Difference between revisions of "Preventing CAT calls in Generics"
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[[Category:ECMA]] | [[Category:ECMA]] | ||
− | {{ | + | {{UnderConstruction}} |
==Introduction== | ==Introduction== | ||
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l_student: STUDENT | l_student: STUDENT | ||
l_any_stack: STACK [PERSON] | l_any_stack: STACK [PERSON] | ||
− | + | l_student_stack: STACK [STUDENT] | |
do | do | ||
l_person_stack := l_student_stack -- line 1 | l_person_stack := l_student_stack -- line 1 | ||
Line 39: | Line 39: | ||
Currently no static check will prohibit you from writing things like this. At runtime on ''line 2'' the first CAT call occurs, which most likely wont do any harm to a list. But the object returned by <e>item</e> on ''line 3'' is not of type <e>STUDENT</e> but of type <e>PERSON</e> and at least now we have a serious problem if one invokes features specific to a student on <e>l_student</e>. | Currently no static check will prohibit you from writing things like this. At runtime on ''line 2'' the first CAT call occurs, which most likely wont do any harm to a list. But the object returned by <e>item</e> on ''line 3'' is not of type <e>STUDENT</e> but of type <e>PERSON</e> and at least now we have a serious problem if one invokes features specific to a student on <e>l_student</e>. | ||
− | The issue is that the <e>put</e> feature of <e>l_person_stack</e> allows you to put objects of type <e>PERSON</e> on the stack even though the actual type of the attached object is <e>STACK [STUDENT]</e> and is referenced by <e> | + | The issue is that the <e>put</e> feature of <e>l_person_stack</e> allows you to put objects of type <e>PERSON</e> on the stack even though the actual type of the attached object is <e>STACK [STUDENT]</e> and is referenced by <e>l_student_stack</e> whose <e>item</e> feature guarantees, that the returned object will be of type <e>STUDENT</e>. |
This solution will now extend the type system and the generic derivation of Eiffel in such away, that the type of a formal occurring as an argument in a feature declaration and the type of a formal occurring as a result type can be set independently. The type system will be extended with rules which allow only assignments between generic types if it cannot possibly lead to problems like the one mentioned above. | This solution will now extend the type system and the generic derivation of Eiffel in such away, that the type of a formal occurring as an argument in a feature declaration and the type of a formal occurring as a result type can be set independently. The type system will be extended with rules which allow only assignments between generic types if it cannot possibly lead to problems like the one mentioned above. | ||
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{{Note| Why do we need that? | {{Note| Why do we need that? | ||
− | We | + | We want to ensure that one has a read only list. One cannot use a <e>LIST [ANY..NONE]</e> because one would not be allowed to assign a <e>LIST [INTEGER]</e> to it. This is because one can put Void into a list of type <e>LIST [ANY..NONE]</e>, which is invalid for a list of integer as <e>INTEGER</e> is expanded.}} |
== Validity == | == Validity == | ||
Line 110: | Line 110: | ||
==Conformance Rules== | ==Conformance Rules== | ||
− | We make another more abstract example to illustrate the conformance rules. They can easily be derived by applying the fact that its save for argument types to be | + | We make another more abstract example to illustrate the conformance rules. They can easily be derived by applying the fact that its save for argument types to be contra-variant and for result types to be covariant. This is actually a very important as it is the basis where the conformance is based uppon. |
Interface conformance rule: | Interface conformance rule: | ||
− | An interface B is conform to an interface A if for every feature f_a in A there is a corresponding feature f_b available from B | + | An interface B is conform to an interface A if for every feature f_a in A |
− | + | there is a corresponding feature f_b available from B and for each feature | |
+ | the arguments of f_a conform to those of f_b and the result type of f_b is | ||
+ | conform to the one of f_a. | ||
<e> | <e> | ||
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T := LIST [ANY..T] .item | T := LIST [ANY..T] .item | ||
</e> | </e> | ||
− | |||
==Agents== | ==Agents== | ||
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=== How to generate the call signature for a given agent type === | === How to generate the call signature for a given agent type === | ||
− | To build the signature of the call routine one simply takes he second parameter and | + | To build the signature of the call routine one simply takes he second parameter and puts it as the first. As the second parameter we put nothing. |
Example: | Example: |
Latest revision as of 19:27, 19 April 2007
Contents
Introduction
The problem with the way generics are implemented in Eiffel right now is that CAT calls can occur.
class PERSON end class STUDENT inherit PERSON end class EMPLOYEE inherit PERSON end class EMPLOYED_STUDENT inherit EMPLOYEE STUDENT end
local l_person: PERSON l_student: STUDENT l_any_stack: STACK [PERSON] l_student_stack: STACK [STUDENT] do l_person_stack := l_student_stack -- line 1 l_person_stack.put (l_person) -- line 2 l_student := l_student_stack.item -- line 3
Currently no static check will prohibit you from writing things like this. At runtime on line 2 the first CAT call occurs, which most likely wont do any harm to a list. But the object returned by item
on line 3 is not of type STUDENT
but of type PERSON
and at least now we have a serious problem if one invokes features specific to a student on l_student
.
The issue is that the put
feature of l_person_stack
allows you to put objects of type PERSON
on the stack even though the actual type of the attached object is STACK [STUDENT]
and is referenced by l_student_stack
whose item
feature guarantees, that the returned object will be of type STUDENT
.
This solution will now extend the type system and the generic derivation of Eiffel in such away, that the type of a formal occurring as an argument in a feature declaration and the type of a formal occurring as a result type can be set independently. The type system will be extended with rules which allow only assignments between generic types if it cannot possibly lead to problems like the one mentioned above.
Syntax
LIST [G] can be declared in the following way:
l_list: LIST [PERSON..EXMLPOYED_STUDENT]
LIST[A]
is a shorthand for LIST[A..A]
.
LIST[A..]
is also a possible syntax.
Another syntax could look as follows:
<type_for_arguments>:<type_for_return_types>
This would more resemble an actual generated signature of a feature which looks initially like
class EXAMPLE [G] feature example (a_g: G): G end
A type declaration with this syntax would look like:
local l_example: EXAMPLE [EMLPOYED_STYDENT: STUDENT] l_employed_student: EMPLOYED_STUDENT l_person: PERSON do -- l_example.example (a_g: EMPLOYED_STUDENT): STUDENT l_person := l_example.example (l_employed_student) -- valid end
LIST[:A]
is the equivalent to LIST[A..]
.
LIST[A]
is a shorthand for LIST[A: A]
.
But let's stick with the initial syntax for now.
Semantics
As we already pointed out, this solution is an extension to the type system. It helps you to proper derive an interface of a generic type.
For example an actual type parameter for G in LIST [G]
is PERSON..EMPLOYED_STUDENT.
The interface generated by this derivation is simply that the first type (PERSON) is taken wherever G occurs as a return type.
The second type (EMPLOYED_STUDENT) is taken wherever G occurs as an argument type.
(generic derived) class LIST[PERSON..EMPLOYED_STUDENT] put (v: EMPLOYED_STUDENT) item: PERSON
If we encounter a form like LIST [A..] it simply means that no feature which has the formal in the argument can be called.
Note: Why do we need that?
We want to ensure that one has a read only list. One cannot use a LIST [ANY..NONE]
because one would not be allowed to assign a LIST [INTEGER]
to it. This is because one can put Void into a list of type LIST [ANY..NONE]
, which is invalid for a list of integer as INTEGER
is expanded.
Validity
LIST[<first_type>..<second_type>]
Such a generic derivation is valid if:
- 1: the second type conforms to the constraint of the formal.
- 2: the second type conforms to the first type
Conformance Rules
We make another more abstract example to illustrate the conformance rules. They can easily be derived by applying the fact that its save for argument types to be contra-variant and for result types to be covariant. This is actually a very important as it is the basis where the conformance is based uppon.
Interface conformance rule:
An interface B is conform to an interface A if for every feature f_a in A there is a corresponding feature f_b available from B and for each feature the arguments of f_a conform to those of f_b and the result type of f_b is conform to the one of f_a.
local l_a: A l_b: B do -- is legal if the interface conformance rule holds l_a := l_b end
Example of an actual generic conformance table
class T end class U inherit T -- no covariant feature redefinition end
conforms to | LIST [ANY] | LIST [T] | LIST [T..NONE] | LIST [ANY..T] | LIST [U] |
---|---|---|---|---|---|
LIST [ANY] | true | false | false | true | false |
LIST [T] | false | true | true | true | false |
LIST [T..NONE] | false | false | true | false | false |
LIST [ANY..T] | false | false | false | true | false |
LIST [U] | false | false | true | false | true |
-- legal T := LIST [T..NONE] .item LIST [T..NONE] .put (Void) -- illegal U := LIST [T..NONE] .item LIST [T..NONE] .put (T) -- legal LIST [ANY..T] .put (T) LIST [ANY..T] .put (U) ANY := LIST [ANY..T] .item -- illegal LIST [ANY..T] .put (ANY) T := LIST [ANY..T] .item
Agents
The neat thing about this extension is, that there is no need to cut down the expressiveness of the agent mechanism to make them perfectly save to use with full support for all legal situations.
Procedure class:
class PROCEDURE [BASE_TYPE, OPEN_ARGS -> TUPLE []] -- Signature of call is generated by the compiler. To visualize this we add _reflected to the argument tuple. call (args: OPEN_ARGS_reflected) do end end
Agent example
Type declaration:
an_agent: PROCEDURE [ANY..NONE, TUPLE..TUPLE [ANY..T]] --> like agent (T) -- This signature promises that the caller is going to give at least one argument which conforms to T. -- Note: The signature for the call routine has to be reflected by the compiler into : TUPLE [T..]..NONE -- This is because we can give a tuple containing more than one element and it element type has to conform to T. -- legal an_agent.call ([T]) an_agent.call ([T, ...]) an_agent.call ([U, ...]) -- illegal an_agent.call ([])
Instantiation:
agent_empty := agent () do end --> PROCEDURE [ANY, TUPLE []] agent_any := agent (a: ANY) do end --> PROCEDURE [ANY, TUPLE [ANY]] agent_t := agent (t: T) do end --> PROCEDURE [ANY, TUPLE [T]] agent_u := agent (u: U) do end --> PROCEDURE [ANY, TUPLE [U]] -- legal an_agent := agent_empty an_agent := agent_any an_agent := agent_t -- illegal an_agent := agent_u
There might be a concern about the fact that the compiler generates the signature of the call method. But I think that its not wrong to have compiler support for agents, as they are such a fundamental core concept that is simply important that one could sacrifice expressive power or type safety just to avoid explicit support from the compiler.
How to generate the call signature for a given agent type
To build the signature of the call routine one simply takes he second parameter and puts it as the first. As the second parameter we put nothing.
Example:
TUPLE [ANY..T, ANY..U, ANY..V]
leads to
TUPLE [T..,U..,V..]
This basically states that all I want is to be able to read an object of at least type T, U, V and that I'm not going to put anything into this tuple.