Rewriting rules for event model decomposition: Difference between revisions

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imported>Pascal
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|<math>v \bcmin E</math>||<math>v \bcmsuch v' \in E</math>||<font id="rule_3">Rule 3</font>
|<math>v \bcmin E</math>||<math>v \bcmsuch v' \in E</math>||<font id="rule_3">Rule 3</font>
|}
|}
Thus, each Event-B assignment can be expressed in a "becomes such that" form, and more precisely as <math>v_1,...,v_n \bcmsuch P(v_1,...v_n,v_1',...v_n')</math>, where <math>P</math> is a before-after predicate.


== Rewriting rules on Event-B actions ==
== Rewriting rules on Event-B actions ==

Revision as of 12:44, 7 July 2009

The purpose of this page is to list and justify the rewriting / simplification rules applied in the event model decomposition, when building the actions of an external event of a sub-machine from those of an initial event in the non-decomposed machine.

Equivalence relation

It is possible to define an equivalence relation on the Event-B actions, and by restriction on the Event-B assignments. Two actions are considered as being equivalent if the proof obligations generated for these actions are logically equivalent.

This relation is represented with the \defi symbol.

Rewriting rules on Event-B assignments

As detailed in the modelling language, the Event-B assignments are formed of two parts:

  • A left-hand side, which is a list of free identifiers.
  • A right-hand side.

There are various kinds of assignments:

  • The \bcmsuch ("becomes such that") assignment is the most general (non-deterministic) assignment, where a predicate is given on the before and after values of assigned identifiers. The after values of the assigned identifiers are denoted by a primed identifier whose prefix is the assigned identifier.
  • The \bcmeq ("becomes equal to") assignment is the deterministic assignment where an expression is given for each assigned identifier.
  • The \bcmin ("becomes member of") assignment is the set-based (non-deterministic) assignment, where a set expression is given for the assigned identifier.

Let v and w be variables, and E and F be expressions. In the following table, the left-hand assignments are equivalent (\defi) to the right-hand ones (see the B-book):

v \bcmeq E v \bcmsuch v' = E Rule 1
v(E) \bcmeq F v \bcmeq v \ovl \{E \mapsto F\} Rule 2
v \bcmin E v \bcmsuch v' \in E Rule 3

Rewriting rules on Event-B actions

Let v and w be variables, E and F be expressions, and P and Q be predicates. The left-hand actions are equivalent (\defi) to the right-hand ones:

\begin{array}{ll}v\!\!\! &\bcmsuch P(v,v')\\ w\!\!\! &\bcmsuch Q(w,w') \end{array} v,w \bcmsuch P(v,v') \land Q(w,w') Rule 4
v,w \bcmeq E,F \begin{array}{ll}v\!\!\! &\bcmeq E\\ w\!\!\! &\bcmeq F \end{array} Rule 5

Simplification rules on Event-B predicates

Let x_i, y and z be variables, and P and Q be predicates.

  • Rule 6: If P(x_1,...,x_n,y)~ is equal to y = Q(x_1,...,x_n)~, then the \exists y.P(x1,...,x_n,y) predicate is true, and it may be deleted in conjunctive predicates (\land) where it appears.
  • Rule 7: The (\exists z \qdot P(x_1,...,x_n,z) \land Q(y_1,...,y_m)) predicate, where z \notin \{x_1,...,x_n,y_1,...,y_m\}, may be rewritten as (\exists z \qdot P(x_1,...,x_n,z)) \land Q(y_1,...,y_m).
  • Rule 8: The \exists z \qdot P(x_1,...,x_n,z) predicate may be deleted in conjunctive predicates where it appears if the y \bcmsuch P(x_1,...,x_n,y') assignment is among the actions of the initial event. It indeed is nothing else but the feasibility (FIS) proof obligation for such an assignment, and a model to be decomposed is assumed to be proved (see the section related to the proof obligations in the event model decomposition).

Example

Let a, b and x be variables, and P and Q be predicates.

a,b \bcmsuch \exists x \qdot P(a,a',x) \land Q(b,b')
\defi (Rule 7)
a,b \bcmsuch (\exists x \qdot P(a,a',x)) \land Q(b,b')
\defi (Rule 4)
\begin{array}{ll}a\!\!\! &\bcmsuch \exists x \qdot P(a,a',x)\\ b\!\!\! &\bcmsuch Q(b,b')\end{array}