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== Creating the Service Implementation == | == Creating the Service Implementation == | ||
Revision as of 10:53, 28 September 2007
In this tutorial I'll demonstrate the process for integrating third-party services inside EiffelStudio and hooking up internal parts of EiffelStudio to use the new service.
Before we begin you should have a fundamental understanding of what a service is and a clear understanding of the guidelines for writing service
Note: This tutorial is followed up by another tutorial for creating an EiffelStudio tool for displaying information published by the service.
Contents
Getting Started
When extending EiffelStudio, it is a good idea to separate your code from the EiffelStudio code. The Customizing the EiffelStudio Project page describes the process of doing this.
Overview
IN this tutorial we'll be showing you how to create a service use to log messages. Although the service contains a simple interface, it's actually quite complete in that the service itself will make use of the Event List Service as a demonstration how reusing services in EiffelStudio can make development strategies quicker and easier.
Creating a Service Interface
The very first step in creating a service is to define a service interface. A service interface should contain either all deferred routines or deferred routines with only effective routines that reference the service interface directly or other interfaces in the EiffelStudio ecosystem.
Note: It is important to realize that the interface abstraction allows for complete freedom to be given to the implementation of the service. Implementation details are not public and should remain that way. No consumer of the service should ever attempt to reverse assign a retrieve service to the implementation class but to the interface class. Consumer of the service should not have to rely on the implementation details of a service and doing so will potentially break code in the future or if a different implementation is returned than expected when querying to a specific service.
This tutorial is creating a logger service so it makes senses we should create a service interface class call LOGGER_SERVICE_S. Create a deferred class LOGGER_SERVICE_S in your extension project cluster.
Note: All service interfaces, by convention, are suffixed _SERVICE_S. This makes it clear to a consumer that they are using a service interface. All other related interfaces for the service should be suffixed _I to indicate an interface.
The first step is to define LOGGER_SERVICE_S as an actually service. In order to achieve this LOGGER_SERVICE_S must inherit SERVICE_I. As of EiffelStudio 6.1 SERVICE_I does not contain any effective or deferred routines, it's merley a place holder for future additions and a method of classification.
So now you should have something looking like this:
deferred class LOGGER_SERVICE_S inherit SERVICE_I end
Of course this doesn't do all that much, in fact it does nothing! We need to add a way to log messages. For this we'll add put routines; put_message and put_message_with_severity.
A logger shouldn't just simply log a message, it's just not powerful enough. So the put routines for the service should permit categorization and even indicate a level of severity incase a logger service consumer deems that a particular entry deserves more or less attention. Fortunatly Griffin offeres built in support for categorization and a basic priority level, which will serve quite nicely as a translation for a log item severity level.
Categories and Priorities
ENVIRONMENT_CATEGORIES is a class consisting of constants defining EiffelStudio environment region categories. There are constants for the compiler, debugger the editor and so forth. As extenders you are free to add your own categories and utilize them. Any class can access a single instance of ENVIRONMENT_CATEGORIES through SHARED_ENVIRONMENT_CATEGORIES.categories.
PRIORITY_LEVELS is another class containing constants for basic priority levels; high, normal and low. Any class can access a single instance of PRIORITY_LEVELS through SHARED_PRIORITY_LEVELS.priorities.
We want to make use of both categories and priorites in the logger service so LOGGER_SERVICE_S should inherit both SHARED_ENVIRONMENT_CATEGORIES and SHARED_PRIORITY_LEVELS.
Warning: Inheriting the shared classes should not affect the service interface so be sure to set the export status when inheriting those shared classes!
ENVIRONMENT_CATEGORIES and PRIORITY_LEVELS in addition to being constant definition classes, also contain validation functions to ensure a category identifier is a known identifiers, as it true for a priorty identifier. In the practice of Design by Contract our service routines are going to be passed a category and severity (priority) level, which require validation. Given SHARED_ENVIRONMENT_CATEGORIES.categories and SHARED_PRIORITY_LEVELS.priorities are not exported members of the interface we'll need to create proxy query functions, which is actually good design. These proxy function can then be used an service routine preconditions and can also be used by a service consumer client when making the call to one of the service routines.
Below is the complete code for adding categories and severity levels to the logger service interface. The proxy function is_valid_category has been added for category validation and is_valid_severity_level added for severity level validation.
deferred class LOGGER_SERVICE_I inherit SERVICE_I SHARED_ENVIRONMENT_CATEGORIES export {NONE} all end SHARED_PRIORITY_LEVELS export {NONE} all end feature -- Query frozen is_valid_category (a_cat: NATURAL_8): BOOLEAN -- Determines if `a_cat' is a valid logger category -- -- `a_cat': A category identifier to validate. -- `Result': True to indicate the category is valid; False otherwise. do Result := categories.is_valid_category (a_cat) end frozen is_valid_severity_level (a_level: INTEGER_8): BOOLEAN -- Determines if `a_level' is a valid severity level -- -- `a_level': A severity level. -- `Result': True to indicate the level of severity is valid; False otherwise. do Result := priorities.is_valid_priority_level (a_level) end end
Adding Service Functionality
Still, the logger service has not functionality. The service interface is now at a stage where the actual service routines can be added. We're going to add three routines; two to log messages and another to clear the log.
Note: The logger created here is very simple. It would be highly likely for you to add routines to flush log entries and even provide a mutable status attribute to set an auto-flush mode. It's actually important to realize your design before releasing a service in a version of EiffelStudio, because once released then service interface may be used by others. In our case there is no flush routine, which means a later implementation of the logger service who's message flushing capabilities are expensive, will suffer bad performance penalties. The interface was already released without a flush routine so now a flush has to be performed every time a log message is added because existing consumer clients are not using the new service version's flush routine.
When designing a service it's necessary to think how the service might be used by EiffelStudio, the Eiffel compiler and what might happen in the future. In the case of the logger you may have one EiffelStudio SKU that presents logged information in an embedded EiffelStudio tool, in another it may be pushed to the OS event log, in another it may be written to a file. Or, you might have all three available and a preference to indicate how added log messages are handled.
Here is the basic interface with the previous interface members elided for clarity.
deferred class LOGGER_SERVICE_I ... feature -- Extension put_message (a_msg: STRING_32; a_cat: NATURAL_8) -- Logs a message. -- -- `a_msg': Message text to log. -- `a_cat': A message category, see {ENVIRONMENT_CATEGORIES}. require a_msg_attached: a_msg /= Void not_a_msg_is_empty: not a_msg.is_empty a_cat_is_empty_is_valid_category: is_valid_category (a_cat) do put_message_with_severity (a_msg, a_cat, {PRIORITY_LEVELS}.normal) end put_message_with_severity (a_msg: STRING_32; a_cat: NATURAL_8; a_level: INTEGER_8) -- Logs a message specifying a severity level. -- -- `a_msg': Message text to log. -- `a_cat': A message category, see {ENVIRONMENT_CATEGORIES}. -- `a_level': A severity level for the message, See {PRIORITY_LEVELS}. require a_msg_attached: a_msg /= Void not_a_msg_is_empty: not a_msg.is_empty a_cat_is_empty_is_valid_category: is_valid_category (a_cat) a_level_is_valid_severity_level: is_valid_severity_level (a_level) deferred end feature -- Removal clear_log -- Clear any cached log data deferred end ... end
Adding Events
To be a good service citizen of EiffelStudio it is highly desirable to provide events service consumers can hook up to. Not all services have events but it so happens that the logger service is interacted with in a way that tools or other services may be interested in; a message is added and messaged are cleared.
Griffin provides its own even mechanism using EVENT_TYPE, which is an extremely powerful event abstraction that is simple to use.
To facilitate event hooks we'll add the events message_logged_events to notify subscribes when a message is added, and cleared_events to notify subscribes when a clear operation was performed.
deferred class LOGGER_SERVICE_I ... feature -- Events message_logged_events: EVENT_TYPE [TUPLE [service: LOGGER_SERVICE_I; message: STRING_32; category: NATURAL_8; level: INTEGER_8]] -- Events called when a message has been logged deferred result_attached: Result /= Void result_consistent: Result = Result end cleared_events: EVENT_TYPE [TUPLE [service: LOGGER_SERVICE_I]] -- Events called when the messages have been cleared from the log deferred result_attached: Result /= Void result_consistent: Result = Result end ... end
Note, the events are deferred also. This given a logger service implementation the option to implement the events as attributes or deferred-evaluation functions, for performance and memory footprint optimizations. The postcondition result_consistent ensures that any deferred-evaluation/once-per-object implementation actually performs the correct per-object caching.
Respecting the events could be implemented using lazy-evaluation no class invariants have been added to ensure the event attributes are always attached, because (A) in deferred-evaluation they may not be attached until called and (B) evaluating the class invariants would remove any optimization benefits of deferred-evaluation as they would be evaluated after the service has been created.
Note: For events implemented as attributes it's desirable for the implementation to add the appropriate invariants to ensure the events at in an attached state after the logger service has been created.
Creating a Consumer
Consumer helper classes are a nice addition to adding a new service. It makes working with an added service so much easier and it take only a minute to create a consumer.
A consumer is a helper class that provides cached access to a service. Service consumers can then simply inherit one or more consumer helper classes to gain access to desired services.
Note: As a convention all service consumer helper classes are suffix by _SERVICE_CONSUMER.
Below is literally all the code you need to create a consumer helper class for your service. It simply renames the features from a generic class base class as to provide non-conflict feature names when using multiple service consumer helper classes from a single class.
class LOGGER_SERVICE_CONSUMER inherit SERVICE_CONSUMER [LOGGER_SERVICE_S] rename service as logger_service, is_service_available as is_logger_service_available, internal_service as internal_logger_service end end
Creating the Service Implementation
The ground work has been laid for basing the implementation of the logger service on. In this tutorial we are simply going to make use of the Event List Service, which does an fantastic job of proving facilities for adding and removing added object (call event items). It means our implementation is basically a proxy to another service. Using another service saves time and effort to go from design to integration. The additional benefit of using the Event List Service is that an EiffelStudio tool can be created very quick to display the logged messages because EiffelStudio foundations provides base implementation for tools built using consuming the Event List Service (for those that are interested see ES_EVENT_LIST_TOOL_BASE and ES_CLICKABLE_EVENT_LIST_TOOL_BASE.)
Below is the stub implementation for the effective logger service.
Note: Just like service interfaces, interface and service consumers, effective service classes should always yield the name of the service with the _S suffix removed.
class LOGGER_SERVICE inherit LOGGER_SERVICE_S SAFE_AUTO_DISPOSABLE EVENT_LIST_SERVICE_CONSUMER export {NONE} all end create make feature {NONE} -- Initialization make -- Initialize logger service. do -- Initialize events create message_logged_events create cleared_events -- Set up automatic cleaning of event object auto_dispose (message_logged_events) auto_dispose (cleared_events) end feature -- Extension put_message_with_severity (a_msg: STRING_32; a_cat: NATURAL_8; a_level: INTEGER_8) -- Logs a message specifying a severity level. -- -- `a_msg': Message text to log. -- `a_cat': A optional message category. -- `a_level': A serverity level for the message. do end feature -- Removal clear_log -- Clear any cached log data do end feature -- Events message_logged_events: EVENT_TYPE [TUPLE [service: LOGGER_SERVICE_S; message: STRING_32; category: NATURAL_8; level: INTEGER_8]] -- Events called when a message has been logged cleared_events: EVENT_TYPE [TUPLE [service: LOGGER_SERVICE_S]] -- Events called when the messages have been cleared from the log invariant message_logged_events_attached: not is_zombie implies message_logged_events /= Void cleared_events_attached: not is_zombie implies cleard_events /= Void end
The service is an implementation of the previously defined logger service interface (LOGGER_SERVICE_S) so we have to inherit the interface so later the SOA core can validated the service when it's registered, but more on this later.
Also inherited is SAFE_AUTO_DISPOSABLE, a memory resource management base class for handling automatically disposing of class objects when then class object itself is disposed. As the service hosts two events, after creation of those event they are added to the auto-dispose pool to automatic disposal. This saves the logger service from having to implement safe_disposable and performing the resource management manually. For more information on resource management see EiffelStudio Memory Management.
As stated this implementation is actually using the Event List Service so access to the service is provided using the service consumer EVENT_LIST_SERVICE_CONSUMER.
A creation routine make has been added for the class to create the implemented event attribute objects and register them with the auto disposable pool from SAFE_AUTO_DISPOSABLE. As recommended the events, implemented as attributes, have class invariants to ensure their validity for the life time of the object.
All the other routines are empty stubs waiting to be implemented.
