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Length: 7141 (0x1be5)
Types: TextFile
Names: »B«
└─⟦a7d1ea751⟧ Bits:30000550 8mm tape, Rational 1000, !users!projects 94_04_11
└─⟦129cab021⟧ »DATA«
└─⟦this⟧
└─⟦2f6cfab89⟧ Bits:30000547 8mm tape, Rational 1000, !projects 94-01-04
└─⟦d65440be7⟧ »DATA«
└─⟦this⟧
└─⟦a7d1ea751⟧ Bits:30000550 8mm tape, Rational 1000, !users!projects 94_04_11
└─⟦129cab021⟧ »DATA«
└─⟦e24fb53b7⟧
└─⟦this⟧
package body Generic_Predicate is
type Predicate_Owners is (System, User);
package System_Defined is
type Operators is (Is_Equal, Is_Less, Is_Less_Or_Equal, Is_Greater,
Is_Greater_Or_Equal, Is_Different, Is_Any);
function Match (Using_Operator : Operators;
Value : Integer;
Against : Integer) return Boolean;
function Image (Op : Operators) return String;
end System_Defined;
package Primary_Predicate is
type Sub_Classes is (Alias_Definition, Predicate_Conjunction);
type Object (Kind : Sub_Classes := Alias_Definition) is
record
case Kind is
when Alias_Definition =>
The_Alias : Alias.Name;
when Predicate_Conjunction =>
The_Left_Predicate : Generic_Predicate.Object;
The_Right_Predicate : Generic_Predicate.Object;
end case;
end record;
function Make_Alias_Definition (The_Alias : Alias.Name) return Object;
function Make_Conjunction
(Left, Right : Generic_Predicate.Object) return Object;
procedure Put (The_Object : Object; Where : Output_Stream.Object);
function Match (Value : Integer; Against : Object) return Boolean;
end Primary_Predicate;
package Unary_Predicate is
type Object (Owner : Predicate_Owners := System) is
record
case Owner is
when System =>
The_System_Operator : System_Defined.Operators;
when User =>
The_User_Operator : User_Defined_Operators;
end case;
end record;
function Make (The_Operator : System_Defined.Operators) return Object;
function Make (The_Operator : User_Defined_Operators) return Object;
procedure Put (The_Object : Object; Where : Output_Stream.Object);
function Match (Value : Integer; Against : Object) return Boolean;
end Unary_Predicate;
package Binary_Predicate is
type Object (Owner : Predicate_Owners := System) is
record
The_Operand : Expression_Object;
case Owner is
when System =>
The_System_Operator : System_Defined.Operators;
when User =>
The_User_Operator : User_Defined_Operators;
end case;
end record;
function Make (The_Operator : System_Defined.Operators;
The_Operand : Expression_Object) return Object;
function Make (The_Operator : User_Defined_Operators;
The_Operand : Expression_Object) return Object;
procedure Put (The_Object : Object; Where : Output_Stream.Object);
function Match (Value : Integer; Against : Object) return Boolean;
end Binary_Predicate;
type Object_Structure (Sub_Class : Sub_Classes) is
record
case Sub_Class is
when Primary =>
The_Primary_Code : Primary_Predicate.Object;
when Unary =>
The_Unary_Code : Unary_Predicate.Object;
when Binary =>
The_Binary_Code : Binary_Predicate.Object;
when Undefined =>
null;
end case;
end record;
function New_Node (For_Code : Object_Structure) return Object is
Result : Object;
begin
Result := new Object_Structure (Sub_Class => For_Code.Sub_Class);
Result.all := For_Code;
return Result;
end New_Node;
function Define_As (The_Alias : Alias.Name) return Object is
The_Predicate : Primary_Predicate.Object;
begin
The_Predicate := Primary_Predicate.Make_Alias_Definition (The_Alias);
return New_Node (For_Code => (Sub_Class => Primary,
The_Primary_Code => The_Predicate));
end Define_As;
function "and" (Left, Right : Object) return Object is
The_Predicate : Primary_Predicate.Object;
begin
if Left = Null_Predicate then
return Right;
elsif Right = Null_Predicate then
return Left;
else
The_Predicate := Primary_Predicate.Make_Conjunction (Left, Right);
return New_Node (For_Code => (Sub_Class => Primary,
The_Primary_Code => The_Predicate));
end if;
end "and";
function Unary_User_Predicate return Object is
The_Code : Unary_Predicate.Object;
begin
The_Code := Unary_Predicate.Make (Operator);
return New_Node (For_Code => (Sub_Class => Unary,
The_Unary_Code => The_Code));
end Unary_User_Predicate;
function Binary_User_Predicate
(Using_Value : Expression_Object) return Object is
The_Code : Binary_Predicate.Object;
begin
The_Code := Binary_Predicate.Make (Operator, Using_Value);
return New_Node (For_Code => (Sub_Class => Binary,
The_Binary_Code => The_Code));
end Binary_User_Predicate;
function Match (Value : Integer; Against : Object) return Boolean is
begin
if Against = Null_Predicate then
return False;
else
case Against.Sub_Class is
when Primary =>
return Primary_Predicate.Match
(Value, Against.The_Primary_Code);
when Unary =>
return Unary_Predicate.Match
(Value, Against.The_Unary_Code);
when Binary =>
return Binary_Predicate.Match
(Value, Against.The_Binary_Code);
when Undefined =>
raise Illegal_Operation;
end case;
end if;
end Match;
procedure Put (The_Object : Object; Where : Output_Stream.Object) is
use Output_Stream;
begin
if The_Object /= Null_Predicate then
case The_Object.Sub_Class is
when Primary =>
Primary_Predicate.Put (The_Object.The_Primary_Code, Where);
when Unary =>
Unary_Predicate.Put (The_Object.The_Unary_Code, Where);
when Binary =>
Binary_Predicate.Put (The_Object.The_Binary_Code, Where);
when Undefined =>
Put ("Undefined predicate", Where);
end case;
end if;
end Put;
package body System_Defined is separate;
package body Primary_Predicate is separate;
package body Unary_Predicate is separate;
package body Binary_Predicate is separate;
package body System_Defined_Predicate is separate;
end Generic_Predicate;