1 / 42

CS251 – Software Engineering Lecture 3: Process and Life Cycle

CS251 – Software Engineering Lecture 3: Process and Life Cycle. www.acadox.com/join/563R9V. حكمة اليوم. أفلم يسيروا في الأرض فتكون لهم قلوب يعقلون بها أو آذان يسمعون بها فإنها لا تعمى الأبصار ولكن تعمى القلوب التي في الصدور. Assessment. Midterm exam (10%) Final exam (60%)

morenow
Download Presentation

CS251 – Software Engineering Lecture 3: Process and Life Cycle

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CS251 – Software EngineeringLecture 3: Process and Life Cycle www.acadox.com/join/563R9V

  2. حكمة اليوم • أفلم يسيروا في الأرض فتكون لهم قلوب يعقلون بها أو آذان يسمعون بها • فإنها لا تعمى الأبصار ولكن تعمى القلوب التي في الصدور

  3. Assessment • Midterm exam (10%) • Final exam (60%) • Project: 18~20% + 4% • Assignments: 10~12%

  4. Course TAs and Page • http://www.acadox.com/class/2604 • TAs • دسوقى عبد القوى d.abdelqawy@fci-cu.edu.eg • مصطفى سعد m.saad@fci-cu.edu.eg • عمرو سمير a.samir@fci-cu.edu.eg • دينا محمود dina.mahmoud@fci-cu.edu.eg • خالد على o.khaled@fci-cu.edu.eg • محمود خضير m.khodier@fci-cu.edu.eg • أمنية سامىomnia.samy@fci-cu.edu.eg • يمنى مجدىyomna@fci-cu.edu.eg

  5. Lab Objectives • Help you get deeper understanding • Train you on the concepts explained in the lectures. • Prepare and follow up project work • Answer questions • Save your time!

  6. The Project • Students are given a problem description • It has three Phases • Requirements and Plan • Iteration 1 • Iteration 2 • Group size is 3 or 4. • Topics will posted ASAP • Strict deadlines

  7. What is ‘Software Engineering’?... • A term used occasionally in 1950s, 1960s • Popularized in 1968 at NATO Software Engineering Conference (http://homepages.cs.ncl.ac.uk/brian.randell/NATO/)

  8. What is Software? • More than computer programs. • The collection of programs, documentation and configuration data that ensures correct execution. • Three major types: • Generic Product: Stand alone, Sold on open market. • Customized Product: For specific customer. • Embedded Product: Built into hardware.

  9. The Nature of Software • Intangible: • Opposite of physical artifacts, e.g., Computer vs Windows XP • Hard to understand the development process. • Easy to Reproduce: • Costly design and construction, cheap manufacturing. • Malleable: • Easy to change, even without full understanding. • Untrained people can “hack” something together.

  10. Software Development Problems • “Software is not constrained by materials, or governed by physical laws, or by manufacturing process” ---- (Sommerville) • Allows almost unbounded complexity: • Exponential growth of complexity w.r.t. to the size of a program: twice the size, four times the complexity; • Example: Windows XP has 40millions lines of source code (estimation).

  11. Software Development Problems • Difficulty in understanding and managing the complexity causes: • Late completion: • “vaporware” that are announced but never produced • Overrunning Cost: • Denver Airport Automated Baggage System, 2 billions US dollar over budget • Unreliable • Difficult to maintain • Etc…

  12. What is Engineering? • Systematically identify, understand, and integrate the constraints on a design to produce a successful result. • Constraints may include: • available resources, • physical or technical limitations, • flexibility for future modifications and additions, • cost, manufacturability, and serviceability. • Deduce specifications from the limits. • Ethical Practices.

  13. Quality of Good Software • Usability • Easy to learn and use. • Efficiency • Does not waste resources such as CPU time and memory. • Dependability • Reliable, secure and safe. • Maintainability • Easily evolved (modified) to meet changing requirement. • Reusability • Parts can be reused, with minor or no modification.

  14. Quality of Good Software • Can be quite different based on your viewpoint: Customer: - Solves problems at acceptable cost (time and resource). User: - Easy to learn - Efficient to use - Get work done Developer Manager: - Sells more and pleases customers - Costing less to develop and maintain Developer: - Easy to design and maintain

  15. So, ‘Software Engineering’ is IEEE Standard 610.12: • The application of a systematic, disciplined, quantifiable approach to the development, operation, and maintenance of software, that is, the application of engineering to software. • “Designing, building and maintaining large software systems”. - I. Sommerville • “Multi-person construction of multi-version software”. - D. L. Parnas

  16. What is Software Engineering?... • “Technological and managerial discipline of software products that are developed and modified on time and within cost estimates”. – R. Fairley • “Software development is not simply a case of sitting down at a terminal and typing in the program code”. – M. Priestley • A discipline that guides the process of solving customers’ problems by the systematic development and evolution of large, high-quality software systems within cost, time and other constraints. – our definition

  17. CPSC-4360-01, CPSC-5360-01, Lecture 1

  18. Course Contents • Overview of Software Engineering ½ Week • Software Disasters ½ Week • Review of OOP 1 Week • Software Lifecycle and SW Engineering Processes 1 Week • Requirements Eng. (SRS, use cases, storyboards) 1 Week • Software Modeling and Analysis and UML 3 Weeks • Software Patterns 1 Week • Software Architecture 1 Week • Software Construction 1 Week • Software Quality and Testing 1 Week • Software Configuration and Project Management 1 Week

  19. 2. Software Life Cycle • Conception • Feasibility Study • Requirements’ Gathering • Overall Design • Detailed Design • Development (Coding, Programming) • Testing (Unit, Integration, Acceptance) • Deployment / Training • Maintenance and Evolution

  20. Process of Building a House Same life cycle Different Process

  21. 2. Software Life Cycle Specification • Conception • Feasibility Study • Requirements’ Gathering • Overall Design • Detailed Design • Development (Coding, Programming) • Testing (Unit, Integration, Acceptance) • Deployment / Training • Maintenance and Evolution Development Validation Evolution

  22. Important Terms • Software life-cycle • Phases • Development cycle and evolution cycle • Software process • Discipline, activities, roles, and artifacts • Iterations • Milestones

  23. 2. Software Life Cycle (As in RUP) Inception • Conception • Feasibility Study • Requirements’ Gathering • Overall Design • Detailed Design • Development (Coding, Programming) • Testing (Unit, Integration, Acceptance) • Deployment / Training • Maintenance and Evolution Elaboration Construction Transition

  24. CS251 – Software EngineeringLecture 3: Process and Life Cycle www.acadox.com/join/563R9V

  25. Inception Elaboration Construction Transition T I M E Phases of the Development Cycle Inception - Define the scope of project Elaboration - Plan project, specify features, baseline system Construction - Build the product Transition- Transition the product into end user community

  26. Software Process • The set of activities and associatedresults that produce a software product. • Four fundamental process activities: • Software Specification • Software Development • Software Validation • Software Evolution • Can be organized in different ways, described at varying level of details → different software development process models

  27. 6.3. What is a Lifecycle Model? Definition. A (software/system) lifecycle model is a description of the sequence of activities carried out in an SE project, and the relative order of these activities.

  28. Activity 1: Software Specification • Customers and Software Engineers • Define the software to be produced • Define the constraints on its operations • Typical Stages: • Feasibility Study: • Is it possible with the current technologies + within budget? • Domain Analysis: • What is the background for the software? • Requirements Gathering and Analysis: • What is it that the user wants? • Requirements Specification: • Formal documentation on User and System requirements. • Requirements Validation: • Check for realism, consistency, and completeness.

  29. Activity 2: Software Development • Consists of Design and Programming • System Analysts • Design: decide how the requirement can be implemented. • Programmers • Coding: translate high level design into real code in a chosen programming language.

  30. Activity 2: Software Development • Typical Stages (Design): • Architectural Design: Split into subsystems • Abstract Specification: High level specification on the services and constraints for each subsystem • Interface Design: Interface with other subsystems are defined • Component Design: Split the services and allocate to components within a subsystem • Data Structure Design: Choose appropriate data structure • Algorithm Design: Design and specify algorithm used to provide services High Level Low Level

  31. Activity 2: Software Development • Typical Stages (Programming): • Data structure and algorithm design (from the design stage) may be delegated to the programmer. • Personal activity. Usually without a predefined process. • Debugging: Low level testing of code. Reveals program defects (bugs).

  32. Activity 3: Software Validation • Software Engineer (or dedicated tester) and Customer: • Check the software to ensure it meets the customers’ requirements. • Typical Stages: • Component Testing: Independent testing of individual components in subsystem. • System Testing: Testing of integrated components. Can be multi-levels, e.g., subsystem → system. • Acceptance Testing: Tested with customer supplied data. Final test before operation. • Interactive activity that feedback to previous stages: • E.g., an error in component testing triggers re-coding.

  33. Activity 4: Software Evolution • Customers and Software Engineers: • Define changing requirements. • Modify the software system to adapt. • Typical Work: • Update the system for minor new requirements, e.g., changing the telephone number from 7 digits to 8 digits, changing the date representation (the Millennium Bug). • Could be drastic, more like redevelopment, e.g., windows95 →windows98 → windowsXP.

  34. Simple Software Process Example • In the simplest cases, code is written directly from some statements of requirements. Process Artifact

  35. Simple Software Process Example • Two processes: • ‘Analyze requirements’ • ‘Write code’ • Two artifacts: • ‘Requirements specification’ • ‘Source code’ • ‘Requirements specification’ can be written as: • an informal outline or • a highly detailed description.

  36. Simple Software Process Example • Software Specification: • Analyze Requirement → Requirement Documentation • Software Development: • Design: • Data structure and algorithm • Programming: • Write Code → Source Code • Debugging • Software Validation: • Compare against sample outputs • Software Evolution: • Not applicable.

  37. A More Complex Software Process • It is better to design before you code. • On larger projects, intermediate pieces of documentation are produced.

  38. A More Complex Software Process • One new process: • ‘Design module structure’ - splitting the program into modules and subroutines • One new artifact: • ‘Structure chart’ – is based on the information contained in the ‘requirements specification’ • Both the ‘requirements specification’ and the ‘structure chart’ are used when writing the final code.

  39. A More Complex Software Process • Software Specification: • Analyze Requirement → Requirement Documentation • Software Development: • Design: • Design of the functions/modules/classes • Programming: • Write Code → Source Code • Debugging • Software Validation: • Compare against sample outputs • Software Evolution: • Not applicable.

More Related