6. DESIGN II: DETAILED DESIGN

6. DESIGN II:DETAILED DESIGN

Software Engineering Roadmap: Chapter 6 Focus Develop Architecture - see chapter 5 Identify corporate practices Perform Detailed Design - apply design patterns - accommodate use cases supply methods - exploit libraries (Java, Swing…) - describe methods where required - develop detailed object models - dev. detailed logic (pseudo-code) Plan project Analyze requirements Maintain Integrate & test system Design Implement Test units Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Chapter Learning Goals • Understand how design patterns describe some detailed designs • Specify classes and functions completely • Specify algorithms • use flowcharts • use pseudocode Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

1. Introduction to Detailed Design Objective: To fully prepare for implementation of a system that meets requirements. Outcomes: (1) blueprints (models), (2) associated details (documentation), (3) detailed implementation plan for construction, integration and testing

Relating Use Cases, Architecture, & Detailed Design 1. Use case -- analysis “Cars should be able to travel from the top of Smith Hill at 65 mph, travel in a straight line, and arrive at Jones Hollow within 3 minutes.” 2. Domain classes 3. Architecure Cable Auto Road Pylon

Relating Use Cases, Architecture, & Detailed Design 1. Use case (part of requirements) “Cars should be able to travel from the top of Smith Hill at 65 mph, travel in a straight line, and arrive at Jones Hollow within 3 minutes.” 2. Domain classes 3. Architecure Cable (not specifically required) Auto Road Pylon 4. Detailed Design (added for detailed design) Support use case Auto Cable Guardrail Road Smith Hill Pylon Jones Hollow Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

What is the difference between high-level (architectural) design and detailed design? • High-Level Design • Detailed Design

Typical Roadmap for Detailed Design • 1. Begin with architectural models -- see chapter 5 • class model: domain & architectural classes • overall state model* • overall data flow model* • use case model • 2. Introduce classes & design patterns* which connect the architecture classes with the domain classes -- sections 1 and 5 • concentrate on riskiest parts first; try alternatives 3. Refine models, make consistent, ensure complete 4. Specify class invariants* -- section 3.1 For each class ... 5. Specify methods with pre- and post-conditions, flowcharts* & pseudocode* -- sections 3 and 4 For each method ... 6. Sketch unit test plans -- see chapter 8 For each unit ... 7. Inspect test plans & design -- section 9 * if applicable 8.Release for implementation Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Organize the Team for Detailed Design 1/2 One way to ... 1. Prepare for a detailed design kick-off meeting. • Ensure team members aware of the models (views) they are expected to produce • typically object model, sequence diagrams, state, & data flow • Ensure team members aware of the notation expected • typically: UML plus a pseudocode standard and/or example • Design leader prepares list of modules • Design leader creates a meeting agenda • Project leader allocates time to agenda items (people can speak about detailed designs indefinitely if allowed to!) • allocate the time among the agenda items Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Organize the Team for Detailed Design 2/2 One way to ... 2. Hold the kick-off meeting • Designate someone to monitor the agenda item time • Confirm that the architecture is ready for detailed design • Make sure that module interfaces the are clear • revise as a group if not • Don’t try to develop detailed designs as a group • not necessary: individuals have the responsibility • groups are seldom good at designing details together • Allocate modules to members • Request time estimates to design lead by a fixed date • Write out the conclusions and copy/e-mail every member • Decide how and when the results are to be reviewed 3. Update the documentation set • more detailed schedule with modules & inspections 4. Inspect the detailed designs (see section 9) 5. Rework as a result of inspections 6. Conduct post mortem and write out lessons learned Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Unified Software Development Process: Design U. P. Term Requirements Analysis Design Implemen- tation Test (Jacobson et al) Inception Elaboration Construction Transition 1* Jacobson et al: 2 3 Prelim. iterations Iter. #1 Iter. #n Iter. #n+1 Iter. #m Iter. #m+1 Iter. #k ….. ….. *Key: terminology used in this book “Detailed design” 1 = “Requirements” 2 = “Achitecture” 3 =

1. Conceptual & abstract 2. Applicable to several designs 3. «control», «entity» & «boundary» class stereotypes 4. Less formal 5. Less expensive to develop 1. Concrete: implementation blueprint 2. Specific for an implementation 3. No limit on class stereotypes 4. More formal 5. More expensive to develop (~ 5 times) Analysis Design 1/2 After Jacobson et al: USDP

6. Outlines the design 7. Emerges from conceptual thinking 8. Flexibility still exists for process modifications 9. Relatively unconstrained 10. Less focus on sequence diagrams 11. Few layers 6. Manifests the design (architecture one view) 7. May use tools (e.g. visual, round-trip engineering) 8. Maintaining estabished process is a high priority 9. Constrained by the analysis & architecture 10. More focus on seq. diag. 11. Many layers Analysis Design 2/2 After Jacobson et al: USDP

Designing Against Interfaces Client code Used code Abstract layer BillingClient listCustomers() billCustomers() Customer bill() printAccounts() -- written in terms of Customer (not specific types of Customer) Concrete (non-abstract) layer RegularCustomer bill() printAccounts() Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Reusing Components • Functionality we need is becoming more convenient to locate and reuse • Microsoft MFC library • Visual Basic controls • COM objects • OMG’s CORBA • Javascript and Java Applet libraries • JavaBeans (servlet code) • Enterprise JavaBeans

2. Sequence and data flow diagrams for detailed design

Refine Models for Detailed Design1/2: Sequence Diagrams One way to ... 1. Begin with the sequence diagrams constructed for detailed requirements and/or architecture (if any) corresponding to the use cases. 2. Introduce additional use cases, if necessary, to describe how parts of the design typically interact with the rest of the application. 3. Provide sequence diagrams with complete details • be sure that the exact objects & their classes are specified • select specific function names in place of natural language (calls of one object to another to perform an operation) Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Refine Models for Detailed Design2/2: Data Flow Diagrams One way to ... 1. Gather data flow diagrams (DFD’s) constructed for detailed requirements and/or architecture (if any). 2. Introduce additional DFD’s, if necessary, to explain data and processing flows. 3. Indicate what part(s) of the other models the DFD’s corresponds to. • e.g., “the following DFD is for each Account object” 4. Provide all details on the DFD’s • indicate clearly the nature of the processing at each node • indicate clearly the kind of data transmitted • expand processing nodes into DFD’s if the processing description requires more detail Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Requirements: Sequence Diagram for Engage Foreign Character Use Case :Encounter Game freddie: Foreign Character :Engagement :Engagement Display :Player Character 1.1 create; display 1.2 create 2.1 execute 2.2 change quality values 3.1 Display result 3.2 create Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Design: Sequence Diagram for Encounter Foreign Character Use Case :Encounter game :Encounter Cast freddie: Foreign Character engagement: Engagement 1.1 displayForeignChar() :Engagement Display 1.2 display() 1.3 new Engagement() 2. execute() :Player’s main character 2.1 setPlayerQuality() 2.2 setQuality() 2.3 setForeignQuality() 3.1 new EngagementDisplay() 2.4 setQuality() 3.2 displayResult() Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Classes of the EncounterForeignCharacter Use Case EngagementDisplay displayResult() Engagement execute() EncounterGame PlayerCharacter setQuality() EncounterCast displayForeignChar() setPlayerQuality() setForeignQuality() ForeignCharacter setQuality() Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Account Cus- tomer screen template unacceptable ATM users local log Deposit- screen. display() Account. getPass- word() Account. verifyPass- word() status pass- word Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission. Detailed Data Flow Diagram for a Banking Application Customer. getDetails() Account. getDeposit() customer info User

CRC Cards • Class Responsibility and Collaboration cards provide an effective technique for exploring the possible ways of allocating responsibilities to classes and the collaborations that are necessary to fullfil the responsibilities. • A helpful demonstration: • http://www.csd.abdn.ac.uk/~ecompata/teaching/CS3015/information/crc.shtml

Design Refinement with CRC Cards • Exercise: • Use Case: You are registering for a new course in astronomy. You require permission from the instructor and you must interact with the registrars office to signup and pay for the course. • Develop the classes and responsibilities using CRC cards

3. Specifying classes and functions

Specify A Class One way to ... 1. Gather the attributes listed in the SRS. • if the SRS is organized by class 2. Add additional attributes required for the design. 3. Name a method corresponding to each of the requirements for this class. • easy if the SRS is organized by class 4. Name additional methods required for the design. 5. Show the attributes & methods on the object model. 6. State class invariants. Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Specify a Function One way to ... 1. Note the section(s) of the SRS or SDD which this function (method) satisfies. 2. State what expressions the function must leave invariant. 3. State the method’s pre-conditions (what it assumes). 4. State the method’s post-conditions (its effects). 5. Provide pseudocode and/or a flowchart to specify the algorithm to be used. • unless very straightforward Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Classes at Detailed Design Data type Range Default value Security issues Canister Class name + numCanisters: int - numWafers: int - size: float Attribute: type +: visible from without + display() - getNumSlotsOpen() + setStatus() Operations Interface specs Functional details Invariants Responsibilities: -- describes each canister undergoing fabrication Place for comments Instance details Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

4. Specifying algorithms

Parameter & settings make sense? Flowchart Examplefor setName() N Y Nominal path Set _name to “defaultName" Parameter name too long? N Y protected final void setName( String aName ) { // Check legitimacy of parameter and settings if( ( aName == null ) || ( maxNumCharsInName() <= 0 ) || ( maxNumCharsInName() > alltimeLimitOfNameLength() ) ) { _name = new String( "defaultName" ); System.out.println ( "defaultName selected by GameCharacter.setName()"); } else // Truncate if aName too long if( aName.length() > maxNumCharsInName() ) _name = new String ( aName.getBytes(), 0, maxNumCharsInName() ); else // assign the parameter name _name = new String( aName ); } Set _name to parameter Truncate name Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Pseuodocode Example • FOR number of microseconds supplied by operator • IF number of microseconds exceeds critical value • Try to get supervisor's approval • IF no supervisor's approval • abort with "no supervisor approval for unusual • duration" message ENDIF ENDIF See later section tbd for inspection results of this pseudocode . . . .

Pseudocode Extraction • //p FOR number of microseconds supplied by operator • for( int i = 0; i < numMicrosecs; ++I ) { • //p IF number of microseconds exceeds critical value • if( numMicrosecs > • XRayPolicies.CRITICAL_NUM_MICROSECS ) • //p Try to get supervisor's approval • int supervisorMicrosecsApproval = • getApprovalOfSuperForLongExposure(); • //p IF no supervisor approval • if( supervisorMicrosecsApproval <= 0 ) • throw ( new SupervisorMicrosecsApprovalException() ); • . . . . . . . . . Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Advantages of Pseudocode & Flowcharts • Clarify algorithms in many cases • Impose increased discipline on the process of documenting detailed design • Provide additional level at which inspection can be performed • Help to trap defects before they become code • Increases product reliability • May decrease overall costs Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Disadvantages of Pseudocode & Flowcharts • Creates an additional level of documentation to maintain • Introduces error possibilities in translating to code • May require tool to extract pseudocode and facilitate drawing flowcharts Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

5. Design Patterns II: Techniques of detailed design

Apply Design Patterns in Detailed Design One way to ... 1. Become familiar with the design problems solved by design patterns • at a minimum, understand the distinction among (C) creational vs. (S) structural vs. (B) behavioral patterns Consider each part of the detailed design in turn: 2. Determine whether the problem has to do with (C) creating something complex, (S) representing a complex structure, or (B) capturing behavior 3. Determine whether there is a design patterns that addresses the problem • try looking in the category identified (C, S, or B) • use this book and/or Gamma et al [Ga] 4. Decide if benefits outweigh drawbacks • benefits usually include increased flexibility • drawbacks increased class complexity(?), less efficient(?) Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

User Interface Design • System users often judge a system by its interface rather than its functionality • A poorly designed interface can cause a user to make catastrophic errors • Poor user interface design is the reason why so many software systems are never used

User-Centred design • User-centred design is an approach to UI design where the needs of the user are paramount and where the user is involved in the design process • UI design always involves the development of prototype interfaces • See UI_design.ppt

7. Standards, notation and tools for detailed design

IEEE 1016-1987 Software Design Document Table of Contents (Reaffirmed 1993) 1. Introduction 1.1. Purpose 1.2. Scope 1.3. Definitions, acronyms & abbreviations 2. References 3. Decomposition description 3.1. Module decomposition 3.1.1 Module 1 description 3.1.1 Module 2 description 3.2 Concurrent process decomposition 3.2.1 Process 1 description 3.2.2 Process 2 description 3.3 Data decomposition 3.3.1 Data entry 1 description 3.3.2 Data entry 2 description 4. Dependency description 4.1 Intermodule dependencies 4.2 Interprocess dependencies 4.3 Data dependencies 5. Interface description 5.1 Module interface 5.1.1 Module 1 description 5.1.2 Module 2 description 5.2 Process interface 5.2.1 Process 1 description 5.2.2 Process 2 description 6. Detailed design 6.1 Module detailed design 6.1.1 Module 1 detail 6.2.2 Module 2 detail 6.2 Data detailed design 6.2.1 Data entity 1 detail 6.2.2 Data entity 2 detail Architecture • Can be replaced with: • 6.1 Class#1 detailed design • 6.1.1 Attributes • 6.1.2 Methods • 6.1.3 Instance details • 6.1.4. Other: • - UI details (if applicable)

8. Effects on projects of completing detailed designs

Bring the ProjectUp-to-Date After Completing Detailed Design 1. Make sure the SDD reflects latest version of detailed design, as settled on after inspections. 2. Give complete detail to the schedule (SPMP). 3. Allocate precise tasks to team members (SPMP). 4. Improve project cost & time estimates (see below). 5. Update the SCMP to reflect the new parts. 6. Review process by which the detailed design was created, & determine improvements. Include ... • time taken; broken down to include • preparation of the designs • inspection • change • defect summary • number remaining open, found at detailed design, closed at detailed design • where injected; include previous phases & detailed design stages One way to ... Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Estimate Size & Time from Detailed Designs One way to ... 1. Start with the list of methods • ensure completeness, otherwise underestimate will result 2. Estimate the lines of code (LOC) for each • classify as very small, small, medium, large, very large • normally in ± 7% / 24% / 38% / 24% / 7% proportions • use personal data to covert to LOC • otherwise use Humphry’s table below 3. Sum the LOC 4. Covert LOC to person-hours • use personal conversion factor if possible • otherwise use published factor 5. Ensure that your estimates of method sizes and time will be compared and saved at project end. Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

9. Quality in detailed designs

Inspect‡ Detailed Designs 1 of 2 One way to ... 1. Prepare to record metrics during the design process. • Include (1.1) time taken; (1.2) type of defect; (1.3) severity 2. Ensure each architecture module is expanded. 3. Ensure each detail is part of the architecture. • if a detail does not belong to any such module, the architecture may have to be revised 4. Ensure the design fulfills its required functions 5. Ensure that design is complete (classes & methods) 6. Ensure that the design is testable. ‡ See chapter 1 for inspection procedures. Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Inspect Detailed Designs 2 of 2 7. Check detailed design for -- • simplicity a design that few can understand (after a legitimate effort!) is expensive to maintain, and can result in defects • generality enables design of similar applications? • expandability enables enhancements? • efficiency speed, storage • portability 8. Ensure all details are provided • only code itself is excluded as a “detail” • the detail work must be done eventually, and this is the best time to do it: don’t postpose One way to ... Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Inspection for Defects • Identify defect and its type • Specify its severity (two methods following slides) • Identify the source of the defect – so that the defect does not occur in another project … • At another time, usually one person works on a resolution to defect

Severity Description Urgent Failure causes system crash, unrecoverable data loss; or jeopardizes personnel High Causes impairment of critical system functions, and no workaround solution does exist Medium Causes impairment of critical system functions, though a workaround solution does exist Low Causes inconvenience or annoyance None None of the above Table 6.2 IEEE 1044.1 Severity classification Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Severity Description Major Requirement(s) not satisfied Medium Neither major nor trivial Trivial A defect which will not affect operation or maintenance Table 6.3 Defect severity classification using Triage Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

Types of Defects (1) (IEEE) • [PS] Logic problem (forgotten cases or steps; duplicate logic; extreme conditions neglected; unnecessary functions; misinterpretation; missing condition test; checking wrong variable; iterating loop incorrectly etc.) • [PS] Computational problem (Equation insufficient or incorrect; precision loss; sign convention fault) Adapted from Software Engineering: An Object-Oriented Perspective by Eric J. Braude (Wiley 2001), with permission.

6. DESIGN II: DETAILED DESIGN