Lexi case study (Part 2)

Lexi case study (Part 2) Presentation by Matt Deckard

User Operations • Support different operations • Cut, copy, paste • Formatting • Printing • Etc. • Support different Uis • Menus • Buttons • Keyboard shortcuts • Etc.

User Operations • Avoid coupling operations and UIs • Use multiple UIs for single operations • Change UIs in the future • Avoid creating dependencies to classes operations are defined in • Undo and Redo • Want some, but not all operations to be undoable • Un-undoable operations: • Saving • Creating new documents • Printing • Don’t want arbitrary limit on levels of undo

User Operations • Encapsulate user operations • GUI menus are just glyphs that perform actions in response to user interaction • Create subclass of Glyph called MenuItem • But don’t want to make each operation a subclass of MenuItem (avoid decoupling!) • Parameterize menu items by uper operations • How?

User Operations • How should user operations be parameterized? • Simple function call has drawbacks: • Doesn’t address undo/redo • Hard to associate state with function • Difficult to extend, reuse • Use objects instead • Can store state, implement undo/redo • Use inheritance to extend, reuse

Command class • Command: abstract class representing user operation • Based on abstract method Execute() • Subclasses will implement Execute() according to the operation they represent • Subclasses can delegate parts of user operation to other objects • Command objects are treated uniformly by requestor • MenuItem will store instance of Command object to encapsulate its associated user operation

Command class • Undoability • Add abstract Unexecute() method • During Execute(), Commands will store whatever information they need to undo later • Add abstract Reversible() method • Returns true if and only if this Command is undoable • Allows Commands to determine undoability at runtime • i.e. redundant or vacuous Commands shouldn’t be undoable • Command history • Need list of Commands to support multiple undos • Traverse back and forth through list to undo and redo • Call Unexecute() when undoing, Execute() when redoing

Command class

Command Pattern • Encapsulates a request (user operation) • Prescribes uniform interface for requests • Shields clients from request’s implementation • Allows delegation of request to other objects • Provides centralized access to functionality • Allows to queue or log requests • Supports undo, redo • AKA “Action”, “Transaction” • Similar to functor (but not quite the same)

Command Pattern • Related patterns • Use with Composite and you’ve got: macros! • Use with Memento to remember state (for undo) • Use Prototype to copy command before putting in undo list, to distinguish multiple invocations of same command

Spellchecking and Hyphenation • Textual analysis • Want to support multiple algorithms, addition of new ones in future • Avoid coupling to document structure • Add other types of analysis in future • i.e. search, word count, etc. • Two pieces: • Accessing information to be analyzed • Performing the analysis

Accessing scattered information • Data access • Glyphs may be stored in different ways • Need mechanism to access all of them • Traversal • Different analyses may access Glyphs in different ways (i.e. forward vs. reverse search) • Issues • Only Glyphs know their data structure • Glyph interface shouldn’t be biased toward one structure over another • i.e. using integer index biased us toward arrays • Want to provide multiple access and traversal methods

Accessing scattered information • One approach: adding methods to Glyph • voidFirst(Traversal) – initializes specified traversal • voidNext() – advances to next Glyph in traversal • boolIsDone() – reports if traversal is over • Glyph* GetCurrent() – accesses current glyph • Replaces Child() • voidInsert(Glyph*) – inserts Glyph at current pos • Replaces Insert(Glyph*, int)

Accessing scattered information • Issues with this approach • Must extend Traversal enumeration to support new traversals • Would also have to change lots of subclasses • Difficult to reuse mechanism for other object structures • Doesn’t support multiple traversals in parallel

Iterator class • Better approach: encapsulate access and traversal • Iterator • Abstract class • Defines interface for access and traversal • Subclass contains reference to structure it traverses • CreateIterator() • By default, will return NullIterator • Subclasses can override, based on their structure • Iterators can use CreateIterator() on their root glyphs to support different traversal

Iterator class • Example: PreorderIterator • First() • Calls CreateIterator() on root • Calls First() on returned Iterator • Pushes Iterator onto stack • CurrentItem() • Calls CurrentItem() on Iteratorat top of stack • Returns result • Next() • Calls CreateIterator() on top Iterator • Calls First() on returned Iterator • Pushes Iteratoronto stack • Calls IsDone() on latest Iterator. If true, pops it off and repeats

Iterator class

Iterator Pattern • Abstracts traversal algorithm • Shields clients from internal structure of objects traversed • Gain flexability, usability • Easy to extend • Easy to reuse by parameterizing object type • Can perform multiple traversals in parallel

Performing the analysis • Want to distinguish analysis from traversal • Flexibility, reusability • Different analyses might require same traversal • Want to distinguish different types of glyphs • Different analyses consider different glyphs • Could abstract in Glyph, have subclasses implement • Drawbacks to this approach: • Have to change multiple subclasses • Obscures basic glyph interface

Performing the analysis • Encapsulate the analysis • Create analysis classes • For now, let’s consider a SpellChecker class • Iterator has instance of SpellChecker • Uses SpellChecker instance as it traverses • SpellChecker accumulates information as it is used

Performing the analysis • How to distinguish glyphs? • SpellChecker treats different glyph types differently • Don’t want to resort to type tests or casting (gross) • Instead, have the glyph object tellSpellChecker to check it • Glyph has abstract CheckMe() method • SpellChecker has methods for every glyph subclass, i.e. CheckCharacter(), CheckRow(), CheckImage(), etc. • Glyph sublcasses will override CheckMe() to call the appropriate method in SpellChecker

Performing the analysis

Performing the analysis • Adding new analyzers • Will be difficult if we define them as separate classes • Instead, abstract it as a Visitor class • CheckMe() becomes the Accept() method • Takes any Visitor as parameter, so don’t have to touch glyph subclasses when adding new analyzers • CheckCharacter(), etc become the Visit() method • Overloaded, takes visited subclass as parameter • Need one for every subclass that implements Accept()

Visitor Pattern • Can be applied to any object structure • Visitees needn’t have common parent class • Tradeoff: • When you add Visitors you don’t have to update object structure, BUT: • When you add subclasses to object structure, you DO have to update your Visitor classes • Sometimes can provide default “do nothing” operation in Visitor • Helps avoid “polluting” classes with many operations • Helps to separate groups of common operations • Can accumulate state as they visit elements • Sometimes compromises encapsulation of visitee • elements

Summary • Needed to support different user operations • Encapsulate the concept that varies (Command) • Needed to support different methods of accessing and traversing data • Encapsulate the concept that varies (Iterator) • Needed to support different analysis algorithms • Encapsulate the concept that varies (Visitor) • (Are we seeing a pattern here?)

Lexi case study (Part 2)

Lexi case study (Part 2)

Presentation Transcript

Case Study 2

Case Study Module 4 Part 2

Lexi Case Study

Case Study 2

Case study- Dell

Case Study

CASE STUDY

Case Study 2

Case Study # 2

Case study – part 1

Case Study

Case Study

Case Study

Case Study 1 and Projects

Measuring the Internet: A case study

Lexi case study (Part 2)

Case study – part 1