[Skip Navigation] [ CSUSB ] / [CNS] / [CSE] / [R J Botting] / [CS375] [Search ]
[About] [Contact] [Grades] [Objectives] [Patterns] [Projects] [Schedule] [Syllabus]
Session: [01] [02] [03] [04] [05] [06] [07] [08] [09] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20]
[Text Version] patterns.html Thu Mar 21 14:14:04 PDT 2013
Opening the PDF files on this page may require you to download Adobe Reader or an equivalent viewer (GhostScript).

Contents


    Patterns and Principles

      What is a Pattern

      A pattern can be a recurring structure in a domain or business model. It can be a pretty useful way of solving a recurring problem in coding a program. It can be a recurring way of dividing up the responsibilities (functionaliity) into a maintainable set of objects. The key word is recurring -- if it has not been used 3 times then it is not a pattern.

      Domain and Business Model Patterns

      In a typical busines or doamin model there will be many simple patterns that appear.

      The first set of patterns come from the fact that Entity-Relationship modelling is also business modelling. The following examples come from my CSE372 (Computers in Organisations) course. Here are some classic analysis patterns that I've noticed over the years. Use this list to help discover ERD models:

        Sentences lead to Relations: Sentences often describe relationships between entities: Jo Doe is married to Jane Roe. Student Joe Coyote is enrolled in CSE372. Joe Coyote is working as a Librarian on the "FIS" project team in CS372.
        1. A simple relationship between only two entities can be shown as simple link. RJBOTTING teaches CSE372.

          Simple Relation between two Entities

        2. But many-to-many and n-ary relationships are best treated as entities. For example: An Enrollment links a Section to a Student....

          Relationship between 3 Entities

        3. A sentence can relate entities of the same type. For example a Marriage relates two People. The different occurrences play different roles. For example in a traditional a Marriage has one Person who is playing the roll of husband and a second person playing the role of wife.

          Relationship with two roles of one type

        4. Some sentences describe an entity in terms of its attributes. When an entity has a property that is a value of a simple data type: a number, Boolean, character, string, or one of a number of enumerated values, then it is best shown as an attribute. For example a Person may have attributes: gender, age, height, ...

          Entity with attributes

        5. Notice: an entity can have attributes and be related to other entities. A Relationship can also have attributes, and be related to other Entities. However be careful not to record the same fact in multiple ways.


        Master and Detail Pattern Example: A Sale has a number of Items. An Order has a number of order items.

        master (1)-(*) detail.

        Pattern -- Actor plays a Role for a Time A Person can be a Student in a Quarter. A Person can Work on campus in a Quarter. They can be a Teacher in another Quarter. Combinations of roles are possible at one time.

        Actor--Role--Time

        Events Time and Place Pattern Event of a particular Type takes place at a Time and a Place. Example: CSE372 meets 4-6pm in JBH146 during winter quarter 2007.

        Event at Place in Time of Type...

        Description and Instance Pattern Example: A product describes a sales Item. Also good for entities that are grouped by shared attribute values. Example: A Course has many Sections.

        Description(1)-(*)Instance.

        Part and Whole Pattern Building has many rooms. A Week has many days. Dog has 4 legs. Project has team members.

        Whole(1)---Part

        Access Point Pattern -- An entity selects a collection of entities needed for a process. Example: DeansList of Students with GPA>3.9. This example is an "Operational Master" and expresses a functional requirement as an object. Another version is when when the Access Point links to a list or set of objects: for example an Inventory of Items on the shelves in a Store, a list of people with accounts, a catalog of all the books in a library, or a Ledger describing resources owned by a enterprise. Access(1)---Instance

        General and Particular Pattern -- A Student and a Teacher are special types of Person. In an ERD the special types are shown with a 0..1 multiplicity in the General. In general, you can have a whole hierarchy of special types. There are ways to document whether the special types overlap or not (UML Generalization). Avoid this detail in simple ERDs.

        General(1)---(0..1)Particular

        The Enumeration pattern It is very common to define an entity type not by its relationships and attributes, but by listing its possible values. For example: Gender, Race, Boolean, ... Either document the values elsewhere or use the <<enumeration>> stereotype in the UML for the second of these. Do not confuse listing the attributes of an entity: Person has age, gender, eye color, ... with listing the possible values of an enumerated date type: Gender = {male, female, unknown}. Another example: student status = (fresher, sophomore, junior, senior, graduate).

        Type={value1, value2, ...}

        By the way it is a common error to forget the "<<enumeration>>" and so turn the possible values of a simple entity into the attributes of a complex and erroneous one.

      Software Design Patterns

      Reoccuring solutions to complex and subtle problems in software design -- for example allowing the software to work with an expanding number of interface frameworks without recompiling everything each time. See [ Software_design_pattern ] on the Wikipedia.

      GRASP -- General Responsibility Assignment Software Patterns

      From Craig Larman [ ../cs375/text.html ]

    1. Expert::=allocate a responsibility to a class that has the information. Look in both the design classes and the domain model to find a type of object that knows enough to handle the responsibility. Knowledge includes having the data, and also knowing who has got the data! Sketch

      [Look for info in the domain]

    2. Creator::=creating an object should be the responsibility of a class that is closely related to the created object. Notice that you always need at least one way of creating an object that doesn't depend on already having an object of that type already. So which class or object is close to the created object. Sketch

      [owners and close friends make good creators]

      Or else you can use a GoF Factory -- a Pure_Fabrication.

    3. Low_coupling::=Assign a responsibilities so that class depends less on other classes using a "need to know basis". Organize responsibilities so that classes do not depend on each other two much.

    4. High_cohesion::=Design elements to have strongly related and focused responsibilities".

    5. Controller::=Assign the responsibility for handling system event messages to a class representing either the whole system, device, or subsystem, or representing the use case /scenario within which the system event occurs. Controllers often translate IDs_to_Objects where the objects are in the Domain Layer and are Information Experts. Note: Choose controllers carefully to avoid low cohesion.

      [Possible controllers]

      Compare [ MVC ] (Model-View-Controller) and see IDs_to_Objects below.

    6. Polymorphism::=`Give the same name to services in different objects when the services are similar or related`. Classify objects, using inheritance/generalization, to allow the right version of a service to be executes for the object in question. You can call all your Pets in the same way.... and the Dogs come to you, and the Cats think about it, for example.

      [Class send message to object of right type]

      Example [ Strategy ] in the GOF patterns below.

    7. Pure_Fabrication::=assigning a highly cohesive set of responsibilities to an artificial convenience class that doesn't represent a problem domain concept.

      [Assign operation to an invented class of object]

    8. Indirection::=Assign a responsibility to a class that knows where to find an object that can complete the task, Avoid coupling by an intermediate (smart?) object.

      [Put object in the middle]

      You can have indirect access to an abstraction without knowing the precise concrete implementation of the abstraction. Polymorphism makes sure you get the right behavior.

    9. PV::=Protected_variation.
    10. Protected_Variations::=Identify points of predicted variation or instability and assign responsibilities to create a stable interface around them.
      1. Parnas: Separate your design decisions into separate modules. See Parnas.
      2. SDM: Separate physical from logical structures in separate processes.
      3. GoF: Template_Method, Facade, Proxy, Adapter,...

      GoF Patterns

      1. GoF::="The Gang of Four".... see GoF_book and
      2. The_Gang_of_Four::abbreviation={Erich Gamma, Richard Helm, Ralph Johnson, John Vlissides}, Four OO thinkers who wrote an influential book of design patterns.
      3. GoF_book::=following, [Gammaetal94] , note -- uses a pre-UML notation.

        Set of_GoF_Patterns

        {Abstract_factory , Adapter , Bridge , Builder , Command , Composite , Decorator , Facade , Flyweight , Interpreter , Iterator , Mediator , Observer , Prototype , Proxy , Singleton , Strategy , State , Template_Method , Visitor}

        Links on the Gang of Four patterns. THe Wikipedia has articles of varying quality on the GoF patterns. Here [ Design_Patterns_(book) ] is a link to a description of the book. Here [ http://pw.tech-arts.co.jp/download/design_pattern/ ] are some quite good UML diagrams but I'm not sure of the descriptions. And the WikiWikiWeb [ wiki?DesignPatterns ] discusses them all -- but is short of diagrams (if you like diagrams). More links: [click here [socket symbol] if you can fill this hole]

        Many GoF combine two or more GRASP patterns. For example State is a Pure_Fabrication that uses Indirection to protect a class from state changes (PV).

      4. Abstract_factory::GoF=To allow a client to create an object without knowing what type of object it is design a common interface for creating families of similarly or related objects. See Factory. This is an example of a Pure_Fabrication that uses Polymorphism to Protect_Variations. [ wiki?AbstractFactoryPattern ]

        [Wikimedia diagram]

        [ Abstract_Factory ] (article).

      5. Adapter::GoF=Introduce a class to convert the interface of one component into another interface. Think plugs and sockets. make one interface for one or more suppliers. Unlike Proxy and Bridge, an adapter converts different interfaces into one common one. Uses pure fabrication to protect variation in an interface and ise indirection and polymorphism to make easy to extend.

        [Use a new interface that polymorphically selects the right object and message]

        (general form) and code [ fig25_25_1.cpp ] [ test.fig25_25_1.cpp ] (From Larman05)

      6. Bridge::GoF=A class of objects that acts as an interface between clients and an implementation. Unlike an Adapter the Bridge connects to a family of objects with the same operations. [ wiki?BridgePattern ] [ bridge_s.jpg ] [ Bridge_pattern ]

      7. Builder::GoF=How to constuct complex objects with varying parts? A director calls various builders as needed, a variation on the Factory patterns. [ Builder_pattern ] [ wiki?BuilderPattern ]

      8. Chain_of_Responsibillity::GoF=Attach responsibillities to a linked list of abstract handlers each is a special concrete handler. [click here [socket symbol] if you can fill this hole]

      9. Command::GoF=Design objects that know how to do (and undo) a family of tasks and pass them to other objects to be used as needed. [ wiki?CommandPattern ]

      10. Composite::GoF=Make complex and simple kinds of an object share behavior. And often the complex objects keep a list of their parts: each of which is a similar kind of object.

        [Client referes to a Component that may be a leaf or composite...]

        [ wiki?CompositePattern ] [ PatternComposite.aspx ]

      11. Decorator::GoF=A class can take an object and wrap new functions around it.

        [ decorator.gif ] (complex diagram) [ TestDecorator.java ] [ wiki?DecoratorPattern ]

      12. Wrapper::=Decorator.

      13. Facade::GoF=A class or object provides a single point of entry for services of a subsystem, Hide a complex system of objects behind a single object. Pay no attention to the man behind the curtain. [ wiki?FacadePattern ] [ PatternFacade.aspx ] [ Facade_pattern ]

      14. Factory::=an object/operation/class is designed solely to create other kinds of object. A factory is an alternative to a Creator that calls the constructor in a class. Because it is a member of a different class (the factory) we can get objects without having to know precisely what class they are instances of. Other patterns need the ability to create concrete implementations of an abstraction -- but without knowing which implementation has been chosen. This is not a GoF pattern, see Abstract_factory, FactoryMethod, and Builder.

      15. FactoryMethod::=an operation that creates an object. THis provides flexibillity that a constructor is not able to provide -- for example different names or run time selection of the concrete type of object. Typically there is a hierarchy of classes all providing the same operation to create objects of different types. Similarly the resulting object should be a specific object in a hierarchy of products.

        [Concrete creators make procucts and shar a common interface]

        (From Wikimedia) See [ Factory_method_pattern ] on the Wikipedia.

      16. Flyweight::GoF=when you have lots of small similar objects keep exemplas ina data structure and point to those for the details. [ wiki?FlyweightPattern ] [ Flyweight_pattern ] Classic example: characters in wordprocessing. Used for State and Strategy. Used with Composite.

      17. Interpreter::GoF=Complex rules and formulas are encoded as expressions that can be evaluated. An abstract Expression can be a terminal or nonterminal expression and nonterminal expression have many abstract parts in them. [ interpreter.gif ] [ PatternInterpreter.aspx ] [ hanoi_article.html ] (Includes Composite and Inpterpreter as an OO solution of the Classic Towers of Hanoi problem). Here [ is-interpreter-an-anti-pattern ] is a discussion of whether Interpreter is actually a bad idea (and Anti-Pattern) and a smarter move is just to embed a ready made laguage and interpreter.

      18. Iterator::GoF=Provide access to each item in a container in turn, A typical iterator has operations that return: first(), next(), isDone(), currentItem(). Alternative is Visitor. [click here [socket symbol] Iterator if you can fill this hole]

      19. Mediator::GoF=A collection of Colleagues work together without direct coupling because they use a Mediator object. [click here [socket symbol] Mediator if you can fill this hole]

      20. Memento::GoF=An object creates a memento of a particular event that is passed to a caretaker until the state has to be recalled. [click here [socket symbol] Memento if you can fill this hole]

      21. Observer::GoF=An object that implements the operations that let it subscribe to learn about other objects. Objects that need to see what an object is doing can join a collection maintained by the observed object. These are subscribers. The observed object publishes the changes to the subscribers using one or more special operations that a listed in an interface that the observers all implement. It is also possible for an object to subscribe other objects as observers.

        (sequence diagram: ob subscribes and gets update in return)

        (Class diagram Observer and Subject)

        [ wiki?ObserverPattern ] [ PatternObserver.aspx ]

      22. Prototype::GoF=Create objects by asking an object to clone itself, all concrete prototypes share a common clone() interface. [click here [socket symbol] if you can fill this hole]

      23. Proxy::GoF=Design an object that can stand in for other objects and knows which object it is representing and how to simulate it. As a result we can change the real object with out breaking the client.

        [A client is protected from variations by a common interface and multiple real and imitation objects]

        [ wiki?ProxyPattern ]

      24. Singleton::GoF=To make sure that there is precisely one object in a class and provide access to it. [Implementing and using a Singleton class]

        [ Singleton.pdf ] [ singleton.cpp ] [ test.singleton.cpp ] [ wiki?SingletonPattern ] [ PatternSingleton.aspx ]

      25. Strategy::GoF=Place different ways to do something behind a common interface and use indirection via an object to pick the right one. [ wiki?StrategyPattern ] [ PatternStrategy.aspx? ]

        [There are many ways to solve a problem and the client does not need to know which one is used]

      26. State::GoF=When an object changes behaviors (responsibilities) with time, place the state in a different State object and place the different behaviors in special kinds of State object. Note: in most programming language can not change its class! Also note that an efficient State implementation can use Singleton for the states. [ wiki?StatePattern ] (on the WikiWikiWeb). Examples: [ StatePatternExample.html ] [ test.State.cpp ] [ State.cpp ] (using lazy Singleton and a "call back") OR [ State2.cpp ] (using eager Singleton, breaking CQS principle, and hiding the initial state) [ test.State2.cpp ] , Exercise: redraw the UML diagram to show the changed classes between State and State2.

      27. Template_Method::GoF=A method in a class can use abstract operations (hooks) that are defined in a subclass so that the subclass provides some functionality while using the overall method. The classic example is a method that sorts a vector of data in a Sortable class but uses an undefined "less_than" operation. Other classes extend the Sortable and define "less_than" and can then sort the data Their way, right away. [ wiki?TemplateMethodPattern ] This result is also called a Framework.

      28. Visitor::GoF=A visitor object can be taken to many or all the items in a data structure visiting each one and gathering information, All visitors must implement the same interface which is called by the elements in an accept method. Diferent types of element can use different operations in the interface if necesary. [click here [socket symbol] if you can fill this hole]

      . . . . . . . . . ( end of section GoF Patterns) <<Contents | End>>

      XP Principles

    11. DRY::=Don't repeat yourself.
    12. YAGNI::=You Aint' Gonna Need It. When in doubt leave it out! Keep It Simple Stupid! Only analyse, design, implement, and test a function that your client actually needs now.

      Persistence Principles

    13. tables::=All data can be expressed by a collection of simple tables.

    14. Persistence_as_a_superclass::=`Put all the persistence code into a superclass and then any class can become persistent by inheriting from the persistence class`. Notice that this can get clumsy and in Java foul up more important extensions.

    15. ACID::principle="Atomic, Consistent, Isolated, and Durable". Jim Gray's ACID principles of Data Base transactions.
      • atomic::=a transaction either completes or does nothing. -- no interrupts.
      • consistent::=a transaction never leaves the data in a state that breaks the rules. A marriage has two people: no more, no less.
      • isolated::=The effect of a transaction is hidden from other transactions until it is complete.
      • durable::=A transaction, once completed, is never lost -- even if things break down or fail.

    16. database_mapper::=The class of the object determines what data needs to be stored so define objects for each class to handle the tables.

    17. cache_management::=Databases should manage their own caches.

    18. hide_SQL::=Put all the SQL in one object -- a singleton -- and keep it separate from the rest of the code. Treats SQL as an external entity with its own secrets. See Parnas.

      Exception Principles

    19. Convert_exceptions::=If you can not handle an exception then convert it to a higher level exception.
    20. Name_the_problem_not_the_thrower::=name exceptions to indicate what is wrong not where it came from.
    21. centralize_error_logging::pattern. Have a single object that is responsible for recording bad things.
    22. standard_error_dialog::pattern. Have a standard user interface for reporting and sorting out errors.

      OO Principles

    23. IDs_to_Objects::="An object is more than its ID or Key and more useful", so when you are given an identifier or key you should replace it by the correct object as soon as possible. So, for example a Controller will find the object that fits the ID. The are several places the controller can look to find(id) including an internal data structure listing all the possible objects. But using a data structure in the Controler means that the controller becomes responsible for updating this list -- which means lower cohesion. The Controler can not send the find(ID) to the object because the object has not been found yet! In Larman's text book in Chapter 17 the Controller Register sends the Store a request to find the customer with a particular ID.

      Of course, the Creator of an object has the information to store IDs and their objects. So a simple solution is to use the metaclass (where the Constructor is). The diagram below shows the Controller using a static function to ask the Class that created the objects which one matches the id. The returned object is then sent on to other objects to get the work done:-

      [Controller asks creator to convert ID to Object]

      So, the creator Class in the above diagram will probably declare (in C++):

       		private: string id;
       		private: static map<string, *Object> objects;
       		public:  static Object* find(string id){return objects[id];
       		private: void addThis(string id){objects[id]=this;}
       		private: void removeThis(){objects.delete(Pair(this->id, this);}
       		public: Class(string id, ...) {... addThis(id); ...}
      Note the above code needs testing and adapting to the particular situation.

      If the exact class of the object is not known, the Controller cannot turn to that class to find the id. For example, when I login to MyCoyote it does not know whether I am a student or a faculty member, until it looks up my ID. In this case we might well have decided to use a Factory object to construct the object we need. The top level one can keep track of all the IDs and the specific objects that are needed. Then we use Polymorphism:

       	Abstract_Class * object = Factory.getInstance().find(id);
    24. The Factory::find(id) will return the address of an object in one of the special concrete classes. For example, it can return a Faculty object or a Student object as a special kind of Person class, by abstraction.

    25. OO::=Object Oriented Principles, including abstraction, extension, polymorphism, etc.

    26. OID::=Objects should know their own identity... and this can be expressed as a simple data item and stored in data tables, and hidden from the user.

    27. abstraction::OO=Variables and parameters should be declared as reference or pointers to abstract data types whenever possible, and containers as holding pointers to abstractions. Also known as Aim high -- allow your pointers to refer to abstractions and then they can point to many special kinds of object. For example(in C++):
      1. Declare variable abstract and assign address of concrete:
         		List * example = new SpecialKindOfList(....);
         		Person * dick = new Faculty(....);

      2. Declare parameters as refs to abstractions
         		void zark(List &w){....}
      3. Declare containers as containing pointers to abstractions:
         		map<string, Person*> people;
         		people.insert(string("Dick"), dick);

    28. extension::OO=Extend classes rather than reinventing the wheel. Polymorphism lets you add new functions to a class by putting them in a subclass. This can be separately compiled and linked into the running system without having to compile the base class.

    29. polymorphism::OO=let objects sweat the details for you. See GRASP Polymorphism

      Other Principles

    30. Parnas::=place different decisions in different modules, for example
      • 1971: Put input, output, and logic in separate modules that communicate by function calls.
      • Separate the physical from the logical. For example: physical=magnetic tape, logical=sequence of records.
      • Hide a data structure inside an Abstract Data Type -- -- --(ADT)
      • Hide an algorithm behind a Strategy.
      • Hide external systems behind a Facade.
      • Hide communications between parts inside a Mediator.
      • Hide libraries behind a Facade, an Adapter, or a Bridge.
      • Hide SQL inside a package or object (hide_SQL).
      • Hide the User inside a User_interface (UI) Package.
      • Separate particular Applications from Business Logic and Domain classes.
      • Separate Model, View, and Controller. See MVC
      • Hide a RDBMS behind a simple OO persistence layer.

    31. CQS::=Command_Query_Separation,
    32. Command_Query_Separation::principle=Operations should either do something and return nothing or return something and do nothing, NOT both,
      1. void doSomething(data);// nothing returned
      2. Type getSomething(data);//leaves everything the same.

      This dates back to the the theory of abstract data types and was inherited by Meyer into objected oriented coding style. This principle leads to code that is slightly more verbose but very much clearer. It also reduces bugs by the principle of Least_Surprise.

    33. Least_Surprise::principle=`Whenever you design anything choose a design that minimizes the surprises that the user may experience`. Henry Ledgard proposed this for programming languages but it also applies to user interfaces, common appliances, and object-oriented classes. Apple had a tendency to extend so that the user experiences occasional pleasant surprises: the user does the wrong thing and the system does the right thing. This is also called
    34. DWIM::="Do What I Mean". This is a dangerous philosophy because it back fires.

    35. Model_View_controller::pattern=MVC. [ mvc.gif ]
    36. MVC::pattern="Model-View-Controller",
        This patterns suggests separating the logic of the data (Model) from the code that interfaces with the user (View+Controler).
      • Separate Model (data + ...) from View(what the user sees...) from Control (what the user can do...). [ MVCinUML.gif ] (UML diagram of View, Controller and Model packages)
      • In some methods yo split Boundary, Control and Entity objects. And use special icons for them: [ icons.gif ] (Graphic showing common icons and stereotypes).

        The code that describes user interfaces is independent of the code for the logic of an enterprise or application. The appearance of the user interface for a pay-roll should be separated from the rules for calculating your with-holdings. Neither should the choice of the user interface framework change the calculations. So the wise designer splits all the user interface code into specialized classes that communicate with the application specific classes. This is splitting the users "View" from the logical "Model". As a result the "Model" classes can reflect the Domain or Business model and so are easier to understand and get right... and keep right.

        As a result you can change the View (add a new one, rip out the AWT and put in Swing, ...) without worrying about the payroll logic.

        Here is a paper [ 1121341.1121453 ] that has a set of Java programs that access a time server and show the user the time of day found on that server. One program has a command line interface, one has a menu driven ASCII interface and one a GUI interface, but they share a common "model" of how to access the time server. This class never changes... each interface is implemented as a new class that uses the model:

        View -> Model

        The diagrams in the paper are not correct UML, do not use them!

        In general, there are lots of classes defining the user interface and many classes in the Model. In the UML use packages to contain them.

        More strictly the user interface code is split into two sets of classes. The View and the Controler. Typically the user communicates with controlers that change the model. The view classes get data from the model and are responsible for rendering it to the user.

         		User ---> Controler ----> Model -----> View -----> User

      • Also see [ Model-view-controller ] for the history and a list of frameworks that use MVC.

    37. FURPS+::requirements={Functional, Usability, reliability, Performance, supportability, Implementation, Interface, Operations, Packaging, Legal}, Grady92.

    38. KISS::=Keep It Simple, Stupid, see XP.YAGNI. "Do the simplest thing that could possibly work."

    39. PQRST::requirements={Purposes, Qualities, Realities, Systems, Techie}, from RJB.
      Net
      1. Purposes include functions and use cases and define why someone wants the software. To help us sell items to customers.
      2. Qualities are the needed properties of the software like security and performance criteria.
      3. Realities are domain models. We have the problem of integrating different views of the the real world
      4. Systems are the existing systems that we are replacing, using, modifying, and even competing with.
      5. Techie include technologies, techniques, etc. and describe what and how we might construct the software -- the decisions we make: eg.-- use VB and MySQL.

      (End of Net)

    40. The_Hollywood_Principle::pattern="Don't call us, we will call you", This is a common implementation pattern for interacting with a framwork or operating system. Instead of the program calling the operating system when it needs to something, it waits to be called by the environment when events happen. Detail at [ Hollywood_Principle ] on the Wikipedia. The GoF Observer pattern uses the Hollywood Priciple. The classic GoF State pattern uses it to change the state.

      AntiPatterns -- Patterns that occur but don't resolve the forces well

        The Ball of Mud Pattern or God Object

        Defined in [ God_object ] on the Wikipedia.

        You should read and study this an excellent, short, and readable blog entry [ 001003.html ] describing the ways in which system and software architecture goes astray and ultimately becomes unmanageable.

      Good Links on Patterns

      A good list, overview and, discussion of patterns can be found at [ wiki?CategoryPattern ] on the WikiWikiWeb.

      Another source of pattern information is [ Patterns.aspx ] but this is biased towards C# and is an advert for $2,000 courses.

      Here is a nice resource [ http://home.earthlink.net/~huston2/dp/ ] and visual [ patterns.html ] provided by Vince Huston. Here is a quiz [ patterns_quiz.html ]

      The Wikipedia [ http://en.wikipedia.org/wiki/ ] also documents many (if not all) patterns [ Category:Software_design_patterns ] here.

      Paul Wagner [Wagner05] Has listed a dozen commain model patterns: [ domainPatterns.png ] that are useful in domain or business modelling.

      Narasimha Bolloju [Bolloju04] [BollojuLeung06] claims that if you know about a dozen common domain model patters then you make better models, quicker. Here is a visual summary [ 19Bolloju04.gif ] of the following list

    41. Collaboration_patterns::#Pattern=following,
      • E1: Role (1)-(0..*) Transaction
      • E6: Transaction (1)-(0..*) FollowupTransaction
      • E5: Specification (1)-(0..*) Transaction
      • E3: CompositeTransaction (1)<*>-(0..*) LineItem
      • E2: Place (1)-(0..*) Transaction
      • R: Actor (1)-(0..*) Role
      • T1: Item (1)-(0..*) SpecificItem
      • T4: Group (1)<>-(0..*) Member
      • E4: SpecificItem (1)-(0..*) Transaction
      • T2: Assembly(1)<*>-(0..*) Part
      • P: OuterPlace (1)-(0..*) Place
      • T3: Container (1)<*>-(0..*) Content

    . . . . . . . . . ( end of section Patterns and Principles) <<Contents | End>>

    Standard Definitions

  1. Artifact::="Anything that is created in the course of a project".
  2. artifact::=see above.

  3. DCD::diagram="Design Class Diagram", shows the classes that will be implemented in code. [ 02DiceGameClasses.gif ] (example).
  4. Deliverables::="A packet of artifacts that must be prepared by a deadline for review or distribution".

  5. Glossary::= See http://cse.csusb.edu/dick/cs375/uml.glossary.html.
  6. GoF::="Gang of Four", [ patterns.html#GoF ]
  7. GRASP::patterns="General Responsibility Assignment Software Patterns", a set of guidelines for designing objects and classes. They take a single event that the system must handle and determine a good set of objects and/or classes to carry it out. See [ patterns.html#GRASP -- General Responsibility Assignment Software Patterns ]
  8. Grades::= See http://cse.csusb.edu/dick/cs375/grading/.

  9. KISS::Folk_law="Keep It Simple, Stupid", in agile processes this means never drawing a diagram or preparing a document that doesn't provide value to the clients and stakeholders. In all processes it means never designing or coding what has no value now, see YAGNI.

  10. OO::shorthand="Object-Oriented".
  11. OOAD::="Object-Oriented Analysis and Design", See chapter 1 in text.

  12. patterns::="Documented families of problems and matching solutions", see Patterns.
  13. Patterns::= See http://cse.csusb.edu/dick/cs375/patterns.html.

  14. Process::="How to develop software".

  15. RJB::=The author of this document, RJB="Richard J Botting, Comp Sci and Engineering School, CSUSB".
  16. RUP::Process="Rational UP", a proprietary version of UP.

  17. SSD::="System Sequence Diagrams", see chapter 10 and [ 02DiceGameSSD.gif ] (example).

  18. TBA::="To Be Announced".

  19. UML::="Unified Modeling Language". [ Unified_Modeling_Language ]

  20. UP::="Unified Process", an iterative, risk-driven, and evolutionary way to develop OO software.

  21. YAGNI::XP="You Ain't Gonna Need It", an XP slogan that stops you planning and coding for things that are not yet needed. As a rule the future is not predictable enough to program a feature until the stakeholders actually need it now. In this class it also means "It won't be on the final or in quizzes".

  22. XP::="Extreme Programming", the ultimate iterative, code-centric, user-involved process.

( End of document ) <<Contents | Top