7.2 Package Bodies
In contrast to the entities declared in the visible
part of a package, the entities declared in the
package_body
are visible only within the
package_body
itself. As a consequence, a package with a
package_body
can be used for the construction of a group of related subprograms in
which the logical operations available to clients are clearly isolated
from the internal entities.
Syntax
Legality Rules
Static Semantics
In any
package_body
without
statements
there is an implicit
null_statement.
For any
package_declaration
without an explicit completion, there is an implicit
package_body
containing a single
null_statement.
For a noninstance, nonlibrary package, this body occurs at the end of
the
declarative_part
of the innermost enclosing program unit or
block_statement;
if there are several such packages, the order of the implicit
package_bodies
is unspecified.
(For an instance, the implicit
package_body
occurs at the place of the instantiation (see
12.3).
For a library package, the place is partially determined by the elaboration
dependences (see Clause
10).)
Dynamic Semantics
NOTE 1 A variable declared in the
body of a package is only visible within this body and, consequently,
its value can only be changed within the
package_body.
In the absence of local tasks, the value of such a variable remains unchanged
between calls issued from outside the package to subprograms declared
in the visible part. The properties of such a variable are similar to
those of a “static” variable of C.
NOTE 2 The elaboration of the body
of a subprogram explicitly declared in the visible part of a package
is caused by the elaboration of the body of the package. Hence a call
of such a subprogram by an outside program unit raises the exception
Program_Error if the call takes place before the elaboration of the
package_body
(see
3.11).
Examples
Example of a package
body (see 7.1):
package body Rational_Numbers is
procedure Same_Denominator (X,Y : in out Rational) is
begin
-- reduces X and Y to the same denominator:
...
end Same_Denominator;
function "="(X,Y : Rational) return Boolean is
U : Rational := X;
V : Rational := Y;
begin
Same_Denominator (U,V);
return U.Numerator = V.Numerator;
end "=";
function "/" (X,Y : Integer) return Rational is
begin
if Y > 0 then
return (Numerator => X, Denominator => Y);
else
return (Numerator => -X, Denominator => -Y);
end if;
end "/";
function "+" (X,Y : Rational) return Rational is ... end "+";
function "-" (X,Y : Rational) return Rational is ... end "-";
function "*" (X,Y : Rational) return Rational is ... end "*";
function "/" (X,Y : Rational) return Rational is ... end "/";
end Rational_Numbers;
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