CITADEL
Overview
CITADEL (Contract-Inference Tool that Applies Daikon to the Eiffel Language) is a tool that provides an Eiffel front-end for the Daikon invariant detector. It is being implemented as a Master's project by Nadia Polikarpova supervised by Ilinca Ciupa (ETH).
Discussions
- Flattened variables
Nadia: Daikon can process values of only few types: five scalar types (boolean, integer, double, string and hashcode) and five more types, which are arrays of these scalars. So, if in Eiffel code we a have a variable of one of basic types (BOOLEAN, NATURAL, INTEGER, REAL or STRING) we can print its value directly as if it has one of Daikon's types. If, however, we have a variable of any other type, we have to collect all the information about it that is of interest and is available at certain program point, and present this information to Daikon as a set of variables, which have Daikon types. The information of interest about a variable includes results of all queries that can be called on this variable at this program point. However, since queries results may themselves be of non-basic types, we have to perform this operation recursively (to a certain depth). For a reference variable information of interest includes also its address (Daikon type "hashcode" is intended for representing object addresses). For example, if we had a variable c: POINT, queries of class POINT available at current program point were `x: REAL', `y: REAL' and `twin: POINT' and flattening depth were set to 2, then `c.flattened' would be a set of variables: {$c, c.x, c.y, $c.twin, c.twin.x, c.twin.y}. Containers need special kind of flattening. If we want Daikon to handle them sensibly, they should be converted to arrays of scalars (to be more precise, it should be done only if all container elements are observable at current program point...). It isn't difficult for descendants of CONTAINER class from standard library. Instrumenter may check, if a variable is an indirect instance of CONTAINER, get its `linear_representation', then traverse it and output as array. I think that in the first version we may leave aside those containers, that aren't inherited from CONTAINER.
Ilinca: I'm not sure about the idea of including argument-less functions in this flattened form. What if the precondition of the function doesn't hold or we run into some kind of trouble when executing the function body (trouble such as the contracts of a sub-call made by this function not holding or other bugs)? On the other hand, including functions would bring significantly more information about the state of the object... Does the Daikon frontend for Java, for instance, by default evaluate functions too as part of the flattened form of the objects?
Nadia: Well, this idea is disputable, of cause. In Java considering argument-less functions as variables is more dangerous, because Java, like all C-family languages, encourages side-effects in functions. However, in Daikon front-end for Java there exists an option that allows using functions as variables. Together with enabling this option user has to provide a special "purity" file that lists those functions from the system, that are side-effect free. This feature is described in Daikon User Manual, page 82. Considering functions as variables is even more relevant in Eiffel context by two main reasons. Firstly, Eiffel encourages absence of abstract side-effects in functions (and, I believe, most Eiffel functions indeed do not have abstract side-effect, am I right?). For those cases, when some functions in system are known to have side-effect, we can allow user to specify an "impurity" file, that would list those functions. I think that these cases would be rare. Secondly, Eiffel advocates uniform access principle. Routine's clients don't have to know, which queries, used in precondition, are attributes and which are functions. If inferred preconditions contained only attributes, it would be inconsistent with uniform access principle, I think... The issue with functions' preconditions that you've mentioned isn't a big problem. If after flattening we got a variable of the form, e.g., `x.f1.f2', where `f1' and `f2' are functions, printing instructions for this variable can be like this: if x.f1_precondition_holds and then x.f1.f2_precondition_holds then print (x.f1.f2) else print (Nonsensical) end "Nonsensical" is a special Daikon value that indicates that variable cannot be evaluated. Function preconditions are known after parsing. To be able to evaluate them separately, we may, for example, wrap them into functions. `f1_precondition_holds' in the above code is an example of such a function, that was introduced by instrumenter and added to x's generating class. BTW, for attributes we also need check in printing instructions: the target on which attribute is called should be non-void, otherwise attribute value should be printed as `Nonsensical'. As for troubles that may arise when calling functions... As I understand, exception in a function, called when its precondition holds, is a bug. So, if it happens, we can just tell user that we found a bug in certain function and that before inferring contracts the bug should be fixed.
- Support for loop invariants
Ilinca: Does the "classic" Daikon support loop invariants?
Nadia: Daikon uses standard program point suffixes to infer more invariants. E.g., it understands that some_routine:::ENTER and some_routine:::EXIT are entry and exit points of the same routine. Thanks to this, it knows `old' values of variables at exit and can infer invariants like "x = old x". As I understood, if Daikon sees an unknown suffix, it treats corresponding program point as, so to say, "standalone" and doesn't try to connect it with any other. We don't need any extra support from Daikon to handle loop invariants. If we want to infer loop invariants, we should introduce a separate program point for each loop. So, we need a way to distinguish loops within a routine. One way is to take its position in source code as index. However, I thought, that position is too unstable to become loop identifier, so I chose instruction number instead. These numbers are unique numbers of instructions within surrounding routine, they may be used not only for loops, but for arbitrary instructions. CI_INSTRUCTION_COUNTER is responsible for counting instruction while iterating through AST.
- Inferring contracts for generic classes
Nadia: there are actually two different cases. 1. Contracts inside generic classes. This is not really a problem. Entities, which have parameter type, can be treated as if their generator is constraining class (ANY, if genericity is unconstrained). 2. Contracts in clients of generic classes. Here some problems arise. If we have an entity `x: ARRAYED_LIST[INTEGER]', its flattening involves processing the `item' query. `item' is declared to be of type `G' in ARRAYED_LIST and, as I understand, parsing is not enough (some type analysis is needed) to infer that `G' means `INTEGER' in current context. Two approaches to this problem, that I see at present, are: perform such a type analysis in compile time (with the help of gobo compilation facilities) or leave some flattening work until runtime, when reflections may be used to determine variable's generating class.