1 / 40

System Models

System Models. Object-Oriented Software Engineering CS350. System Model. Conceptual model that describes and represents a system Required to describe and represent multiple views Describes and represents the multiple views possibly using two different approaches Non-architectural

maxwell-sanders
Télécharger la présentation

System Models

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. System Models Object-Oriented Software EngineeringCS350

  2. System Model • Conceptual model that describes and represents a system • Required to describe and represent multiple views • Describes and represents the multiple views possibly using two different approaches • Non-architectural • Architectural

  3. System Model • A system comprises multiple views such as … • Planning • Requirement (analysis) • Design • Implementation • Deployment • Structure • Behavior • Input data • Output data

  4. Data Flow Diagram(DFD) • Graphical representation of the "flow" of data through an information system, modeling its process aspects • Often a preliminary step used to create an overview of the system which can later be elaborate • DFDs can also be used for the visualization of data processing (structured design)

  5. Data Flow Diagram (DFD) • Shows what kinds of information will be input to and output from the system • Where the data will come from and go to • Where the data will be stored • Does not show information about the timing of processes, or information about whether processes will operate in sequence or in parallel (which is shown on a flowchart)

  6. Data Flow Diagram(DFD) Function Input/Output File/Database Flow

  7. Data Flow Diagram(DFD)

  8. State Machine • Used to give an abstract description of the behavior of a system • This behavior is analyzed and represented in series of events, that could occur in one or more possible states • Each diagram usually represents objects of a single class and track the different states of its objects through the system

  9. State Machine • Can be used to graphically represent finite state machines(C.E. Shannon & W. Weaver, "The Mathematical Theory of Communication“, 1949) • Another possible representation is the State transition table

  10. Examples

  11. Examples

  12. State Diagram Vs. Flowchart • State machine performs actions in response to explicit events • Flowchart does not need explicit events but rather transitions from node to node in its graph automatically upon completion of activities

  13. Exercise • Create a state diagram to model the operation of a simple cell phone • The cell phone has an on/off switch • It has a numeric keypad that produces a keypad press event with a digit as its argument • The phone has a three-way switch that is set to ringing, vibrating, or both; it determines the action of the phone when a call comes in • The phone also has an action button that (a) initiates a call when seven digits have been entered, (b) answers a call when the phone is ringing or vibrating, and (c) terminates a call (hangs up) if a call is in progress • If the action button is pressed when fewer than seven digits have been entered and the phone is not ringing, the digits are erased (this is how dialing mistakes are corrected) • Finally, the phone has a display that shows the digits that have been pressed so far, if any • Use at least one composite state in your model

  14. Events & States

  15. Event • Something that happens • Affects the system • Type of occurrence rather than actual occurrence • Can have parameters • Placed in an event queue when received • Becomes current event when dispatched • Is consumed after being processed

  16. State • Captures the relevant aspects of the system's history • In programming, instead of recording using a multitude of variables, flags, and convoluted logic, you rely mainly on just one state variable • State machines supplemented with variables are called extended state machines

  17. State Vs. Extended State • State • Qualitative aspects of a system • Extended state • Quantitative aspects of a system

  18. State Vs. Extended State • Example: A state machine representing the behavior of a pocket calculator • Could use an extended state variable DecimalFlagto remember that the user entered the decimal point to avoid entering multiple decimal points in the same number • A better solution is to observe that entering a decimal point really leads to a distinct state entering_the_fractional_part_of_a_numberin which the calculator ignores decimal points

  19. State Vs. Extended State • Why? • It eliminates one extended state variable and the need to initialize and test it • The state-based solution is more robust because the context information is used very locally (only in this particular state) and is discarded as soon as it becomes irrelevant

  20. Guard Condition • Needed when using an extended state machine • Boolean expressions • Evaluated dynamically based on the value of extended state variables and event parameters • Think IF-THEN-ELSE

  21. Action • Performed when an event is dispatched • Examples: • Changing a variable • Performing I/O • Invoking a function • Generating another event instance • Changing to another state

  22. Transition • Aka state transition • Switching from one state to another • Caused by a trigger event • Can have a guard in extended state machines(BTW, guard expressions should have NO side effects, such as affecting other guards)

  23. Run-to-Completion (RTC) • All state machine formalisms assume that a state machine completes processing of each event before it can start processing the next event • This is called run-to-completion • Requires an event queue • During event processing, the system is unresponsive, so the ill-defined state has no practical significance

  24. Hierarchically Nested States • A state machine will attempt to handle any event in the context of the substate, which conceptually is at the lower level of the hierarchy

  25. Hierarchically Nested States • If the substate "result" does not prescribe how to handle the event, the event is not • Rather, it is handled at the higher level context of the superstate "on"

  26. Hierarchically Nested States • This system is in state "result" as well as "on“ • State nesting is not limited to one level

  27. Hierarchically Nested States • States that contain other states are called composite states • States without internal structure are called simple states • A nested state is called a direct substate when it is not contained by any other state • Otherwise, it is referred to as a transitively nested substate

  28. Hierarchically Nested States • Top state • Abstract root of state machine • Programming by difference • Ignoring commonly handled events, which are automatically handled by higher-level states

  29. Orthogonal Regions • Address the frequent problem of a combinatorial increase in the number of states when the behavior of a system is fragmented into independent, concurrently active parts

  30. Orthogonal Regions • Here the complete state is the Cartesian product of the two components and four states

  31. Entry/Exit Actions • Entry action - entry to a state • Exit action - exit from a state • Provide means for guaranteed initialization and cleanup

  32. Internal Transitions • Internal actions that execute but do not lead to a change of state (state transition) • In the absence of entry and exit actions, internal transitions would be identical to self-transitions

  33. Transition Execution Sequence • Evaluate the guard condition associated with the transition and perform the following steps only if the guard evaluates to TRUE • Exit the source state configuration • Execute the actions associated with the transition • Enter the target state configuration

  34. Local Vs. external Transitions • Doesn’t cause exit from and reentry to the main source state if … • the main target state is a substate of the main source • the main target is a superstate of the main source state

  35. Event Deferral • Sometimes an event arrives when a state machine cannot handle the event • Every state can include a clause[event list]/defer • If an event in the current state’s deferred event list occurs, the event will be saved (deferred) for future processing until a state is entered that does not list the event in its deferred event list

  36. Other Symbols • Initial pseudostate • Terminate pseudostate • Entry point • Exit point • Choice

  37. Other Symbols • Fork • Join • Final state

  38. Exercise • Interpret the following diagrams

  39. Exercise

  40. Exercise

More Related