llvm-gcc-4.0/gcc/testsuite/ada/acats/tests/cd/cdd2a01.a - llvm-archive - Git at Google

 -- CDD2A01.A
 --
 --                             Grant of Unlimited Rights
 --
 --     The Ada Conformity Assessment Authority (ACAA) holds unlimited
 --     rights in the software and documentation contained herein. Unlimited
 --     rights are the same as those granted by the U.S. Government for older
 --     parts of the Ada Conformity Assessment Test Suite, and are defined
 --     in DFAR 252.227-7013(a)(19). By making this public release, the ACAA
 --     intends to confer upon all recipients unlimited rights equal to those
 --     held by the ACAA. These rights include rights to use, duplicate,
 --     release or disclose the released technical data and computer software
 --     in whole or in part, in any manner and for any purpose whatsoever, and
 --     to have or permit others to do so.
 --
 --                                    DISCLAIMER
 --
 --     ALL MATERIALS OR INFORMATION HEREIN RELEASED, MADE AVAILABLE OR
 --     DISCLOSED ARE AS IS.  THE GOVERNMENT MAKES NO EXPRESS OR IMPLIED
 --     WARRANTY AS TO ANY MATTER WHATSOEVER, INCLUDING THE CONDITIONS OF THE
 --     SOFTWARE, DOCUMENTATION OR OTHER INFORMATION RELEASED, MADE AVAILABLE
 --     OR DISCLOSED, OR THE OWNERSHIP, MERCHANTABILITY, OR FITNESS FOR A
 --     PARTICULAR PURPOSE OF SAID MATERIAL.
 --*
 --
 -- OBJECTIVE:
 --    Check that the Read and Write attributes for a type extension are created
 --    from the parent type's attribute (which may be user-defined) and those
 --    for the extension components.  Also check that the default Input and
 --    Output attributes are used for a type extension, even if the parent
 --    type's attribute is user-defined.  (Defect Report 8652/0040,
 --     as reflected in Technical Corrigendum 1, penultimate sentence of
 --     13.13.2(9/1) and 13.13.2(25/1)).
 --
 -- CHANGE HISTORY:
 --    30 JUL 2001   PHL   Initial version.
 --     5 DEC 2001   RLB   Reformatted for ACATS.
 --
 --!
 with Ada.Streams;
 use Ada.Streams;
 with FDD2A00;
 use FDD2A00;
 with Report;
 use Report;
 procedure CDD2A01 is

     Input_Output_Error : exception;

     type Int is range 1 .. 1000;
     type Str is array (Int range <>) of Character;

     procedure Read (Stream : access Root_Stream_Type'Class;
                     Item : out Int'Base);
     procedure Write (Stream : access Root_Stream_Type'Class; Item : Int'Base);
     function Input (Stream : access Root_Stream_Type'Class) return Int'Base;
     procedure Output (Stream : access Root_Stream_Type'Class; Item : Int'Base);

     for Int'Read use Read;
     for Int'Write use Write;
     for Int'Input use Input;
     for Int'Output use Output;


     type Parent (D1, D2 : Int; B : Boolean) is tagged
         record
             S : Str (D1 .. D2);
             case B is
                 when False =>
                     C1 : Integer;
                 when True =>
                     C2 : Float;
             end case;
         end record;

     procedure Read (Stream : access Root_Stream_Type'Class; Item : out Parent);
     procedure Write (Stream : access Root_Stream_Type'Class; Item : Parent);
     function Input (Stream : access Root_Stream_Type'Class) return Parent;
     procedure Output (Stream : access Root_Stream_Type'Class; Item : Parent);

     for Parent'Read use Read;
     for Parent'Write use Write;
     for Parent'Input use Input;
     for Parent'Output use Output;


     procedure Actual_Read
                  (Stream : access Root_Stream_Type'Class; Item : out Int) is
     begin
         Integer'Read (Stream, Integer (Item));
     end Actual_Read;

     procedure Actual_Write
                  (Stream : access Root_Stream_Type'Class; Item : Int) is
     begin
         Integer'Write (Stream, Integer (Item));
     end Actual_Write;

     function Actual_Input (Stream : access Root_Stream_Type'Class) return Int is
     begin
         return Int (Integer'Input (Stream));
     end Actual_Input;

     procedure Actual_Output
                  (Stream : access Root_Stream_Type'Class; Item : Int) is
     begin
         Integer'Output (Stream, Integer (Item));
     end Actual_Output;


     procedure Actual_Read
                  (Stream : access Root_Stream_Type'Class; Item : out Parent) is
     begin
         case Item.B is
             when False =>
                 Item.C1 := 7;
             when True =>
                 Float'Read (Stream, Item.C2);
         end case;
         Str'Read (Stream, Item.S);
     end Actual_Read;

     procedure Actual_Write
                  (Stream : access Root_Stream_Type'Class; Item : Parent) is
     begin
         case Item.B is
             when False =>
                 null; -- Don't write C1
             when True =>
                 Float'Write (Stream, Item.C2);
         end case;
         Str'Write (Stream, Item.S);
     end Actual_Write;

     function Actual_Input
                 (Stream : access Root_Stream_Type'Class) return Parent is
         X : Parent (1, 1, True);
     begin
         raise Input_Output_Error;
         return X;
     end Actual_Input;

     procedure Actual_Output
                  (Stream : access Root_Stream_Type'Class; Item : Parent) is
     begin
         raise Input_Output_Error;
     end Actual_Output;

     package Int_Ops is new Counting_Stream_Ops (T => Int'Base,
                                                 Actual_Write => Actual_Write,
                                                 Actual_Input => Actual_Input,
                                                 Actual_Read => Actual_Read,
                                                 Actual_Output => Actual_Output);

     package Parent_Ops is
        new Counting_Stream_Ops (T => Parent,
                                 Actual_Write => Actual_Write,
                                 Actual_Input => Actual_Input,
                                 Actual_Read => Actual_Read,
                                 Actual_Output => Actual_Output);

     procedure Read (Stream : access Root_Stream_Type'Class; Item : out Int'Base)
        renames Int_Ops.Read;
     procedure Write (Stream : access Root_Stream_Type'Class; Item : Int'Base)
        renames Int_Ops.Write;
     function Input (Stream : access Root_Stream_Type'Class) return Int'Base
        renames Int_Ops.Input;
     procedure Output (Stream : access Root_Stream_Type'Class; Item : Int'Base)
        renames Int_Ops.Output;

     procedure Read (Stream : access Root_Stream_Type'Class; Item : out Parent)
        renames Parent_Ops.Read;
     procedure Write (Stream : access Root_Stream_Type'Class; Item : Parent)
        renames Parent_Ops.Write;
     function Input (Stream : access Root_Stream_Type'Class) return Parent
        renames Parent_Ops.Input;
     procedure Output (Stream : access Root_Stream_Type'Class; Item : Parent)
        renames Parent_Ops.Output;

     type Derived1 is new Parent with
         record
             C3 : Int;
         end record;

     type Derived2 (D : Int) is new Parent (D1 => D,
                                            D2 => D,
                                            B => False) with
         record
             C3 : Int;
         end record;

 begin
     Test ("CDD2A01",
           "Check that the Read and Write attributes for a type " &
              "extension are created from the parent type's " &
              "attribute (which may be user-defined) and those for the " &
              "extension components; also check that the default input " &
              "and output attributes are used for a type extension, even " &
              "if the parent type's attribute is user-defined");

     Test1:
         declare
             S : aliased My_Stream (1000);
             X1 : Derived1 (D1 => Int (Ident_Int (2)),
                            D2 => Int (Ident_Int (5)),
                            B => Ident_Bool (True));
             Y1 : Derived1 := (D1 => 3,
                               D2 => 6,
                               B => False,
                               S => Str (Ident_Str ("3456")),
                               C1 => Ident_Int (100),
                               C3 => Int (Ident_Int (88)));
             X2 : Derived1 (D1 => Int (Ident_Int (2)),
                            D2 => Int (Ident_Int (5)),
                            B => Ident_Bool (True));
         begin
             X1.S := Str (Ident_Str ("bcde"));
             X1.C2 := Float (Ident_Int (4));
             X1.C3 := Int (Ident_Int (99));

             Derived1'Write (S'Access, X1);
             if Int_Ops.Get_Counts /=
                (Read => 0, Write => 1, Input => 0, Output => 0) then
                 Failed ("Error writing extension components - 1");
             end if;
             if Parent_Ops.Get_Counts /=
                (Read => 0, Write => 1, Input => 0, Output => 0) then
                 Failed ("Didn't call parent type's Write - 1");
             end if;

             Derived1'Read (S'Access, X2);
             if Int_Ops.Get_Counts /=
                (Read => 1, Write => 1, Input => 0, Output => 0) then
                 Failed ("Error reading extension components - 1");
             end if;
             if Parent_Ops.Get_Counts /=
                (Read => 1, Write => 1, Input => 0, Output => 0) then
                 Failed ("Didn't call inherited Read - 1");
             end if;

             if X2 /= (D1 => 2,
                       D2 => 5,
                       B => True,
                       S => Str (Ident_Str ("bcde")),
                       C2 => Float (Ident_Int (4)),
                       C3 => Int (Ident_Int (99))) then
                 Failed
                    ("Inherited Read and Write are not inverses of each other - 1");
             end if;

             begin
                 Derived1'Output (S'Access, Y1);
                 if Int_Ops.Get_Counts /=
                    (Read => 1, Write => 4, Input => 0, Output => 0) then
                     Failed ("Error writing extension components - 2");
                 end if;
                 if Parent_Ops.Get_Counts /=
                    (Read => 1, Write => 2, Input => 0, Output => 0) then
                     Failed ("Didn't call inherited Write - 2");
                 end if;
             exception
                 when Input_Output_Error =>
                     Failed ("Did call inherited Output - 2");
             end;

             begin
                 declare
                     Y2 : Derived1 := Derived1'Input (S'Access);
                 begin
                     if Int_Ops.Get_Counts /=
                        (Read => 4, Write => 4, Input => 0, Output => 0) then
                         Failed ("Error reading extension components - 2");
                     end if;
                     if Parent_Ops.Get_Counts /=
                        (Read => 2, Write => 2, Input => 0, Output => 0) then
                         Failed ("Didn't call inherited Read - 2");
                     end if;
                     if Y2 /= (D1 => 3,
                               D2 => 6,
                               B => False,
                               S => Str (Ident_Str ("3456")),
                               C1 => Ident_Int (7),
                               C3 => Int (Ident_Int (88))) then
                         Failed
                            ("Input and Output are not inverses of each other - 2");
                     end if;
                 end;
             exception
                 when Input_Output_Error =>
                     Failed ("Did call inherited Input - 2");
             end;

         end Test1;

     Test2:
         declare
             S : aliased My_Stream (1000);
             X1 : Derived2 (D => Int (Ident_Int (7)));
             Y1 : Derived2 := (D => 8,
                               S => Str (Ident_Str ("8")),
                               C1 => Ident_Int (200),
                               C3 => Int (Ident_Int (77)));
             X2 : Derived2 (D => Int (Ident_Int (7)));
         begin
             X1.S := Str (Ident_Str ("g"));
             X1.C1 := Ident_Int (4);
             X1.C3 := Int (Ident_Int (666));

             Derived2'Write (S'Access, X1);
             if Int_Ops.Get_Counts /=
                (Read => 4, Write => 5, Input => 0, Output => 0) then
                 Failed ("Error writing extension components - 3");
             end if;
             if Parent_Ops.Get_Counts /=
                (Read => 2, Write => 3, Input => 0, Output => 0) then
                 Failed ("Didn't call inherited Write - 3");
             end if;

             Derived2'Read (S'Access, X2);
             if Int_Ops.Get_Counts /=
                (Read => 5, Write => 5, Input => 0, Output => 0) then
                 Failed ("Error reading extension components - 3");
             end if;
             if Parent_Ops.Get_Counts /=
                (Read => 3, Write => 3, Input => 0, Output => 0) then
                 Failed ("Didn't call inherited Read - 3");
             end if;

             if X2 /= (D => 7,
                       S => Str (Ident_Str ("g")),
                       C1 => Ident_Int (7),
                       C3 => Int (Ident_Int (666))) then
                 Failed ("Read and Write are not inverses of each other - 3");
             end if;

             begin
                 Derived2'Output (S'Access, Y1);
                 if Int_Ops.Get_Counts /=
                    (Read => 5, Write => 7, Input => 0, Output => 0) then
                     Failed ("Error writing extension components - 4");
                 end if;
                 if Parent_Ops.Get_Counts /=
                    (Read => 3, Write => 4, Input => 0, Output => 0) then
                     Failed ("Didn't call inherited Write - 4");
                 end if;
             exception
                 when Input_Output_Error =>
                     Failed ("Did call inherited Output - 4");
             end;

             begin
                 declare
                     Y2 : Derived2 := Derived2'Input (S'Access);
                 begin
                     if Int_Ops.Get_Counts /=
                        (Read => 7, Write => 7, Input => 0, Output => 0) then
                         Failed ("Error reading extension components - 4");
                     end if;
                     if Parent_Ops.Get_Counts /=
                        (Read => 4, Write => 4, Input => 0, Output => 0) then
                         Failed ("Didn't call inherited Read - 4");
                     end if;
                     if Y2 /= (D => 8,
                               S => Str (Ident_Str ("8")),
                               C1 => Ident_Int (7),
                               C3 => Int (Ident_Int (77))) then
                         Failed
                            ("Input and Output are not inverses of each other - 4");
                     end if;
                 end;
             exception
                 when Input_Output_Error =>
                     Failed ("Did call inherited Input - 4");
             end;

         end Test2;

     Result;
 end CDD2A01;
	-- CDD2A01.A
	--
	-- Grant of Unlimited Rights
	--
	-- The Ada Conformity Assessment Authority (ACAA) holds unlimited
	-- rights in the software and documentation contained herein. Unlimited
	-- rights are the same as those granted by the U.S. Government for older
	-- parts of the Ada Conformity Assessment Test Suite, and are defined
	-- in DFAR 252.227-7013(a)(19). By making this public release, the ACAA
	-- intends to confer upon all recipients unlimited rights equal to those
	-- held by the ACAA. These rights include rights to use, duplicate,
	-- release or disclose the released technical data and computer software
	-- in whole or in part, in any manner and for any purpose whatsoever, and
	-- to have or permit others to do so.
	--
	-- DISCLAIMER
	--
	-- ALL MATERIALS OR INFORMATION HEREIN RELEASED, MADE AVAILABLE OR
	-- DISCLOSED ARE AS IS. THE GOVERNMENT MAKES NO EXPRESS OR IMPLIED
	-- WARRANTY AS TO ANY MATTER WHATSOEVER, INCLUDING THE CONDITIONS OF THE
	-- SOFTWARE, DOCUMENTATION OR OTHER INFORMATION RELEASED, MADE AVAILABLE
	-- OR DISCLOSED, OR THE OWNERSHIP, MERCHANTABILITY, OR FITNESS FOR A
	-- PARTICULAR PURPOSE OF SAID MATERIAL.
	--*
	--
	-- OBJECTIVE:
	-- Check that the Read and Write attributes for a type extension are created
	-- from the parent type's attribute (which may be user-defined) and those
	-- for the extension components. Also check that the default Input and
	-- Output attributes are used for a type extension, even if the parent
	-- type's attribute is user-defined. (Defect Report 8652/0040,
	-- as reflected in Technical Corrigendum 1, penultimate sentence of
	-- 13.13.2(9/1) and 13.13.2(25/1)).
	--
	-- CHANGE HISTORY:
	-- 30 JUL 2001 PHL Initial version.
	-- 5 DEC 2001 RLB Reformatted for ACATS.
	--
	--!
	with Ada.Streams;
	use Ada.Streams;
	with FDD2A00;
	use FDD2A00;
	with Report;
	use Report;
	procedure CDD2A01 is

	Input_Output_Error : exception;

	type Int is range 1 .. 1000;
	type Str is array (Int range <>) of Character;

	procedure Read (Stream : access Root_Stream_Type'Class;
	Item : out Int'Base);
	procedure Write (Stream : access Root_Stream_Type'Class; Item : Int'Base);
	function Input (Stream : access Root_Stream_Type'Class) return Int'Base;
	procedure Output (Stream : access Root_Stream_Type'Class; Item : Int'Base);

	for Int'Read use Read;
	for Int'Write use Write;
	for Int'Input use Input;
	for Int'Output use Output;


	type Parent (D1, D2 : Int; B : Boolean) is tagged
	record
	S : Str (D1 .. D2);
	case B is
	when False =>
	C1 : Integer;
	when True =>
	C2 : Float;
	end case;
	end record;

	procedure Read (Stream : access Root_Stream_Type'Class; Item : out Parent);
	procedure Write (Stream : access Root_Stream_Type'Class; Item : Parent);
	function Input (Stream : access Root_Stream_Type'Class) return Parent;
	procedure Output (Stream : access Root_Stream_Type'Class; Item : Parent);

	for Parent'Read use Read;
	for Parent'Write use Write;
	for Parent'Input use Input;
	for Parent'Output use Output;


	procedure Actual_Read
	(Stream : access Root_Stream_Type'Class; Item : out Int) is
	begin
	Integer'Read (Stream, Integer (Item));
	end Actual_Read;

	procedure Actual_Write
	(Stream : access Root_Stream_Type'Class; Item : Int) is
	begin
	Integer'Write (Stream, Integer (Item));
	end Actual_Write;

	function Actual_Input (Stream : access Root_Stream_Type'Class) return Int is
	begin
	return Int (Integer'Input (Stream));
	end Actual_Input;

	procedure Actual_Output
	(Stream : access Root_Stream_Type'Class; Item : Int) is
	begin
	Integer'Output (Stream, Integer (Item));
	end Actual_Output;


	procedure Actual_Read
	(Stream : access Root_Stream_Type'Class; Item : out Parent) is
	begin
	case Item.B is
	when False =>
	Item.C1 := 7;
	when True =>
	Float'Read (Stream, Item.C2);
	end case;
	Str'Read (Stream, Item.S);
	end Actual_Read;

	procedure Actual_Write
	(Stream : access Root_Stream_Type'Class; Item : Parent) is
	begin
	case Item.B is
	when False =>
	null; -- Don't write C1
	when True =>
	Float'Write (Stream, Item.C2);
	end case;
	Str'Write (Stream, Item.S);
	end Actual_Write;

	function Actual_Input
	(Stream : access Root_Stream_Type'Class) return Parent is
	X : Parent (1, 1, True);
	begin
	raise Input_Output_Error;
	return X;
	end Actual_Input;

	procedure Actual_Output
	(Stream : access Root_Stream_Type'Class; Item : Parent) is
	begin
	raise Input_Output_Error;
	end Actual_Output;

	package Int_Ops is new Counting_Stream_Ops (T => Int'Base,
	Actual_Write => Actual_Write,
	Actual_Input => Actual_Input,
	Actual_Read => Actual_Read,
	Actual_Output => Actual_Output);

	package Parent_Ops is
	new Counting_Stream_Ops (T => Parent,
	Actual_Write => Actual_Write,
	Actual_Input => Actual_Input,
	Actual_Read => Actual_Read,
	Actual_Output => Actual_Output);

	procedure Read (Stream : access Root_Stream_Type'Class; Item : out Int'Base)
	renames Int_Ops.Read;
	procedure Write (Stream : access Root_Stream_Type'Class; Item : Int'Base)
	renames Int_Ops.Write;
	function Input (Stream : access Root_Stream_Type'Class) return Int'Base
	renames Int_Ops.Input;
	procedure Output (Stream : access Root_Stream_Type'Class; Item : Int'Base)
	renames Int_Ops.Output;

	procedure Read (Stream : access Root_Stream_Type'Class; Item : out Parent)
	renames Parent_Ops.Read;
	procedure Write (Stream : access Root_Stream_Type'Class; Item : Parent)
	renames Parent_Ops.Write;
	function Input (Stream : access Root_Stream_Type'Class) return Parent
	renames Parent_Ops.Input;
	procedure Output (Stream : access Root_Stream_Type'Class; Item : Parent)
	renames Parent_Ops.Output;

	type Derived1 is new Parent with
	record
	C3 : Int;
	end record;

	type Derived2 (D : Int) is new Parent (D1 => D,
	D2 => D,
	B => False) with
	record
	C3 : Int;
	end record;

	begin
	Test ("CDD2A01",
	"Check that the Read and Write attributes for a type " &
	"extension are created from the parent type's " &
	"attribute (which may be user-defined) and those for the " &
	"extension components; also check that the default input " &
	"and output attributes are used for a type extension, even " &
	"if the parent type's attribute is user-defined");

	Test1:
	declare
	S : aliased My_Stream (1000);
	X1 : Derived1 (D1 => Int (Ident_Int (2)),
	D2 => Int (Ident_Int (5)),
	B => Ident_Bool (True));
	Y1 : Derived1 := (D1 => 3,
	D2 => 6,
	B => False,
	S => Str (Ident_Str ("3456")),
	C1 => Ident_Int (100),
	C3 => Int (Ident_Int (88)));
	X2 : Derived1 (D1 => Int (Ident_Int (2)),
	D2 => Int (Ident_Int (5)),
	B => Ident_Bool (True));
	begin
	X1.S := Str (Ident_Str ("bcde"));
	X1.C2 := Float (Ident_Int (4));
	X1.C3 := Int (Ident_Int (99));

	Derived1'Write (S'Access, X1);
	if Int_Ops.Get_Counts /=
	(Read => 0, Write => 1, Input => 0, Output => 0) then
	Failed ("Error writing extension components - 1");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 0, Write => 1, Input => 0, Output => 0) then
	Failed ("Didn't call parent type's Write - 1");
	end if;

	Derived1'Read (S'Access, X2);
	if Int_Ops.Get_Counts /=
	(Read => 1, Write => 1, Input => 0, Output => 0) then
	Failed ("Error reading extension components - 1");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 1, Write => 1, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Read - 1");
	end if;

	if X2 /= (D1 => 2,
	D2 => 5,
	B => True,
	S => Str (Ident_Str ("bcde")),
	C2 => Float (Ident_Int (4)),
	C3 => Int (Ident_Int (99))) then
	Failed
	("Inherited Read and Write are not inverses of each other - 1");
	end if;

	begin
	Derived1'Output (S'Access, Y1);
	if Int_Ops.Get_Counts /=
	(Read => 1, Write => 4, Input => 0, Output => 0) then
	Failed ("Error writing extension components - 2");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 1, Write => 2, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Write - 2");
	end if;
	exception
	when Input_Output_Error =>
	Failed ("Did call inherited Output - 2");
	end;

	begin
	declare
	Y2 : Derived1 := Derived1'Input (S'Access);
	begin
	if Int_Ops.Get_Counts /=
	(Read => 4, Write => 4, Input => 0, Output => 0) then
	Failed ("Error reading extension components - 2");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 2, Write => 2, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Read - 2");
	end if;
	if Y2 /= (D1 => 3,
	D2 => 6,
	B => False,
	S => Str (Ident_Str ("3456")),
	C1 => Ident_Int (7),
	C3 => Int (Ident_Int (88))) then
	Failed
	("Input and Output are not inverses of each other - 2");
	end if;
	end;
	exception
	when Input_Output_Error =>
	Failed ("Did call inherited Input - 2");
	end;

	end Test1;

	Test2:
	declare
	S : aliased My_Stream (1000);
	X1 : Derived2 (D => Int (Ident_Int (7)));
	Y1 : Derived2 := (D => 8,
	S => Str (Ident_Str ("8")),
	C1 => Ident_Int (200),
	C3 => Int (Ident_Int (77)));
	X2 : Derived2 (D => Int (Ident_Int (7)));
	begin
	X1.S := Str (Ident_Str ("g"));
	X1.C1 := Ident_Int (4);
	X1.C3 := Int (Ident_Int (666));

	Derived2'Write (S'Access, X1);
	if Int_Ops.Get_Counts /=
	(Read => 4, Write => 5, Input => 0, Output => 0) then
	Failed ("Error writing extension components - 3");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 2, Write => 3, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Write - 3");
	end if;

	Derived2'Read (S'Access, X2);
	if Int_Ops.Get_Counts /=
	(Read => 5, Write => 5, Input => 0, Output => 0) then
	Failed ("Error reading extension components - 3");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 3, Write => 3, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Read - 3");
	end if;

	if X2 /= (D => 7,
	S => Str (Ident_Str ("g")),
	C1 => Ident_Int (7),
	C3 => Int (Ident_Int (666))) then
	Failed ("Read and Write are not inverses of each other - 3");
	end if;

	begin
	Derived2'Output (S'Access, Y1);
	if Int_Ops.Get_Counts /=
	(Read => 5, Write => 7, Input => 0, Output => 0) then
	Failed ("Error writing extension components - 4");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 3, Write => 4, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Write - 4");
	end if;
	exception
	when Input_Output_Error =>
	Failed ("Did call inherited Output - 4");
	end;

	begin
	declare
	Y2 : Derived2 := Derived2'Input (S'Access);
	begin
	if Int_Ops.Get_Counts /=
	(Read => 7, Write => 7, Input => 0, Output => 0) then
	Failed ("Error reading extension components - 4");
	end if;
	if Parent_Ops.Get_Counts /=
	(Read => 4, Write => 4, Input => 0, Output => 0) then
	Failed ("Didn't call inherited Read - 4");
	end if;
	if Y2 /= (D => 8,
	S => Str (Ident_Str ("8")),
	C1 => Ident_Int (7),
	C3 => Int (Ident_Int (77))) then
	Failed
	("Input and Output are not inverses of each other - 4");
	end if;
	end;
	exception
	when Input_Output_Error =>
	Failed ("Did call inherited Input - 4");
	end;

	end Test2;

	Result;
	end CDD2A01;