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B.1 Interfacing Pragmas
1
A pragma
Import is used to import an entity defined in a foreign language into
an Ada program, thus allowing a foreign-language subprogram to be called
from Ada, or a foreign-language variable to be accessed from Ada. In
contrast, a pragma Export is used
to export an Ada entity to a foreign language, thus allowing an Ada subprogram
to be called from a foreign language, or an Ada object to be accessed
from a foreign language. The pragmas
Import and Export are intended primarily for objects and subprograms,
although implementations are allowed to support other entities.
2
A pragma
Convention is used to specify that an Ada entity should use the conventions
of another language. It is intended primarily for types and ``callback''
subprograms. For example, ``pragma Convention(Fortran, Matrix);''
implies that Matrix should be represented according to the conventions
of the supported Fortran implementation, namely column-major order.
3
A pragma
Linker_Options is used to specify the system linker parameters needed
when a given compilation unit is included in a partition.
Syntax
4
{interfacing
pragma [distributed]} {interfacing
pragma (Import) [partial]} {pragma,
interfacing (Import) [partial]} {interfacing
pragma (Export) [partial]} {pragma,
interfacing (Export) [partial]} {interfacing
pragma (Convention) [partial]} {pragma,
interfacing (Convention) [partial]} {pragma,
interfacing (Linker_Options) [partial]} An
interfacing pragma is a representation
pragma
that is one of the
pragmas Import,
Export, or Convention. Their forms, together with that of the related
pragma Linker_Options, are as follows:
5
pragma Import(
[Convention =>]
convention_identifier,
[Entity =>]
local_name
[, [External_Name =>]
string_expression]
[, [Link_Name =>]
string_expression]);
6
pragma Export(
[Convention =>]
convention_identifier,
[Entity =>]
local_name
[, [External_Name =>]
string_expression]
[, [Link_Name =>]
string_expression]);
7
pragma Convention([Convention
=>]
convention_identifier,[Entity
=>]
local_name);
8
pragma Linker_Options(
string_expression);
9
A pragma
Linker_Options is allowed only at the place of a declarative_item.
9.1/1
{
8652/0058}
For pragmas Import and Export, the argument
for Link_Name shall not be given without the pragma_argument_identifier
unless the argument for External_Name is given.
Name Resolution Rules
10
{expected type (link name)
[partial]} The expected type for a
string_expression
in an interfacing pragma or in pragma Linker_Options is String.
10.a
Ramification: There is
no language-defined support for external or link names of type Wide_String,
or of other string types. Implementations may, of course, have additional
pragmas for that purpose. Note that allowing both String and Wide_String
in the same pragma would cause ambiguities.
Legality Rules
11
{convention}
The
convention_identifier
of an interfacing pragma shall be the name of a
convention. The convention
names are implementation defined, except for certain language-defined ones,
such as Ada and Intrinsic, as explained in
6.3.1,
``
Conformance Rules''. [Additional convention names
generally represent the calling conventions of foreign languages, language implementations,
or specific run-time models.]
{calling convention}
The convention of a callable entity is its
calling convention.
11.a
Implementation defined: Implementation-defined
convention names.
11.b
Discussion: We considered
representing the convention names using an enumeration type declared
in System. Then, convention_identifier
would be changed to convention_name,
and we would make its expected type be the enumeration type. We didn't
do this because it seems to introduce extra complexity, and because the
list of available languages is better represented as the list of children
of package Interfaces -- a more open-ended sort of list.
12
{compatible
(a type, with a convention)} If
L
is a
convention_identifier
for a language, then a type T is said to be
compatible with convention
L, (alternatively, is said to be an
L-compatible type) if
any of the following conditions are met:
13
- T is declared in a language interface package corresponding to
L and is defined to be L-compatible (see B.3,
B.3.1, B.3.2, B.4,
B.5),
14
- {eligible (a type, for a convention)}
Convention L has been specified for T in a
pragma Convention, and T is eligible
for convention L; that is:
15
- T is an array type with either an unconstrained or statically-constrained
first subtype, and its component type is L-compatible,
16
- T is a record type that has no discriminants and that only
has components with statically-constrained subtypes, and each component
type is L-compatible,
17
- T is an access-to-object type, and its designated type
is L-compatible,
18
- T is an access-to-subprogram type, and its designated profile's
parameter and result types are all L-compatible.
19
- T is derived from an L-compatible type,
20
- The implementation permits T as an L-compatible
type.
20.a
Discussion: For example,
an implementation might permit Integer as a C-compatible type, though
the C type to which it corresponds might be different in different environments.
21
If pragma
Convention applies to a type, then the type shall either be compatible
with or eligible for the convention specified in the pragma.
21.a
Ramification: If a type
is derived from an L-compatible type, the derived type is by default
L-compatible, but it is also permitted to specify pragma Convention
for the derived type.
21.b
It is permitted to specify pragma
Convention for an incomplete type, but in the complete declaration each
component must be L-compatible.
21.c
If each component of a record
type is L-compatible, then the record type itself is only L-compatible
if it has a pragma Convention.
22
A
pragma
Import shall be the completion of a declaration.
{notwithstanding}
Notwithstanding any rule to the contrary, a
pragma
Import may serve as the completion of any kind of (explicit) declaration
if supported by an implementation for that kind of declaration. If a
completion is a
pragma Import, then
it shall appear in the same
declarative_part,
package_specification,
task_definition
or
protected_definition as the declaration.
For a library unit, it shall appear in the same
compilation,
before any subsequent
compilation_units
other than
pragmas. If the
local_name
denotes more than one entity, then the
pragma
Import is the completion of all of them.
22.a
Discussion: For declarations
of deferred constants and subprograms, we mention pragma Import explicitly
as a possible completion. For other declarations that require completions,
we ignore the possibility of pragma Import. Nevertheless, if an implementation
chooses to allow a pragma Import
to complete the declaration of a task, protected type, incomplete type,
private type, etc., it may do so, and the normal completion is then not
allowed for that declaration.
23
{imported entity}
{exported entity} An
entity specified as the Entity argument to a
pragma
Import (or
pragma Export) is said
to be
imported (respectively,
exported).
24
The declaration of an imported object shall not
include an explicit initialization expression. [Default initializations
are not performed.]
24.a
Proof: This follows from
the ``Notwithstanding ...'' wording in the Dynamics Semantics paragraphs
below.
25
The type of an imported or exported object shall
be compatible with the convention specified in the corresponding pragma.
25.a
Ramification: This implies,
for example, that importing an Integer object might be illegal, whereas
importing an object of type Interfaces.C.int would be permitted.
26
For an imported or exported subprogram, the result
and parameter types shall each be compatible with the convention specified
in the corresponding pragma.
27
The external name and link name string_expressions
of a pragma Import or Export, and
the string_expression of
a pragma Linker_Options, shall be
static.
Static Semantics
28
{representation pragma (Import)
[partial]} {pragma, representation
(Import) [partial]} {representation
pragma (Export) [partial]} {pragma,
representation (Export) [partial]} {representation
pragma (Convention) [partial]} {pragma,
representation (Convention) [partial]} {aspect
of representation (convention, calling convention) [partial]}
{convention (aspect of representation)}
Import, Export, and Convention
pragmas
are representation pragmas that specify the
convention aspect
of representation.
{aspect of representation (imported)
[partial]} {imported (aspect
of representation)} {aspect
of representation (exported) [partial]} {exported
(aspect of representation)} In addition,
Import and Export
pragmas specify
the
imported and
exported aspects of representation, respectively.
29
{program unit pragma
(Import) [partial]} {pragma,
program unit (Import) [partial]} {program
unit pragma (Export) [partial]} {pragma,
program unit (Export) [partial]} {program
unit pragma (Convention) [partial]} {pragma,
program unit (Convention) [partial]} An interfacing
pragma is a program unit pragma when applied to a program unit (see
10.1.5).
30
An interfacing
pragma defines the convention of the entity denoted by the local_name.
The convention represents the calling convention or representation convention
of the entity. For an access-to-subprogram type, it represents the calling
convention of designated subprograms. In addition:
31
- A pragma Import specifies
that the entity is defined externally (that is, outside the Ada program).
32
- A pragma Export specifies
that the entity is used externally.
33
- A pragma Import or
Export optionally specifies an entity's external name, link name, or
both.
34
{external name} An
external name is a string value for the name used by a foreign
language program either for an entity that an Ada program imports, or
for referring to an entity that an Ada program exports.
35
{link name} A
link name is a string value for the name of an exported or imported
entity, based on the conventions of the foreign language's compiler in
interfacing with the system's linker tool.
36
The meaning of link names is implementation defined.
If neither a link name nor the Address attribute of an imported or exported
entity is specified, then a link name is chosen in an implementation-defined
manner, based on the external name if one is specified.
36.a
Implementation defined: The
meaning of link names.
36.b
Ramification: For example,
an implementation might always prepend "_", and then pass it
to the system linker.
36.c
Implementation defined: The
manner of choosing link names when neither the link name nor the address
of an imported or exported entity is specified.
36.d
Ramification: Normally,
this will be the entity's defining name, or some simple transformation
thereof.
37
Pragma Linker_Options has the effect of passing
its string argument as a parameter to the system linker (if one exists),
if the immediately enclosing compilation unit is included in the partition
being linked. The interpretation of the string argument, and the way
in which the string arguments from multiple Linker_Options pragmas are
combined, is implementation defined.
37.a
Implementation defined: The
effect of pragma Linker_Options.
Dynamic Semantics
38
{elaboration (declaration named
by a pragma Import) [partial]} {notwithstanding}
Notwithstanding what this International Standard
says elsewhere, the elaboration of a declaration denoted by the
local_name
of a
pragma Import does not create
the entity. Such an elaboration has no other effect than to allow the
defining name to denote the external entity.
38.a
Ramification: This implies
that default initializations are skipped. (Explicit initializations are
illegal.) For example, an imported access object is not initialized
to null.
38.b
Note that the local_name
in a pragma Import might denote
more than one declaration; in that case, the entity of all of those declarations
will be the external entity.
38.c
Discussion: This ``notwithstanding''
wording is better than saying ``unless named by a pragma
Import'' on every definition of elaboration. It says we recognize the
contradiction, and this rule takes precedence.
Implementation Advice
39
If an implementation supports pragma Export to
a given language, then it should also allow the main subprogram to be
written in that language. It should support some mechanism for invoking
the elaboration of the Ada library units included in the system, and
for invoking the finalization of the environment task. On typical systems,
the recommended mechanism is to provide two subprograms whose link names
are "adainit" and "adafinal". Adainit should contain
the elaboration code for library units. Adafinal should contain the finalization
code. These subprograms should have no effect the second and subsequent
time they are called.
{adainit} {adafinal}
{Elaboration (of library units for
a foreign language main subprogram)} {Finalization
(of environment task for a foreign language main subprogram)}
39.a
Ramification: For example,
if the main subprogram is written in C, it can call adainit before the
first call to an Ada subprogram, and adafinal after the last.
40
Automatic elaboration of preelaborated packages
should be provided when pragma Export
is supported.
41
For each supported convention L other
than Intrinsic, an implementation should support Import and Export pragmas
for objects of L-compatible types and for subprograms, and pragma
Convention for L-eligible types and for subprograms, presuming
the other language has corresponding features. Pragma
Convention need not be supported for scalar types.
41.a
Reason: Pragma Convention
is not necessary for scalar types, since the language interface packages
declare scalar types corresponding to those provided by the respective
foreign languages.
41.b
Implementation Note: If
an implementation supports interfacing to C++, it should do so via the
convention identifier C_Plus_Plus (in additional to any C++-implementation-specific
ones).
41.c
Reason: The reason for
giving the advice about C++ is to encourage uniformity among implementations,
given that the name of the language is not syntactically legal as an
identifier. We place this advice
in the AARM, rather than the RM95 proper, because (as of this writing)
C++ is not an international standard, and we don't want to refer to a
such a language from an international standard.
42
1 Implementations may place
restrictions on interfacing pragmas; for example, requiring each exported
entity to be declared at the library level.
42.a
Proof: Arbitrary restrictions are
allowed by 13.1.
42.b
Ramification: Such a restriction
might be to disallow them altogether. Alternatively, the implementation
might allow them only for certain kinds of entities, or only for certain
conventions.
43
2 A pragma
Import specifies the conventions for accessing external entities. It
is possible that the actual entity is written in assembly language, but
reflects the conventions of a particular language. For example, pragma
Import(Ada, ...) can be used to interface to an assembly language routine
that obeys the Ada compiler's calling conventions.
44
3 To obtain ``call-back''
to an Ada subprogram from a foreign language environment, pragma
Convention should be specified both for the access-to-subprogram type
and the specific subprogram(s) to which 'Access is applied.
45
4 It is illegal to specify
more than one of Import, Export, or Convention for a given entity.
46
5 The local_name
in an interfacing pragma can denote more than one entity in the case
of overloading. Such a pragma applies
to all of the denoted entities.
47
47.a
Ramification: The Intrinsic convention
(see 6.3.1) implies that the entity is somehow ``built
in'' to the implementation. Thus, it generally does not make sense for users
to specify Intrinsic in a pragma Import.
The intention is that only implementations will specify Intrinsic in a pragma
Import. The language also defines certain subprograms to be Intrinsic.
47.b
Discussion: There are many
imaginable interfacing pragmas that don't make any sense. For example,
setting the Convention of a protected procedure to Ada is probably wrong.
Rather than enumerating all such cases, however, we leave it up to implementations
to decide what is sensible.
48
7 If both External_Name and
Link_Name are specified for an Import or Export pragma, then the External_Name
is ignored.
49
8 An interfacing pragma might
result in an effect that violates Ada semantics.
Examples
50
Example of interfacing
pragmas:
51
package Fortran_Library is
function Sqrt (X : Float) return Float;
function Exp (X : Float) return Float;
private
pragma Import(Fortran, Sqrt);
pragma Import(Fortran, Exp);
end Fortran_Library;
Extensions to Ada 83
51.a
{extensions to Ada 83}
Interfacing pragmas are new to Ada 95. Pragma Import
replaces Ada 83's pragma Interface. Existing implementations can continue
to support pragma Interface for upward compatibility.
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