binary Search Trees (BST) • Can be implemented using arrays, structs and pointers • Used in problems dealing with: • Searching • Hierarchy • Ancestor/descendant relationship • Classification Prof. Amr Goneid, AUC

  17. Graphs • Non-Linear, many-to-many. • Can be implemented using arrays or linked lists • Used to model a variety of problems dealing with: • Networks • Circuits • Web • Relationship • Paths Prof. Amr Goneid, AUC

  18. 4. Another Classification of Abstract Structures According to their functions Special Abstract Structures Containers Strings Dictionaries Geometric DS Priority Queues Disjoint Sets Graphs Prof. Amr Goneid, AUC

  19. Containers • Permit storage and retrieval of data items independent of content (access by location only). • Support two basic operations: • Put (x,C): Insert item x in container C • Get (C): Retrieve next item from C. Prof. Amr Goneid, AUC

  20. Containers • Examples: • Stacks: Last-In-First-Out (LIFO) structures • Queues: First-In-First-Out (FIFO) structures • Tables: Retrieval by position. Prof. Amr Goneid, AUC

  21. Dictionaries • A form of container that permits access by content. • Support the following main operations: • Insert (D,x): Insert item x in dictionary D • Delete (D,x): Delete item x from D • Search (D,k): search for key k in D Prof. Amr Goneid, AUC

  22. Dictionaries • Examples: • Unsorted arrays and Linked Lists:permit linear search • Sorted arrays:permit Binary search • Ordered Lists:permit linear search • Binary Search Trees (BST): fast support of all dictionary operations. • Hash Tables: Fast retrieval by hashing key to a position. Prof. Amr Goneid, AUC

  23. Priority Queues • Allow processing items according to a certain order (Priority) • Support the following main operations: • Insert (Q,x): Insert item x in priority queue Q • Remove (Q): Return and remove item with Highest/Lowest Priority Prof. Amr Goneid, AUC

  24. Priority Queues • Examples: • Heaps and Partially Ordered Trees (POT) • Major DS in HeapSort Prof. Amr Goneid, AUC

  25. Disjoint Sets • Disjoint sets are collections of elements with no common elements between the sets. • A set can be identified by a parentnode and children nodes. Prof. Amr Goneid, AUC

  26. Disjoint Sets • Support the following main operations: • Find (i): Find Parent (set) containing node (i) • Union (i,j): make set (i) the child of set (j) • Examples: • Representation of disjoint collections of data • Representation of Trees, Forests and Graphs Prof. Amr Goneid, AUC

  27. Graphs • Can be used to represent any relationship and a wide variety of structures. Prof. Amr Goneid, AUC

  28. Graphs • Can be used to represent any relationship and a wide variety of structures. • Well-known graph algorithms are the basis for many applications. Examples of such algorithms are: • Minimum Spanning Trees • Graph traversal (Depth-First and Breadth-First) • Shortest Path Algorithms Prof. Amr Goneid, AUC

  29. 5. Special Data Structures • Strings: Typically represented as arrays of characters. Various operations support pattern matching and string editing Prof. Amr Goneid, AUC

  30. 5. Special Data Structures • Geometric Data Structures: Represent collections of data points and regions. Data points can represent segments. Segments can represent polygons that can represent regions. Prof. Amr Goneid, AUC

  31. 6. OOP & Classes • The first step in creating an ADT is the process of Data Abstraction • Data Abstraction provides a complete description of the following items independent of the way it will be implemented: • A definition of the ADT. • Elements or members of that ADT. • Relationship between the members. • The fundamental operations on the members. Prof. Amr Goneid, AUC

  32. ADT Implementation Usually, an ADT can be implemented in different ways. To the applications, such implementation should be completely hidden. The Implementation part will describe: • how the ADT will be implemented using native Data Structures or other pre-defined ADT’s in C++. • how the relationships and fundamental operations on the members will be implemented as C++ functions. • In Object Oriented Programming, ADTs are created as Classes Prof. Amr Goneid, AUC

  33. OOP and Classes • Object-Oriented Programming (OOP) focuses on creating ADT’s called “Classes” that identify “objects” and how they work together. • A class contains “data members” + “function members” in one object. • A member function tells an object to “operate on itself” in some way. • Objects are “self-contained”, carrying their own operations. Prof. Amr Goneid, AUC

  34. Data Encapsulation, Classes and Objects • A Class of objects is a user-defined Abstract Data Type (ADT) • An object is an instance of the class • Once a class is defined, an object can be declared to be of that type. For example, we have encountered the string class before. Since it has been defined, we can declare: string message; So, now messageis an object of that class • Classes can be used by more than one program. Prof. Amr Goneid, AUC

  35. Sharing Classes Class Class Class Class Class Program Program Program Standard Classes User Classes Prof. Amr Goneid, AUC

  36. Classes & Encapsulation • C++ classes are similar to structs, with the main difference being that classes can have member functions, or methods, as well as variables, or data members in their definitions. • Combining data and operations (methods) together in an object is called encapsulation. • An object of a class can operate on itself by the methods or member functions of that class. e.g., an object of class string can operate by: .find .length .at .erase etc Prof. Amr Goneid, AUC

  37. 7. Examples on Modeling • Problem: In Encryption problems, we need to do arithmetic on very large integers (e.g. 300 digits or more) • ADTs: List • Data Structures: 1-D array or Linked List Prof. Amr Goneid, AUC

  38. Examples on Modeling • Problem: (Knapsack Problem) We have (n) objects each with a weight and a price and a container with maximum capacity (m). Select whole or fractions of the objects such that the total weight does not exceed (m) and the total price is maximum • ADTs: List • Data Structures: 1-D array or Linked List Prof. Amr Goneid, AUC

  39. Examples on Modeling • Problem: (Chess Games) 8-Queens problem, Knight’s Tour problem, etc • ADTs: Board ADT • Data Structures: 2-D array Prof. Amr Goneid, AUC

  40. Examples on Modeling • Problem: (Dictionary) We would like to build and use a small dictionary of words that translates from language (A) to language (B) • ADTs: Key Table or List • Data Structures: 1-D array or linked list Prof. Amr Goneid, AUC

  41. Examples on Modeling • Problem: (Small and fast Directory) We would like to build and use a small and fast directory to check username and pass word logins • ADTs: Hash Table • Data Structures: 1-D array Prof. Amr Goneid, AUC

  42. Examples on Modeling • Problem: (Large and fast Directory) We would like to build and use a large and fast telephone directory. • ADTs: Binary Search Tree • Data Structures: Linked Structure (Nodes) Prof. Amr Goneid, AUC

  43. Examples on Modeling • Problems: • Evaluation of arithmetic expressions • The Hanoi Towers game • ADTs: Stack • Data Structures: 1-D array or Linked List Prof. Amr Goneid, AUC

  44. Examples on Modeling • Problem: We would like to simulate the waiting process for airplanes to land in an airport. • ADTs: Queue • Data Structures: 1-D array or Linked List Prof. Amr Goneid, AUC

  45. Examples on Modeling • Problem: • Sorting a set of elements • Selection of the kth smallest (largest) element • ADTs: Priority Queue • Data Structures: 1-D array Prof. Amr Goneid, AUC

  46. Examples on Modeling • Problem: • Find the shortest path between a source and a destination • Find the exit in a Maze • ADTs: Graph • Data Structures: 2-D array or Linked list Prof. Amr Goneid, AUC

  47. Examples on Modeling • Problem: Find a wiring scheme for electrical power with minimum cost of wiring • ADTs: Graph Priority Queue Disjoint Sets • Data Structures: 1-D arrays, 2-D array, Linked list Prof. Amr Goneid, AUC

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