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NAME="OVERVIEW.APPROACHES">Approaches to Configurability</H1

><P

>The purpose of configurability is to control the behavior of

components. A scheduler component may or may not support time slicing;

it may or may not support multiple priorities; it may or may not

perform error checking on arguments passed to the scheduler routines.

In the context of a desktop application a button widget may contain

some text or it may contain a picture; the text may be displayed in a

variety of fonts; the foreground and background color may vary. When

an application uses a component there must be some way of specifying

the desired behavior. The component writer has no way of knowing in

advance exactly how a particular component will end up being used.</P

><P

>One way to control the behavior is at run time. The application

creates an instance of a button object, and then instructs this object

to display either text or a picture. No special effort by the

application developer is required, since a button can always support

all desired behavior. There is of course a major disadvantage in

terms of the size of the final application image: the code that gets

linked with the application has to provide support for all possible

behavior, even if the application does not require it.</P

><P

>Another approach is to control the behavior at link-time, typically

by using inheritance in an object-oriented language. The button

library provides an abstract base class <TT

CLASS="CLASSNAME"

>Button</TT

>

and derived classes <TT

CLASS="CLASSNAME"

>TextButton</TT

> and

<TT

CLASS="CLASSNAME"

>PictureButton</TT

>. If an application only uses text

buttons then it will only create objects of type

<TT

CLASS="CLASSNAME"

>TextButton</TT

>, and the code for the

<TT

CLASS="CLASSNAME"

>PictureButton</TT

> class does not get used. In

many cases this approach works rather well and reduces the final image

size, but there are limitations. The main one is that you can only

have so many derived classes before the system gets unmanageable: a

derived class

<TT

CLASS="CLASSNAME"

>TextButtonUsingABorderWidthOfOnePlusAWhiteBackgroundAndBlackForegroundAndATwelvePointTimesFontAndNoErrorCheckingOrAssertions</TT

>

is not particularly sensible as far as most application developers are

concerned.</P

><P

>The <SPAN

CLASS="APPLICATION"

>eCos</SPAN

> component framework allows the behavior of components to

be controlled at an even earlier time: when the component source code

gets compiled and turned into a library. The button component could

provide options, for example an option that only text buttons need to

be supported. The component gets built and becomes part of a library

intended specifically for the application, and the library will

contain only the code that is required by this application and nothing

else. A different application with different requirements would need

its own version of the library, configured separately.</P

><P

>In theory compile-time configurability should give the best possible

results in terms of code size, because it allows code to be controlled

at the individual statement level rather than at the function or

object level. Consider an example more closely related to embedded

systems, a package to support multi-threading. A standard routine

within such a package allows applications to kill threads

asynchronously: the POSIX routine for this is

<TT

CLASS="FUNCTION"

>pthread_cancel</TT

>; the equivalent routine in µITRON

is <TT

CLASS="FUNCTION"

>ter_tsk</TT

>. These routines themselves tend to

involve a significant amount of code, but that is not the real

problem: other parts of the system require extra code and data for the

kill routine to be able to function correctly. For example if a thread

is blocked while waiting on a mutex and is killed off by another

thread then the kill operation may have to do two things: remove the

thread from the mutex's queue of waiting threads; and undo the

effects, if any, of priority inheritance. The implementation requires

extra fields in the thread data structure so that the kill routine

knows about the thread's current state, and extra code in the mutex

routines to fill in and clear these extra fields correctly.</P

><P

>Most embedded applications do not require the ability to kill off a

thread asynchronously, and hence the kill routine will not get linked

into the final application image. Without compile-time configurability

this would still mean that the mutex code and similar parts of the

system contain code and data that serve no useful purpose in this

application. The <SPAN

CLASS="APPLICATION"

>eCos</SPAN

> approach allows the user to select that the

thread kill functionality is not required, and all the components can

adapt to this at compile-time. For example the code in the mutex lock

routine contains statements to support the killing of threads, but

these statements will only get compiled in if that functionality is

required. The overall result is that the final application image

contains only the code and data that is really needed for the

application to work, and nothing else.</P

><P

>Of course there are complications. To return to the button example,

the application code might only use text buttons directly, but it

might also use some higher-level widget such as a file selector and

this file selector might require buttons with pictures. Therefore the

button code must still be compiled to support pictures as well as

text. The configuration tools must be aware of the dependencies

between components and ensure that the internal constraints are met,

as well as the external requirements of the application code. An area

of particular concern is conflicting requirements: a button component

might be written in such a way that it can only support either text

buttons or picture buttons, but not both in one application; this

would represent a weakness in the component itself rather than in the

component framework as a whole.</P

><P

>Compile-time configurability is not intended to replace the other

approaches but rather to complement them. There will be times when

run-time selection of behavior is desirable: for example an

application may need to be able to change the baud rate of a serial

line, and the system must then provide a way of doing this at

run-time. There will also be times when link-time selection is

desirable: for example a C library might provide two different random

number routines <TT

CLASS="FUNCTION"

>rand</TT

> and

<TT

CLASS="FUNCTION"

>lrand48</TT

>; these do not affect other code so there

is no good reason for the C library component not to provide both of

these, and allow the application code to use none, one, or both of

them as appropriate; any unused functions will just get eliminated at

link-time. Compile-time selection of behavior is another option, and

it can be the most powerful one of the three and the best suited to

embedded systems development.</P

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