1 / 27

ניתוח ועיצוב מערכות תוכנה אביב 2012

ניתוח ועיצוב מערכות תוכנה אביב 2012. שפת אילוצי העצמים Object Constraints Language (OCL). Outline. What is OCL Types of constraints Constraints structure OCL expressions Examples Textbook: Jos Warmer and Anneke Kleppe , “The Object Constraint Language ” Available on Google Books.

haroun
Télécharger la présentation

ניתוח ועיצוב מערכות תוכנה אביב 2012

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. ניתוח ועיצוב מערכות תוכנהאביב 2012 שפת אילוצי העצמיםObject Constraints Language (OCL)

  2. Outline • What is OCL • Types of constraints • Constraints structure • OCL expressions • Examples • Textbook: Jos Warmer and AnnekeKleppe,“The Object Constraint Language”Available on Google Books

  3. What is OCL • It is intended for the specification of additional requirements (constrains) which cannot or be expressed graphically. • To specify invariants on classes and types in the class model. • To describe pre- and post- conditions on operations. • To describe guards. • To specify target (sets) for messages and actions. • To specify constraints on operations. • To specify derivation rules for attributes for any expression over a UML model.

  4. Types of Constraints • An invariant is a constraint that states a condition that must always be met by all instances of the class, type, or interface. • An invariant is described using an expression that evaluates to true if the invariant is met. • Invariants must be true all the time (Class diagram). • A precondition to an operation is a restriction that must be true at the moment that the operation is going to be executed. • The obligations are specified by post conditions (Sequential diagram). • A postcondition to an operation is a restriction that must be true at the moment that the operation has just ended its execution (Sequential diagram). • A guard is a constraint that must be true before a state transition fires (State machine diagram).

  5. Constraints Structure contextTypenamec_type[name]: <OCL–expression> • The context is keyword introduces the context for the expression. Each OCL expression is written in the context of an instance of a specific type. • Typename is the name of the type or the class for which the invariant constrain applies. • c_type is the type of the constrain: • invariant, pre/post-condition, guard. • [name] – optional, the names of the constraint. • OCL - expression should accept value “true” for all instances of Typename. • For example: • Context Packagename1::class1 inv : … • Context class2 inv : …

  6. Basic Data Types • Operations above basic types of data (Boolean, Integer, Real, String);

  7. Collections • set : the mathematical set. • It is not ordered and does not contain duplicate elements. • bag : A container. • It is not ordered and contain duplicate elements. • sequence : An container. • It is ordered and contain duplicate elements. collection  asSet() : can be used to convert any collection into a set (remove duplicates).

  8. implies operator,  operator • Implies: •  • Operations on collections. • Do not mix ‘’ with ‘implies’ as in logical notation!

  9. Collection Operations • <collection> → … → isEmpty( ) → notEmpty ( ) → exists ( e:T | <b.e.>)  isUnique(e:T | <v.e>) Boolean: → forAll ( e:T* | <b.e.>)  forAll(e:T1,f;T2|<b.e.>) → excludes ( object ) → includes ( object ) → includesAll ( collection ) → count ( object ) Numeral: → size ( ) → sum ( ) → select ( e:T | <b.e.>)  asSet() Collections:→ reject ( e:T | <b.e.>) including(object), excluding(object) → collect ( e:T | <v.e.>) includingAll(collection), excludingAll(collection) Generic:→ iterate ( e:T1; r:T2 = <v.e.> | <v.e.>) • b.e. stands for: boolean expression • v.e. stands for: value expression (as seen in the Structural Modeling, Part B lecture (slides 59-60)).

  10. Collection Operations - Select select ( e:T | <b.e.>): SQL-like select, returning a sub-collection of the original. animals select(a:Animal | a.family == “Reptile”) reject ( e:T | <b.e.>) is select’s complementary operation. From a collection of animals – to a <= collection of animals! • e stands for iterator expression, • T stands for type. • b.e. stands for: boolean expression • v.e. stands for: value expression

  11. Collection Operations - Collect collect ( e:T | <v.e.>): from every member of the collection, take something. Thus this operation might return a collection of different type than the original! animals collect(a:Animal | a.name) From a collection of animals– to a collection of strings! Shorthand Notation:students.studentCard – only in ‘collect’!!! Alice Bob Carol DaveEve Mallory Peggy VictorTrent Trudy Walter Paul

  12. OCL – expression • Operations above objects: <class>.<attribute> <class>.<role>.<attribute> (preferred) <class>.<class name>.<attribute> • context Employee inv: self.age>17 andself.age<=100 • context Employee inv: self.age>30 orself.workplace.number<5 • context Department inv: self.number<5 orself.employee select(age<=30)size()=0 • context Department inv: self.employeeexist(job=“manager”) andself.company.year<=self.year • context Company inv: self.department.employeeforAll(age<=67) • Operations above collections: <collection>→<operation> • דוגמאות: • גיל העובדים חייב להיות בין 18 ל- 100 • גיל מינימלי של העובדים במחלקות 5 ומעלה חייב להיות לפחות 31. • לכל מחלקה חייב להיות "מנהל" ושנת הקמת המחלקה לא מוקדם משנת הקמת החברה • פנסיונרים לא מועסקים בחברה

  13. Example 1: treating collections as instances, enumerations • If a person has a wife, she must be female and the person must be male. • context Person inv: WifenotEmpty() implies (wife.gender=Gender::female and self.gender=Gender::male) //note: after a collection has been validated to be of size 1, it can be treated as an instance! • If a person has a husband, he must be male and the person must be female. • context Person inv: HusbandnotEmpty() implies (husband.gender=Gender::male and self.gender=Gender::female)

  14. Example 1 (Cont.) • If a person is male he can't have pink car • context Person inv: (self.gender==Gender::male) implies (self.ownsselect(c|c.color==‘pink’)size()=0) • If a person is unemployed he can't own cars in value of more then 500,000$ • context Person inv: (self.unemployed) implies (self.owns collect(c | c.value)  sum()<= 500000) • A person can’t have cars in more then 3 different colors • context Person inv: self.owns  collect(c|c.color) asSet()  size()<=3 (אם האדם מובטל אז) (יוצר אוסף של ערכי הרכבים שברשותו) (חשב סכום ערכי הרכבים תבדוק שהוא קטן מ-500000) (יוצר אוסף של צבעי הרכבים שברשותו) (הפוך את האוסף ל set - השאר אחד מכל צבע) (ספירת כמות צבעים ובדיקה שאין יותר מ 3 צבעים)

  15. Example 1 (Cont.) • A person between the age of 0 to 18 can’t own a yellow car while person between the age of 18 and 21 can own one yellow car at most and a person older then 21 can own as many yellow cars as he like. • context Person inv: let amountOfYellowCars : Integer = self.ownsselect(c:Car | c.color = “yellow”)size() in if (self.age < 18) then(amountOfYellowCars = 0) else if (self.age < 21) then (amountOfYellowCars <= 1) else true endif endif

  16. Example 2 • The sum of the values of all securities must be at least 20% more than the amount of the credit. • context Credit invsufficientSecurities: securities.Value  sum()>self.Amount * 1.2 • A credit of a given customer can only be secured by securities that are owned by the given customer. (הלוואה של לקוח נתון מאובטחת רק ע"י ערבויות ששייכות לאותו הלקוח ) • context Credit invonlyOwnedSecurities: securities.ownerforAll(aa:Customer|aa = self.customer) • aa is instance of owner!!!!

  17. Instance and Type Operations • Instances have the following operations: self.oclIsTypeOf(T) returns true iff self is of type T self.oclIsKindOf(T) returns true iff (self is of type T) V (self’s subtype of T) Self.oclAsType(T) used for casting (for instance, from Abstract class to Subclass). • Types have the ‘allInstances’ member: T.allInstances returns a collection of all T instances. Example: “At least 1 animal has to eat meat”: Animals.allInstances exists(a:Animal|a.eats == “Meat”) In reality, this is usually frowned upon (we’ll see it later!)

  18. Example 3: allInstances, type checks, recursion • All people should be married • context Person inv: Person.allInstancesforAll(p:Person | p.married) • In a Class all the Attributes have different names. • context Class inv: self.features select(f|f.oclIsTypeOf(Attribute))isUnique(a:Attribute|a.name) (collection of Attributes) (collection of Features)

  19. Association Class * • Navigate to an association class: • If the context is Teacher, you could navigate to the association class with the expression: self.Room. • This expression would result in a collection of all the room assignments for all the courses to which the teacher is assigned. • Navigate from an association class to either end of the association: • Starting with a context of the Room class, the expressions: self.instructor self.course is valid. • Navigating from an association class always results in a single object.

  20. Example 4 - Train • All trains must own at least one wagon • context Train invatLeastOneWagon:self.wagon  size() >= 1 • A wagon and its successor wagon should belong to the same train • context Wagon invbelongToTheSameTrain:self.succ  notEmpty() implies self.succ.train = self.train • All the trains will have the same number of wagons • context Train invsameNumberOfWagons:Train.allInstances  forAll(x:Train,y:Train | x.wagonsize() = y.wagonsize() )

  21. Example 4 - Train • There do not exists two different wagons directly linked to each other in a cyclic way • not necessary : consider two wagon instances w1,w2. • If these two instances are linked with an ‘Order’ link, one has to assume the role of ‘succ’ and the second must assume the role of ‘pred’ – two can’t close a cycle! • But how do you prevent a cycle of > 2 wagons? • Context Train invNoCycles: Wagoncollect(w | w.succ)size() = Wagon.size()-1 Will this work?

  22. Advanced Topics in OCL • Types and Subtypes via oclIsTypeOf and oclIsKindOf

  23. Advanced Topics in OCL

  24. Advanced Topics in OCL

  25. Advanced Topics in OCL • Preconditions, Postconditions, Operations (sic, p.155) • Navigation into class method using ‘::’ • post : result = participants  This is how we define the result! • Keywords: <attribute>@pre , pre , post , result .

  26. Advanced Topics in OCL • Avoid allInstances (Warmer and Kleppe, p.67) “A Person has no more than 2 parents:” context Person Inv: parents  size() <= 2 context Person Inv: Person.allInstancesforAll(p:Person|p.parentssize()<= 2) “The use of allInstances is discouraged, because it makes the invariant more complex [even to the point of hiding it.]... “In most systems... It is difficult to find all instances of a class. Unless an explicit tracking device keeps a record of all instances of a certain class as they are created and deleted, there is no way to find them. Thus, there is no way to implement the invariant using a programming language equivalent to the allInstances operation.

  27. Advanced Topics in OCL And this is just the beginning... • Handling message-passing between objects • Tuples and Tuple Types • Unvefined Values: the OclVoid type • Retyping or Casting Unfortunately, these along with many other OCL features are out of the scope of our course.

More Related