The latest adaptation of my exploratory project is known as
the Message Service.
The Message Service (MS) is a framework for the delivery of
individual messages from a producer component to the consumer components that
have registered for the topic of the message.
The delivery will occur within the application of the producer as well
as other (remote) applications based upon the Message Service.
The Message Service is a Microsoft Windows PC based
application written almost exclusively in Ada.
However, it consigns Operating System (OS) interfaces to particular Ada
packages so that it can easily be supported by Linux as well (and has been in
the past).
The Message Service uses its own mechanism for the delivery
of local messages and Microsoft Pipes for delivery between applications. (Linux named pipes will support delivery
between applications when running under Linux as the OS. This was implemented in previous versions of
the exploratory project so the modifications are known.) In addition, previous versions also supported
the use of TCP/IP for delivery between applications –
either hosted by a single PC or multiple PCs.
The OS interfaces are mainly hidden within the Message
Service framework and not accessible to the User Components. Where the term User Components refers to OS
threads whose purpose is to support the objective of the application. This adaptation moved Remote IO to a user
component. To support the move of this
feature specific OS interfaces were made visible via the Remote_Itf package.
This adaptation of the exploratory project consigns the
actual message delivery between applications to an input/output (IO) user
component. Previously the delivery of
topic messages between applications was implemented within the framework. With this modification of the project
architecture other such user components can be developed to interface to
non-framework based applications – for instance, A661 display applications. Or, at least, separate Ada packages can be
implemented within the Remote IO component to interface to each particular
category of remote application.
The User Components are Installed by an application specific
Ada package that are invoked directly from the Ada main procedure of the Ada
based application. Otherwise, each
application contains common code. The
OS folders that contain the application consist of the common code as well as
folders that are specific to the application.
The OS interface code is written to recognize which operating system the
application is running under. If this
wasn't so builds could be done by operating system by also having OS specific
folders.
The current architecture has the following
components/threads (figure Message Service Overall Structure) where the IO
component has multiple threads. The
framework has the threads and packages of figure Message Service Framework
Structure.
The above figure illustrates six User Components along with
the Apps package and the IO Framework Friend Component which is actually a
component with subcomponents to be illustrated below. It is considered a friend of the Message Service Framework since
it is installed by the Framework rather than the Apps package that is invoked
by the Ada main procedure to install the user components of the particular
application. As a friend component it
enjoys access to selected IO procedures/functions and uses an OS event to start
the framework Support thread and is likewise started by an OS event rather than
the framework topics selected by the user components.
The Apps package is invoked when the OS launches the
application. It reads the Configuration
file to obtain the allowed applications with their executable names and whether
the application is a Message Service Framework based application or another
non-MS application such as an A661 Display application and the communication
methods that the application supports.
The Apps package uses this information to build a table including the
information. The Apps package contains
an application unique procedure that invokes the Install procedures of the User
Components of the application.
The messages between the IO component and the framework are
communicated via queues where the address of the message is passed in the queue
rather than the message data to avoid unnecessary copying of the message
data. Note: "To Queue" is an
abbreviation of "To IO Framework Component" and similarly for
"From Queue". The Start Event
causes the thread to recover from an OS Wait and to read the queue for
attributes of received messages to be delivered to local user components or
transmitted to a remote application.
The messages between the user components are delivered via a
framework topic feature. This mechanism
is supported by each user component registering with the framework which topics
it will publish and which it wants to have delivered to it. The framework keeps track of this and when a
user component publishes a topic it delivers the message data of the topic to
the components that registered to consume it.
An application that isn't based upon the Message Service
framework will, of course, have its own mechanism to deliver messages. Such applications will communicate with MS
applications via communication buses such as pipes and TCP/IP and the MS
framework will deliver the received message as a topic to the user component
that has registered to consume it.
Likewise, topic messages to be transmitted will be converted as
necessary for the particular remote application by that application's IO
component.
The diagram of the IO Framework Friend Component is below.
The IO Framework Friend Component consists of
1) the Remote IO thread that receives OS wakeup events from
the MS Framework to transmit messages to the remote applications,
2) a Receive thread for each framework based remote
application of the configuration, and
3) the Monitor thread to watch for disconnects between the
local application and a remote application.
The Receive threads queue notifications of messages received
from remote applications as they are received.
Queuing of a message sends an OS wakeup event to the Remote thread of
the MS Framework. When awoken from its
Wait, the Remote thread will publish the topic data portion of the received
message to the user components that have registered for the topic.
Likewise, when user components publish topics that a remote
application has registered to consume, the OS Framework will deliver the topic
message to the Remote component which will then queue it for delivery to the IO
Framework Friend Component. This will
send the OS wakeup event of the Remote IO thread which will then cause the
message to be transmitted.
Both the Receive threads and Transmit use particular IO
driver packages. For instance, there
will be a Receive thread for each supported method of external communications
for each remote application of the configuration. Transmit, on the other hand, will select the supported method of
communications and invoke its transmit routine.
The Remote IO thread can also be awakened by the Monitor
thread to treat changes in the status of the connection between the local
application and a remote application.
Likewise, the dequeued To Remote IO items can indicate errors that should
be logged rather than a message to be transmitted.
The Remote_Itf package is a friend interface to particular
OS functions and procedures otherwise hidden within the Framework. It also contains the circular queues and the
mechanism for sending the OS wakeup events to either the Remote thread of the
Framework or the Remote_IO thread. The
OS event selected depends upon which queue had an added message element.
There are other support procedures, of course, besides those
illustrated.
The Message Service Framework is
illustrated above.
The User Components interface with the Message Service
Framework via the Itf package which, in turn, invokes the Itf package
procedures of the Message-Itf package that is a child package of Message.
If the request is to register the User Component or one of
the topics it will produce or consume, the Message-Itf procedure will invoke
the Scheduler package to allocate the component or the Message-Registry package
to update the topic tables. Since these
requests precede the starting of the threads, each such request will be treated
without thread concurrency. That is,
these requests run under the Operating System launch thread where there are no
other running threads.
If the request is to obtain a message buffer, publish an
instance of a topic (the message buffer), or get any recently published topics
that the user component has registered to consume the Message-Itf package
buffers the request and sends an OS wakeup event to the Support thread within
the Message-Support package. The
Support thread then invokes one of Message-Delivery procedures. Since the Support thread is the highest
priority thread, only one such topic request will be treated at a time.
After all User Components of the particular application have
been installed, Scheduler will start the User Component threads as well as the
framework threads. Besides the Support
and Remote threads, these include the Event Driven and the three different
periodic threads that implement the delivery of topics to the various user
components.
Note: If a user component has installed itself to run as a
Periodic thread it will run as one of the Scheduler Periodic threads. Similarly for Aperiodic and Pseudo
Periodic. If the user component
installed itself as an Event Driven thread, it will be run as one of the Scheduler
Event Driven threads when its topic is published. That is, the Scheduler creates a thread farm with an instance of
each kind of thread as the user components install themselves. Any particular User Component thread is a
thread from the Scheduler thread farm.
Periodic threads are run at a rate specified by the
install. Aperiodic threads run and then
Scheduler Aperiodic delays for the specified interval and then activates the
user component entry point once again.
Pseudo Periodic threads wait for their OS start event every time they
return from the user component. Thus
they are all similar but have a different mechanism to provide their periodicity.
No matter the cause for how a user component is run, the
availability of the topic instances (i.e., messages) disappears after the user
component returns control to the Scheduler.
Following the return the Scheduler thread invokes a Message Release
procedure that releases the message data buffer of the topic that was
temporarily allocated to the user component.
So if a component needs to retain particular data from a received
message it must copy it from the message.
A user component is provided a pointer to the message data
buffer upon its return from its Itf request for a particular topic (or for any
newly available topic). It can then
type cast the pointer to the format of the topic's data and examine it without
the need to copy it from the data buffer.
When the component is going to publish a topic message it, of course,
must copy data values into the data buffer via the supplied pointer.
Each consumer of a particular topic is provided its own data
buffer each time the topic is published.
Therefore, a component can attempt to modify the message that it
receives but such a modification will not affect the message delivered to
another component and will also not be useful.
In this manner the Message Service attempts to avoid excessive copying
of data which can effect performance.
This feature also exists for the messages created to be
transmitted to other applications or those received from other
applications. Since the Remote and
Receive threads do not know in advance which topic will be delivered to the
Remote_IO thread for transmit or from a Receive thread for delivery to a local
user consumer component, these message buffers are pre-allocated at the maximum
size. As a buffer is needed for
transmit or for the next receive, the assigned buffer is marked as no longer
available. To avoid copying only the
address of the buffer is passed in the From Remote IO or To Remote IO
queues. After the data has been
transmitted by Remote IO or published by Remote for delivery to a local user
component a Release command is queued to enable the buffer to once again be
marked as available.
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