Changes to the Mathematical Language of Event-B: Difference between revisions

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This document describes the evolution of the Event-B mathematical language that will soon take place. The previous version of the language will still be supported.
This document describes the evolution of the Event-B mathematical language that happened in release 1.0.0.  See [[Event-B_Mathematical_Language]] for a full description of the language.


== Identity and Projections ==
== Generic Identity and Projections ==


Three operators were still unary while they could be atomic:
Three operators were still unary while they could be atomic and generic:
* the identity relation <math>\id</math>
* the identity relation <math>\id</math>
* the first projection  <math>\prjone</math>
* the first projection  <math>\prjone</math>
* the second projection <math>\prjtwo</math>
* the second projection <math>\prjtwo</math>


These operators are defined as follows:
These operators are defined as follows in the old version:


  <math>
  <math>
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which is a particular case of a set being defined by listing all its elements.
which is a particular case of a set being defined by listing all its elements.
=== Partition Wizard ===
{{TODO}}


== Operator Associativity ==
== Operator Associativity ==
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* bijection
* bijection


have no more relative priorities and lose associativity. Instead, users have to make it explicit by entering parenthesis in formulas.
have no more relative priorities and loose associativity. Instead, users have to make it explicit by entering parenthesis in formulas.
 
[[Category:Event-B]]
[[Category:User documentation]]

Latest revision as of 12:38, 17 April 2009

This document describes the evolution of the Event-B mathematical language that happened in release 1.0.0. See Event-B_Mathematical_Language for a full description of the language.

Generic Identity and Projections

Three operators were still unary while they could be atomic and generic:

  • the identity relation \id
  • the first projection \prjone
  • the second projection \prjtwo

These operators are defined as follows in the old version:


 \begin{matrix}
  E\mapsto F &\in\id(S) && E\in S\;\land\; F = E\\
  (E\mapsto F)\mapsto G &\in\prjone(r)
  && E\mapsto F\in r\;\land\; G = E\\
  (E\mapsto F)\mapsto G &\in\prjtwo(r)
  && E\mapsto F\in r\;\land\; G = F    .
 \end{matrix}
 

If we drop the parameter, we get much more straightforward definitions that capture the essence of the operator. The new definitions are


 \begin{matrix}
 E\mapsto F &\in\id && E = F\\
 (E\mapsto F)\mapsto G &\in\prjone && E = G\\
 (E\mapsto F)\mapsto G &\in\prjtwo && F = G    .
 \end{matrix}
 

We have the following equivalence between the old and the new versions of the operators


 \begin{matrix}
    \textbf{Old Version} & \textbf{New Version}\\
    \id(S)  & S\domres id\\
    \prjone(r) & r\domres\prjone\\
    \prjtwo(r) & r\domres\prjtwo  .
 \end{matrix}
 

Moreover, in the case where the parameter is not needed, then it can be dropped altogether: no domain restriction is needed. For instance, to express that a relation r is irreflexive, one would now write r\binter\id = \emptyset.

Partition

A new partition predicate is introduced. It is intended to provide an easier way to enter enumerated sets, while getting rid of the \frac{n(n-1)}{2} axioms needed to express pairwise distinctness (or disjointness). The partition operator is defined as follows:


 \begin{array}{ll}
 partition(E_0, E_1, \ldots, E_n)\defi &
  E_0 = E_1\bunion \cdots\bunion E_n \\ &
  \;\land\; E_1\binter E_2=\emptyset
  \;\land\;\cdots
  \;\land\; E_{n-1}\binter E_n = \emptyset \\ &
  (\;\land\; i \ne j \limp E_i \binter E_j = \emptyset ) \\
 \end{array}
 


where the E_i are expressions bearing the same type.

Then, we can enter into a context :


  \begin{array}{ll}
    \mathsf{set}  & S\\
    \mathsf{constant}  & a_1\\
    \vdots & \vdots\\
    \mathsf{constant}  & a_n\\
    \mathsf{axiom}  & partition(S, \{a_1\}, \ldots, \{a_n\})
  \end{array}
 

which is a particular case of a set being defined by listing all its elements.


Partition Wizard

TODO

Operator Associativity

Operators used to build sets of relations or functions, viz.

  • relation
  • total relation
  • surjective relation
  • total surjective relation
  • partial function
  • total function
  • partial injection
  • total injection
  • partial surjection
  • total surjection
  • bijection

have no more relative priorities and loose associativity. Instead, users have to make it explicit by entering parenthesis in formulas.