-- CA11001.A
--
--                             Grant of Unlimited Rights
--
--     Under contracts F33600-87-D-0337, F33600-84-D-0280, MDA903-79-C-0687,
--     F08630-91-C-0015, and DCA100-97-D-0025, the U.S. Government obtained 
--     unlimited rights in the software and documentation contained herein.
--     Unlimited rights are defined in DFAR 252.227-7013(a)(19).  By making 
--     this public release, the Government intends to confer upon all 
--     recipients unlimited rights  equal to those held by the Government.  
--     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 a child unit can be used to provide an alternate view and
--      operations on a private type in its parent package.  Check that a 
--      child unit can be a package.  Check that a WITH of a child unit 
--      includes an implicit WITH of its ancestor unit.  
--
-- TEST DESCRIPTION:
--      Declare a private type in a package specification. Declare 
--      subprograms for the type.
--
--      Add a public child to the above package.  Within the body of this
--      package, access the private type. Declare operations to read and 
--      write to its parent private type.
--
--      In the main program, "with" the child.  Declare objects of the
--      parent private type.  Access the subprograms from both parent and
--      child packages.
--
--
-- CHANGE HISTORY:
--      06 Dec 94   SAIC    ACVC 2.0
--
--!

package CA11001_0 is   -- Cartesian_Complex
--  This package represents a Cartesian view of a complex number.  It contains 
--  a private type plus subprograms to construct and decompose a complex 
--  number.

   type Complex_Int is range 0 .. 100;

   type Complex_Type is private;

   Constant_Complex : constant Complex_Type;

   Complex_Error : exception;

   procedure Cartesian_Assign   (R, I : in     Complex_Int; 
                                 C    :    out Complex_Type);

   function Cartesian_Real_Part (C : Complex_Type) 
     return Complex_Int;

   function Cartesian_Imag_Part (C : Complex_Type) 
     return Complex_Int;

   function Complex (Real, Imaginary : Complex_Int)
     return Complex_Type;                             

private
   type Complex_Type is                      -- Parent private type
      record
         Real, Imaginary : Complex_Int;
      end record;

   Constant_Complex : constant Complex_Type := (Real => 0, Imaginary => 0);

end CA11001_0;       -- Cartesian_Complex

--=======================================================================--

package body CA11001_0 is  -- Cartesian_Complex

   procedure Cartesian_Assign (R, I : in     Complex_Int; 
                               C    :    out Complex_Type) is
   begin
      C.Real      := R;
      C.Imaginary := I;
   end Cartesian_Assign;
   -------------------------------------------------------------
   function Cartesian_Real_Part (C : Complex_Type) 
     return Complex_Int is
   begin
      return C.Real;
   end Cartesian_Real_Part;
   -------------------------------------------------------------
   function Cartesian_Imag_Part (C : Complex_Type) 
     return Complex_Int is
   begin
      return C.Imaginary;
   end Cartesian_Imag_Part;
   -------------------------------------------------------------
   function Complex (Real, Imaginary : Complex_Int)
     return Complex_Type is
   begin
      return (Real, Imaginary);
   end Complex;

end CA11001_0;      -- Cartesian_Complex

--=======================================================================--

package CA11001_0.CA11001_1 is    -- Polar_Complex
--  This public child provides a different view of the private type from its
--  parent.  It provides a polar view by the provision of subprograms which
--  construct and decompose a complex number.

   procedure Polar_Assign (R, Theta : in     Complex_Int; 
                           C        :    out Complex_Type);  
                                             -- Complex_Type is a 
                                             -- record of CA11001_0

   function Polar_Real_Part (C: Complex_Type) return Complex_Int;           

   function Polar_Imag_Part (C: Complex_Type) return Complex_Int;

   function Equals_Const (Num : Complex_Type) return Boolean;

end CA11001_0.CA11001_1;    -- Polar_Complex

--=======================================================================--

package body CA11001_0.CA11001_1 is   -- Polar_Complex

   function Cos (Angle : Complex_Int) return Complex_Int is
      Num : constant Complex_Int := 2;
   begin
      return (Angle * Num);   -- not true Cosine function
   end Cos;
   -------------------------------------------------------------
   function Sine (Angle : Complex_Int) return Complex_Int is
   begin
      return 1;     -- not true Sine function
   end Sine;
   -------------------------------------------------------------
   function Sqrt (Num : Complex_Int) 
     return Complex_Int is
   begin
     return (Num);     -- not true Square root function
   end Sqrt;
   -------------------------------------------------------------
   function Tan  (Angle : Complex_Int) return Complex_Int is
   begin
     return Angle;     -- not true Tangent function
   end Tan;
   -------------------------------------------------------------
   procedure Polar_Assign (R, Theta : in     Complex_Int;  
                           C        :    out Complex_Type) is 
   begin
      if R = 0 and Theta = 0 then
         raise Complex_Error;
      end if;
      C.Real := R * Cos (Theta);
      C.Imaginary := R * Sine (Theta);
   end Polar_Assign;
   -------------------------------------------------------------
   function Polar_Real_Part (C: Complex_Type) return Complex_Int is
   begin
      return Sqrt ((Cartesian_Imag_Part (C)) ** 2 + 
                   (Cartesian_Real_Part (C)) ** 2);
   end Polar_Real_Part;
   -------------------------------------------------------------
   function Polar_Imag_Part (C: Complex_Type) return Complex_Int is
   begin
      return (Tan (Cartesian_Imag_Part (C) / 
              Cartesian_Real_Part (C)));
   end Polar_Imag_Part;
   -------------------------------------------------------------
   function Equals_Const (Num : Complex_Type) return Boolean is
   begin
      return Num.Real = Constant_Complex.Real and
         Num.Imaginary = Constant_Complex.Imaginary;
   end Equals_Const;

end CA11001_0.CA11001_1;     -- Polar_Complex

--=======================================================================--

with CA11001_0.CA11001_1;        -- Polar_Complex
with Report;

procedure CA11001 is

   Complex_No  : CA11001_0.Complex_Type;    -- Complex_Type is a
                                            -- record of CA11001_0

   Complex_5x2 : CA11001_0.Complex_Type := CA11001_0.Complex (5, 2);

   Int_2       :  CA11001_0.Complex_Int 
               := CA11001_0.Complex_Int (Report.Ident_Int (2));

begin

   Report.Test ("CA11001", "Check that a child unit can be used " &
                "to provide an alternate view and operations " &
                "on a private type in its parent package");

   Basic_View_Subtest:

   begin
      -- Assign using Cartesian coordinates.
      CA11001_0.Cartesian_Assign 
        (CA11001_0.Complex_Int (Report.Ident_Int (1)), Int_2, Complex_No);

      -- Read back in Polar coordinates.
      -- Polar values are surrogates used in checking for correct
      -- subprogram calls.
      if CA11001_0."/=" (CA11001_0.CA11001_1.Polar_Real_Part (Complex_No),
        CA11001_0.Cartesian_Real_Part (Complex_5x2)) and CA11001_0."/="
          (CA11001_0.CA11001_1.Polar_Imag_Part (Complex_No),  
            CA11001_0.Cartesian_Imag_Part (Complex_5x2)) then
           Report.Failed ("Incorrect Cartesian result");
      end if;

   end Basic_View_Subtest;
   -------------------------------------------------------------
   Alternate_View_Subtest:
   begin
      -- Assign using Polar coordinates.
      CA11001_0.CA11001_1.Polar_Assign 
        (Int_2, CA11001_0.Complex_Int (Report.Ident_Int (3)), Complex_No);

      -- Read back in Cartesian coordinates.
      if CA11001_0."/=" (CA11001_0.Cartesian_Real_Part 
        (Complex_No), CA11001_0.Complex_Int (Report.Ident_Int (12))) or 
          CA11001_0."/=" (CA11001_0.Cartesian_Imag_Part (Complex_No), Int_2) 
      then
         Report.Failed ("Incorrect Polar result");
      end if;
   end Alternate_View_Subtest;
   -------------------------------------------------------------
   Other_Subtest:
   begin
      -- Assign using Polar coordinates.
      CA11001_0.CA11001_1.Polar_Assign 
        (CA11001_0.Complex_Int (Report.Ident_Int (0)), Int_2, Complex_No);

      -- Compare with Complex_Num in CA11001_0.
      if not CA11001_0.CA11001_1.Equals_Const (Complex_No)
        then
         Report.Failed ("Incorrect result");
      end if;
   end Other_Subtest;
   -------------------------------------------------------------
   Exception_Subtest:
   begin
      -- Raised parent's exception.
      CA11001_0.CA11001_1.Polar_Assign 
        (CA11001_0.Complex_Int (Report.Ident_Int (0)), 
           CA11001_0.Complex_Int (Report.Ident_Int (0)), Complex_No);
      Report.Failed ("Exception was not raised");
   exception
      when CA11001_0.Complex_Error => 
         null;
      when others                  =>
         Report.Failed ("Unexpected exception raised in test");
   end Exception_Subtest;

   Report.Result;

end CA11001;