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1 UML--definition UML: stands for "unified modeling language” unifies methods of Booch, Rumbaugh (OMT or Object Modeling Technique), and Jacobson (OOSE.

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Presentation on theme: "1 UML--definition UML: stands for "unified modeling language” unifies methods of Booch, Rumbaugh (OMT or Object Modeling Technique), and Jacobson (OOSE."— Presentation transcript:

1 1 UML--definition UML: stands for "unified modeling language” unifies methods of Booch, Rumbaugh (OMT or Object Modeling Technique), and Jacobson (OOSE or Object-Oriented Software Engineering) mainly a modeling language, not a complete development method Early versions -- second half of the 90's Not all methods we will use are officially part of the UML description

2 2 UML--references Most of the examples below, plus more on UML, issues can be found in: 1. Booch, Rumbaugh, and Jacobson, The Unified Modeling Language User Guide 2. Fowler and Scott, UML Distilled 3. Horstmann, Practical Object-Oriented Development in C++ and Java 4. Pressman, Software Engineering, A Practitioner's Approach

3 3 Tools for analysis, specification, and design We can use the following tools: Analysis and specification: Use cases Dataflow diagrams Analysis, specification, and design: Entity-relationship (ER) diagrams Class-Responsibility-Collaborator (CRC) cards Object message diagrams State diagrams Sequence diagrams

4 4 Requirements Analysis and Specification: Requirements / Specification: ----What is needed? ----If there is a current implementation, what are the problems with it? ----How can we translate customer needs and wants into a usable specification for the design stage? Initially, requirements may be fuzzy and poorly stated--analysis stage sharpens and focuses the (customer) requirements Some tools for requirements analysis & specification: ----use cases ----data flow diagrams ----”user stories” (XP) Requirements analysis and specification

5 5 USE CASES: a part of the ”Unified Modeling Language" (UML) which we will also use for design each identifies a way the system will be used and the "actors" (people or devices) that will use it (an interaction between the user and the system) each use case should capture some user-visible function and achieve some discrete goal for the user an actual user can have many actor roles in these use cases an instance of a use case is usually called a "scenario" Use cases

6 6 Example (based on Booch, Rumbaugh, and Jacobson, The Unified Modeling Language User Guide): Example use case Should also be supplemented with written requirements

7 7 Data flow diagram (DFD): ----graphical technique to show information flow and transforms applied as data move from input to output ----each function or information transformer is represented by a circle or "bubble" ----data labels are placed on arrows showing information flow ----external entities (data "producers" or "consumers") are shown as square boxes Data flow diagrams (1)

8 8 The data flow diagram does not describe the processing sequence; it is not a flowchart. But it can be very useful during requirements analysis for a system being developed. A DFD can be used to provide a functional model for the system being developed, thus supplementing the class relationship, object message, and state diagram models of UML. Functional models based on DFD's were part of the Object Modeling Technique (OMT) developed by Rumbaugh, one of the three main designers of UML. Data flow diagrams (2)

9 9 Example (based on examples in Pressman, Software Engineering, A Practitioner's Approach): Data flow diagrams--example

10 10 Requirements document must be as clear as possible, consistent, complete Important parts of a requirements document (Berezin, 1999): 1. Application Overview: -- objectives -- (business process—how application fits) -- user roles and responsibilities -- interactions with other systems -- (replacement of legacy systems) -- (production rollout considerations) -- terminology Requirements document

11 11 Important parts of a requirements document (continued): 2. Functional requirements: -- functionality precise, detailed, for each user class address security, auditing, reporting, ability of users to modify application -- (scope (for a multiphase project) ) -- performance -- usability -- concurrency Requirements document--continued

12 12 Specification: must be as complete as possible, consistent, clear Specification

13 13 Principles of specification: 1. functionality should be separate from implementation 2. model of system behavior must include both data and functional responses to external stimuli 3. interaction with other components must be specified 4. environment of operation must be defined 5. "cognitive model" should describe the system as seen by the user community; do not create a design or implementation model 6. must be tolerant of incompleteness and allow for additions 7. must allow for change Principles of specification

14 14 Result of specification step: Software Requirements Specification must include: --complete information description --detailed functional description --representation of system behavior --performance requirements --design constraints --appropriate validation criteria (for example, acceptance tests) --……. Software requirements specification

15 15 example candidate formats for specification: IEEE 830-1984 Department of Defense at the end of this process, customer and developer must conduct a Specification Review Specification format

16 16 ER diagrams Entity-relationship diagrams / class diagrams: These diagrams represent the relationships between the classes in the system. There are three basic types of relationship: inheritance ("is-a") aggregation ("has-a”) association ("uses") These are commonly diagrammed as follows:

17 17 ER diagram: is-a is-a: draw an arrow from the derived to the base class: manager employee

18 18 ER diagram--has-a has-a: draw a line with a diamond on the end at the "container" class. Cardinalities may also be shown (1:1, 1:n, 1:0…m; 1:*, i.e., any number > 0, 1:1…*, i.e., any number > 1): car tire 1 4

19 19 ER diagram--uses uses or association: there are many ways to represent this relationship, e.g., cargasstation company employee employs works for

20 20 CRC cards CRC cards: class--responsibilities--collaborators cards "responsibilities" = operators, methods "collaborators" = related classes (for a particular operator or method) Make one actual card for each discovered class, with responsibilities and collaborators on the front, data fields on the back. CRC cards are not really part of UML, but are often used in conjunction with it.

21 21 CRC card--example Example (based on Horstmann, Practical Object-Oriented Development in C++ and Java): frontback Class Mailbox OperationsRelationships (Responsibilities)(Collaborators) get current messageMessage, Messagequeue play greeting ----------- Queue of new messages Queue of kept messages Greeting Extension number Passcode Class Mailbox

22 22 Common classes Common types of classes which the developer can look for include: tangible things, e.g., Mailbox, Document system interfaces and devices, e.g., DisplayWindow, Input Reader agents, e.g., Paginator, which computes document page breaks, or InputReader events and transactions, e.g., MouseEvent,CustomerArrival users and roles, e.g., Administrator, User systems, e.g., mailsystem (overall), InitializationSystem (initializes) containers, e.g., Mailbox, Invoice, Event foundation classes, e.g., String, Date, Vector, etc.

23 23 Example—bank simulation (Horstmann) Teller 1 Teller 2 Teller 3 Teller 4 Customer 1Customer 3Customer 2 Horstmann, Mastering Object- Oriented Design in C++, Wiley, 1995

24 24 Example—bank simulation (Horstmann), cont. An initial solution (Horstmann, p. 388): Event Departure Arrival Customer Bank EventQueue Application Bank Statistics

25 25 Example—bank simulation (Horstmann), cont. An improved solution (Horstmann, p. 391): Event Departure Arrival Customer Bank EventQueue Simulation Bank Statistics

26 26 UML Constructs to Be Covered UML language contains many methods which will not be covered here. (And some of the methods we are covering are not officially part of UML, although they are often used with UML, e.g., CRC cards). What we have covered so far: use cases, data flow diagrams--for requirements analysis, design specification ER diagrams, CRC cards--for initial design To be covered: collaboration or object-message diagrams, state diagrams, sequence diagrams--for more detailed design and dynamic aspects

27 27 Additional UML Tools We Will Use Additional UML tools we will use: Collaboration or Object message diagrams State diagrams Sequence diagrams These allow us to further refine the design, in preparation for coding.

28 28 Object Message Diagrams Collaboration or Object message diagrams: Each “responsibility” on a CRC card will be implemented as one or more functions, with information being shared by the collaborators as needed. The collaboration or object message diagram makes each information-sharing event explicit, by showing the flow of function calls or “messages” related to that event, and gives a more precise way to check on the design being constructed. (Not ALL functions need to be diagrammed this way, if the information-sharing mechanism is simple and obvious.)

29 29 Information Sharing Options Information Sharing options: In a collaboration or object message diagram we use a rectangle to represent each participating object (labeled by object name or by class name: object name) and we denote each function call by a labeled line or arrow from the calling object to the object responsible for carrying out the function. These calls can be sequentially numbered. These connecting lines can also be labeled to show the status of the objects carrying out the functions in question. Labels used are: S--the object itself F--data field of the object itself P--procedure parameter G--global variable L--local variable

30 30 Information Sharing--Example--Part 1 of 3 Example: A contrived but instructive example in Practical Object-Oriented Development in C++ and Java by Cay Horstmann (Wiley 1997) considers the case where an object of class Car must carry out the operation add_gas by accessing an object from class GasStation. This can give examples of the cases above, as follows:

31 31 Information Sharing--Example--Part 2 of 3 buy_gas void Car::add_gas(GasStation& station) { station.buy_gas(…); } //add_gas has procedure parameter of type //GasStation buy_gas void Car::add_gas( ) { the_gas_station.buy_gas(…); } //there is ONE global gas station buy_gas void Car::add_gas( ) { _my_gas_station -> buy_gas(…); } //car has ptr to its "own" station, a field in //the “car” object CarGasStation: station P Car GasStation: _my_gas_station FCar GasStation: the_gas_station G

32 32 Information Sharing Example--Part 3 of 3 buy_gas void Car::add_gas( ) {GasStation* station = new GasStation( ); station -> buy_gas(…); delete station; } //"build and destroy a station” (local variable) 2. buy_gas void Car::add_gas( ) {GasStation* station = find_gas_station(); station -> buy_gas(…); } //Car class has a “find_gas_station” 1.find_gas_station //operation which it must ask itself to //carry out; the return value, of type //GasStation, is a local variable CarGasStation: station L CarGasStation: station L S

33 33 Information Sharing--Another Example--Part 1 of 2 Here is another example, also taken from Horstmann, which is more realistic. This diagram shows the messages necessary to execute the "process_dialing" operation in a mail system. Note that "receive_message" can be carried out in two ways, depending on whether the message is for the administrator or for a general reader. The steps to be carried out are: 1. Read input 2a. If input is 9999, have administrator mailbox receive message. 2b1. If input is another extension, find the mailbox for that extension. 2b2. Have that mailbox receive a message.

34 34 Information Sharing--Another Example--Part 2 of 2 MailSystem Mailbox AdminMailbox InputReader S F G L process_dialing1. read_input 2b2. receive message 2b1. locate mailbox 2a. receive message Steps: 1. read_input 2. receive message (case a or case b)

35 35 State Diagram State Diagram: another way of adding detail to the design--models dynamic behavior describes all the possible states a particular object can be in and how that object's state changes as a result of events that affect that object usually drawn for a single class to show behavior of a single object used to clarify dynamic behavior within the system, as needed

36 36 State Diagram--Properties A state diagram contains a "start" point, states, and transitions from one state to another. Each state is labeled by its name and by the activities which occur when in that state. Transitions can have three optional labels: Event [Guard] / Action. A transition is triggered by an Event. If there is no Event, then the transition is triggered as soon as the state activities are completed. A Guard can be true or false. If the Guard is false, the transition is not taken. An Action is completed during the transition.

37 37 State Diagram--Example Example: this state diagram example for an "order" in an order- processing system is from Fowler and Scott, UML Distilled (Addison-Wesley, 1997): Checking check item Dispatching initiate delivery Waiting Delivered start /get first item [not all items checked] /get next item [all items checked && all items available] [all items checked && some items not in stock] item received [some items not in stock] item received [all items in stock] delivered

38 38 Sequence Diagram Sequence Diagram: a sequence diagram also models dynamic behavior typically a sequence diagram shows how objects act together to implement a single use case messages passed between the objects are also shown sequence diagrams help to show the overall flow of control in the part of the program being modeled they can also be used to show: concurrent processes asynchronous behavior

39 39 Sequence Diagram--Syntax Objects in the sequence diagram are shown as boxes at the top below each object is a dashed vertical line--the object’s “lifeline” an arrow between two lifelines represents each message arrows are labeled with message names and can also include information on arguments and control information two types of control: condition, e.g., [is greaterthan zero] iteration, e.g., *[for all array items] “return” arrows can also be included

40 40 Sequence Diagram--Example Example from Fowler and Scott, UML Distilled (note: dashed horizontal line denotes “return”): an Order Entry window an Order an Order Line a Stock Item a Reorder Item a Delivery Item prepare() *[for all order lines] prepare() hasStock:=check() remove() [hasStock] needsReorder := needsToReorder() [needsReorder] new [hasStock] new


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