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 13.1 Operational and Representation Items Representation Items

  {8652/0009} {AI95-00137-01} [Representation and operational items can be used to specify aspects of entities. Two kinds of aspects of entities can be specified: aspects of representation and operational aspects. Representation items specify how the types and other entities of the language are to be mapped onto the underlying machine. Operational items specify other properties of entities.]
{8652/0009} {AI95-00137-01} {representation item} {representation pragma [distributed]} {pragma, representation [distributed]} There are six three kinds of representation items: attribute_definition_clauses for representation attributes, enumeration_representation_clauses, record_representation_clauses, at_clauses, representation_clauses, component_clauses, and representation pragmas. [Representation items specify how the types and other entities of the language are to be mapped onto the underlying machine. They can be provided to give more efficient representation or to interface with features that are outside the domain of the language (for example, peripheral hardware). Representation items also specify other specifiable properties of entities. A representation item applies to an entity identified by a local_name, which denotes an entity declared local to the current declarative region, or a library unit declared immediately preceding a representation pragma in a compilation.]
  {8652/0009} {AI95-00137-01} An {operational item} operational item is an attribute_definition_clause for an operational attribute.
  {8652/0009} {AI95-00137-01} [An operational item or a representation item applies to an entity identified by a local_name, which denotes an entity declared local to the current declarative region, or a library unit declared immediately preceding a representation pragma in a compilation.]

Language Design Principles

{8652/0009} {AI95-00137-01} Aspects of representation are intended to refer to properties that need to be known before the compiler can generate code to create or access an entity. For instance, the size of an object needs to be known before the object can be created. Conversely, operational aspects are those that only need to be known before they can be used. For instance, how an object is read from a stream only needs to be known when a stream read is executed. Thus, aspects of representation have stricter rules as to when they can be specified.
{AI95-00291-02} Confirming the value of an aspect with an operational or representation item should never change the semantics of the aspect. Thus Size = 8 (for example) means the same thing whether it was specified with a representation item or whether the compiler chose this value by default. 


{8652/0009} {AI95-00137-01} aspect_clause representation_clause ::= attribute_definition_clause
      | enumeration_representation_clause
      | record_representation_clause
      | at_clause
local_name ::= direct_name
      | direct_name'attribute_designator
      | library_unit_name
{8652/0009} {AI95-00137-01} A representation pragma is allowed only at places where an aspect_clause a representation_clause or compilation_unit is allowed. {representation_clause: See aspect_clause}

Name Resolution Rules

{8652/0009} {AI95-00137-01} In an operational item or a representation item, if the local_name is a direct_name, then it shall resolve to denote a declaration (or, in the case of a pragma, one or more declarations) that occurs immediately within the same declarative region as the representation item. If the local_name has an attribute_designator, then it shall resolve to denote an implementation-defined component (see 13.5.1) or a class-wide type implicitly declared immediately within the same declarative region as the representation item. A local_name that is a library_unit_name (only permitted in a representation pragma) shall resolve to denote the library_item that immediately precedes (except for other pragmas) the representation pragma. 
Reason: {8652/0009} {AI95-00137-01} This is a Name Resolution Rule, because we don't want an operational or a representation item for X to be ambiguous just because there's another X declared in an outer declarative region. It doesn't make much difference, since most operational or representation items are for types or subtypes, and type and subtype names can't be overloaded. 
Ramification: {8652/0009} {AI95-00137-01} The visibility rules imply that the declaration has to occur before the operational or representation item.
{8652/0009} {AI95-00137-01} For objects, this implies that operational or representation items can be applied only to stand-alone objects. 

Legality Rules

{8652/0009} {AI95-00137-01} The local_name of an aspect_clause a representation_clause or representation pragma shall statically denote an entity (or, in the case of a pragma, one or more entities) declared immediately preceding it in a compilation, or within the same declarative_part, package_specification, task_definition, protected_definition, or record_definition as the representation or operational item. If a local_name denotes a [local] callable entity, it may do so through a [local] subprogram_renaming_declaration [(as a way to resolve ambiguity in the presence of overloading)]; otherwise, the local_name shall not denote a renaming_declaration.
Ramification: The “statically denote” part implies that it is impossible to specify the representation of an object that is not a stand-alone object, except in the case of a representation item like pragma Atomic that is allowed inside a component_list (in which case the representation item specifies the representation of components of all objects of the type). It also prevents the problem of renamings of things like “P.all” (where P is an access-to-subprogram value) or “E(I)” (where E is an entry family).
The part about where the denoted entity has to have been declared appears twice — once as a Name Resolution Rule, and once as a Legality Rule. Suppose P renames Q, and we have a representation item in a declarative_part whose local_name is P. The fact that the representation item has to appear in the same declarative_part as P is a Name Resolution Rule, whereas the fact that the representation item has to appear in the same declarative_part as Q is a Legality Rule. This is subtle, but it seems like the least confusing set of rules. 
Discussion: A separate Legality Rule applies for component_clauses. See 13.5.1, “Record Representation Clauses”. 
{AI95-00291-02} {representation of an object} {size (of an object)} The representation of an object consists of a certain number of bits (the size of the object). For an object of an elementary type, these These are the bits that are normally read or updated by the machine code when loading, storing, or operating-on the value of the object. For an object of a composite type, these are the bits reserved for this object, and include bits occupied by subcomponents of the object. If This includes some padding bits, when the size of an the object is greater than that the size of its subtype, the additional bits are padding bits.. {gaps} {padding bits} For an elementary object, these Such padding bits are considered to be part of the representation of the object, rather than being gaps between objects, if these bits are normally read and updated along with the others. For a composite object, padding bits might not be read or updated in any given composite operation, depending on the implementation.
To be honest: {AI95-00291-02} {contiguous representation [partial]} {discontiguous representation [partial]} Discontiguous representations are allowed, but the ones we're interested in here are generally contiguous sequences of bits. For a discontiguous representation, the size doesn't necessarily describe the “footprint” of the object in memory (that is, the amount of space taken in the address space for the object). 
Discussion: {AI95-00291-02} In the case of composite objects, we want the implementation to have the flexibility to either do operations component-by-component, or with a block operation covering all of the bits. We carefully avoid giving a preference in the wording. There is no requirement for the choice to be documented, either, as the implementation can make that choice based on many factors, and could make a different choice for different operations on the same object.
{AI95-00291-02} In the case of a properly aligned, contiguous object whose size is a multiple of the storage unit size, no other bits should be read or updated as part of operating on the object. We don't say this normatively because it would be difficult to normatively define “properly aligned” or “contiguous”. 
Ramification: Two objects with the same value do not necessarily have the same representation. For example, an implementation might represent False as zero and True as any odd value. Similarly, two objects (of the same type) with the same sequence of bits do not necessarily have the same value. For example, an implementation might use a biased representation in some cases but not others: 
subtype S is Integer range 1..256;
type A is array(Natural range 1..4) of S;
pragma Pack(A);
X : S := 3;
Y : A := (1, 2, 3, 4);
The implementation might use a biased-by-1 representation for the array elements, but not for X. X and Y(3) have the same value, but different representation: the representation of X is a sequence of (say) 32 bits: 0...011, whereas the representation of Y(3) is a sequence of 8 bits: 00000010 (assuming a two's complement representation).
Such tricks are not required, but are allowed.
Discussion: The value of any padding bits is not specified by the language, though for a numeric type, it will be much harder to properly implement the predefined operations if the padding bits are not either all zero, or a sign extension. 
Ramification: For example, suppose S'Size = 2, and an object X is of subtype S. If the machine code typically uses a 32-bit load instruction to load the value of X, then X'Size should be 32, even though 30 bits of the value are just zeros or sign-extension bits. On the other hand, if the machine code typically masks out those 30 bits, then X'Size should be 2. Usually, such masking only happens for components of a composite type for which packing, Component_Size, or record layout is specified.
Note, however, that the formal parameter of an instance of Unchecked_Conversion is a special case. Its Size is required to be the same as that of its subtype.
Note that we don't generally talk about the representation of a value. A value is considered to be an amorphous blob without any particular representation. An object is considered to be more concrete. 
{aspect of representation [distributed]} {representation aspect} {directly specified (of an aspect of representation of an entity)} A representation item directly specifies an aspect of representation of the entity denoted by the local_name, except in the case of a type-related representation item, whose local_name shall denote a first subtype, and which directly specifies an aspect of the subtype's type. {type-related (representation item) [distributed]} {subtype-specific (of a representation item) [distributed]} {type-related (aspect) [distributed]} {subtype-specific (of an aspect) [distributed]} A representation item that names a subtype is either subtype-specific (Size and Alignment clauses) or type-related (all others). [Subtype-specific aspects may differ for different subtypes of the same type.] 
To be honest: Type-related and subtype-specific are defined likewise for the corresponding aspects of representation. 
To be honest: Some representation items directly specify more than one aspect. 
Discussion: For example, a pragma Export specifies the convention of an entity, and also specifies that it is exported. 
Ramification: Each specifiable attribute constitutes a separate aspect. An enumeration_representation_clause specifies the coding aspect. A record_representation_clause (without the mod_clause) specifies the record layout aspect. Each representation pragma specifies a separate aspect. 
Reason: We don't need to say that an at_clause or a mod_clause specify separate aspects, because these are equivalent to attribute_definition_clauses. See J.7, “At Clauses”, and J.8, “Mod Clauses”.
Ramification: The following representation items are type-related: 
The following representation items are subtype-specific: 
The following representation items do not apply to subtypes, so they are neither type-related nor subtype-specific:
  {8652/0009} {AI95-00137-01} An operational item directly specifies an operational aspect of the type of the subtype denoted by the local_name. The local_name of an operational item shall denote a first subtype. An operational item that names a subtype is type-related. {operational aspect [distributed]} {directly specified (of an operational aspect of an entity)} {type-related (operational item) [distributed]} {type-related (aspect) [partial]}
Ramification: {8652/0009} {AI95-00137-01} The following operational items are type-related:
A representation item that directly specifies an aspect of a subtype or type shall appear after the type is completely defined (see 3.11.1), and before the subtype or type is frozen (see 13.14). If a representation item is given that directly specifies an aspect of an entity, then it is illegal to give another representation item that directly specifies the same aspect of the entity. 
Ramification: {8652/0009} {AI95-00137-01} The fact that a representation item (or operational item, see next paragraph) that directly specifies an aspect of an entity is required to appear before the entity is frozen prevents changing the representation of an entity after using the entity in ways that require the representation to be known. 
  {8652/0009} {AI95-00137-01} An operational item that directly specifies an aspect of a type shall appear before the type is frozen (see 13.14). If an operational item is given that directly specifies an aspect of a type, then it is illegal to give another operational item that directly specifies the same aspect of the type. 
Ramification: Unlike representation items, operational items can be specified on partial views. Since they don't affect the representation, the full declaration need not be known to determine their legality. 
For an untagged derived type, no type-related representation items are allowed if the parent type is a by-reference type, or has any user-defined primitive subprograms. 
Ramification: {8652/0009} {AI95-00137-01} On the other hand, subtype-specific representation items may be given for the first subtype of such a type, as can operational items
Reason: The reason for forbidding type-related representation items on untagged by-reference types is because a change of representation is impossible when passing by reference (to an inherited subprogram). The reason for forbidding type-related representation items on untagged types with user-defined primitive subprograms was to prevent implicit change of representation for type-related aspects of representation upon calling inherited subprograms, because such changes of representation are likely to be expensive at run time. Changes of subtype-specific representation attributes, however, are likely to be cheap. This rule is not needed for tagged types, because other rules prevent a type-related representation item from changing the representation of the parent part; we want to allow a type-related representation item on a type extension to specify aspects of the extension part. For example, a pragma Pack will cause packing of the extension part, but not of the parent part. 
 {8652/0009} {AI95-00137-01} {8652/0011} {AI95-00117-01} {AI95-00326-01} Operational and r Representation aspects of a generic formal parameter are the same as those of the actual. Operational and representation aspects of a partial view are the same for all views of a type as those of the full view. A type-related representation item is not allowed for a descendant of a generic formal untagged type. 
Ramification: {8652/0009} {AI95-00137-01} Representation items are allowed for types whose subcomponent types or index subtypes are generic formal types. Operational items and subtype-related representation items are allowed on descendants of generic formal types. 
Reason: Since it is not known whether a formal type has user-defined primitive subprograms, specifying type-related representation items for them is not allowed, unless they are tagged (in which case only the extension part is affected in any case). 
Ramification: {AI95-00326-01} All views of a type, including the incomplete and partial views, have the same operational and representation aspects. That's important so that the properties don't change when changing views. While most aspects are not available for an incomplete view, we don't want to leave any holes by not saying that they are the same.
A representation item that specifies the Size for a given subtype, or the size or storage place for an object (including a component) of a given subtype, shall allow for enough storage space to accommodate any value of the subtype.
 {8652/0009} {AI95-00137-01} A representation or operational item that is not supported by the implementation is illegal, or raises an exception at run time.
   {AI95-00251-01} A type_declaration is illegal if it has one or more progenitors, and a representation item applies to an ancestor, and this representation item conflicts with the representation of some other ancestor. The cases that cause conflicts are implementation defined. 
Implementation defined: The cases that cause conflicts between the representation of the ancestors of a type_declaration.
Reason: This rule is needed because it may be the case that only the combination of types in a type declaration causes a conflict. Thus it is not possible, in general, to reject the original representation item. For instance:
package Pkg1 is
   type Ifc is interface;
   type T is tagged record
      Fld : Integer;
   end record;
   for T use record
      Fld at 0 range 0 .. Integer'Size - 1;
   end record;
end Pkg1;
Assume the implementation uses a single tag with a default offset of zero, and that it allows the use of non-default locations for the tag (and thus accepts representation items like the one above). The representation item will force a non-default location for the tag (by putting a component other than the tag into the default location). Clearly, this package will be accepted by the implementation. However, other declarations could cause trouble. For instance, the implementation could reject:
with Pkg1;
package Pkg2 is
   type NewT is new Pkg1.T and Pkg1.Ifc with null record;
end Pkg2;
because the declarations of T and Ifc have a conflict in their representation items. This is clearly necessary (it's hard to imagine how Ifc'Class could work with the tag at a location other than the one it is expecting).
Conflicts will usually involve implementation-defined attributes (for specifying the location of the tag, for instance), although the example above shows that doesn't have to be the case. For this reason, we didn't try to specify exactly what causes a conflict; it will depend on the implementation's implementation model and what representation items it allows. 
Implementation Note: An implementation can only use this rule to reject type_declarations where one its ancestors has a representation item. An implementation must ensure that the default representations of ancestors cannot conflict.

Static Semantics

If two subtypes statically match, then their subtype-specific aspects (Size and Alignment) are the same. {statically matching (effect on subtype-specific aspects) [partial]}
Reason: This is necessary because we allow (for example) conversion between access types whose designated subtypes statically match. Note that it is illegal to specify an aspect (including a subtype-specific one) for a nonfirst subtype.
Consider, for example: 
package P1 is
    subtype S1 is Integer range 0..2**16-1;
    for S1'Size use 16; -- Illegal!
        -- S1'Size would be 16 by default.
    type A1 is access all S1;
    X1: A1;
end P1;
package P2 is
    subtype S2 is Integer range 0..2**16-1;
    for S2'Size use 32; -- Illegal!
    type A2 is access all S2;
    X2: A2;
end P2;
procedure Q is
    use P1, P2;
    type Array1 is array(Integer range <>) of aliased S1;
    pragma Pack(Array1);
    Obj1: Array1(1..100);
    type Array2 is array(Integer range <>) of aliased S2;
    pragma Pack(Array2);
    Obj2: Array2(1..100);
    X1 := Obj2(17)'Unchecked_ Access;
    X2 := Obj1(17)'Unchecked_ Access;
end Q;
Loads and stores through X1 would read and write 16 bits, but X1 points to a 32-bit location. Depending on the endianness of the machine, loads might load the wrong 16 bits. Stores would fail to zero the other half in any case.
Loads and stores through X2 would read and write 32 bits, but X2 points to a 16-bit location. Thus, adjacent memory locations would be trashed.
Hence, the above is illegal. Furthermore, the compiler is forbidden from choosing different Sizes by default, for the same reason.
The same issues apply to Alignment.
 {8652/0040} {AI95-00108-01} A derived type inherits each type-related aspect of representation of its parent type that was directly specified before the declaration of the derived type, or (in the case where the parent is derived) that was inherited by the parent type from the grandparent type. A derived subtype inherits each subtype-specific aspect of representation of its parent subtype that was directly specified before the declaration of the derived type, or (in the case where the parent is derived) that was inherited by the parent subtype from the grandparent subtype, but only if the parent subtype statically matches the first subtype of the parent type. An inherited aspect of representation is overridden by a subsequent representation item that specifies the same aspect of the type or subtype. 
To be honest: A record_representation_clause for a record extension does not override the layout of the parent part; if the layout was specified for the parent type, it is inherited by the record extension. 
Ramification: If a representation item for the parent appears after the derived_type_definition, then inheritance does not happen for that representation item. 
   {8652/0040} {AI95-00108-01} {AI95-00444-01} In contrast, whether operational aspects are inherited by an untagged a derived type depends on each specific aspect. [Operational aspects are never inherited for a tagged type.] When operational aspects are inherited by an untagged a derived type, aspects that were directly specified by operational items that are visible at the point before the declaration of the derived type declaration, or (in the case where the parent is derived) that were inherited by the parent type from the grandparent type are inherited. An inherited operational aspect is overridden by a subsequent operational item that specifies the same aspect of the type.
Ramification: As with representation items, if an operational item for the parent appears after the derived_type_definition, then inheritance does not happen for that operational item. 
Discussion: {AI95-00444-01} Only Currently, only untagged types inherit operational aspects. Inheritance from tagged types causes problems, as the different views can have different visibility on operational items — potentially leading to operational items that depend on the view. We want aspects to be the same for all views. Untagged types don't have this problem as plain private types don't have ancestors, and thus can't inherit anything. In addition, it seems unlikely that we'll need inheritance for tagged types, as usually we'll want to incorporate the parent's operation into a new one that also handles any extension components. We considered writing this rule that way, but rejected it as that could be too specific for future operational aspects. (After all, that is precisely the problem that caused us to introduce “operational aspects” in the first place.) 
   {AI95-00444-01} When an aspect that is a subprogram is inherited, the derived type inherits the aspect in the same way that a derived type inherits a user-defined primitive subprogram from its parent (see 3.4).
Reason: This defines the parameter names and types, and the needed implicit conversions.
Each aspect of representation of an entity is as follows: 
Ramification: This rule implies that queries of the aspect return the specified value. For example, if the user writes “for X'Size use 32;”, then a query of X'Size will return 32. 
Ramification: {8652/0009} {AI95-00137-01} Note that representation items representation_clauses can affect the semantics of the entity.
The rules forbid things like “for S'Base'Alignment use ...” and “for S'Base use record ...”. 
Discussion: The intent is that implementations will represent the components of a composite value in the same way for all subtypes of a given composite type. Hence, Component_Size and record layout are type-related aspects. 
   {8652/0040} {AI95-00108-01} {specified (of an operational aspect of an entity)} If an operational aspect is specified for an entity (meaning that it is either directly specified or inherited), then that aspect of the entity is as specified. Otherwise, the aspect of the entity has the default value for that aspect.
   {AI95-00291-02} A representation item that specifies an aspect of representation that would have been chosen in the absence of the representation item is said to be confirming.{confirming (representation item)}

Dynamic Semantics

 {8652/0009} {AI95-00137-01} {elaboration (aspect_clause) [partial]} {elaboration (representation_clause) [partial]} For the elaboration of an aspect_clause a representation_clause, any evaluable constructs within it are evaluated. 
Ramification: Elaboration of representation pragmas is covered by the general rules for pragmas in Section 2. 

Implementation Permissions

An implementation may interpret aspects of representation in an implementation-defined manner. An implementation may place implementation-defined restrictions on representation items. {recommended level of support [distributed]} A recommended level of support is specified for representation items and related features in each subclause. These recommendations are changed to requirements for implementations that support the Systems Programming Annex (see C.2, “Required Representation Support”).
Implementation defined: The interpretation of each aspect of representation.
Implementation defined: Any restrictions placed upon representation items.
Ramification: Implementation-defined restrictions may be enforced either at compile time or at run time. There is no requirement that an implementation justify any such restrictions. They can be based on avoiding implementation complexity, or on avoiding excessive inefficiency, for example.
{8652/0009} {AI95-00137-01} There is no such permission for operational aspects.

Implementation Advice

{recommended level of support (with respect to nonstatic expressions) [partial]} The recommended level of support for all representation items is qualified as follows: 
To be honest: A confirming representation item might not be possible for some entities. For instance, consider an unconstrained array. The size of such a type is implementation-defined, and might not actually be a representable value, or might not be static. 
Reason: This is to avoid the following sort of thing: 
X : Integer := F(...);
Y : Address := G(...);
for X'Address use Y;
In the above, we have to evaluate the initialization expression for X before we know where to put the result. This seems like an unreasonable implementation burden.
The above code should instead be written like this: 
Y : constant Address := G(...);
X : Integer := F(...);
for X'Address use Y;
This allows the expression “Y” to be safely evaluated before X is created.
The constant could be a formal parameter of mode in.
An implementation can support other nonstatic expressions if it wants to. Expressions of type Address are hardly ever static, but their value might be known at compile time anyway in many cases. 
Reason: The intent is that access types, type System.Address, and the pointer used for a by-reference parameter should be implementable as a single machine address — bit-field pointers should not be required. (There is no requirement that this implementation be used — we just want to make sure it's its feasible.) 
Implementation Note: {AI95-00291-02} We want subprograms to be able to assume the properties of the types of their parameters inside of subprograms. While many objects can be copied to allow this (and thus do not need limitations), aliased or by-reference objects cannot be copied (their memory location is part of their identity). Thus, Note that the above rule does not apply to types that merely allow by-reference parameter passing; for such types, a copy typically needs to be made at the call site when a bit-aligned component is passed as a parameter.
Reason: Since all bits of elementary objects participate in operations, aliased objects must not have a different size than that assumed by users of the access type. 
Reason: Unlike elementary objects, there is no requirement that all bits of a composite object participate in operations. Thus, as long as the object is the same or larger in size than that expected by the access type, all is well. 
Ramification: This rule presumes that the implementation allocates an object of a size specified to be larger than the default size in such a way that access of the default size suffices to correctly read and write the value of the object.
Reason: Aspects of representations are often not well-defined for such types.
Ramification: {AI95-00291-02} A pragma Pack will typically not pack so tightly as to disobey the above rules rule. A Component_Size clause or record_representation_clause will typically be by illegal if it disobeys the above rules rule. Atomic components have similar restrictions (see C.6, “Shared Variable Control”). 
 {AI95-00291-02} For purposes of these rules, the determination of whether a representation item applied to a type could cause an object to have some property is based solely on the properties of the type itself, not on any available information about how the type is used. In particular, it presumes that minimally aligned objects of this type might be declared at some point. 
Implementation Advice: The recommended level of support for all representation items should be followed.

Incompatibilities With Ada 83

{incompatibilities with Ada 83} It is now illegal for a representation item to cause a derived by-reference type to have a different record layout from its parent. This is necessary for by-reference parameter passing to be feasible. This only affects programs that specify the representation of types derived from types containing tasks; most by-reference types are new to Ada 95. For example, if A1 is an array of tasks, and A2 is derived from A1, it is illegal to apply a pragma Pack to A2. 

Extensions to Ada 83

{8652/0009} {AI95-00137-01} {extensions to Ada 83} Ada 95 allows additional aspect_clauses representation_clauses for objects. 

Wording Changes from Ada 83

{8652/0009} {AI95-00137-01} The syntax rule for type_representation_clause is removed; the right-hand side of that rule is moved up to where it was used, in aspect_clause representation_clause. There are two references to “type representation clause” in RM83, both in Section 13; these have been reworded. Also, the representation_clause has been renamed the aspect_clause to reflect that it can be used to control more than just representation aspects.
{8652/0009} {AI95-00137-01} {AI95-00114-01} We have defined a new term “representation item,” which includes all representation clauses representation_clauses and representation pragmas, as well as component_clauses. This is convenient because the rules are almost identical for all of them three. We have also defined the new terms “operational item” and “operational aspects” in order to conveniently handle new types of specifiable specifable entities.
All of the forcing occurrence stuff has been moved into its own subclause (see 13.14), and rewritten to use the term “freezing”.
RM83-13.1(10) requires implementation-defined restrictions on representation items to be enforced at compile time. However, that is impossible in some cases. If the user specifies a junk (nonstatic) address in an address clause, and the implementation chooses to detect the error (for example, using hardware memory management with protected pages), then it's clearly going to be a run-time error. It seems silly to call that “semantics” rather than “a restriction.”
RM83-13.1(10) tries to pretend that representation_clauses don't affect the semantics of the program. One counter-example is the Small clause. Ada 95 has more counter-examples. We have noted the opposite above.
Some of the more stringent requirements are moved to C.2, “Required Representation Support”. 

Extensions to Ada 95

{AI95-00291-02} {extensions to Ada 95} Amendment Correction: Confirming representation items are defined, and the recommended level of support is now that they always be supported.

Wording Changes from Ada 95

{8652/0009} {AI95-00137-01} Corrigendum: Added operational items in order to eliminate unnecessary restrictions and permissions on stream attributes. As part of this, representation_clause was renamed to aspect_clause.
{8652/0009} {AI95-00137-01} {AI95-00326-01} Corrigendum: Added wording to say that the partial and full views have the same operational and representation aspects. Ada 2005 extends this to cover all views, including the incomplete view.
{8652/0040} {AI95-00108-01} Corrigendum: Changed operational items to have inheritance specified for each such aspect.
{AI95-00251-01} Added wording to allow the rejection of types with progenitors that have conflicting representation items.
{AI95-00291-02} The description of the representation of an object was clarified (with great difficulty reaching agreement). Added wording to say that representation items on aliased and by-reference objects never need be supported if they would not be implementable without distributed overhead even if other recommended level of support says otherwise. This wording matches the rules with reality.
{AI95-00444-01} Added wording so that inheritance depends on whether operational items are visible rather than whether they occur before the declaration (we don't want to look into private parts). Limited operational inheritance to untagged types to avoid anomolies with private extensions (this is not incompatible, no existing operational attribute used this capability). Also added wording to clearly define that subprogram inheritance works like derivation of subprograms. 

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