separate (H2.Scheme.Execute) procedure Apply is pragma Inline (Apply); Operand: aliased Object_Pointer; Func: aliased Object_Pointer; Args: aliased Object_Pointer; -- ------------------------------------------------------------- -- List manipulation procedures -- ------------------------------------------------------------- procedure Apply_Car_Procedure is Ptr: Object_Pointer := Args; A: Object_Pointer; begin if not Is_Cons(Ptr) or else Get_Cdr(Ptr) /= Nil_Pointer then Ada.Text_IO.Put_Line ("WRONG NUMBER OF ARGUMETNS FOR CAR"); raise Syntax_Error; end if; A := Get_Car(Ptr); -- the first argument if not Is_Cons(A) then Ada.Text_IO.Put_Line ("EXPECTED CONS-CELL FOR CAR"); raise Evaluation_Error; end if; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Get_Car(A)); end Apply_Car_Procedure; procedure Apply_Cdr_Procedure is Ptr: Object_Pointer := Args; A: Object_Pointer; begin if not Is_Cons(Ptr) or else Get_Cdr(Ptr) /= Nil_Pointer then Ada.Text_IO.Put_Line ("WRONG NUMBER OF ARGUMETNS FOR CDR"); raise Syntax_Error; end if; A := Get_Car(Ptr); -- the first argument if not Is_Cons(A) then Ada.Text_IO.Put_Line ("EXPECTED CONS-CELL FOR CDR"); raise Evaluation_Error; end if; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Get_Cdr(A)); end Apply_Cdr_Procedure; procedure Apply_Cons_Procedure is Ptr: Object_Pointer := Args; A: Object_Pointer; B: Object_Pointer; begin if not Is_Cons(Ptr) or else not Is_Cons(Get_Cdr(Ptr)) or else Get_Cdr(Get_Cdr(Ptr)) /= Nil_Pointer then Ada.Text_IO.Put_Line ("WRONG NUMBER OF ARGUMETNS FOR CONS"); raise Syntax_Error; end if; A := Get_Car(Ptr); -- the first argument B := Get_Car(Get_Cdr(Ptr)); -- the second argument Ptr := Make_Cons (Interp.Self, A, B); -- change car Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Ptr); end Apply_Cons_Procedure; procedure Apply_Setcar_Procedure is Ptr: Object_Pointer := Args; A: Object_Pointer; B: Object_Pointer; begin if not Is_Cons(Ptr) or else not Is_Cons(Get_Cdr(Ptr)) or else Get_Cdr(Get_Cdr(Ptr)) /= Nil_Pointer then Ada.Text_IO.Put_Line ("WRONG NUMBER OF ARGUMETNS FOR SET-CAR!"); raise Syntax_Error; end if; A := Get_Car(Ptr); -- the first argument if not Is_Cons(A) then Ada.Text_IO.Put_Line ("EXPECTED CONS-CELL FOR Setcar"); raise Evaluation_Error; end if; B := Get_Car(Get_Cdr(Ptr)); -- the second argument Set_Car (A, B); -- change car Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, A); end Apply_Setcar_Procedure; procedure Apply_Setcdr_Procedure is Ptr: Object_Pointer := Args; A: Object_Pointer; B: Object_Pointer; begin if not Is_Cons(Ptr) or else not Is_Cons(Get_Cdr(Ptr)) or else Get_Cdr(Get_Cdr(Ptr)) /= Nil_Pointer then Ada.Text_IO.Put_Line ("WRONG NUMBER OF ARGUMETNS FOR SET-CDR!"); raise Syntax_Error; end if; A := Get_Car(Ptr); -- the first argument if not Is_Cons(A) then Ada.Text_IO.Put_Line ("EXPECTED CONS-CELL FOR Setcdr"); raise Evaluation_Error; end if; B := Get_Car(Get_Cdr(Ptr)); -- the second argument Set_Cdr (A, B); -- change cdr Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, A); end Apply_Setcdr_Procedure; -- ------------------------------------------------------------- -- Arithmetic procedures -- ------------------------------------------------------------- procedure Apply_Add_Procedure is Ptr: Object_Pointer := Args; Num: Object_Integer := 0; -- TODO: support BIGNUM Car: Object_Pointer; begin while Is_Cons(Ptr) loop -- TODO: check if car is an integer or bignum or something else. -- if something else, error Car := Get_Car(Ptr); if not Is_Integer(Car) then Ada.Text_IO.Put ("NOT INTEGER FOR ADD"); Print (Interp, Car); raise Evaluation_Error; end if; Num := Num + Pointer_To_Integer(Car); Ptr := Get_Cdr(Ptr); end loop; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Integer_To_Pointer(Num)); end Apply_Add_Procedure; procedure Apply_Subtract_Procedure is Ptr: Object_Pointer := Args; Num: Object_Integer := 0; -- TODO: support BIGNUM Car: Object_Pointer; begin if Is_Cons(Ptr) then Car := Get_Car(Ptr); if not Is_Integer(Car) then raise Evaluation_Error; end if; Num := Pointer_To_Integer(Car); Ptr := Get_Cdr(Ptr); while Is_Cons(Ptr) loop -- TODO: check if car is an integer or bignum or something else. -- if something else, error Car := Get_Car(Ptr); if not Is_Integer(Car) then raise Evaluation_Error; end if; Num := Num - Pointer_To_Integer(Car); Ptr := Get_Cdr(Ptr); end loop; end if; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Integer_To_Pointer(Num)); end Apply_Subtract_Procedure; procedure Apply_Multiply_Procedure is Ptr: Object_Pointer := Args; Num: Object_Integer := 1; -- TODO: support BIGNUM Car: Object_Pointer; begin while Is_Cons(Ptr) loop -- TODO: check if car is an integer or bignum or something else. -- if something else, error Car := Get_Car(Ptr); if not Is_Integer(Car) then Ada.Text_IO.Put ("NOT INTEGER FOR MULTIPLY"); Print (Interp, Car); raise Evaluation_Error; end if; Num := Num * Pointer_To_Integer(Car); Ptr := Get_Cdr(Ptr); end loop; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Integer_To_Pointer(Num)); end Apply_Multiply_Procedure; procedure Apply_Quotient_Procedure is Ptr: Object_Pointer := Args; Num: Object_Integer := 1; -- TODO: support BIGNUM Car: Object_Pointer; begin while Is_Cons(Ptr) loop -- TODO: check if car is an integer or bignum or something else. -- if something else, error Car := Get_Car(Ptr); if not Is_Integer(Car) then Ada.Text_IO.Put ("NOT INTEGER FOR MULTIPLY"); Print (Interp, Car); raise Evaluation_Error; end if; Num := Num * Pointer_To_Integer(Car); Ptr := Get_Cdr(Ptr); end loop; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Integer_To_Pointer(Num)); end Apply_Quotient_Procedure; generic with function Validate (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean; with function Compare (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean; procedure Apply_Compare_Procedure; procedure Apply_Compare_Procedure is -- TODO: support other values Ptr: Object_Pointer := Args; X: Object_Pointer; Y: Object_Pointer; Bool: Object_Pointer := True_Pointer; begin if Is_Cons(Ptr) and then Is_Cons(Get_Cdr(Ptr)) then -- at least 2 actual arguments X := Get_Car(Ptr); Ptr := Get_Cdr(Ptr); while Is_Cons(Ptr) loop Y := Get_Car(Ptr); if not Validate(X, Y) then ADA.TEXT_IO.PUT_LINE ("NON INTEGER FOR COMPARISION"); raise Evaluation_Error; end if; if not Compare(X, Y) then Bool := False_Pointer; exit; end if; X := Y; Ptr := Get_Cdr(Ptr); end loop; Pop_Frame (Interp); -- Done with the current frame Chain_Frame_Result (Interp, Interp.Stack, Bool); else Ada.Text_IO.Put_line ("TOO FEW ARGUMETNS FOR COMPARISON"); raise Syntax_Error; end if; end Apply_Compare_Procedure; function Validate_Numeric (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Is_Integer(X) and then Is_Integer(Y); end Validate_Numeric; function Equal_To (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Pointer_To_Integer(X) = Pointer_To_Integer(Y); end Equal_To; function Greater_Than (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Pointer_To_Integer(X) > Pointer_To_Integer(Y); end Greater_Than; function Less_Than (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Pointer_To_Integer(X) < Pointer_To_Integer(Y); end Less_Than; function Greater_Or_Equal (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Pointer_To_Integer(X) >= Pointer_To_Integer(Y); end Greater_Or_Equal; function Less_Or_Equal (X: in Object_Pointer; Y: in Object_Pointer) return Standard.Boolean is -- TODO: support BIGNUM, OTHER DATA TYPES begin return Pointer_To_Integer(X) <= Pointer_To_Integer(Y); end Less_Or_Equal; procedure Apply_EQ_Procedure is new Apply_Compare_Procedure (Validate_Numeric, Equal_To); procedure Apply_GT_Procedure is new Apply_Compare_Procedure (Validate_Numeric, Greater_Than); procedure Apply_LT_Procedure is new Apply_Compare_Procedure (Validate_Numeric, Less_Than); procedure Apply_GE_Procedure is new Apply_Compare_Procedure (Validate_Numeric, Greater_Or_Equal); procedure Apply_LE_Procedure is new Apply_Compare_Procedure (Validate_Numeric, Less_Or_Equal); procedure Apply_Closure is Fbody: aliased Object_Pointer; Formal: aliased Object_Pointer; Actual: aliased Object_Pointer; begin Push_Top (Interp, Fbody'Unchecked_Access); Push_Top (Interp, Formal'Unchecked_Access); Push_Top (Interp, Actual'Unchecked_Access); -- For a closure created of "(lambda (x y) (+ x y) (* x y))" -- Get_Closure_Code(Func) returns "((x y) (+ x y) (* x y))" -- Push a new environmen for the closure Interp.Environment := Make_Environment(Interp.Self, Get_Closure_Environment(Func)); Fbody := Get_Closure_Code(Func); pragma Assert (Is_Cons(Fbody)); -- the lambda evaluator must ensure this. Formal := Get_Car(Fbody); -- Formal argument list Actual := Args; -- Actual argument list Fbody := Get_Cdr(Fbody); -- Real function body pragma Assert (Is_Cons(Fbody)); -- the lambda evaluator must ensure this. if Is_Symbol(Formal) then -- Closure made of a lambda expression with a single formal argument -- e.g) (lambda x (car x)) -- Apply the whole actual argument list to the closure. Put_Environment (Interp, Formal, Actual); else while Is_Cons(Formal) loop if not Is_Cons(Actual) then Ada.Text_IO.Put_Line (">>>> Too few arguments for CLOSURE <<<<"); raise Evaluation_Error; end if; -- Insert the key/value pair into the environment Put_Environment (Interp, Get_Car(Formal), Get_Car(Actual)); Formal := Get_Cdr(Formal); Actual := Get_Cdr(Actual); end loop; -- Perform cosmetic checks for the parameter list if Is_Symbol(Formal) then -- The last formal argument to the closure is in a CDR. -- Assign the remaining actual arguments to the last formal argument -- e.g) ((lambda (x y . z) z) 1 2 3 4 5) Put_Environment (Interp, Formal, Actual); else -- The lambda evaluator must ensure all formal arguments are symbols. pragma Assert (Formal = Nil_Pointer); if Actual /= Nil_Pointer then Ada.Text_IO.Put_Line (">>>> TOO MANY ARGUMETNS FOR CLOSURE <<<<"); raise Evaluation_Error; end if; end if; end if; -- TODO: is it correct to keep the environement in the frame? Set_Frame_Opcode (Interp.Stack, Opcode_Evaluate_Group); Set_Frame_Operand (Interp.Stack, Fbody); Clear_Frame_Result (Interp.Stack); Pop_Tops (Interp, 3); end Apply_Closure; begin Push_Top (Interp, Operand'Unchecked_Access); Push_Top (Interp, Func'Unchecked_Access); Push_Top (Interp, Args'Unchecked_Access); Operand := Get_Frame_Operand(Interp.Stack); pragma Assert (Is_Cons(Operand)); ada.text_io.put ("OPERAND TO APPLY => "); Print (Interp, Operand); Func := Get_Car(Operand); if not Is_Normal_Pointer(Func) then Ada.Text_IO.Put_Line ("INVALID FUNCTION TYPE"); raise Evaluation_Error; end if; Args := Get_Cdr(Operand); case Func.Tag is when Procedure_Object => case Get_Procedure_Opcode(Func) is when Car_Procedure => Apply_Car_Procedure; when Cdr_Procedure => Apply_Cdr_Procedure; when Cons_Procedure => Apply_Cons_Procedure; when Setcar_Procedure => Apply_Setcar_Procedure; when Setcdr_Procedure => Apply_Setcdr_Procedure; when Add_Procedure => Apply_Add_Procedure; when Subtract_Procedure => Apply_Subtract_Procedure; when Multiply_Procedure => Apply_Multiply_Procedure; when Quotient_Procedure => Apply_Quotient_Procedure; --when Remainder_Procedure => -- Apply_Remainder_Procedure; when EQ_Procedure => Apply_EQ_Procedure; when GT_Procedure => Apply_GT_Procedure; when LT_Procedure => Apply_LT_Procedure; when GE_Procedure => Apply_GE_Procedure; when LE_Procedure => Apply_LE_Procedure; when others => raise Internal_Error; end case; when Closure_Object => Apply_Closure; when Continuation_Object => null; when others => Ada.Text_IO.Put_Line ("INVALID FUNCTION TYPE"); raise Internal_Error; end case; Pop_Tops (Interp, 3); end Apply;