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h1. SpeADL Reference Guide
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In SpeADL, a set of abstractions are provided to describe [[SpeADL Minus Reference|typical component-oriented architectures]].
On top of these, SpeADL introduces additional abstractions that complete them in order to describe dynamic architectures, in particular for Multi-Agent Systems.
The motivations behind these abstractions are fully discussed in the "Ph.D. thesis":http://www.irit.fr/~Victor.Noel/PhD/Dissertation that led to the creation of MAY, here we stay at the user level.
The main idea with these abstractions is to define software components, called ecosystems, that are able to dynamically create other software components, called species, and to link such components to their ecosystem in a safe and controlled manner.
For example, one could define a Bank component containing a Database and that creates Account component which themselves requires access to the Database.
Or one could define a MAS component that creates Agent components (themselves architectured as desired) connected to simulated situated entities living in a common 2D environment.
With these abstractions, one can actually implement its own interconnection mechanism between the dynamically created components and their creating component.
This enables for example to cleanly and easily implement any needed interaction mechanism in a MAS when there exists no agent-oriented framework proposing it, to develop domain-specific relations between the agents and their environment or more generally to easily separate concerns (the agents architecture, the simulated agents, the communication) by composing them while explicitly taking into account the 1..N relation existing between an ecosystem and its species.
This document focuses on SpeADL, for the implementation, the reader can refer to the [[SpeADL Java Reference|Java for SpeADL reference guide]].
h2. SpeADL⁻
It is needed to understand the content of the [[SpeADL Minus Reference|SpeADL⁻ Reference Guide]] before reading the current document.
h2. Ecosystem and Species Definition
From an external point of view, an ecosystem is exactly similar to a component: it has provided ports that can be accessed and required ports that must be connected.
It has a name, can have type parameters and be a specialisation of another component.
It has an implementation in Java, it can be used as a part of another component (or ecosystem) or instantiated directly if it has no required ports.
Its only specificity is that it can contain what is called species, a special kind of component definitions that can only be defined in an ecosystem.
Actually, a component is just an ecosystem without any species.
Species are to ecosystems what Java non-static inner classes are to Java classes: they are components that can only be instantiated from within an ecosystem instance.
Because of this particular relation to ecosystems, species can access elements inside the ecosystem in two different ways:
* Directly to the parts and ports of the ecosystem.
* Indirectly through a special construct called _uses_ that enables to take into account the dynamic creation aspects of the species to:
** Build tailored ecosystem-species relations.
** Build tailored inter-species relations mediated by the ecosystem.
Uses are discussed [[SpeADL Full Reference#The Use Abstraction|below]].
h3. Keywords
An ecosystem definition is declared with the keyword *ecosystem* followed by a name, optional type parameters and optional specialization.
Provided and required ports can be declared as with normal component definitions with the keywords *provides* and *requires*.
Parts can be declared as with normal component definitions with the keyword *part*.
A part can reference a typical component or an ecosystem.
A species is declared inside an ecosystem with the keyword *species* followed by a name starting with a capital.
It can't have type parameters but follows those of its ecosystem, and cannot specialise another component.
A species can have parameters (for initialisation) in-between inbetween *( * and * )* and separated by *, *: they are of the form _name: Type, name2: Type2_.
Provided and required ports can be declared as with normal component definitions with the keywords *provides* and *requires*.
Parts can be declared as with normal component definitions with the keyword *part*.
Uses are declared with the keyword *use* as discussed [[SpeADL Full Reference#The Use Abstraction|below]].
h3. Details
Declaring a species means that an instance of the ecosystem containing it will be able to create new instances of the species at runtime.
Such species will be considered strongly linked to the containing ecosystem instance that created them: this is a thus 1..N relation.
The bindings of the parts can point to ports inside the species, as with a normal component, but also to ports inside the ecosystem containing the species.
They can NOT point to other species of the ecosystem (for inter-species connection, one must exploit the use abstraction detailed [[SpeADL Full Reference#The Use Abstraction|below]]).
h3. Example
<pre>
namespace simple.ecos {
ecosystem MyFirstEco {
species S(name: String) {
provides p1: AJavaInterface = c.portName
provides p2: AJavaInterface
requires p3: AnotherJavaInterface
part c: MyBeautifulComponent {
bind anotherPortName to p3
}
}
}
}
</pre>
h2. The Use Abstraction
As we said previously, species can only be defined inside ecosystems.
Such a relation can be exploited either:
* At the SpeADL level with the bindings and delegation from the species to the ecosystem as described [[SpeADL Full Reference#Ecosystem and Species Definition|above]].
* At a higher-level using advanced interconnection mechanisms between ecosystem and their species.
We focus on the second point in this section with the *use* abstraction.
It is a construct that enables to:
* Build tailored ecosystem-species relations.
* Build tailored inter-species relations mediated by the ecosystem.
h3. Keywords
Inside a species, a special type of part (and for the rest it behave exactly as a part) can be declared using the keyword *use* followed by a name without capital letter.
It follows the syntax _use name: partName.SpeciesName_ where:
* _partName_ is the name of a part in the ecosystem containing the current species and whose type is an ecosystem.
* _SpeciesName_ is the name of a species declared in the ecosystem of _partName_.
* And optionally a list of arguments for the species parameters: one can refer to the parameters of the containing species only.
h3. Details
The important point about the *use* abstraction is that it relies on the definition of ecosystem and species: it is a way to recursively exploit an ecosystem and its species in another ecosystem and its species.
The contained ecosystem and its parts are instantiated with the containing ecosystem, and its species instantiated with the species that use them.
h3. Example
<pre>
namespace simple.ecos {
ecosystem MySecondEco {
part e: MyFirstEco
species S(name: String) {
part c: MySimpleComponent
use s: e.S(name) {
bind p3 to c.p1
}
}
}
}
</pre>