Reification (computer science)
Reification is the process by which an abstract idea about a computer program is turned into an explicit data model or other object created in a programming language. A computable/addressable object — a resource — is created in a system as a proxy for a non computable/addressable object. By means of reification, something that was previously implicit, unexpressed, and possibly inexpressible is explicitly formulated and made available to conceptual (logical or computational) manipulation. Informally, reification is often referred to as "making something a first-class citizen" within the scope of a particular system. Some aspect of a system can be reified at language design time, which is related to reflection in programming languages. It can be applied as a stepwise refinement at system design time. Reification is one of the most frequently used techniques of conceptual analysis and knowledge representation.
Reification and reflective programming languages
In the context of programming languages, reification is the process by which a user program or any aspect of a programming language that was implicit in the translated program and the run-time system, are expressed in the language itself. This process makes it available to the program, which can inspect all these aspects as ordinary data. In reflective languages, reification data is causally connected to the related reified aspect such that a modification to one of them affects the other. Therefore, the reification data is always a faithful representation of the related reified aspect. Reification data is often said to be made a first class object. Reification, at least partially, has been experienced in many languages to date: in early Lisp dialects and in current Prolog dialects, programs have been treated as data, although the causal connection has often been left to the responsibility of the programmer. In Smalltalk-80, the compiler from the source text to bytecode has been part of the run-time system since the very first implementations of the language.[1]
- The C programming language reifies the low-level detail of memory addresses.
- Many programming language designs encapsulate the details of memory allocation in the compiler and the run-time system. In the design of the C programming language, the memory address is reified and is available for direct manipulation by other language constructs. For example, the following code may be used when implementing a memory-mapped device driver. The buffer pointer is a proxy for the memory address 0xB800000.
char* buffer = (char*) 0xB800000; buffer[0] = 10;
- Functional programming languages based on lambda-calculus reify the concept of a procedure abstraction and procedure application in the form of the Lambda expression.
- The Scheme programming language reifies continuations (approximately, the call stack).
- In C#, reification is used to make parametric polymorphism implemented as generics as a first-class feature of the language.
- In Java programming language, there exist "reifiable types" that are "completely available at run time" (i.e. their information is not erased during compilation).[2]
- REBOL reifies code as data and vice-versa.
- Many languages, such as Curl, JavaScript, and Lisp provide an
eval
orevaluate
procedure that effectively reifies the language interpreter. - The Logtalk framework for Prolog offers a means to explore reification in the context of logic programming.
- Smalltalk and Actor languages permit the reification of blocks and messages,[3] which are equivalent of lambda expressions in Lisp, and thisContext which is a reification of the current executing block.
Data reification vs. data refinement
Data reification (stepwise refinement) involves finding a more concrete representation of the abstract data types used in a formal specification.
Data reification is the terminology of the Vienna Development Method (VDM) that most other people would call data refinement. An example is taking a step towards an implementation by replacing a data representation without a counterpart in the intended implementation language, such as sets, by one that does have a counterpart (such as maps with fixed domains that can be implemented by arrays), or at least one that is closer to having a counterpart, such as sequences. The VDM community prefers the word "reification" over "refinement", as the process has more to do with concretising an idea than with refining it.[4]
For similar usages, see Reification (linguistics).
Reification in conceptual modeling
Reification is widely used in conceptual modeling.[5] Reifying a relationship means viewing it as an entity. The purpose of reifying a relationship is to make it explicit, when additional information needs to be added to it. Consider the relationship typeIsMemberOf(member:Person, Committee)
. An instance of IsMemberOf
is a relationship that represents the fact that a person is a member of a committee. The figure below shows an example population of IsMemberOf
relationship in tabular form. Person P1 is a member of committees C1 and C2. Person P2 is a member of committee C1 only. The same fact, however, could also be viewed as an entity. Viewing a relationship as an entity, one can say that the entity reifies the relationship. This is called reification of a relationship. Like any other entity, it must be an instance of an entity type. In the present example, the entity type has been named Membership
. For each instance of IsMemberOf
, there is one and only one instance of Membership
, and vice versa. Now, it becomes possible to add more information to the original relationship. As an example, we can express the fact that "person p1 was nominated to be the member of committee c1 by person p2". Reified relationship Membership
can be used as the source of a new relationship IsNominatedBy(Membership, Person)
.
For related usages see Reification (knowledge representation).
Reification in Unified Modeling Language (UML)
Reification on Semantic Web
RDF and OWL
In Semantic Web languages, such as Resource Description Framework (RDF) and Web Ontology Language (OWL), a statement is a binary relation. It is used to link two individuals or an individual and a value. Applications sometimes need to describe other RDF statements, for instance, to record information like when statements were made, or who made them, which is sometimes called "provenance" information. As an example, we may want to represent properties of a relation, such as our certainty about it, severity or strength of a relation, relevance of a relation, and so on.
The example from the conceptual modeling section describes a particular person with URIref person:p1
, who is a member of the committee:c1
. The RDF triple from that description is
person:p1 committee:isMemberOf committee:c1 .
It might be useful to record who nominated this particular person to this committee.
RDF provides a built-in vocabulary intended for describing RDF statements. A description of a statement using this vocabulary is called a reification of the statement. The RDF reification vocabulary consists of the type rdf:Statement
, and the properties rdf:subject
, rdf:predicate
, and rdf:object
.[7]
Using the reification vocabulary, a reification of the statement about the person's membership would be given by assigning the statement a URIref such as committee:membership12345
so that describing statements can be written as follows:
committee:membership12345 rdf:type rdf:Statement . committee:membership12345 rdf:subject person:p1 . committee:membership12345 rdf:predicate committee:isMemberOf . committee:membership12345 rdf:object committee:c1 .
These statements say that the resource identified by the URIref committee:membership12345
is an RDF statement, that the subject of the statement refers to the resource identified by person:p1
, the predicate of the statement refers to the resource identified by committee:isMemberOf
, and the object of the statement refers to the resource committee:c1
. Assuming that the original statement is actually identified by committee:membership12345
, it should be clear by comparing the original statement with the reification that the reification actually does describe it. The conventional use of the RDF reification vocabulary always involves describing a statement using four statements in this pattern. Therefore, they are sometimes referred to as the "reification quad".[7]
Using reification according to this convention, we could record the fact that person:p2
made the nomination described by the original statement by adding the statement
person:p2 committee:nominated committee:membership12345
It is important to note that in the conventional use of reification, the subject of the reification triples is assumed to identify a particular instance of a triple in a particular RDF document, rather than some arbitrary triple having the same subject, predicate, and object. This particular convention is used because reification is intended for expressing properties such as dates of composition and source information, as in the examples given already, and these properties need to be applied to specific instances of triples.
The power of the reification vocabulary in RDF is restricted by the lack of a built-in means for assigning URIrefs to statements, so in order to express "provenance" information of this kind in RDF, one has to use some mechanism (outside of RDF) to assign URIs to individual RDF statements, then make further statements about those individual statements, using their URIs to identify them.[7]
Reification in Topic Maps
In an XML Topic Map (XTM), only a topic can have a name or play a role in an association. One may use an association to make an assertion about a topic, but one cannot directly make assertions about that assertion. However, it is possible to create a topic that reifies a non-topic construct in a map, thus enabling the association to be named and treated as a topic itself.[8]
Reification and n-ary relations
In Semantic Web languages, such as RDF and OWL, a property is a binary relation used to link two individuals or an individual and a value. However, in some cases, the natural and convenient way to represent certain concepts is to use relations to link an individual to more than just one individual or value. These relations are called n-ary relations. Examples are representing relations among multiple individuals, such as a committee, a person who is a committee member and another person who has nominated the first person to become the committee member, or a buyer, a seller, and an object that was bought when describing a purchase of a book.
A more general approach to reification is to create an explicit new class and n new properties to represent an n-ary relation, making an instance of the relation linking the n individuals an instance of this class. This approach can also be used to represent provenance information and other properties for an individual relation instance.[9]
:p1 a :Person ; :has_membership _:membership_12345 . _:membership_12345 a :Membership ; :committee :c1; :nominated_by :p2 .
Reification vs. quotation
It is also important to note that the reification described here is not the same as "quotation" found in other languages. Instead, the reification describes the relationship between a particular instance of a triple and the resources the triple refers to. The reification can be read intuitively as saying "this RDF triple talks about these things", rather than (as in quotation) "this RDF triple has this form." For instance, in the reification example used in this section, the triple:
committee:membership12345 rdf:subject person:p1 .
describing the rdf:subject
of the original statement says that the subject of the statement is the resource (the person) identified by the URIref person:p1
. It does not state that the subject of the statement is the URIref itself (i.e., a string beginning with certain characters), as quotation would.
See also
Look up reification in Wiktionary, the free dictionary. |
- Denotational semantics
- Formal semantics of programming languages
- Meta-circular evaluator
- Metamodeling
- Metaobject
- Metaprogramming
- Normalization by evaluation
- Operational semantics
- Reflection (computer science)
- Resource Description Framework
- Self-interpreter
- Topic Maps
References
- ↑ J. Malenfant, M. Jacques and F.-N. Demers, A Tutorial on Behavioral Reflection and its Implementation
- ↑ The Java Language Specification, section 4.7, Java SE 7 Edition
- ↑ "Smalltalk Blocks And Closures". C2.com. 2009-10-15. Retrieved 2010-10-09.
- ↑ Formal Methods Europe, Frequently Asked Questions, part 13.
- ↑ Antoni Olivé, Conceptual Modeling of Information Systems, Springer Verlag, 2007.
- ↑ Unified Modeling Language, UML superstructure, Object Management Group, 2007-11-02.
- ↑ 7.0 7.1 7.2 "RDF Primer". W3.org. Retrieved 2010-10-09.
- ↑ Practical Introduction into Topic Maps.
- ↑ "W3C Defining N-ary relations on Semantic Web". W3.org. Retrieved 2010-10-09.