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< Taxonomy | 2. Methodology
As explained under Development end Verification and validation, we should state what is given and what not. This should be done for one Chinese Box, i.e. one instance of the Rationality Square and Correctness Theorem at a time.
Inhoud
Problem statement form correctness
Please stay at one level and don't climb up and down! It can be helpful, however, also to fill in a problem statement form for the surrounding artefact.
| Problem | ||
|---|---|---|
| Question | Answer | Explanation |
| →properties | ||
| How are the properties under discussion defined? |
|
|
| Can the customer be consulted? Who? | ||
| What is the problem domain? | ||
| Can a Domain expert for the problem domain be consulted? Who? | ||
| →specification | ||
| Which →specification language is (to be) used? Why? | ||
| Is there a specification? |
|
|
| If the specification is not fixed: how can it be Validated? | ||
| Does the customer or his domain expert understand the specification language? | ||
| →blueprint | ||
| Which blueprint language is (to be) used? Why? | ||
| How complete is the blueprint? |
|
|
| Do the providers of parts or their Domain experts understand the respective →specification languages from the →blueprint? | ||
| How should it be established that the blueprint satisfies the specification? | ||
| How should it be established that the artefact is a correct realisation of the blueprint? | ||
| →artefact | ||
| How much of the artefact exists? Where? |
|
|
| If it does not (fully) exist, how and by whom will it be realised? | ||
| What are the solution domains for the missing parts? | ||
| Who are the Domain experts for the missing parts and their interfaces? | ||
| How can the artefact be Validated w.r.t. a specification? | ||
| Plan | ||
| Step | To do | Comment |
| 1 | ||
| 2 | ||
Examples
Case Study1. The batch plant and its control program
| Problem #001 | Batch plant: Find the specification for the control | |
|---|---|---|
| Question | Answer | Explanation |
| Properties | ||
| How are the properties under discussion defined? | The physical chemical plant is given, including a computer, but without a control program. The required properties are: pump batches around in this plant. | |
| Can the customer be consulted? Who? | The customer is the one who defined this case study | |
| What is the problem domain? | Chemical reactions, mixing, separating | |
| Can a domain expert for the problem domain be consulted? Who? | Yes: Nanette | |
| Specification | ||
| Which specification language is (to be) used? Why? | A dialect of predicate logic | Predicate logic because it is basic, a dialect to improve readability |
| Is there a complete, formal specification? |
|
|
| If the specification is not fixed: how can it be validated? | By asking the "customer" | |
| Does the customer or his domain expert understand the specification language? | Nanette can understand a specification in predicate logic if someone helps. | |
| Blueprint | ||
| Which blueprint language is (to be) used? Why? | the same dialect of predicate logic | verification |
| How complete is the blueprint? |
|
A decomposition in 2 parts is mandatory:
There is no further decomposition or specification for the plant, only a diagram. It shows the interface to the computer program. |
| Do the providers of parts or their domain experts understand the respective specification languages from the blueprint? | They can explain their diagram. With a little help they can be made to understand the blueprint to be written in logic. | |
| How should it be established that the blueprint satisfies the specification? | Theorem proving with PVS | |
| How should it be established that the artefact is a correct realisation of the blueprint? | For the plant: ask plant expert. For the program: compile and load | |
| Artefact | ||
| How much of the artefact exists? Where? |
|
The control program is missing. The rest of the plant exists, but no meaningful decomposition is defined. |
| If it does not (fully) exist, how and by whom will it be realised? | Angelika will write a control program and send it to Nanette, who will load it into the computer | See problem statement #002 |
| What are the solution domains for the missing parts? | Programming language | |
| Who are the domain experts for the missing parts and their interfaces? | Angelika and Hanno | |
| How can the artefact be validated w.r.t. a specification? | By a correctness proof for this theorem and that of statement #002 | Or, in this simple case, by a test. Once it runs, one can see that it works. |
| Plan | ||
| 1 | Decompose existing plant | Non-Monotonic Refinement |
| 2 | Specify components of plant together with overall goal | Non-Monotonic Refinement |
| 3 | Determine specification of control to obtain a provable correctness theorem | |
| 4 | Prove theorem | PVS |
| Problem #002 | Batch Plant: code for the control program | |
|---|---|---|
| Question | Answer | Explanation |
| Properties | ||
| How are the properties under discussion defined? | Problem statement #001 | |
| Can the customer be consulted? Who? | Yes, Angelika | Angelika derived the specification and proved the surrounding correctness theorem |
| What is the problem domain? | Software | |
| Can a domain expert for the problem domain be consulted? Who? | Yes: Hanno | He knows about program correctness |
| Specification | ||
| Which specification language is (to be) used? Why? | A dialect of predicate logic | Given from Problem #001 |
| Is there a complete, formal specification? |
|
|
| If the specification is not fixed: how can it be validated? | ||
| Does the customer or his domain expert understand the specification language? | Yes. | |
| Blueprint | ||
| Which blueprint language is (to be) used? Why? | The programming language | Because the computer is given |
| How complete is the blueprint? |
|
|
| Do the providers of parts or their domain experts understand the respective specification languages from the blueprint? | no | Not necessary. The parts are the contructs of the programming language. The programmers understand these and do not need providers' support. |
| How should it be established that the blueprint satisfies the specification? | software engineering: proving a program correct by constructing it | |
| How should it be established that the artefact is a correct realisation of the blueprint? | compilation, loading | |
| Artefact | ||
| How much of the artefact exists? Where? |
|
All of the parts exist because they are the constructs of an existing programming language. |
| If it does not (fully) exist, how and by whom will it be realised? | Angelika will derive a control program from the specification developed under proplem statement #001 | A program is its own blueprint. It has just to be compiled and loaded by Nanette. |
| What are the solution domains for the missing parts? | ||
| Who are the domain experts for the missing parts and their interfaces? | ||
| How can the artefact be validated w.r.t. a specification? | Correctness proof a posteriori or systematic development | We assume compilation and loading to be correct. |
| Plan | ||
| 1 | Write a program for a given, fixed specification | standard software engineering |
| 2 | Compile and load it | |
Protocol verification
| Problem | Verification of the alternating pit protocol | |
|---|---|---|
| Question | Answer | Explanation |
| Properties | ||
| How are the properties under discussion defined? | Reliable communication via a lossy channel | |
| Can the customer be consulted? Who? | Yes | The designer of the surrounding artefact wants to rely on communication but became aware that channels can lose messages. He will be able to help to decide what is acceptable and what not in order to obtain a correct design |
| What is the problem domain? | Computer networks | |
| Can a domain expert for the problem domain be consulted? Who? | Yes | The same designer of the surounding artefact. |
| Specification | ||
| Which specification language is (to be) used? Why? | May be chosen | |
| Is there a complete, formal specification? |
|
There is an informal specification in terms of "as good as possible". The definitive specification will have to be found as the strongest specification that is satisfied by the protocol under discussion. |
| If the specification is not fixed: how can it be validated? | By asking the customer | |
| Does the customer or his domain expert understand the specification language? | Will depend on the language | |
| Blueprint | ||
| Which blueprint language is (to be) used? Why? | algorithms plus a suitable specification language for lossy channels | |
| How complete is the blueprint? |
|
|
| Do the providers of parts or their domain experts understand the respective specification languages from the blueprint? | Yes. | |
| How should it be established that the blueprint satisfies the specification? | Formal verification. | |
| How should it be established that the artefact is a correct realisation of the blueprint? | For the algorithms: compilation. For the channel: validation. | |
| Artefact | ||
| How much of the artefact exists? Where? |
|
|
| If it does not (fully) exist, how and by whom will it be realised? | ||
| What are the solution domains for the missing parts? | ||
| Who are the domain experts for the missing parts and their interfaces? | ||
| How can the artefact be validated w.r.t. a specification? | By a correctness proof plus validation of the specification of the lossy channel. | That is the problem! |
| Plan | ||
| 1 | Fault hypothesis: write and validate a specification for the lossy channel | |
| 2 | Derive a realistic specification for the overall system | Non-Monotonic Refinement |
| 3 | Choose a proof method | and translate everything into the languages supported by the proof tool, if necessary |
| 4 | Prove it. | |
Protocol verification
| Problem | Verification of the plans for a self--assembly home--trainer | |
|---|---|---|
| Question | Answer | Explanation |
| Properties | ||
| How are the properties under discussion defined? | We want to know if our assembly--plan, which goes with our cheap hometrainers that people can assemble themselves, at home, is adequate. | |
| Can the customer be consulted? Who? | Yes | We can interview the manufacturer of the product. |
| What is the problem domain? | Parts, Assembly--plans, Users | |
| Can a domain expert for the problem domain be consulted? Who? | Yes | The designer(s) of the home--trainer, the writer(s) of the assembly plan, the (representative) end--users of the product. |
| Specification | ||
| Which specification language is (to be) used? Why? | Probably some form of (untimed) state machines. | To model the successive states of the parts/agregates. |
| Is there a complete, formal specification? |
|
There is an implicit specification in terms of the combination of assembly--plan, parts and average user competence as natural language interpreter/mechanic. |
| If the specification is not fixed: how can it be validated? | We have all the parts and the assembly--plans. We can see if our specifcation is adequate by checking if all the possible assembly steps we modeled are possible in practice and if everything that is possible in practice is either modeled or explicitly disallowed based on the blueprints. | |
| Does the customer or his domain expert understand the specification language? | No | |
| Blueprint | ||
| Which blueprint language is (to be) used? Why? | For the parts: CAD/CAM plans. For the assembly plan: natural language with diagrams and pictures. | For the parts: this is the industries' established way to communicate these designs. For the assembly plans: we cannot assume anything more from users. |
| How complete is the blueprint? |
|
|
| Do the providers of parts or their domain experts understand the respective specification languages from the blueprint? | We assume they do. | |
| How should it be established that the blueprint satisfies the specification? | We can do systematic justification based on our own competence as natural language users. Possibly experiment with users. | |
| How should it be established that the artefact is a correct realisation of the blueprint? | For the parts: this is a matter of quality assurance. For the assembly--plans: this is trivial since they are simply printed. | |
| Artefact | ||
| How much of the artefact exists? Where? |
|
The unfinished artefact is the realisation of the blueprints which, in our case is a package of parts (which is given) and an assembly plan (which is directly printed from the blueprints). The correct behavior of this unfinished artefact when offered to a user should lead to a user with a hometrainer (as specified by us). |
| If it does not (fully) exist, how and by whom will it be realised? | User. | |
| What are the solution domains for the missing parts? | Not applicable. | |
| Who are the domain experts for the missing parts and their interfaces? | Not applicable. | |
| How can the artefact be validated w.r.t. a specification? | By checking if all the possible sequences of steps allowed by the assembly plans + parts are modeled in the specification and, vice versa, all the possible sequences modeled in the specification are allowed by the assembly plans + parts. | |
| Plan | ||
| 1 | Model the possible assembly steps allowed by the current assembly plan. | |
| 2 | Derive a realistic specification for parts and the ways in which the assembly steps combine them into agregates. | Non-Monotonic Refinement |
| 3 | Model the possible, desired results of the assembly process. | Discuss with designers whether each possible resulting device is still a home--trainer. |
| 4 | Prove that all possible assembly sequences lead to a desired result. | |
