Revision as of 14:16, 29 June 2011

Objective

This page describes the design of the reasoner MembershipGoal and its associated tactic MembershipGoalTac.
This reasoner discharges sequent whose goal denotes a membership which can be inferred with hypotheses. Here an basic example of what it discharges :
$H,\quad x\in S,\quad S\subset T,\quad T\subseteq U \quad\vdash x\in U$

Analysis

Such sequent are proved by PP and ML. But, these provers have both drawbacks :

All the visible are added as needed hypotheses, which is most of the time not the case.
They take quite consequent time to prove it (even with the basic example given here above, the difference in time execution is noticeable).
If there are too many hypotheses, or if the expression of the $x$ is too complicated, they may not prove it.

This is particularly true when in the list of inclusion expressions of each side of the relation are not equal. For example : $H,\quad a\in S,\quad S\subset T_1\cap T_2,\quad T_1\cup T_3\subseteq U\quad\vdash a\in U$

Such a reasoner contributes to prove more Proof Obligations automatically, faster and with fewer needed hypotheses which makes proof rule more legible and proof replay less sensitive to modifications.

Tactic

This part explains how the tactic (MembershipGoalTac) associated to the reasoner MembershipGoal is working.

Goal

The tactic (as the reasoner) should works only on goals such as :

$<goal>\quad:\quad<member>\quad\in\quad<set>$
$<member>\quad:\quad UE\quad\mid\quad FA$
$<set>\quad:\quad UE\otimes UE\quad\mid\quad UE\parallel UE\quad\mid\quad <union>\quad\left[\cup <union>\right]$
$<union>\quad:\quad<cprod>\quad\left[\cprod<cprod>\right]$
$<cprod>\quad:\quad<set>\quad\mid\quad UE$
$UE\quad:\quad Every~untagged~expressions$
$FA\quad:\quad Every~expressions~tagged~as~a~function~application$

For example those examples matches with the definition here above :

$f(x)\in g\otimes h$
$x\in A\cprod\left(B\cup C\right)$

Every other goals denoting a membership should be re-

Hypotheses

The hard part is to find the hypotheses leading to discharge the sequent. To do so, the tactic recovers three kinds of hypotheses :

the ones related to the left member of the goal (this is the start point):
- $x\in \cdots$
- $\cdots\mapsto x\mapsto\cdots\in\cdots$
- $\left\{\cdots, x,\cdots\right\}\subseteq\cdots$
the ones denoting inclusion (all but the ones matching the description of the first point) :
- $\cdots\subset\cdots$
- $\cdots\subseteq\cdots$
the one from which we can infer inclusion :
- $f\in A\;op\;B \quad\vdash\quad f\subseteq A\cprod B\quad\bigl($ where $op$ is one of : $\quad\rel, \trel, \srel, \strel, \pfun, \tfun, \pinj, \tinj, \psur, \tsur, \tbij\bigr)$
- $f\subseteq A\cprod B \quad\vdash\quad f\otimes f\subseteq A\cprod\left(B\cprod B\right)$

Then, it will search a link between those hypotheses so that the sequent can be discharged.

Find a path

Now that we recovered all the hypotheses that could be useful for the reasoner, it just remains to find a path among the hypotheses leading to discharge the sequent. Depending on the relations on each side of the inclusion, we will act differently. $f$ always represent an expression (may be a domain, a range, etc.).

The following sequent is provable because .
- $x\in f,\quad \varphi (f)\subseteq g\quad\vdash\quad x\in g$
- $\varphi (f) = f\quad\mid\quad f\cup h \quad\mid\quad h\cup f \quad\mid\quad h\ovl f$
The following sequent is provable because .
- $x\in \psi (f),\quad f\subseteq g\quad\vdash\quad x\in g$
- $\psi (f) = f\quad\mid\quad f\cap h \quad\mid\quad h\cap f \quad\mid\quad f\setminus h \quad\mid\quad f\ransub A \quad\mid\quad f\ranres A \quad\mid\quad A\domsub f \quad\mid\quad A\domres f$
We can generalized the first two points. This is the Russian dolls system. We can easily prove a sequent with multiple inclusions by going from hypothesis to hypothesis.
- $x\in \psi (f),\quad \varphi (f)\subseteq g\quad\vdash\quad x\in g$
For some relations, positions are needed to be known to continue to find hypotheses, but it is not always necessary.
- $x\mapsto y\in f,\quad f\subseteq A\cprod B\quad\vdash\quad x\in A$
- $x\in dom(f),\quad f\subseteq A\cprod B\quad\vdash\quad x\in A$
- $x\in ran(f),\quad f\subseteq A\cprod B\quad\vdash\quad x\in B$
- $x\in f,\quad f\otimes g\subseteq A\cprod\left(B\cprod C\right)\quad\vdash\quad x\in A\cprod B$
- $x\in f,\quad f\parallel g\subseteq \left(A\cprod C\right)\cprod\left(B\cprod D\right)\quad\vdash\quad x\in A\cprod B$
Those rewrites can be useful when the Russian dolls system does not succeed.
- $dom(f)\cup dom(g) = dom(f\ovl g)$
- $ran(f)\cup ran(g)\subseteq ran(f\ovl g)$
- $dom(A\domres f) = dom(f)\cap A$
- $dom(A\domsub f) = dom(f)\setminus A$
- $ran(f\ranres A) = ran(f)\cap A$
- $ran(f\ransub A) = ran(f)\setminus A$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\subseteq A\cprod B$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f^{-1}\subseteq B\cprod A$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f[A]\subseteq B$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres prj1 = prj1\ranres f\subseteq A\cprod B\cprod A$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres prj2 = prj2\ranres f\subseteq A\cprod B\cprod B$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres id = id\ranres f\subseteq (A\cprod B)\cprod(A\cprod B)$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in B\;op_2\;C\;\lor\; g\subseteq B\cprod C \quad\vdash\quad f;g = g\circ f \subseteq A\cprod C$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in A\;op_2\;C\;\lor\; g\subseteq A\cprod C \quad\vdash\quad f\otimes g \subseteq A\cprod (B\cprod C)$
- $f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in C\;op_2\;D\;\lor\; g\subseteq C\cprod D \quad\vdash\quad f\parallel g \subseteq (A\cprod C)\cprod (B\cprod D)$
$\bigl($ where $op_1$ and $op_2$ are ones of : $\quad\rel, \trel, \srel, \strel, \pfun, \tfun, \pinj, \tinj, \psur, \tsur, \tbij\bigr)$

By using these inclusion and rewrites, it tries to find a path among the recovered hypotheses. Every hypotheses denoting an inclusion should be used only once. Every hypotheses from which new hypothesis can be inferred could be used as many times as wanted. Among all paths that lead to discharge the sequent, the tactic give the first it finds. Moreover, so that the reasoner does not do the same work as the tactic of writing new hypothesis, it gives all needed hypotheses and added hypotheses in the input.

Reasoner

This part describes how the reasoner works.

Goal

The goal must match the same kind of goal as describes in the tactic part.

Input

Because we do not want to do the job of re-writing, every added hypotheses used to discharge the sequent should be contained in the input (the reasoner must extend HypothesesReasoner) as well as hypotheses used to perform the re-writing and hypotheses used to discharge the sequent. Thus we get those obligations :

Every added hypotheses must be re-writable with hypotheses contained in the sequent and in the input.
Every added hypotheses should be used to discharge the sequent.
Hypotheses used to perform re-writing could be also used to discharge a sequent and may be used several times to prove that added hypotheses are re-writable.
Hypotheses used to discharge the sequent should be used only once in the path (no loop allowed).
It checks that with all these hypotheses can actually discharge the sequent

If all those tests pass, then the sequent is discharged. The added hypotheses are set as AddedHyps, and all the other hypotheses of the input are set as NeededHps.

@@ Line 1: / Line 1: @@
-==Introduction==
+= Objective =
-The measurement plugin to the RODIN platform will provide information both about the model itself and about the process of building the model. It has a double purpose:
+This page describes the design of the reasoner MembershipGoal and its associated tactic MembershipGoalTac.<br>
+This reasoner discharges sequent whose goal denotes a membership which can be inferred with hypotheses. Here an basic example of what it discharges :<br>
+<math>H,\quad x\in S,\quad S\subset T,\quad T\subseteq U \quad\vdash x\in U</math>
-* provide feedback to the user about the quality of the Event-B model he is building and about potential problems in it or in the way he is building it.
+= Analysis =
-* automate the data collection process for the measurement and assessment WP. This data collected will be analyzed to identify global transfer (increase in model quality, size, complexity,...), tool shortcomings (usability, prover), modelling issues (to be addressed by training, language, tool evolution,...), etc.
-This work is planned for project year 2. This chapter introduces the main requirements of the tool. A more detailed analysis is available in deliverables of the measurement WP:
+Such sequent are proved by PP and ML. But, these provers have both drawbacks :
+*All the visible are added as needed hypotheses, which is most of the time not the case.
+*They take quite consequent time to prove it (even with the basic example given here above, the difference in time execution is noticeable).
+*If there are too many hypotheses, or if the expression of the <math>x</math> is too complicated, they may not prove it.
+This is particularly true when in the list of inclusion expressions of each side of the relation are not equal. For example : <math>H,\quad a\in S,\quad S\subset T_1\cap T_2,\quad T_1\cup T_3\subseteq  U\quad\vdash a\in U</math>
+<p>
+Such a reasoner contributes to prove more Proof Obligations automatically, faster and with fewer needed hypotheses which makes proof rule more legible and proof replay less sensitive to modifications.
-* D7 for a state of the art about metrics for formal models
+= Tactic =
-* D10 for technologies identified to implement the plug-in
-==Requirements==
+This part explains how the tactic (MembershipGoalTac) associated to the reasoner MembershipGoal is working.
+== Goal ==
+The tactic (as the reasoner) should works only on goals such as :
+*<math><goal>\quad:\quad<member>\quad\in\quad<set></math>
+*<math><member>\quad:\quad UE\quad\mid\quad FA</math>
+*<math><set>\quad:\quad UE\otimes UE\quad\mid\quad UE\parallel UE\quad\mid\quad <union>\quad\left[\cup <union>\right]</math>
+*<math><union>\quad:\quad<cprod>\quad\left[\cprod<cprod>\right]</math>
+*<math><cprod>\quad:\quad<set>\quad\mid\quad UE</math>
+*<math>UE\quad:\quad Every~untagged~expressions</math>
+*<math>FA\quad:\quad Every~expressions~tagged~as~a~function~application</math>
+For example those examples matches with the definition here above :
+*<math>f(x)\in g\otimes h</math>
+*<math>x\in A\cprod\left(B\cup C\right)</math>
+Every other goals denoting a membership should be re-
+== Hypotheses ==
+The hard part is to find the hypotheses leading to discharge the sequent. To do so, the tactic recovers three kinds of hypotheses :
+#the ones related to the left member of the goal <math>\left( x\in S\right)</math> (this is the start point):
+#*<math>x\in \cdots</math>
+#*<math>\cdots\mapsto x\mapsto\cdots\in\cdots</math>
+#*<math>\left\{\cdots, x,\cdots\right\}\subseteq\cdots</math>
+#the ones denoting inclusion (all but the ones matching the description of the first point) :
+#*<math>\cdots\subset\cdots</math>
+#*<math>\cdots\subseteq\cdots</math>
+#the one from which we can infer inclusion :
+#*<math>f\in A\;op\;B \quad\vdash\quad f\subseteq A\cprod B\quad\bigl(</math> where <math>op</math>  is one of :<math>\quad\rel, \trel, \srel, \strel, \pfun, \tfun, \pinj, \tinj, \psur, \tsur, \tbij\bigr)</math>
+#*<math>f\subseteq A\cprod B \quad\vdash\quad f\otimes f\subseteq A\cprod\left(B\cprod B\right)</math>
+Then, it will search a link between those hypotheses so that the sequent can be discharged.
+== Find a path ==
+Now that we recovered all the hypotheses that could be useful for the reasoner, it <i>just</i> remains to find a path among the hypotheses leading to discharge the sequent. Depending on the relations on each side of the inclusion, we will act differently. <math>f</math> always represent an expression (may be a domain, a range, etc.).
+#The following sequent is provable because <math>f\subseteq \varphi (f)</math>.
+#*<math>x\in f,\quad \varphi (f)\subseteq g\quad\vdash\quad x\in g</math>
+#*<math>\varphi (f) = f\quad\mid\quad f\cup h \quad\mid\quad h\cup f \quad\mid\quad h\ovl f</math>
+#The following sequent is provable because <math>\psi (f)\subseteq f</math>.
+#*<math>x\in \psi (f),\quad f\subseteq g\quad\vdash\quad x\in g</math>
+#*<math>\psi (f) = f\quad\mid\quad f\cap h \quad\mid\quad h\cap f \quad\mid\quad f\setminus h \quad\mid\quad f\ransub A \quad\mid\quad f\ranres A \quad\mid\quad A\domsub f \quad\mid\quad A\domres f</math>
+#We can generalized the first two points. This is the Russian dolls system. We can easily prove a sequent with multiple inclusions by going from hypothesis to hypothesis.
+#*<math>x\in \psi (f),\quad \varphi (f)\subseteq g\quad\vdash\quad x\in g</math>
+#For some relations, <i>positions</i> are needed to be known to continue to find hypotheses, but it is not always necessary.
+#*<math>x\mapsto y\in f,\quad f\subseteq A\cprod B\quad\vdash\quad x\in A</math>
+#*<math>x\in dom(f),\quad f\subseteq A\cprod B\quad\vdash\quad x\in A</math>
+#*<math>x\in ran(f),\quad f\subseteq A\cprod B\quad\vdash\quad x\in B</math>
+#*<math>x\in f,\quad f\otimes g\subseteq A\cprod\left(B\cprod C\right)\quad\vdash\quad x\in A\cprod B</math>
+#*<math>x\in f,\quad f\parallel g\subseteq \left(A\cprod C\right)\cprod\left(B\cprod D\right)\quad\vdash\quad x\in A\cprod B</math>
+#Those rewrites can be useful when the Russian dolls system does not succeed.
+#*<math>dom(f)\cup dom(g) = dom(f\ovl g)</math>
+#*<math>ran(f)\cup ran(g)\subseteq ran(f\ovl g)</math>
+#*<math>dom(A\domres f) = dom(f)\cap A</math>
+#*<math>dom(A\domsub f) = dom(f)\setminus A</math>
+#*<math>ran(f\ranres A) = ran(f)\cap A</math>
+#*<math>ran(f\ransub A) = ran(f)\setminus A</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\subseteq A\cprod B</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f^{-1}\subseteq B\cprod A</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f[A]\subseteq B</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres prj1 = prj1\ranres f\subseteq A\cprod B\cprod A</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres prj2 = prj2\ranres f\subseteq A\cprod B\cprod B</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B\quad\vdash\quad f\domres id = id\ranres f\subseteq (A\cprod B)\cprod(A\cprod B)</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in B\;op_2\;C\;\lor\; g\subseteq B\cprod C \quad\vdash\quad f;g = g\circ f \subseteq A\cprod C</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in A\;op_2\;C\;\lor\; g\subseteq A\cprod C \quad\vdash\quad f\otimes g \subseteq A\cprod (B\cprod C)</math>
+#*<math>f\in A\;op_1\;B\;\lor\; f\subseteq A\cprod B,\quad g\in C\;op_2\;D\;\lor\; g\subseteq C\cprod D \quad\vdash\quad f\parallel g \subseteq (A\cprod C)\cprod (B\cprod D)</math>
+#:<math>\bigl(</math> where <math>op_1</math> and <math>op_2</math> are ones of :<math>\quad\rel, \trel, \srel, \strel, \pfun, \tfun, \pinj, \tinj, \psur, \tsur, \tbij\bigr)</math>
-The plug-in will fulfill the following functional requirements
+By using these inclusion and rewrites, it tries to find a path among the recovered hypotheses. Every hypotheses denoting an inclusion should be used only once. Every hypotheses from which new hypothesis can be inferred could be used as many times as wanted. Among all paths that lead to discharge the sequent, the tactic give the first it finds. Moreover, so that the reasoner does not do the same work as the tactic of writing new hypothesis, it gives all needed hypotheses and added hypotheses in the input.
-* evaluation of low-level model metrics, such as number of events, refinements, etc
+= Reasoner =
-* evaluation of relevant quality metrics such as complexity, maintainability, etc
-* evaluation of tasks related metric such as time spend in modelling, proving or other activities (possibly based on other plugins) such as requirements, model-checking.
-* The user will be given the ability to enable or disable the collection of task related metrics.
-and the following non-functional requirements:
+This part describes how the reasoner works.
-* usability: integration into RODIN, in the Event-B perspective as an additional view
+== Goal ==
-* reactivity: metrics will be updated regularly (at an adequate pace, possibly incrementally) or at user request
+The goal must match the same kind of goal as describes in the tactic part.
-* efficiency: metric evaluation will not significantly slow down the interactivity of the RODIN platform
-* security: strict data management policy to enforce confidentiality of the models, especially the user must be able to see if the plug-in is enabled and no data can leave the tool without the user consent
-[[Category:Plugin]]
+== Input ==
-[[Category:Work in progress]]
+Because we do not want to do the job of re-writing, every added hypotheses used to discharge the sequent should be contained in the input (the reasoner must extend HypothesesReasoner) as well as hypotheses used to perform the re-writing and hypotheses used to discharge the sequent. Thus we get those obligations :
+*Every added hypotheses must be re-writable with hypotheses contained in the sequent and in the input.
+*Every added hypotheses should be used to discharge the sequent.
+*Hypotheses used to perform re-writing could be also used to discharge a sequent and may be used several times to prove that added hypotheses are re-writable.
+*Hypotheses used to discharge the sequent should be used only once in the path (no loop allowed).
+*It checks that with all these hypotheses can actually discharge the sequent
+If all those tests pass, then the sequent is discharged. The added hypotheses are set as AddedHyps, and all the other hypotheses of the input are set as NeededHps.
+[[Category:Design proposal]]

Difference between pages "Measurement Plug-In" and "Membership in Goal"

Revision as of 14:16, 29 June 2011

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Objective

Analysis

Tactic

Goal

Hypotheses

Find a path

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