Mercurial > hg > CbC > CbC_gcc
view gcc/ada/sem_aux.adb @ 131:84e7813d76e9
gcc-8.2
| author | mir3636 |
|---|---|
| date | Thu, 25 Oct 2018 07:37:49 +0900 |
| parents | 04ced10e8804 |
| children | 1830386684a0 |
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------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- S E M _ A U X -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2018, Free Software Foundation, Inc. -- -- -- -- GNAT is free software; you can redistribute it and/or modify it under -- -- terms of the GNU General Public License as published by the Free Soft- -- -- ware Foundation; either version 3, or (at your option) any later ver- -- -- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License -- -- for more details. You should have received a copy of the GNU General -- -- Public License distributed with GNAT; see file COPYING3. If not, go to -- -- http://www.gnu.org/licenses for a complete copy of the license. -- -- -- -- As a special exception, if other files instantiate generics from this -- -- unit, or you link this unit with other files to produce an executable, -- -- this unit does not by itself cause the resulting executable to be -- -- covered by the GNU General Public License. This exception does not -- -- however invalidate any other reasons why the executable file might be -- -- covered by the GNU Public License. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ with Atree; use Atree; with Einfo; use Einfo; with Snames; use Snames; with Stand; use Stand; with Uintp; use Uintp; package body Sem_Aux is ---------------------- -- Ancestor_Subtype -- ---------------------- function Ancestor_Subtype (Typ : Entity_Id) return Entity_Id is begin -- If this is first subtype, or is a base type, then there is no -- ancestor subtype, so we return Empty to indicate this fact. if Is_First_Subtype (Typ) or else Is_Base_Type (Typ) then return Empty; end if; declare D : constant Node_Id := Declaration_Node (Typ); begin -- If we have a subtype declaration, get the ancestor subtype if Nkind (D) = N_Subtype_Declaration then if Nkind (Subtype_Indication (D)) = N_Subtype_Indication then return Entity (Subtype_Mark (Subtype_Indication (D))); else return Entity (Subtype_Indication (D)); end if; -- If not, then no subtype indication is available else return Empty; end if; end; end Ancestor_Subtype; -------------------- -- Available_View -- -------------------- function Available_View (Ent : Entity_Id) return Entity_Id is begin -- Obtain the non-limited view (if available) if Has_Non_Limited_View (Ent) then return Get_Full_View (Non_Limited_View (Ent)); -- In all other cases, return entity unchanged else return Ent; end if; end Available_View; -------------------- -- Constant_Value -- -------------------- function Constant_Value (Ent : Entity_Id) return Node_Id is D : constant Node_Id := Declaration_Node (Ent); Full_D : Node_Id; begin -- If we have no declaration node, then return no constant value. Not -- clear how this can happen, but it does sometimes and this is the -- safest approach. if No (D) then return Empty; -- Normal case where a declaration node is present elsif Nkind (D) = N_Object_Renaming_Declaration then return Renamed_Object (Ent); -- If this is a component declaration whose entity is a constant, it is -- a prival within a protected function (and so has no constant value). elsif Nkind (D) = N_Component_Declaration then return Empty; -- If there is an expression, return it elsif Present (Expression (D)) then return Expression (D); -- For a constant, see if we have a full view elsif Ekind (Ent) = E_Constant and then Present (Full_View (Ent)) then Full_D := Parent (Full_View (Ent)); -- The full view may have been rewritten as an object renaming if Nkind (Full_D) = N_Object_Renaming_Declaration then return Name (Full_D); else return Expression (Full_D); end if; -- Otherwise we have no expression to return else return Empty; end if; end Constant_Value; --------------------------------- -- Corresponding_Unsigned_Type -- --------------------------------- function Corresponding_Unsigned_Type (Typ : Entity_Id) return Entity_Id is pragma Assert (Is_Signed_Integer_Type (Typ)); Siz : constant Uint := Esize (Base_Type (Typ)); begin if Siz = Esize (Standard_Short_Short_Integer) then return Standard_Short_Short_Unsigned; elsif Siz = Esize (Standard_Short_Integer) then return Standard_Short_Unsigned; elsif Siz = Esize (Standard_Unsigned) then return Standard_Unsigned; elsif Siz = Esize (Standard_Long_Integer) then return Standard_Long_Unsigned; elsif Siz = Esize (Standard_Long_Long_Integer) then return Standard_Long_Long_Unsigned; else raise Program_Error; end if; end Corresponding_Unsigned_Type; ----------------------------- -- Enclosing_Dynamic_Scope -- ----------------------------- function Enclosing_Dynamic_Scope (Ent : Entity_Id) return Entity_Id is S : Entity_Id; begin -- The following test is an error defense against some syntax errors -- that can leave scopes very messed up. if Ent = Standard_Standard then return Ent; end if; -- Normal case, search enclosing scopes -- Note: the test for Present (S) should not be required, it defends -- against an ill-formed tree. S := Scope (Ent); loop -- If we somehow got an empty value for Scope, the tree must be -- malformed. Rather than blow up we return Standard in this case. if No (S) then return Standard_Standard; -- Quit if we get to standard or a dynamic scope. We must also -- handle enclosing scopes that have a full view; required to -- locate enclosing scopes that are synchronized private types -- whose full view is a task type. elsif S = Standard_Standard or else Is_Dynamic_Scope (S) or else (Is_Private_Type (S) and then Present (Full_View (S)) and then Is_Dynamic_Scope (Full_View (S))) then return S; -- Otherwise keep climbing else S := Scope (S); end if; end loop; end Enclosing_Dynamic_Scope; ------------------------ -- First_Discriminant -- ------------------------ function First_Discriminant (Typ : Entity_Id) return Entity_Id is Ent : Entity_Id; begin pragma Assert (Has_Discriminants (Typ) or else Has_Unknown_Discriminants (Typ)); Ent := First_Entity (Typ); -- The discriminants are not necessarily contiguous, because access -- discriminants will generate itypes. They are not the first entities -- either because the tag must be ahead of them. if Chars (Ent) = Name_uTag then Ent := Next_Entity (Ent); end if; -- Skip all hidden stored discriminants if any while Present (Ent) loop exit when Ekind (Ent) = E_Discriminant and then not Is_Completely_Hidden (Ent); Ent := Next_Entity (Ent); end loop; -- Call may be on a private type with unknown discriminants, in which -- case Ent is Empty, and as per the spec, we return Empty in this case. -- Historical note: The assertion in previous versions that Ent is a -- discriminant was overly cautious and prevented convenient application -- of this function in the gnatprove context. return Ent; end First_Discriminant; ------------------------------- -- First_Stored_Discriminant -- ------------------------------- function First_Stored_Discriminant (Typ : Entity_Id) return Entity_Id is Ent : Entity_Id; function Has_Completely_Hidden_Discriminant (Typ : Entity_Id) return Boolean; -- Scans the Discriminants to see whether any are Completely_Hidden -- (the mechanism for describing non-specified stored discriminants) -- Note that the entity list for the type may contain anonymous access -- types created by expressions that constrain access discriminants. ---------------------------------------- -- Has_Completely_Hidden_Discriminant -- ---------------------------------------- function Has_Completely_Hidden_Discriminant (Typ : Entity_Id) return Boolean is Ent : Entity_Id; begin pragma Assert (Ekind (Typ) = E_Discriminant); Ent := Typ; while Present (Ent) loop -- Skip anonymous types that may be created by expressions -- used as discriminant constraints on inherited discriminants. if Is_Itype (Ent) then null; elsif Ekind (Ent) = E_Discriminant and then Is_Completely_Hidden (Ent) then return True; end if; Ent := Next_Entity (Ent); end loop; return False; end Has_Completely_Hidden_Discriminant; -- Start of processing for First_Stored_Discriminant begin pragma Assert (Has_Discriminants (Typ) or else Has_Unknown_Discriminants (Typ)); Ent := First_Entity (Typ); if Chars (Ent) = Name_uTag then Ent := Next_Entity (Ent); end if; if Has_Completely_Hidden_Discriminant (Ent) then while Present (Ent) loop exit when Ekind (Ent) = E_Discriminant and then Is_Completely_Hidden (Ent); Ent := Next_Entity (Ent); end loop; end if; pragma Assert (Ekind (Ent) = E_Discriminant); return Ent; end First_Stored_Discriminant; ------------------- -- First_Subtype -- ------------------- function First_Subtype (Typ : Entity_Id) return Entity_Id is B : constant Entity_Id := Base_Type (Typ); F : constant Node_Id := Freeze_Node (B); Ent : Entity_Id; begin -- If the base type has no freeze node, it is a type in Standard, and -- always acts as its own first subtype, except where it is one of the -- predefined integer types. If the type is formal, it is also a first -- subtype, and its base type has no freeze node. On the other hand, a -- subtype of a generic formal is not its own first subtype. Its base -- type, if anonymous, is attached to the formal type decl. from which -- the first subtype is obtained. if No (F) then if B = Base_Type (Standard_Integer) then return Standard_Integer; elsif B = Base_Type (Standard_Long_Integer) then return Standard_Long_Integer; elsif B = Base_Type (Standard_Short_Short_Integer) then return Standard_Short_Short_Integer; elsif B = Base_Type (Standard_Short_Integer) then return Standard_Short_Integer; elsif B = Base_Type (Standard_Long_Long_Integer) then return Standard_Long_Long_Integer; elsif Is_Generic_Type (Typ) then if Present (Parent (B)) then return Defining_Identifier (Parent (B)); else return Defining_Identifier (Associated_Node_For_Itype (B)); end if; else return B; end if; -- Otherwise we check the freeze node, if it has a First_Subtype_Link -- then we use that link, otherwise (happens with some Itypes), we use -- the base type itself. else Ent := First_Subtype_Link (F); if Present (Ent) then return Ent; else return B; end if; end if; end First_Subtype; ------------------------- -- First_Tag_Component -- ------------------------- function First_Tag_Component (Typ : Entity_Id) return Entity_Id is Comp : Entity_Id; Ctyp : Entity_Id; begin Ctyp := Typ; pragma Assert (Is_Tagged_Type (Ctyp)); if Is_Class_Wide_Type (Ctyp) then Ctyp := Root_Type (Ctyp); end if; if Is_Private_Type (Ctyp) then Ctyp := Underlying_Type (Ctyp); -- If the underlying type is missing then the source program has -- errors and there is nothing else to do (the full-type declaration -- associated with the private type declaration is missing). if No (Ctyp) then return Empty; end if; end if; Comp := First_Entity (Ctyp); while Present (Comp) loop if Is_Tag (Comp) then return Comp; end if; Comp := Next_Entity (Comp); end loop; -- No tag component found return Empty; end First_Tag_Component; --------------------- -- Get_Binary_Nkind -- --------------------- function Get_Binary_Nkind (Op : Entity_Id) return Node_Kind is begin case Chars (Op) is when Name_Op_Add => return N_Op_Add; when Name_Op_Concat => return N_Op_Concat; when Name_Op_Expon => return N_Op_Expon; when Name_Op_Subtract => return N_Op_Subtract; when Name_Op_Mod => return N_Op_Mod; when Name_Op_Multiply => return N_Op_Multiply; when Name_Op_Divide => return N_Op_Divide; when Name_Op_Rem => return N_Op_Rem; when Name_Op_And => return N_Op_And; when Name_Op_Eq => return N_Op_Eq; when Name_Op_Ge => return N_Op_Ge; when Name_Op_Gt => return N_Op_Gt; when Name_Op_Le => return N_Op_Le; when Name_Op_Lt => return N_Op_Lt; when Name_Op_Ne => return N_Op_Ne; when Name_Op_Or => return N_Op_Or; when Name_Op_Xor => return N_Op_Xor; when others => raise Program_Error; end case; end Get_Binary_Nkind; ----------------------- -- Get_Called_Entity -- ----------------------- function Get_Called_Entity (Call : Node_Id) return Entity_Id is Nam : constant Node_Id := Name (Call); Id : Entity_Id; begin if Nkind (Nam) = N_Explicit_Dereference then Id := Etype (Nam); pragma Assert (Ekind (Id) = E_Subprogram_Type); elsif Nkind (Nam) = N_Selected_Component then Id := Entity (Selector_Name (Nam)); elsif Nkind (Nam) = N_Indexed_Component then Id := Entity (Selector_Name (Prefix (Nam))); else Id := Entity (Nam); end if; return Id; end Get_Called_Entity; ------------------- -- Get_Low_Bound -- ------------------- function Get_Low_Bound (E : Entity_Id) return Node_Id is begin if Ekind (E) = E_String_Literal_Subtype then return String_Literal_Low_Bound (E); else return Type_Low_Bound (E); end if; end Get_Low_Bound; ------------------ -- Get_Rep_Item -- ------------------ function Get_Rep_Item (E : Entity_Id; Nam : Name_Id; Check_Parents : Boolean := True) return Node_Id is N : Node_Id; begin N := First_Rep_Item (E); while Present (N) loop -- Only one of Priority / Interrupt_Priority can be specified, so -- return whichever one is present to catch illegal duplication. if Nkind (N) = N_Pragma and then (Pragma_Name_Unmapped (N) = Nam or else (Nam = Name_Priority and then Pragma_Name (N) = Name_Interrupt_Priority) or else (Nam = Name_Interrupt_Priority and then Pragma_Name (N) = Name_Priority)) then if Check_Parents then return N; -- If Check_Parents is False, return N if the pragma doesn't -- appear in the Rep_Item chain of the parent. else declare Par : constant Entity_Id := Nearest_Ancestor (E); -- This node represents the parent type of type E (if any) begin if No (Par) then return N; elsif not Present_In_Rep_Item (Par, N) then return N; end if; end; end if; elsif Nkind (N) = N_Attribute_Definition_Clause and then (Chars (N) = Nam or else (Nam = Name_Priority and then Chars (N) = Name_Interrupt_Priority)) then if Check_Parents or else Entity (N) = E then return N; end if; elsif Nkind (N) = N_Aspect_Specification and then (Chars (Identifier (N)) = Nam or else (Nam = Name_Priority and then Chars (Identifier (N)) = Name_Interrupt_Priority)) then if Check_Parents then return N; elsif Entity (N) = E then return N; end if; end if; Next_Rep_Item (N); end loop; return Empty; end Get_Rep_Item; function Get_Rep_Item (E : Entity_Id; Nam1 : Name_Id; Nam2 : Name_Id; Check_Parents : Boolean := True) return Node_Id is Nam1_Item : constant Node_Id := Get_Rep_Item (E, Nam1, Check_Parents); Nam2_Item : constant Node_Id := Get_Rep_Item (E, Nam2, Check_Parents); N : Node_Id; begin -- Check both Nam1_Item and Nam2_Item are present if No (Nam1_Item) then return Nam2_Item; elsif No (Nam2_Item) then return Nam1_Item; end if; -- Return the first node encountered in the list N := First_Rep_Item (E); while Present (N) loop if N = Nam1_Item or else N = Nam2_Item then return N; end if; Next_Rep_Item (N); end loop; return Empty; end Get_Rep_Item; -------------------- -- Get_Rep_Pragma -- -------------------- function Get_Rep_Pragma (E : Entity_Id; Nam : Name_Id; Check_Parents : Boolean := True) return Node_Id is N : constant Node_Id := Get_Rep_Item (E, Nam, Check_Parents); begin if Present (N) and then Nkind (N) = N_Pragma then return N; end if; return Empty; end Get_Rep_Pragma; function Get_Rep_Pragma (E : Entity_Id; Nam1 : Name_Id; Nam2 : Name_Id; Check_Parents : Boolean := True) return Node_Id is Nam1_Item : constant Node_Id := Get_Rep_Pragma (E, Nam1, Check_Parents); Nam2_Item : constant Node_Id := Get_Rep_Pragma (E, Nam2, Check_Parents); N : Node_Id; begin -- Check both Nam1_Item and Nam2_Item are present if No (Nam1_Item) then return Nam2_Item; elsif No (Nam2_Item) then return Nam1_Item; end if; -- Return the first node encountered in the list N := First_Rep_Item (E); while Present (N) loop if N = Nam1_Item or else N = Nam2_Item then return N; end if; Next_Rep_Item (N); end loop; return Empty; end Get_Rep_Pragma; --------------------- -- Get_Unary_Nkind -- --------------------- function Get_Unary_Nkind (Op : Entity_Id) return Node_Kind is begin case Chars (Op) is when Name_Op_Abs => return N_Op_Abs; when Name_Op_Subtract => return N_Op_Minus; when Name_Op_Not => return N_Op_Not; when Name_Op_Add => return N_Op_Plus; when others => raise Program_Error; end case; end Get_Unary_Nkind; --------------------------------- -- Has_External_Tag_Rep_Clause -- --------------------------------- function Has_External_Tag_Rep_Clause (T : Entity_Id) return Boolean is begin pragma Assert (Is_Tagged_Type (T)); return Has_Rep_Item (T, Name_External_Tag, Check_Parents => False); end Has_External_Tag_Rep_Clause; ------------------ -- Has_Rep_Item -- ------------------ function Has_Rep_Item (E : Entity_Id; Nam : Name_Id; Check_Parents : Boolean := True) return Boolean is begin return Present (Get_Rep_Item (E, Nam, Check_Parents)); end Has_Rep_Item; function Has_Rep_Item (E : Entity_Id; Nam1 : Name_Id; Nam2 : Name_Id; Check_Parents : Boolean := True) return Boolean is begin return Present (Get_Rep_Item (E, Nam1, Nam2, Check_Parents)); end Has_Rep_Item; function Has_Rep_Item (E : Entity_Id; N : Node_Id) return Boolean is Item : Node_Id; begin pragma Assert (Nkind_In (N, N_Aspect_Specification, N_Attribute_Definition_Clause, N_Enumeration_Representation_Clause, N_Pragma, N_Record_Representation_Clause)); Item := First_Rep_Item (E); while Present (Item) loop if Item = N then return True; end if; Item := Next_Rep_Item (Item); end loop; return False; end Has_Rep_Item; -------------------- -- Has_Rep_Pragma -- -------------------- function Has_Rep_Pragma (E : Entity_Id; Nam : Name_Id; Check_Parents : Boolean := True) return Boolean is begin return Present (Get_Rep_Pragma (E, Nam, Check_Parents)); end Has_Rep_Pragma; function Has_Rep_Pragma (E : Entity_Id; Nam1 : Name_Id; Nam2 : Name_Id; Check_Parents : Boolean := True) return Boolean is begin return Present (Get_Rep_Pragma (E, Nam1, Nam2, Check_Parents)); end Has_Rep_Pragma; -------------------------------- -- Has_Unconstrained_Elements -- -------------------------------- function Has_Unconstrained_Elements (T : Entity_Id) return Boolean is U_T : constant Entity_Id := Underlying_Type (T); begin if No (U_T) then return False; elsif Is_Record_Type (U_T) then return Has_Discriminants (U_T) and then not Is_Constrained (U_T); elsif Is_Array_Type (U_T) then return Has_Unconstrained_Elements (Component_Type (U_T)); else return False; end if; end Has_Unconstrained_Elements; ---------------------- -- Has_Variant_Part -- ---------------------- function Has_Variant_Part (Typ : Entity_Id) return Boolean is FSTyp : Entity_Id; Decl : Node_Id; TDef : Node_Id; CList : Node_Id; begin if not Is_Type (Typ) then return False; end if; FSTyp := First_Subtype (Typ); if not Has_Discriminants (FSTyp) then return False; end if; -- Proceed with cautious checks here, return False if tree is not -- as expected (may be caused by prior errors). Decl := Declaration_Node (FSTyp); if Nkind (Decl) /= N_Full_Type_Declaration then return False; end if; TDef := Type_Definition (Decl); if Nkind (TDef) /= N_Record_Definition then return False; end if; CList := Component_List (TDef); if Nkind (CList) /= N_Component_List then return False; else return Present (Variant_Part (CList)); end if; end Has_Variant_Part; --------------------- -- In_Generic_Body -- --------------------- function In_Generic_Body (Id : Entity_Id) return Boolean is S : Entity_Id; begin -- Climb scopes looking for generic body S := Id; while Present (S) and then S /= Standard_Standard loop -- Generic package body if Ekind (S) = E_Generic_Package and then In_Package_Body (S) then return True; -- Generic subprogram body elsif Is_Subprogram (S) and then Nkind (Unit_Declaration_Node (S)) = N_Generic_Subprogram_Declaration then return True; end if; S := Scope (S); end loop; -- False if top of scope stack without finding a generic body return False; end In_Generic_Body; ------------------------------- -- Initialization_Suppressed -- ------------------------------- function Initialization_Suppressed (Typ : Entity_Id) return Boolean is begin return Suppress_Initialization (Typ) or else Suppress_Initialization (Base_Type (Typ)); end Initialization_Suppressed; ---------------- -- Initialize -- ---------------- procedure Initialize is begin Obsolescent_Warnings.Init; end Initialize; ------------- -- Is_Body -- ------------- function Is_Body (N : Node_Id) return Boolean is begin return Nkind (N) in N_Body_Stub or else Nkind_In (N, N_Entry_Body, N_Package_Body, N_Protected_Body, N_Subprogram_Body, N_Task_Body); end Is_Body; --------------------- -- Is_By_Copy_Type -- --------------------- function Is_By_Copy_Type (Ent : Entity_Id) return Boolean is begin -- If Id is a private type whose full declaration has not been seen, -- we assume for now that it is not a By_Copy type. Clearly this -- attribute should not be used before the type is frozen, but it is -- needed to build the associated record of a protected type. Another -- place where some lookahead for a full view is needed ??? return Is_Elementary_Type (Ent) or else (Is_Private_Type (Ent) and then Present (Underlying_Type (Ent)) and then Is_Elementary_Type (Underlying_Type (Ent))); end Is_By_Copy_Type; -------------------------- -- Is_By_Reference_Type -- -------------------------- function Is_By_Reference_Type (Ent : Entity_Id) return Boolean is Btype : constant Entity_Id := Base_Type (Ent); begin if Error_Posted (Ent) or else Error_Posted (Btype) then return False; elsif Is_Private_Type (Btype) then declare Utyp : constant Entity_Id := Underlying_Type (Btype); begin if No (Utyp) then return False; else return Is_By_Reference_Type (Utyp); end if; end; elsif Is_Incomplete_Type (Btype) then declare Ftyp : constant Entity_Id := Full_View (Btype); begin -- Return true for a tagged incomplete type built as a shadow -- entity in Build_Limited_Views. It can appear in the profile -- of a thunk and the back end needs to know how it is passed. if No (Ftyp) then return Is_Tagged_Type (Btype); else return Is_By_Reference_Type (Ftyp); end if; end; elsif Is_Concurrent_Type (Btype) then return True; elsif Is_Record_Type (Btype) then if Is_Limited_Record (Btype) or else Is_Tagged_Type (Btype) or else Is_Volatile (Btype) then return True; else declare C : Entity_Id; begin C := First_Component (Btype); while Present (C) loop -- For each component, test if its type is a by reference -- type and if its type is volatile. Also test the component -- itself for being volatile. This happens for example when -- a Volatile aspect is added to a component. if Is_By_Reference_Type (Etype (C)) or else Is_Volatile (Etype (C)) or else Is_Volatile (C) then return True; end if; C := Next_Component (C); end loop; end; return False; end if; elsif Is_Array_Type (Btype) then return Is_Volatile (Btype) or else Is_By_Reference_Type (Component_Type (Btype)) or else Is_Volatile (Component_Type (Btype)) or else Has_Volatile_Components (Btype); else return False; end if; end Is_By_Reference_Type; ------------------------- -- Is_Definite_Subtype -- ------------------------- function Is_Definite_Subtype (T : Entity_Id) return Boolean is pragma Assert (Is_Type (T)); K : constant Entity_Kind := Ekind (T); begin if Is_Constrained (T) then return True; elsif K in Array_Kind or else K in Class_Wide_Kind or else Has_Unknown_Discriminants (T) then return False; -- Known discriminants: definite if there are default values. Note that -- if any discriminant has a default, they all do. elsif Has_Discriminants (T) then return Present (Discriminant_Default_Value (First_Discriminant (T))); else return True; end if; end Is_Definite_Subtype; --------------------- -- Is_Derived_Type -- --------------------- function Is_Derived_Type (Ent : E) return B is Par : Node_Id; begin if Is_Type (Ent) and then Base_Type (Ent) /= Root_Type (Ent) and then not Is_Class_Wide_Type (Ent) -- An access_to_subprogram whose result type is a limited view can -- appear in a return statement, without the full view of the result -- type being available. Do not interpret this as a derived type. and then Ekind (Ent) /= E_Subprogram_Type then if not Is_Numeric_Type (Root_Type (Ent)) then return True; else Par := Parent (First_Subtype (Ent)); return Present (Par) and then Nkind (Par) = N_Full_Type_Declaration and then Nkind (Type_Definition (Par)) = N_Derived_Type_Definition; end if; else return False; end if; end Is_Derived_Type; ----------------------- -- Is_Generic_Formal -- ----------------------- function Is_Generic_Formal (E : Entity_Id) return Boolean is Kind : Node_Kind; begin if No (E) then return False; else -- Formal derived types are rewritten as private extensions, so -- examine original node. Kind := Nkind (Original_Node (Parent (E))); return Nkind_In (Kind, N_Formal_Object_Declaration, N_Formal_Type_Declaration) or else Is_Formal_Subprogram (E) or else (Ekind (E) = E_Package and then Nkind (Original_Node (Unit_Declaration_Node (E))) = N_Formal_Package_Declaration); end if; end Is_Generic_Formal; ------------------------------- -- Is_Immutably_Limited_Type -- ------------------------------- function Is_Immutably_Limited_Type (Ent : Entity_Id) return Boolean is Btype : constant Entity_Id := Available_View (Base_Type (Ent)); begin if Is_Limited_Record (Btype) then return True; elsif Ekind (Btype) = E_Limited_Private_Type and then Nkind (Parent (Btype)) = N_Formal_Type_Declaration then return not In_Package_Body (Scope ((Btype))); elsif Is_Private_Type (Btype) then -- AI05-0063: A type derived from a limited private formal type is -- not immutably limited in a generic body. if Is_Derived_Type (Btype) and then Is_Generic_Type (Etype (Btype)) then if not Is_Limited_Type (Etype (Btype)) then return False; -- A descendant of a limited formal type is not immutably limited -- in the generic body, or in the body of a generic child. elsif Ekind (Scope (Etype (Btype))) = E_Generic_Package then return not In_Package_Body (Scope (Btype)); else return False; end if; else declare Utyp : constant Entity_Id := Underlying_Type (Btype); begin if No (Utyp) then return False; else return Is_Immutably_Limited_Type (Utyp); end if; end; end if; elsif Is_Concurrent_Type (Btype) then return True; else return False; end if; end Is_Immutably_Limited_Type; --------------------- -- Is_Limited_Type -- --------------------- function Is_Limited_Type (Ent : Entity_Id) return Boolean is Btype : constant E := Base_Type (Ent); Rtype : constant E := Root_Type (Btype); begin if not Is_Type (Ent) then return False; elsif Ekind (Btype) = E_Limited_Private_Type or else Is_Limited_Composite (Btype) then return True; elsif Is_Concurrent_Type (Btype) then return True; -- The Is_Limited_Record flag normally indicates that the type is -- limited. The exception is that a type does not inherit limitedness -- from its interface ancestor. So the type may be derived from a -- limited interface, but is not limited. elsif Is_Limited_Record (Ent) and then not Is_Interface (Ent) then return True; -- Otherwise we will look around to see if there is some other reason -- for it to be limited, except that if an error was posted on the -- entity, then just assume it is non-limited, because it can cause -- trouble to recurse into a murky entity resulting from other errors. elsif Error_Posted (Ent) then return False; elsif Is_Record_Type (Btype) then if Is_Limited_Interface (Ent) then return True; -- AI-419: limitedness is not inherited from a limited interface elsif Is_Limited_Record (Rtype) then return not Is_Interface (Rtype) or else Is_Protected_Interface (Rtype) or else Is_Synchronized_Interface (Rtype) or else Is_Task_Interface (Rtype); elsif Is_Class_Wide_Type (Btype) then return Is_Limited_Type (Rtype); else declare C : E; begin C := First_Component (Btype); while Present (C) loop if Is_Limited_Type (Etype (C)) then return True; end if; C := Next_Component (C); end loop; end; return False; end if; elsif Is_Array_Type (Btype) then return Is_Limited_Type (Component_Type (Btype)); else return False; end if; end Is_Limited_Type; --------------------- -- Is_Limited_View -- --------------------- function Is_Limited_View (Ent : Entity_Id) return Boolean is Btype : constant Entity_Id := Available_View (Base_Type (Ent)); begin if Is_Limited_Record (Btype) then return True; elsif Ekind (Btype) = E_Limited_Private_Type and then Nkind (Parent (Btype)) = N_Formal_Type_Declaration then return not In_Package_Body (Scope ((Btype))); elsif Is_Private_Type (Btype) then -- AI05-0063: A type derived from a limited private formal type is -- not immutably limited in a generic body. if Is_Derived_Type (Btype) and then Is_Generic_Type (Etype (Btype)) then if not Is_Limited_Type (Etype (Btype)) then return False; -- A descendant of a limited formal type is not immutably limited -- in the generic body, or in the body of a generic child. elsif Ekind (Scope (Etype (Btype))) = E_Generic_Package then return not In_Package_Body (Scope (Btype)); else return False; end if; else declare Utyp : constant Entity_Id := Underlying_Type (Btype); begin if No (Utyp) then return False; else return Is_Limited_View (Utyp); end if; end; end if; elsif Is_Concurrent_Type (Btype) then return True; elsif Is_Record_Type (Btype) then -- Note that we return True for all limited interfaces, even though -- (unsynchronized) limited interfaces can have descendants that are -- nonlimited, because this is a predicate on the type itself, and -- things like functions with limited interface results need to be -- handled as build in place even though they might return objects -- of a type that is not inherently limited. if Is_Class_Wide_Type (Btype) then return Is_Limited_View (Root_Type (Btype)); else declare C : Entity_Id; begin C := First_Component (Btype); while Present (C) loop -- Don't consider components with interface types (which can -- only occur in the case of a _parent component anyway). -- They don't have any components, plus it would cause this -- function to return true for nonlimited types derived from -- limited interfaces. if not Is_Interface (Etype (C)) and then Is_Limited_View (Etype (C)) then return True; end if; C := Next_Component (C); end loop; end; return False; end if; elsif Is_Array_Type (Btype) then return Is_Limited_View (Component_Type (Btype)); else return False; end if; end Is_Limited_View; ---------------------- -- Nearest_Ancestor -- ---------------------- function Nearest_Ancestor (Typ : Entity_Id) return Entity_Id is D : constant Node_Id := Original_Node (Declaration_Node (Typ)); -- We use the original node of the declaration, because derived -- types from record subtypes are rewritten as record declarations, -- and it is the original declaration that carries the ancestor. begin -- If we have a subtype declaration, get the ancestor subtype if Nkind (D) = N_Subtype_Declaration then if Nkind (Subtype_Indication (D)) = N_Subtype_Indication then return Entity (Subtype_Mark (Subtype_Indication (D))); else return Entity (Subtype_Indication (D)); end if; -- If derived type declaration, find who we are derived from elsif Nkind (D) = N_Full_Type_Declaration and then Nkind (Type_Definition (D)) = N_Derived_Type_Definition then declare DTD : constant Entity_Id := Type_Definition (D); SI : constant Entity_Id := Subtype_Indication (DTD); begin if Is_Entity_Name (SI) then return Entity (SI); else return Entity (Subtype_Mark (SI)); end if; end; -- If derived type and private type, get the full view to find who we -- are derived from. elsif Is_Derived_Type (Typ) and then Is_Private_Type (Typ) and then Present (Full_View (Typ)) then return Nearest_Ancestor (Full_View (Typ)); -- Otherwise, nothing useful to return, return Empty else return Empty; end if; end Nearest_Ancestor; --------------------------- -- Nearest_Dynamic_Scope -- --------------------------- function Nearest_Dynamic_Scope (Ent : Entity_Id) return Entity_Id is begin if Is_Dynamic_Scope (Ent) then return Ent; else return Enclosing_Dynamic_Scope (Ent); end if; end Nearest_Dynamic_Scope; ------------------------ -- Next_Tag_Component -- ------------------------ function Next_Tag_Component (Tag : Entity_Id) return Entity_Id is Comp : Entity_Id; begin pragma Assert (Is_Tag (Tag)); -- Loop to look for next tag component Comp := Next_Entity (Tag); while Present (Comp) loop if Is_Tag (Comp) then pragma Assert (Chars (Comp) /= Name_uTag); return Comp; end if; Comp := Next_Entity (Comp); end loop; -- No tag component found return Empty; end Next_Tag_Component; ----------------------- -- Number_Components -- ----------------------- function Number_Components (Typ : Entity_Id) return Nat is N : Nat := 0; Comp : Entity_Id; begin -- We do not call Einfo.First_Component_Or_Discriminant, as this -- function does not skip completely hidden discriminants, which we -- want to skip here. if Has_Discriminants (Typ) then Comp := First_Discriminant (Typ); else Comp := First_Component (Typ); end if; while Present (Comp) loop N := N + 1; Comp := Next_Component_Or_Discriminant (Comp); end loop; return N; end Number_Components; -------------------------- -- Number_Discriminants -- -------------------------- function Number_Discriminants (Typ : Entity_Id) return Pos is N : Nat := 0; Discr : Entity_Id := First_Discriminant (Typ); begin while Present (Discr) loop N := N + 1; Discr := Next_Discriminant (Discr); end loop; return N; end Number_Discriminants; ---------------------------------------------- -- Object_Type_Has_Constrained_Partial_View -- ---------------------------------------------- function Object_Type_Has_Constrained_Partial_View (Typ : Entity_Id; Scop : Entity_Id) return Boolean is begin return Has_Constrained_Partial_View (Typ) or else (In_Generic_Body (Scop) and then Is_Generic_Type (Base_Type (Typ)) and then Is_Private_Type (Base_Type (Typ)) and then not Is_Tagged_Type (Typ) and then not (Is_Array_Type (Typ) and then not Is_Constrained (Typ)) and then Has_Discriminants (Typ)); end Object_Type_Has_Constrained_Partial_View; ------------------ -- Package_Body -- ------------------ function Package_Body (E : Entity_Id) return Node_Id is N : Node_Id; begin if Ekind (E) = E_Package_Body then N := Parent (E); if Nkind (N) = N_Defining_Program_Unit_Name then N := Parent (N); end if; else N := Package_Spec (E); if Present (Corresponding_Body (N)) then N := Parent (Corresponding_Body (N)); if Nkind (N) = N_Defining_Program_Unit_Name then N := Parent (N); end if; else N := Empty; end if; end if; return N; end Package_Body; ------------------ -- Package_Spec -- ------------------ function Package_Spec (E : Entity_Id) return Node_Id is begin return Parent (Package_Specification (E)); end Package_Spec; --------------------------- -- Package_Specification -- --------------------------- function Package_Specification (E : Entity_Id) return Node_Id is N : Node_Id; begin N := Parent (E); if Nkind (N) = N_Defining_Program_Unit_Name then N := Parent (N); end if; return N; end Package_Specification; --------------------- -- Subprogram_Body -- --------------------- function Subprogram_Body (E : Entity_Id) return Node_Id is Body_E : constant Entity_Id := Subprogram_Body_Entity (E); begin if No (Body_E) then return Empty; else return Parent (Subprogram_Specification (Body_E)); end if; end Subprogram_Body; ---------------------------- -- Subprogram_Body_Entity -- ---------------------------- function Subprogram_Body_Entity (E : Entity_Id) return Entity_Id is N : constant Node_Id := Parent (Subprogram_Specification (E)); -- Declaration for E begin -- If this declaration is not a subprogram body, then it must be a -- subprogram declaration or body stub, from which we can retrieve the -- entity for the corresponding subprogram body if any, or an abstract -- subprogram declaration, for which we return Empty. case Nkind (N) is when N_Subprogram_Body => return E; when N_Subprogram_Body_Stub | N_Subprogram_Declaration => return Corresponding_Body (N); when others => return Empty; end case; end Subprogram_Body_Entity; --------------------- -- Subprogram_Spec -- --------------------- function Subprogram_Spec (E : Entity_Id) return Node_Id is N : constant Node_Id := Parent (Subprogram_Specification (E)); -- Declaration for E begin -- This declaration is either subprogram declaration or a subprogram -- body, in which case return Empty. if Nkind (N) = N_Subprogram_Declaration then return N; else return Empty; end if; end Subprogram_Spec; ------------------------------ -- Subprogram_Specification -- ------------------------------ function Subprogram_Specification (E : Entity_Id) return Node_Id is N : Node_Id; begin N := Parent (E); if Nkind (N) = N_Defining_Program_Unit_Name then N := Parent (N); end if; -- If the Parent pointer of E is not a subprogram specification node -- (going through an intermediate N_Defining_Program_Unit_Name node -- for subprogram units), then E is an inherited operation. Its parent -- points to the type derivation that produces the inheritance: that's -- the node that generates the subprogram specification. Its alias -- is the parent subprogram, and that one points to a subprogram -- declaration, or to another type declaration if this is a hierarchy -- of derivations. if Nkind (N) not in N_Subprogram_Specification then pragma Assert (Present (Alias (E))); N := Subprogram_Specification (Alias (E)); end if; return N; end Subprogram_Specification; --------------- -- Tree_Read -- --------------- procedure Tree_Read is begin Obsolescent_Warnings.Tree_Read; end Tree_Read; ---------------- -- Tree_Write -- ---------------- procedure Tree_Write is begin Obsolescent_Warnings.Tree_Write; end Tree_Write; -------------------- -- Ultimate_Alias -- -------------------- function Ultimate_Alias (Prim : Entity_Id) return Entity_Id is E : Entity_Id := Prim; begin while Present (Alias (E)) loop pragma Assert (Alias (E) /= E); E := Alias (E); end loop; return E; end Ultimate_Alias; -------------------------- -- Unit_Declaration_Node -- -------------------------- function Unit_Declaration_Node (Unit_Id : Entity_Id) return Node_Id is N : Node_Id := Parent (Unit_Id); begin -- Predefined operators do not have a full function declaration if Ekind (Unit_Id) = E_Operator then return N; end if; -- Isn't there some better way to express the following ??? while Nkind (N) /= N_Abstract_Subprogram_Declaration and then Nkind (N) /= N_Entry_Body and then Nkind (N) /= N_Entry_Declaration and then Nkind (N) /= N_Formal_Package_Declaration and then Nkind (N) /= N_Function_Instantiation and then Nkind (N) /= N_Generic_Package_Declaration and then Nkind (N) /= N_Generic_Subprogram_Declaration and then Nkind (N) /= N_Package_Declaration and then Nkind (N) /= N_Package_Body and then Nkind (N) /= N_Package_Instantiation and then Nkind (N) /= N_Package_Renaming_Declaration and then Nkind (N) /= N_Procedure_Instantiation and then Nkind (N) /= N_Protected_Body and then Nkind (N) /= N_Protected_Type_Declaration and then Nkind (N) /= N_Subprogram_Declaration and then Nkind (N) /= N_Subprogram_Body and then Nkind (N) /= N_Subprogram_Body_Stub and then Nkind (N) /= N_Subprogram_Renaming_Declaration and then Nkind (N) /= N_Task_Body and then Nkind (N) /= N_Task_Type_Declaration and then Nkind (N) not in N_Formal_Subprogram_Declaration and then Nkind (N) not in N_Generic_Renaming_Declaration loop N := Parent (N); -- We don't use Assert here, because that causes an infinite loop -- when assertions are turned off. Better to crash. if No (N) then raise Program_Error; end if; end loop; return N; end Unit_Declaration_Node; end Sem_Aux;