C2 Supplement

1. C2 Supplement Jie Ren ICS 123, Fall 2002 Based on Eric Dashofy’s slides for ICS 123, Spring 2000

2. One more example

3. Holds architecture descriptions ArchStudio 3 Manages open issues Critics watch architecture for problems Manages design critics Architecture-to-implementation mappings GUIs for various high-level tools Graphical and syntax-directed editors Manages open files and tools

4. Review of C2 Constraints and Properties

5. A Quick Look at the C2 Style • Asynchronous, event-based communication among autonomous components, mediated by active connectors • No component-component links • Event-flow rules: • Hierarchical application Connector Notifications fall “pull” Requests rise Component “push” Connector

6. Review: C2 Constraints • Components & connectors have two interfaces (top & bottom) • Components must only communicate through a connector • Components may have 0-1 connector connected to each interface • Connectors may have as many components on top & bottom as they want • All communication through INDEPENDENT messages • NO PASSING POINTERS!

7. C2 Constraints (cont). • Substrate Independence • Make assumptions about what components above you can do for you (but not necessarily which specific components those are) • Make no assumptions about what components are below you • Up & Down communication only • No side-side communication

8. Leveraging C2 Constraints • The connector-connector link can be a powerful thing • If you have a component that merely passes messages untouched, consider linking connectors • Also, there are lots of interesting configurations that are non-obvious!

9. Another interesting configuration

10. Circular dependence • What if you have two (or more) components that you really believe are circularly dependent? • Five common solutions… B A

11. Solution 1-3: A+B Solution 1: Merge A B Solution 3: Remove other dependency Solution 2: Remove one dependency A B

12. Solutions 4 & 5: ADT Solution 4:(Data Integration) Communicate via shared data (mini-blackboard style) B A B A Solution 5:(Control Integration) Use a manager that can make requests of either component; notifications are turned into invocations. Manager

13. Try to avoid this… BAD“Magic Mirror” or “Reflectors” approach: Component simply“reflects” notifications or requestsinto the opposite type of message. B A

14. Using c2.fw to Implement C2-style Architectures

15. Overview • For this assignment, you will: • Be implementing the component behaviors of a C2-style architecture using the c2.fw framework • Have components send out messages when necessary • Have components handle all necessary messages • You will NOT: • Create new components • Create or modify an architectural configuration • Create connectors

16. What is c2.fw? • An architecture framework, in Java, that is faithful to the C2 architectural style • “Killer” Features • Pluggable topology manager • You will be using the default topology manager • Pluggable message queueing policy • You will be using one-queue-per-interface • Pluggable threading policy • You will be using one-thread-per-brick • More clear support for brick lifecycles and architecture configurations • You will be using the lifecycles, configurations are taken care of for you • Better support for distribution, dynamism than in previous frameworks • You will not be using this for this assignment

17. Important Classes • AbstractC2Brick • The base class of all C2 bricks • Two interfaces: topIface and bottomIface • Important Methods: • init() - override • Called when the brick is instantiated • begin() - override • Called when the brick is welded into place, send initial messages here • end() - override • Called when the brick is about to be unwelded, send final messages here. Not used in this assignment. • destroy() - override • Called when this brick is about to be destroyed. Not used in this assignment.

18. AbstractC2Brick (cont). • More important methods… • sendToAll(Message m, Interface iface) - Call • Sends message m out the interface iface • iface can be ‘topIface’ for requests or ‘bottomIface’ for notifications • handle(Message m) – Override • Called automatically by the framework when a message arrives on any interface • This is where all message handling is done • getIdentifier() – Override • Call this to get the identifier (class Identifier) of the brick • Call toString() on the identifier to get a string representation of it

19. Notes on Connectors • You will rely on existing connector class • The connector will forward all messages to the other side • Request forwarded upward • Notification forwarded downward

20. More Important Classes • NamedPropertyMessage • A C2 message with a name and a property list • Properties have string names and either simple-type or serializable Object parameters • DO NOT PASS PONINTERS IN PARAMETERS! //Create a named property message NamedPropertyMessage npm = new NamedPropertyMessage(“ChatText”); //Add some parameters npm.addParameter(“Text”, text); npm.addParameter(“Sender”, “Strong Bad”); //Send it upward as a request sendToAll(npm, topIface);

21. More about Message • c2.fw.Message is an interface • Operations are simple: • Where did this message come from? • getSource() • Where did it go? • getDestination() • Is this the same as another message? • equals() • Make me a copy • duplicate() • Source and destination are returned as BrickInterfaceIdPairs • Each contains a brick identifier and an interface identifier • Useful for checking if an incoming message was a request or a notification • If destination interface ID equals(TOP_INTERFACE_ID) it’s a notification • If destination interface ID equals(BOTTOM_INTERFACE_ID) it’s a request

22. Subclassing NamedPropertyMessage • This is possible, but some boilerplate code is required • Enforces better type safety, makes code clearer • You don’t have to do this in this assignment. Using parameters to achieve a goal. • Think how a message flows