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Solutions for Homework Assignment 2

Solutions for Homework Assignment 2. Assignment Points: 50 Due Date: October 17, 2001 Final Date: October 24, 2001 Late Penalty: 5 points.

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Solutions for Homework Assignment 2

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  1. Solutions for Homework Assignment 2 Assignment Points: 50 Due Date: October 17, 2001 Final Date: October 24, 2001 Late Penalty: 5 points.

  2. 5.1. Consider a file system with a graphical user interface, such as Macintosh’s Finder, Microsoft’sWindows Explorer, or Linux’s KDE. The following objects were identified from a use case describing how to copy a file from a floppy disk to a hard disk: File, Icon, TrashCan, Folder, Disk, Pointer. Specify which are entity objects, which are boundary objects, and which are control objects. 5 Points. Entity objects: File, Folder, Disk Boundary objects: Icon, Pointer, TrashCan Control objects: none in this example.

  3. 5.2 Assuming the same file system as before, consider a scenario consisting of selecting a file on a floppy, dragging it to Folder and releasing the mouse. Identify and define at least one control object associated with this scenario. 5 Points. The purpose of a control object is to encapsulate the behavior associated with a user level transaction. In this example, we identify a CopyFile control object, which is responsible for: • Remembering the path of the destination folder • Checking if the file can be copied (access control and disk space). • Remembering the path of the original file • To initiate the file copying.

  4. 5.3. Arrange the objects listed in Exercises 5.1. and 5.2. horizontally on a sequence diagram, the boundary objects to the left, then the control object you identified, and finally, the entity objects. Draw the sequence of interactions resulting from dropping the file into a folder. For now, ignore the exceptional cases. In this specific solution, we did not focus on the Disk, Pointer, and TrashCan objects. The Disk object would be added to the sequence when checking if there is available space. The TrashCan object is needed for scenarios in which Files or Folders are deleted. Note that the interaction among boundary objects can be complex, depending on the user interface components that are used. This sequence diagram, however, only describes user level behavior and should not go into such details. As a result, the sequence diagram depicts a high level view of the interactions between these objects, not the actual sequence of message sends that occurs in the delivered system.

  5. 5.3 continued • Figure below depicts a possible solution to this exercise. The names and parameters of the operations may vary. The diagram, however, should at least contain the following elements: • Two boundary objects, one for the file being copied, and one of the destination folder. • At least one control object remembering the source and destination of the copy, and possibly checking for access rights. • Two entity objects, one for the file being copied, and one of the destination folder.

  6. 5.6. Consider the object model in Figure 5-24 on page 165 in the book (adapted from [Jackson, 1995]): Given your knowledge of the Gregorian calendar, list all the problems with this model. Modify it to correct each of them. 10 Points. The problems with Figure 5-24 on page 165 are related with the multiplicity of the associations. Weeks can straddle month boundaries. Moreover, the multiplicity on other associations can be tightened up: years are always composed of exactly twelve months, months do not straddle year boundaries, and weeks are always composed of seven days. The figure below depicts a possible revised model for this exercise.

  7. 6.2. In Section 6.4.2 on page 193 in the book, we classified design goals into five categories: performance, dependability, cost, maintenance, and end user. Assign one or more categories to each of the following goals: • 5 points. • Users must be given a feedback within 1 second after they issue any command. [Performance] • The TicketDistributor must be able to issue train tickets, even in the event of a network failure.[Dependability] • The housing of the TicketDistributor must allow for new buttons to be installed in the event the number of different fares increases. [Maintenance] • The AutomatedTellerMachine must withstand dictionary attacks (i.e., users attempting to discover a identification number by systematic trial). [Dependability] • The user interface of the system should prevent users from issuing commands in the wrong order. [End user]

  8. 6.3. Consider a system that includes a Web server and two database servers. Both database servers are identical: The first acts as a main server, while the second acts as a redundant backup in case the first one fails. Users use Web browsers to access data through the Web server. They also have the option of using a proprietary client that accesses the databases directly. Draw a UML deployment diagram representing the hardware/software mapping of this system. 10 Points.

  9. 6.7. Why are use cases that describe boundary conditions described during system design (as opposed to during requirements elicitation or analysis)? 5 Points. Use cases that describe boundary conditions DEPEND ON SYSTEM DESIGN DECISIONS. For example, software architecture decisions need to be made before developers can describe how the system is started or shutdown.

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