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diff --git a/gcc-4.8.3/gcc/ada/sem_ch8.adb b/gcc-4.8.3/gcc/ada/sem_ch8.adb new file mode 100644 index 000000000..32d49cc69 --- /dev/null +++ b/gcc-4.8.3/gcc/ada/sem_ch8.adb @@ -0,0 +1,8593 @@ +------------------------------------------------------------------------------ +-- -- +-- GNAT COMPILER COMPONENTS -- +-- -- +-- S E M . C H 8 -- +-- -- +-- B o d y -- +-- -- +-- Copyright (C) 1992-2013, 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. -- +-- -- +-- 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 Debug; use Debug; +with Einfo; use Einfo; +with Elists; use Elists; +with Errout; use Errout; +with Exp_Tss; use Exp_Tss; +with Exp_Util; use Exp_Util; +with Fname; use Fname; +with Freeze; use Freeze; +with Impunit; use Impunit; +with Lib; use Lib; +with Lib.Load; use Lib.Load; +with Lib.Xref; use Lib.Xref; +with Namet; use Namet; +with Namet.Sp; use Namet.Sp; +with Nlists; use Nlists; +with Nmake; use Nmake; +with Opt; use Opt; +with Output; use Output; +with Restrict; use Restrict; +with Rident; use Rident; +with Rtsfind; use Rtsfind; +with Sem; use Sem; +with Sem_Aux; use Sem_Aux; +with Sem_Cat; use Sem_Cat; +with Sem_Ch3; use Sem_Ch3; +with Sem_Ch4; use Sem_Ch4; +with Sem_Ch6; use Sem_Ch6; +with Sem_Ch12; use Sem_Ch12; +with Sem_Ch13; use Sem_Ch13; +with Sem_Dim; use Sem_Dim; +with Sem_Disp; use Sem_Disp; +with Sem_Dist; use Sem_Dist; +with Sem_Eval; use Sem_Eval; +with Sem_Res; use Sem_Res; +with Sem_Util; use Sem_Util; +with Sem_Type; use Sem_Type; +with Stand; use Stand; +with Sinfo; use Sinfo; +with Sinfo.CN; use Sinfo.CN; +with Snames; use Snames; +with Style; use Style; +with Table; +with Targparm; use Targparm; +with Tbuild; use Tbuild; +with Uintp; use Uintp; + +package body Sem_Ch8 is + + ------------------------------------ + -- Visibility and Name Resolution -- + ------------------------------------ + + -- This package handles name resolution and the collection of possible + -- interpretations for overloaded names, prior to overload resolution. + + -- Name resolution is the process that establishes a mapping between source + -- identifiers and the entities they denote at each point in the program. + -- Each entity is represented by a defining occurrence. Each identifier + -- that denotes an entity points to the corresponding defining occurrence. + -- This is the entity of the applied occurrence. Each occurrence holds + -- an index into the names table, where source identifiers are stored. + + -- Each entry in the names table for an identifier or designator uses the + -- Info pointer to hold a link to the currently visible entity that has + -- this name (see subprograms Get_Name_Entity_Id and Set_Name_Entity_Id + -- in package Sem_Util). The visibility is initialized at the beginning of + -- semantic processing to make entities in package Standard immediately + -- visible. The visibility table is used in a more subtle way when + -- compiling subunits (see below). + + -- Entities that have the same name (i.e. homonyms) are chained. In the + -- case of overloaded entities, this chain holds all the possible meanings + -- of a given identifier. The process of overload resolution uses type + -- information to select from this chain the unique meaning of a given + -- identifier. + + -- Entities are also chained in their scope, through the Next_Entity link. + -- As a consequence, the name space is organized as a sparse matrix, where + -- each row corresponds to a scope, and each column to a source identifier. + -- Open scopes, that is to say scopes currently being compiled, have their + -- corresponding rows of entities in order, innermost scope first. + + -- The scopes of packages that are mentioned in context clauses appear in + -- no particular order, interspersed among open scopes. This is because + -- in the course of analyzing the context of a compilation, a package + -- declaration is first an open scope, and subsequently an element of the + -- context. If subunits or child units are present, a parent unit may + -- appear under various guises at various times in the compilation. + + -- When the compilation of the innermost scope is complete, the entities + -- defined therein are no longer visible. If the scope is not a package + -- declaration, these entities are never visible subsequently, and can be + -- removed from visibility chains. If the scope is a package declaration, + -- its visible declarations may still be accessible. Therefore the entities + -- defined in such a scope are left on the visibility chains, and only + -- their visibility (immediately visibility or potential use-visibility) + -- is affected. + + -- The ordering of homonyms on their chain does not necessarily follow + -- the order of their corresponding scopes on the scope stack. For + -- example, if package P and the enclosing scope both contain entities + -- named E, then when compiling the package body the chain for E will + -- hold the global entity first, and the local one (corresponding to + -- the current inner scope) next. As a result, name resolution routines + -- do not assume any relative ordering of the homonym chains, either + -- for scope nesting or to order of appearance of context clauses. + + -- When compiling a child unit, entities in the parent scope are always + -- immediately visible. When compiling the body of a child unit, private + -- entities in the parent must also be made immediately visible. There + -- are separate routines to make the visible and private declarations + -- visible at various times (see package Sem_Ch7). + + -- +--------+ +-----+ + -- | In use |-------->| EU1 |--------------------------> + -- +--------+ +-----+ + -- | | + -- +--------+ +-----+ +-----+ + -- | Stand. |---------------->| ES1 |--------------->| ES2 |---> + -- +--------+ +-----+ +-----+ + -- | | + -- +---------+ | +-----+ + -- | with'ed |------------------------------>| EW2 |---> + -- +---------+ | +-----+ + -- | | + -- +--------+ +-----+ +-----+ + -- | Scope2 |---------------->| E12 |--------------->| E22 |---> + -- +--------+ +-----+ +-----+ + -- | | + -- +--------+ +-----+ +-----+ + -- | Scope1 |---------------->| E11 |--------------->| E12 |---> + -- +--------+ +-----+ +-----+ + -- ^ | | + -- | | | + -- | +---------+ | | + -- | | with'ed |-----------------------------------------> + -- | +---------+ | | + -- | | | + -- Scope stack | | + -- (innermost first) | | + -- +----------------------------+ + -- Names table => | Id1 | | | | Id2 | + -- +----------------------------+ + + -- Name resolution must deal with several syntactic forms: simple names, + -- qualified names, indexed names, and various forms of calls. + + -- Each identifier points to an entry in the names table. The resolution + -- of a simple name consists in traversing the homonym chain, starting + -- from the names table. If an entry is immediately visible, it is the one + -- designated by the identifier. If only potentially use-visible entities + -- are on the chain, we must verify that they do not hide each other. If + -- the entity we find is overloadable, we collect all other overloadable + -- entities on the chain as long as they are not hidden. + -- + -- To resolve expanded names, we must find the entity at the intersection + -- of the entity chain for the scope (the prefix) and the homonym chain + -- for the selector. In general, homonym chains will be much shorter than + -- entity chains, so it is preferable to start from the names table as + -- well. If the entity found is overloadable, we must collect all other + -- interpretations that are defined in the scope denoted by the prefix. + + -- For records, protected types, and tasks, their local entities are + -- removed from visibility chains on exit from the corresponding scope. + -- From the outside, these entities are always accessed by selected + -- notation, and the entity chain for the record type, protected type, + -- etc. is traversed sequentially in order to find the designated entity. + + -- The discriminants of a type and the operations of a protected type or + -- task are unchained on exit from the first view of the type, (such as + -- a private or incomplete type declaration, or a protected type speci- + -- fication) and re-chained when compiling the second view. + + -- In the case of operators, we do not make operators on derived types + -- explicit. As a result, the notation P."+" may denote either a user- + -- defined function with name "+", or else an implicit declaration of the + -- operator "+" in package P. The resolution of expanded names always + -- tries to resolve an operator name as such an implicitly defined entity, + -- in addition to looking for explicit declarations. + + -- All forms of names that denote entities (simple names, expanded names, + -- character literals in some cases) have a Entity attribute, which + -- identifies the entity denoted by the name. + + --------------------- + -- The Scope Stack -- + --------------------- + + -- The Scope stack keeps track of the scopes currently been compiled. + -- Every entity that contains declarations (including records) is placed + -- on the scope stack while it is being processed, and removed at the end. + -- Whenever a non-package scope is exited, the entities defined therein + -- are removed from the visibility table, so that entities in outer scopes + -- become visible (see previous description). On entry to Sem, the scope + -- stack only contains the package Standard. As usual, subunits complicate + -- this picture ever so slightly. + + -- The Rtsfind mechanism can force a call to Semantics while another + -- compilation is in progress. The unit retrieved by Rtsfind must be + -- compiled in its own context, and has no access to the visibility of + -- the unit currently being compiled. The procedures Save_Scope_Stack and + -- Restore_Scope_Stack make entities in current open scopes invisible + -- before compiling the retrieved unit, and restore the compilation + -- environment afterwards. + + ------------------------ + -- Compiling subunits -- + ------------------------ + + -- Subunits must be compiled in the environment of the corresponding stub, + -- that is to say with the same visibility into the parent (and its + -- context) that is available at the point of the stub declaration, but + -- with the additional visibility provided by the context clause of the + -- subunit itself. As a result, compilation of a subunit forces compilation + -- of the parent (see description in lib-). At the point of the stub + -- declaration, Analyze is called recursively to compile the proper body of + -- the subunit, but without reinitializing the names table, nor the scope + -- stack (i.e. standard is not pushed on the stack). In this fashion the + -- context of the subunit is added to the context of the parent, and the + -- subunit is compiled in the correct environment. Note that in the course + -- of processing the context of a subunit, Standard will appear twice on + -- the scope stack: once for the parent of the subunit, and once for the + -- unit in the context clause being compiled. However, the two sets of + -- entities are not linked by homonym chains, so that the compilation of + -- any context unit happens in a fresh visibility environment. + + ------------------------------- + -- Processing of USE Clauses -- + ------------------------------- + + -- Every defining occurrence has a flag indicating if it is potentially use + -- visible. Resolution of simple names examines this flag. The processing + -- of use clauses consists in setting this flag on all visible entities + -- defined in the corresponding package. On exit from the scope of the use + -- clause, the corresponding flag must be reset. However, a package may + -- appear in several nested use clauses (pathological but legal, alas!) + -- which forces us to use a slightly more involved scheme: + + -- a) The defining occurrence for a package holds a flag -In_Use- to + -- indicate that it is currently in the scope of a use clause. If a + -- redundant use clause is encountered, then the corresponding occurrence + -- of the package name is flagged -Redundant_Use-. + + -- b) On exit from a scope, the use clauses in its declarative part are + -- scanned. The visibility flag is reset in all entities declared in + -- package named in a use clause, as long as the package is not flagged + -- as being in a redundant use clause (in which case the outer use + -- clause is still in effect, and the direct visibility of its entities + -- must be retained). + + -- Note that entities are not removed from their homonym chains on exit + -- from the package specification. A subsequent use clause does not need + -- to rechain the visible entities, but only to establish their direct + -- visibility. + + ----------------------------------- + -- Handling private declarations -- + ----------------------------------- + + -- The principle that each entity has a single defining occurrence clashes + -- with the presence of two separate definitions for private types: the + -- first is the private type declaration, and second is the full type + -- declaration. It is important that all references to the type point to + -- the same defining occurrence, namely the first one. To enforce the two + -- separate views of the entity, the corresponding information is swapped + -- between the two declarations. Outside of the package, the defining + -- occurrence only contains the private declaration information, while in + -- the private part and the body of the package the defining occurrence + -- contains the full declaration. To simplify the swap, the defining + -- occurrence that currently holds the private declaration points to the + -- full declaration. During semantic processing the defining occurrence + -- also points to a list of private dependents, that is to say access types + -- or composite types whose designated types or component types are + -- subtypes or derived types of the private type in question. After the + -- full declaration has been seen, the private dependents are updated to + -- indicate that they have full definitions. + + ------------------------------------ + -- Handling of Undefined Messages -- + ------------------------------------ + + -- In normal mode, only the first use of an undefined identifier generates + -- a message. The table Urefs is used to record error messages that have + -- been issued so that second and subsequent ones do not generate further + -- messages. However, the second reference causes text to be added to the + -- original undefined message noting "(more references follow)". The + -- full error list option (-gnatf) forces messages to be generated for + -- every reference and disconnects the use of this table. + + type Uref_Entry is record + Node : Node_Id; + -- Node for identifier for which original message was posted. The + -- Chars field of this identifier is used to detect later references + -- to the same identifier. + + Err : Error_Msg_Id; + -- Records error message Id of original undefined message. Reset to + -- No_Error_Msg after the second occurrence, where it is used to add + -- text to the original message as described above. + + Nvis : Boolean; + -- Set if the message is not visible rather than undefined + + Loc : Source_Ptr; + -- Records location of error message. Used to make sure that we do + -- not consider a, b : undefined as two separate instances, which + -- would otherwise happen, since the parser converts this sequence + -- to a : undefined; b : undefined. + + end record; + + package Urefs is new Table.Table ( + Table_Component_Type => Uref_Entry, + Table_Index_Type => Nat, + Table_Low_Bound => 1, + Table_Initial => 10, + Table_Increment => 100, + Table_Name => "Urefs"); + + Candidate_Renaming : Entity_Id; + -- Holds a candidate interpretation that appears in a subprogram renaming + -- declaration and does not match the given specification, but matches at + -- least on the first formal. Allows better error message when given + -- specification omits defaulted parameters, a common error. + + ----------------------- + -- Local Subprograms -- + ----------------------- + + procedure Analyze_Generic_Renaming + (N : Node_Id; + K : Entity_Kind); + -- Common processing for all three kinds of generic renaming declarations. + -- Enter new name and indicate that it renames the generic unit. + + procedure Analyze_Renamed_Character + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean); + -- Renamed entity is given by a character literal, which must belong + -- to the return type of the new entity. Is_Body indicates whether the + -- declaration is a renaming_as_body. If the original declaration has + -- already been frozen (because of an intervening body, e.g.) the body of + -- the function must be built now. The same applies to the following + -- various renaming procedures. + + procedure Analyze_Renamed_Dereference + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean); + -- Renamed entity is given by an explicit dereference. Prefix must be a + -- conformant access_to_subprogram type. + + procedure Analyze_Renamed_Entry + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean); + -- If the renamed entity in a subprogram renaming is an entry or protected + -- subprogram, build a body for the new entity whose only statement is a + -- call to the renamed entity. + + procedure Analyze_Renamed_Family_Member + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean); + -- Used when the renamed entity is an indexed component. The prefix must + -- denote an entry family. + + procedure Analyze_Renamed_Primitive_Operation + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean); + -- If the renamed entity in a subprogram renaming is a primitive operation + -- or a class-wide operation in prefix form, save the target object, + -- which must be added to the list of actuals in any subsequent call. + -- The renaming operation is intrinsic because the compiler must in + -- fact generate a wrapper for it (6.3.1 (10 1/2)). + + function Applicable_Use (Pack_Name : Node_Id) return Boolean; + -- Common code to Use_One_Package and Set_Use, to determine whether use + -- clause must be processed. Pack_Name is an entity name that references + -- the package in question. + + procedure Attribute_Renaming (N : Node_Id); + -- Analyze renaming of attribute as subprogram. The renaming declaration N + -- is rewritten as a subprogram body that returns the attribute reference + -- applied to the formals of the function. + + procedure Set_Entity_Or_Discriminal (N : Node_Id; E : Entity_Id); + -- Set Entity, with style check if need be. For a discriminant reference, + -- replace by the corresponding discriminal, i.e. the parameter of the + -- initialization procedure that corresponds to the discriminant. + + procedure Check_Frozen_Renaming (N : Node_Id; Subp : Entity_Id); + -- A renaming_as_body may occur after the entity of the original decla- + -- ration has been frozen. In that case, the body of the new entity must + -- be built now, because the usual mechanism of building the renamed + -- body at the point of freezing will not work. Subp is the subprogram + -- for which N provides the Renaming_As_Body. + + procedure Check_In_Previous_With_Clause + (N : Node_Id; + Nam : Node_Id); + -- N is a use_package clause and Nam the package name, or N is a use_type + -- clause and Nam is the prefix of the type name. In either case, verify + -- that the package is visible at that point in the context: either it + -- appears in a previous with_clause, or because it is a fully qualified + -- name and the root ancestor appears in a previous with_clause. + + procedure Check_Library_Unit_Renaming (N : Node_Id; Old_E : Entity_Id); + -- Verify that the entity in a renaming declaration that is a library unit + -- is itself a library unit and not a nested unit or subunit. Also check + -- that if the renaming is a child unit of a generic parent, then the + -- renamed unit must also be a child unit of that parent. Finally, verify + -- that a renamed generic unit is not an implicit child declared within + -- an instance of the parent. + + procedure Chain_Use_Clause (N : Node_Id); + -- Chain use clause onto list of uses clauses headed by First_Use_Clause in + -- the proper scope table entry. This is usually the current scope, but it + -- will be an inner scope when installing the use clauses of the private + -- declarations of a parent unit prior to compiling the private part of a + -- child unit. This chain is traversed when installing/removing use clauses + -- when compiling a subunit or instantiating a generic body on the fly, + -- when it is necessary to save and restore full environments. + + function Has_Implicit_Character_Literal (N : Node_Id) return Boolean; + -- Find a type derived from Character or Wide_Character in the prefix of N. + -- Used to resolved qualified names whose selector is a character literal. + + function Has_Private_With (E : Entity_Id) return Boolean; + -- Ada 2005 (AI-262): Determines if the current compilation unit has a + -- private with on E. + + procedure Find_Expanded_Name (N : Node_Id); + -- The input is a selected component known to be an expanded name. Verify + -- legality of selector given the scope denoted by prefix, and change node + -- N into a expanded name with a properly set Entity field. + + function Find_Renamed_Entity + (N : Node_Id; + Nam : Node_Id; + New_S : Entity_Id; + Is_Actual : Boolean := False) return Entity_Id; + -- Find the renamed entity that corresponds to the given parameter profile + -- in a subprogram renaming declaration. The renamed entity may be an + -- operator, a subprogram, an entry, or a protected operation. Is_Actual + -- indicates that the renaming is the one generated for an actual subpro- + -- gram in an instance, for which special visibility checks apply. + + function Has_Implicit_Operator (N : Node_Id) return Boolean; + -- N is an expanded name whose selector is an operator name (e.g. P."+"). + -- declarative part contains an implicit declaration of an operator if it + -- has a declaration of a type to which one of the predefined operators + -- apply. The existence of this routine is an implementation artifact. A + -- more straightforward but more space-consuming choice would be to make + -- all inherited operators explicit in the symbol table. + + procedure Inherit_Renamed_Profile (New_S : Entity_Id; Old_S : Entity_Id); + -- A subprogram defined by a renaming declaration inherits the parameter + -- profile of the renamed entity. The subtypes given in the subprogram + -- specification are discarded and replaced with those of the renamed + -- subprogram, which are then used to recheck the default values. + + function Is_Appropriate_For_Record (T : Entity_Id) return Boolean; + -- Prefix is appropriate for record if it is of a record type, or an access + -- to such. + + function Is_Appropriate_For_Entry_Prefix (T : Entity_Id) return Boolean; + -- True if it is of a task type, a protected type, or else an access to one + -- of these types. + + procedure Note_Redundant_Use (Clause : Node_Id); + -- Mark the name in a use clause as redundant if the corresponding entity + -- is already use-visible. Emit a warning if the use clause comes from + -- source and the proper warnings are enabled. + + procedure Premature_Usage (N : Node_Id); + -- Diagnose usage of an entity before it is visible + + procedure Use_One_Package (P : Entity_Id; N : Node_Id); + -- Make visible entities declared in package P potentially use-visible + -- in the current context. Also used in the analysis of subunits, when + -- re-installing use clauses of parent units. N is the use_clause that + -- names P (and possibly other packages). + + procedure Use_One_Type (Id : Node_Id; Installed : Boolean := False); + -- Id is the subtype mark from a use type clause. This procedure makes + -- the primitive operators of the type potentially use-visible. The + -- boolean flag Installed indicates that the clause is being reinstalled + -- after previous analysis, and primitive operations are already chained + -- on the Used_Operations list of the clause. + + procedure Write_Info; + -- Write debugging information on entities declared in current scope + + -------------------------------- + -- Analyze_Exception_Renaming -- + -------------------------------- + + -- The language only allows a single identifier, but the tree holds an + -- identifier list. The parser has already issued an error message if + -- there is more than one element in the list. + + procedure Analyze_Exception_Renaming (N : Node_Id) is + Id : constant Node_Id := Defining_Identifier (N); + Nam : constant Node_Id := Name (N); + + begin + Check_SPARK_Restriction ("exception renaming is not allowed", N); + + Enter_Name (Id); + Analyze (Nam); + + Set_Ekind (Id, E_Exception); + Set_Exception_Code (Id, Uint_0); + Set_Etype (Id, Standard_Exception_Type); + Set_Is_Pure (Id, Is_Pure (Current_Scope)); + + if not Is_Entity_Name (Nam) or else + Ekind (Entity (Nam)) /= E_Exception + then + Error_Msg_N ("invalid exception name in renaming", Nam); + else + if Present (Renamed_Object (Entity (Nam))) then + Set_Renamed_Object (Id, Renamed_Object (Entity (Nam))); + else + Set_Renamed_Object (Id, Entity (Nam)); + end if; + end if; + + -- Implementation-defined aspect specifications can appear in a renaming + -- declaration, but not language-defined ones. The call to procedure + -- Analyze_Aspect_Specifications will take care of this error check. + + if Has_Aspects (N) then + Analyze_Aspect_Specifications (N, Id); + end if; + end Analyze_Exception_Renaming; + + --------------------------- + -- Analyze_Expanded_Name -- + --------------------------- + + procedure Analyze_Expanded_Name (N : Node_Id) is + begin + -- If the entity pointer is already set, this is an internal node, or a + -- node that is analyzed more than once, after a tree modification. In + -- such a case there is no resolution to perform, just set the type. For + -- completeness, analyze prefix as well. + + if Present (Entity (N)) then + if Is_Type (Entity (N)) then + Set_Etype (N, Entity (N)); + else + Set_Etype (N, Etype (Entity (N))); + end if; + + Analyze (Prefix (N)); + return; + else + Find_Expanded_Name (N); + end if; + + Analyze_Dimension (N); + end Analyze_Expanded_Name; + + --------------------------------------- + -- Analyze_Generic_Function_Renaming -- + --------------------------------------- + + procedure Analyze_Generic_Function_Renaming (N : Node_Id) is + begin + Analyze_Generic_Renaming (N, E_Generic_Function); + end Analyze_Generic_Function_Renaming; + + -------------------------------------- + -- Analyze_Generic_Package_Renaming -- + -------------------------------------- + + procedure Analyze_Generic_Package_Renaming (N : Node_Id) is + begin + -- Apply the Text_IO Kludge here, since we may be renaming one of the + -- subpackages of Text_IO, then join common routine. + + Text_IO_Kludge (Name (N)); + + Analyze_Generic_Renaming (N, E_Generic_Package); + end Analyze_Generic_Package_Renaming; + + ---------------------------------------- + -- Analyze_Generic_Procedure_Renaming -- + ---------------------------------------- + + procedure Analyze_Generic_Procedure_Renaming (N : Node_Id) is + begin + Analyze_Generic_Renaming (N, E_Generic_Procedure); + end Analyze_Generic_Procedure_Renaming; + + ------------------------------ + -- Analyze_Generic_Renaming -- + ------------------------------ + + procedure Analyze_Generic_Renaming + (N : Node_Id; + K : Entity_Kind) + is + New_P : constant Entity_Id := Defining_Entity (N); + Old_P : Entity_Id; + Inst : Boolean := False; -- prevent junk warning + + begin + if Name (N) = Error then + return; + end if; + + Check_SPARK_Restriction ("generic renaming is not allowed", N); + + Generate_Definition (New_P); + + if Current_Scope /= Standard_Standard then + Set_Is_Pure (New_P, Is_Pure (Current_Scope)); + end if; + + if Nkind (Name (N)) = N_Selected_Component then + Check_Generic_Child_Unit (Name (N), Inst); + else + Analyze (Name (N)); + end if; + + if not Is_Entity_Name (Name (N)) then + Error_Msg_N ("expect entity name in renaming declaration", Name (N)); + Old_P := Any_Id; + else + Old_P := Entity (Name (N)); + end if; + + Enter_Name (New_P); + Set_Ekind (New_P, K); + + if Etype (Old_P) = Any_Type then + null; + + elsif Ekind (Old_P) /= K then + Error_Msg_N ("invalid generic unit name", Name (N)); + + else + if Present (Renamed_Object (Old_P)) then + Set_Renamed_Object (New_P, Renamed_Object (Old_P)); + else + Set_Renamed_Object (New_P, Old_P); + end if; + + Set_Is_Pure (New_P, Is_Pure (Old_P)); + Set_Is_Preelaborated (New_P, Is_Preelaborated (Old_P)); + + Set_Etype (New_P, Etype (Old_P)); + Set_Has_Completion (New_P); + + if In_Open_Scopes (Old_P) then + Error_Msg_N ("within its scope, generic denotes its instance", N); + end if; + + Check_Library_Unit_Renaming (N, Old_P); + end if; + + -- Implementation-defined aspect specifications can appear in a renaming + -- declaration, but not language-defined ones. The call to procedure + -- Analyze_Aspect_Specifications will take care of this error check. + + if Has_Aspects (N) then + Analyze_Aspect_Specifications (N, New_P); + end if; + end Analyze_Generic_Renaming; + + ----------------------------- + -- Analyze_Object_Renaming -- + ----------------------------- + + procedure Analyze_Object_Renaming (N : Node_Id) is + Loc : constant Source_Ptr := Sloc (N); + Id : constant Entity_Id := Defining_Identifier (N); + Dec : Node_Id; + Nam : constant Node_Id := Name (N); + T : Entity_Id; + T2 : Entity_Id; + + procedure Check_Constrained_Object; + -- If the nominal type is unconstrained but the renamed object is + -- constrained, as can happen with renaming an explicit dereference or + -- a function return, build a constrained subtype from the object. If + -- the renaming is for a formal in an accept statement, the analysis + -- has already established its actual subtype. This is only relevant + -- if the renamed object is an explicit dereference. + + function In_Generic_Scope (E : Entity_Id) return Boolean; + -- Determine whether entity E is inside a generic cope + + ------------------------------ + -- Check_Constrained_Object -- + ------------------------------ + + procedure Check_Constrained_Object is + Typ : constant Entity_Id := Etype (Nam); + Subt : Entity_Id; + + begin + if Nkind_In (Nam, N_Function_Call, N_Explicit_Dereference) + and then Is_Composite_Type (Etype (Nam)) + and then not Is_Constrained (Etype (Nam)) + and then not Has_Unknown_Discriminants (Etype (Nam)) + and then Expander_Active + then + -- If Actual_Subtype is already set, nothing to do + + if Ekind_In (Id, E_Variable, E_Constant) + and then Present (Actual_Subtype (Id)) + then + null; + + -- A renaming of an unchecked union has no actual subtype + + elsif Is_Unchecked_Union (Typ) then + null; + + -- If a record is limited its size is invariant. This is the case + -- in particular with record types with an access discirminant + -- that are used in iterators. This is an optimization, but it + -- also prevents typing anomalies when the prefix is further + -- expanded. Limited types with discriminants are included. + + elsif Is_Limited_Record (Typ) + or else + (Ekind (Typ) = E_Limited_Private_Type + and then Has_Discriminants (Typ) + and then Is_Access_Type (Etype (First_Discriminant (Typ)))) + then + null; + + else + Subt := Make_Temporary (Loc, 'T'); + Remove_Side_Effects (Nam); + Insert_Action (N, + Make_Subtype_Declaration (Loc, + Defining_Identifier => Subt, + Subtype_Indication => + Make_Subtype_From_Expr (Nam, Typ))); + Rewrite (Subtype_Mark (N), New_Occurrence_Of (Subt, Loc)); + Set_Etype (Nam, Subt); + end if; + end if; + end Check_Constrained_Object; + + ---------------------- + -- In_Generic_Scope -- + ---------------------- + + function In_Generic_Scope (E : Entity_Id) return Boolean is + S : Entity_Id; + + begin + S := Scope (E); + while Present (S) and then S /= Standard_Standard loop + if Is_Generic_Unit (S) then + return True; + end if; + + S := Scope (S); + end loop; + + return False; + end In_Generic_Scope; + + -- Start of processing for Analyze_Object_Renaming + + begin + if Nam = Error then + return; + end if; + + Check_SPARK_Restriction ("object renaming is not allowed", N); + + Set_Is_Pure (Id, Is_Pure (Current_Scope)); + Enter_Name (Id); + + -- The renaming of a component that depends on a discriminant requires + -- an actual subtype, because in subsequent use of the object Gigi will + -- be unable to locate the actual bounds. This explicit step is required + -- when the renaming is generated in removing side effects of an + -- already-analyzed expression. + + if Nkind (Nam) = N_Selected_Component and then Analyzed (Nam) then + T := Etype (Nam); + Dec := Build_Actual_Subtype_Of_Component (Etype (Nam), Nam); + + if Present (Dec) then + Insert_Action (N, Dec); + T := Defining_Identifier (Dec); + Set_Etype (Nam, T); + end if; + + -- Complete analysis of the subtype mark in any case, for ASIS use + + if Present (Subtype_Mark (N)) then + Find_Type (Subtype_Mark (N)); + end if; + + elsif Present (Subtype_Mark (N)) then + Find_Type (Subtype_Mark (N)); + T := Entity (Subtype_Mark (N)); + Analyze (Nam); + + -- Reject renamings of conversions unless the type is tagged, or + -- the conversion is implicit (which can occur for cases of anonymous + -- access types in Ada 2012). + + if Nkind (Nam) = N_Type_Conversion + and then Comes_From_Source (Nam) + and then not Is_Tagged_Type (T) + then + Error_Msg_N + ("renaming of conversion only allowed for tagged types", Nam); + end if; + + Resolve (Nam, T); + + -- If the renamed object is a function call of a limited type, + -- the expansion of the renaming is complicated by the presence + -- of various temporaries and subtypes that capture constraints + -- of the renamed object. Rewrite node as an object declaration, + -- whose expansion is simpler. Given that the object is limited + -- there is no copy involved and no performance hit. + + if Nkind (Nam) = N_Function_Call + and then Is_Immutably_Limited_Type (Etype (Nam)) + and then not Is_Constrained (Etype (Nam)) + and then Comes_From_Source (N) + then + Set_Etype (Id, T); + Set_Ekind (Id, E_Constant); + Rewrite (N, + Make_Object_Declaration (Loc, + Defining_Identifier => Id, + Constant_Present => True, + Object_Definition => New_Occurrence_Of (Etype (Nam), Loc), + Expression => Relocate_Node (Nam))); + return; + end if; + + -- Ada 2012 (AI05-149): Reject renaming of an anonymous access object + -- when renaming declaration has a named access type. The Ada 2012 + -- coverage rules allow an anonymous access type in the context of + -- an expected named general access type, but the renaming rules + -- require the types to be the same. (An exception is when the type + -- of the renaming is also an anonymous access type, which can only + -- happen due to a renaming created by the expander.) + + if Nkind (Nam) = N_Type_Conversion + and then not Comes_From_Source (Nam) + and then Ekind (Etype (Expression (Nam))) = E_Anonymous_Access_Type + and then Ekind (T) /= E_Anonymous_Access_Type + then + Wrong_Type (Expression (Nam), T); -- Should we give better error??? + end if; + + -- Check that a class-wide object is not being renamed as an object + -- of a specific type. The test for access types is needed to exclude + -- cases where the renamed object is a dynamically tagged access + -- result, such as occurs in certain expansions. + + if Is_Tagged_Type (T) then + Check_Dynamically_Tagged_Expression + (Expr => Nam, + Typ => T, + Related_Nod => N); + end if; + + -- Ada 2005 (AI-230/AI-254): Access renaming + + else pragma Assert (Present (Access_Definition (N))); + T := Access_Definition + (Related_Nod => N, + N => Access_Definition (N)); + + Analyze (Nam); + + -- Ada 2005 AI05-105: if the declaration has an anonymous access + -- type, the renamed object must also have an anonymous type, and + -- this is a name resolution rule. This was implicit in the last part + -- of the first sentence in 8.5.1(3/2), and is made explicit by this + -- recent AI. + + if not Is_Overloaded (Nam) then + if Ekind (Etype (Nam)) /= Ekind (T) then + Error_Msg_N + ("expect anonymous access type in object renaming", N); + end if; + + else + declare + I : Interp_Index; + It : Interp; + Typ : Entity_Id := Empty; + Seen : Boolean := False; + + begin + Get_First_Interp (Nam, I, It); + while Present (It.Typ) loop + + -- Renaming is ambiguous if more than one candidate + -- interpretation is type-conformant with the context. + + if Ekind (It.Typ) = Ekind (T) then + if Ekind (T) = E_Anonymous_Access_Subprogram_Type + and then + Type_Conformant + (Designated_Type (T), Designated_Type (It.Typ)) + then + if not Seen then + Seen := True; + else + Error_Msg_N + ("ambiguous expression in renaming", Nam); + end if; + + elsif Ekind (T) = E_Anonymous_Access_Type + and then + Covers (Designated_Type (T), Designated_Type (It.Typ)) + then + if not Seen then + Seen := True; + else + Error_Msg_N + ("ambiguous expression in renaming", Nam); + end if; + end if; + + if Covers (T, It.Typ) then + Typ := It.Typ; + Set_Etype (Nam, Typ); + Set_Is_Overloaded (Nam, False); + end if; + end if; + + Get_Next_Interp (I, It); + end loop; + end; + end if; + + Resolve (Nam, T); + + -- Ada 2005 (AI-231): "In the case where the type is defined by an + -- access_definition, the renamed entity shall be of an access-to- + -- constant type if and only if the access_definition defines an + -- access-to-constant type" ARM 8.5.1(4) + + if Constant_Present (Access_Definition (N)) + and then not Is_Access_Constant (Etype (Nam)) + then + Error_Msg_N ("(Ada 2005): the renamed object is not " + & "access-to-constant (RM 8.5.1(6))", N); + + elsif not Constant_Present (Access_Definition (N)) + and then Is_Access_Constant (Etype (Nam)) + then + Error_Msg_N ("(Ada 2005): the renamed object is not " + & "access-to-variable (RM 8.5.1(6))", N); + end if; + + if Is_Access_Subprogram_Type (Etype (Nam)) then + Check_Subtype_Conformant + (Designated_Type (T), Designated_Type (Etype (Nam))); + + elsif not Subtypes_Statically_Match + (Designated_Type (T), + Available_View (Designated_Type (Etype (Nam)))) + then + Error_Msg_N + ("subtype of renamed object does not statically match", N); + end if; + end if; + + -- Special processing for renaming function return object. Some errors + -- and warnings are produced only for calls that come from source. + + if Nkind (Nam) = N_Function_Call then + case Ada_Version is + + -- Usage is illegal in Ada 83 + + when Ada_83 => + if Comes_From_Source (Nam) then + Error_Msg_N + ("(Ada 83) cannot rename function return object", Nam); + end if; + + -- In Ada 95, warn for odd case of renaming parameterless function + -- call if this is not a limited type (where this is useful). + + when others => + if Warn_On_Object_Renames_Function + and then No (Parameter_Associations (Nam)) + and then not Is_Limited_Type (Etype (Nam)) + and then Comes_From_Source (Nam) + then + Error_Msg_N + ("renaming function result object is suspicious?R?", Nam); + Error_Msg_NE + ("\function & will be called only once?R?", Nam, + Entity (Name (Nam))); + Error_Msg_N -- CODEFIX + ("\suggest using an initialized constant " + & "object instead?R?", Nam); + end if; + + end case; + end if; + + Check_Constrained_Object; + + -- An object renaming requires an exact match of the type. Class-wide + -- matching is not allowed. + + if Is_Class_Wide_Type (T) + and then Base_Type (Etype (Nam)) /= Base_Type (T) + then + Wrong_Type (Nam, T); + end if; + + T2 := Etype (Nam); + + -- Ada 2005 (AI-326): Handle wrong use of incomplete type + + if Nkind (Nam) = N_Explicit_Dereference + and then Ekind (Etype (T2)) = E_Incomplete_Type + then + Error_Msg_NE ("invalid use of incomplete type&", Id, T2); + return; + + elsif Ekind (Etype (T)) = E_Incomplete_Type then + Error_Msg_NE ("invalid use of incomplete type&", Id, T); + return; + end if; + + -- Ada 2005 (AI-327) + + if Ada_Version >= Ada_2005 + and then Nkind (Nam) = N_Attribute_Reference + and then Attribute_Name (Nam) = Name_Priority + then + null; + + elsif Ada_Version >= Ada_2005 + and then Nkind (Nam) in N_Has_Entity + then + declare + Nam_Decl : Node_Id; + Nam_Ent : Entity_Id; + + begin + if Nkind (Nam) = N_Attribute_Reference then + Nam_Ent := Entity (Prefix (Nam)); + else + Nam_Ent := Entity (Nam); + end if; + + Nam_Decl := Parent (Nam_Ent); + + if Has_Null_Exclusion (N) + and then not Has_Null_Exclusion (Nam_Decl) + then + -- Ada 2005 (AI-423): If the object name denotes a generic + -- formal object of a generic unit G, and the object renaming + -- declaration occurs within the body of G or within the body + -- of a generic unit declared within the declarative region + -- of G, then the declaration of the formal object of G must + -- have a null exclusion or a null-excluding subtype. + + if Is_Formal_Object (Nam_Ent) + and then In_Generic_Scope (Id) + then + if not Can_Never_Be_Null (Etype (Nam_Ent)) then + Error_Msg_N + ("renamed formal does not exclude `NULL` " + & "(RM 8.5.1(4.6/2))", N); + + elsif In_Package_Body (Scope (Id)) then + Error_Msg_N + ("formal object does not have a null exclusion" + & "(RM 8.5.1(4.6/2))", N); + end if; + + -- Ada 2005 (AI-423): Otherwise, the subtype of the object name + -- shall exclude null. + + elsif not Can_Never_Be_Null (Etype (Nam_Ent)) then + Error_Msg_N + ("renamed object does not exclude `NULL` " + & "(RM 8.5.1(4.6/2))", N); + + -- An instance is illegal if it contains a renaming that + -- excludes null, and the actual does not. The renaming + -- declaration has already indicated that the declaration + -- of the renamed actual in the instance will raise + -- constraint_error. + + elsif Nkind (Nam_Decl) = N_Object_Declaration + and then In_Instance + and then Present + (Corresponding_Generic_Association (Nam_Decl)) + and then Nkind (Expression (Nam_Decl)) + = N_Raise_Constraint_Error + then + Error_Msg_N + ("renamed actual does not exclude `NULL` " + & "(RM 8.5.1(4.6/2))", N); + + -- Finally, if there is a null exclusion, the subtype mark + -- must not be null-excluding. + + elsif No (Access_Definition (N)) + and then Can_Never_Be_Null (T) + then + Error_Msg_NE + ("`NOT NULL` not allowed (& already excludes null)", + N, T); + + end if; + + elsif Can_Never_Be_Null (T) + and then not Can_Never_Be_Null (Etype (Nam_Ent)) + then + Error_Msg_N + ("renamed object does not exclude `NULL` " + & "(RM 8.5.1(4.6/2))", N); + + elsif Has_Null_Exclusion (N) + and then No (Access_Definition (N)) + and then Can_Never_Be_Null (T) + then + Error_Msg_NE + ("`NOT NULL` not allowed (& already excludes null)", N, T); + end if; + end; + end if; + + Set_Ekind (Id, E_Variable); + + -- Initialize the object size and alignment. Note that we used to call + -- Init_Size_Align here, but that's wrong for objects which have only + -- an Esize, not an RM_Size field! + + Init_Object_Size_Align (Id); + + if T = Any_Type or else Etype (Nam) = Any_Type then + return; + + -- Verify that the renamed entity is an object or a function call. It + -- may have been rewritten in several ways. + + elsif Is_Object_Reference (Nam) then + if Comes_From_Source (N) + and then Is_Dependent_Component_Of_Mutable_Object (Nam) + then + Error_Msg_N + ("illegal renaming of discriminant-dependent component", Nam); + end if; + + -- A static function call may have been folded into a literal + + elsif Nkind (Original_Node (Nam)) = N_Function_Call + + -- When expansion is disabled, attribute reference is not + -- rewritten as function call. Otherwise it may be rewritten + -- as a conversion, so check original node. + + or else (Nkind (Original_Node (Nam)) = N_Attribute_Reference + and then Is_Function_Attribute_Name + (Attribute_Name (Original_Node (Nam)))) + + -- Weird but legal, equivalent to renaming a function call. + -- Illegal if the literal is the result of constant-folding an + -- attribute reference that is not a function. + + or else (Is_Entity_Name (Nam) + and then Ekind (Entity (Nam)) = E_Enumeration_Literal + and then + Nkind (Original_Node (Nam)) /= N_Attribute_Reference) + + or else (Nkind (Nam) = N_Type_Conversion + and then Is_Tagged_Type (Entity (Subtype_Mark (Nam)))) + then + null; + + elsif Nkind (Nam) = N_Type_Conversion then + Error_Msg_N + ("renaming of conversion only allowed for tagged types", Nam); + + -- Ada 2005 (AI-327) + + elsif Ada_Version >= Ada_2005 + and then Nkind (Nam) = N_Attribute_Reference + and then Attribute_Name (Nam) = Name_Priority + then + null; + + -- Allow internally generated x'Reference expression + + elsif Nkind (Nam) = N_Reference then + null; + + else + Error_Msg_N ("expect object name in renaming", Nam); + end if; + + Set_Etype (Id, T2); + + if not Is_Variable (Nam) then + Set_Ekind (Id, E_Constant); + Set_Never_Set_In_Source (Id, True); + Set_Is_True_Constant (Id, True); + end if; + + Set_Renamed_Object (Id, Nam); + + -- Implementation-defined aspect specifications can appear in a renaming + -- declaration, but not language-defined ones. The call to procedure + -- Analyze_Aspect_Specifications will take care of this error check. + + if Has_Aspects (N) then + Analyze_Aspect_Specifications (N, Id); + end if; + + -- Deal with dimensions + + Analyze_Dimension (N); + end Analyze_Object_Renaming; + + ------------------------------ + -- Analyze_Package_Renaming -- + ------------------------------ + + procedure Analyze_Package_Renaming (N : Node_Id) is + New_P : constant Entity_Id := Defining_Entity (N); + Old_P : Entity_Id; + Spec : Node_Id; + + begin + if Name (N) = Error then + return; + end if; + + -- Apply Text_IO kludge here since we may be renaming a child of Text_IO + + Text_IO_Kludge (Name (N)); + + if Current_Scope /= Standard_Standard then + Set_Is_Pure (New_P, Is_Pure (Current_Scope)); + end if; + + Enter_Name (New_P); + Analyze (Name (N)); + + if Is_Entity_Name (Name (N)) then + Old_P := Entity (Name (N)); + else + Old_P := Any_Id; + end if; + + if Etype (Old_P) = Any_Type then + Error_Msg_N ("expect package name in renaming", Name (N)); + + elsif Ekind (Old_P) /= E_Package + and then not (Ekind (Old_P) = E_Generic_Package + and then In_Open_Scopes (Old_P)) + then + if Ekind (Old_P) = E_Generic_Package then + Error_Msg_N + ("generic package cannot be renamed as a package", Name (N)); + else + Error_Msg_Sloc := Sloc (Old_P); + Error_Msg_NE + ("expect package name in renaming, found& declared#", + Name (N), Old_P); + end if; + + -- Set basic attributes to minimize cascaded errors + + Set_Ekind (New_P, E_Package); + Set_Etype (New_P, Standard_Void_Type); + + -- Here for OK package renaming + + else + -- Entities in the old package are accessible through the renaming + -- entity. The simplest implementation is to have both packages share + -- the entity list. + + Set_Ekind (New_P, E_Package); + Set_Etype (New_P, Standard_Void_Type); + + if Present (Renamed_Object (Old_P)) then + Set_Renamed_Object (New_P, Renamed_Object (Old_P)); + else + Set_Renamed_Object (New_P, Old_P); + end if; + + Set_Has_Completion (New_P); + + Set_First_Entity (New_P, First_Entity (Old_P)); + Set_Last_Entity (New_P, Last_Entity (Old_P)); + Set_First_Private_Entity (New_P, First_Private_Entity (Old_P)); + Check_Library_Unit_Renaming (N, Old_P); + Generate_Reference (Old_P, Name (N)); + + -- If the renaming is in the visible part of a package, then we set + -- Renamed_In_Spec for the renamed package, to prevent giving + -- warnings about no entities referenced. Such a warning would be + -- overenthusiastic, since clients can see entities in the renamed + -- package via the visible package renaming. + + declare + Ent : constant Entity_Id := Cunit_Entity (Current_Sem_Unit); + begin + if Ekind (Ent) = E_Package + and then not In_Private_Part (Ent) + and then In_Extended_Main_Source_Unit (N) + and then Ekind (Old_P) = E_Package + then + Set_Renamed_In_Spec (Old_P); + end if; + end; + + -- If this is the renaming declaration of a package instantiation + -- within itself, it is the declaration that ends the list of actuals + -- for the instantiation. At this point, the subtypes that rename + -- the actuals are flagged as generic, to avoid spurious ambiguities + -- if the actuals for two distinct formals happen to coincide. If + -- the actual is a private type, the subtype has a private completion + -- that is flagged in the same fashion. + + -- Resolution is identical to what is was in the original generic. + -- On exit from the generic instance, these are turned into regular + -- subtypes again, so they are compatible with types in their class. + + if not Is_Generic_Instance (Old_P) then + return; + else + Spec := Specification (Unit_Declaration_Node (Old_P)); + end if; + + if Nkind (Spec) = N_Package_Specification + and then Present (Generic_Parent (Spec)) + and then Old_P = Current_Scope + and then Chars (New_P) = Chars (Generic_Parent (Spec)) + then + declare + E : Entity_Id; + + begin + E := First_Entity (Old_P); + while Present (E) + and then E /= New_P + loop + if Is_Type (E) + and then Nkind (Parent (E)) = N_Subtype_Declaration + then + Set_Is_Generic_Actual_Type (E); + + if Is_Private_Type (E) + and then Present (Full_View (E)) + then + Set_Is_Generic_Actual_Type (Full_View (E)); + end if; + end if; + + Next_Entity (E); + end loop; + end; + end if; + end if; + + -- Implementation-defined aspect specifications can appear in a renaming + -- declaration, but not language-defined ones. The call to procedure + -- Analyze_Aspect_Specifications will take care of this error check. + + if Has_Aspects (N) then + Analyze_Aspect_Specifications (N, New_P); + end if; + end Analyze_Package_Renaming; + + ------------------------------- + -- Analyze_Renamed_Character -- + ------------------------------- + + procedure Analyze_Renamed_Character + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean) + is + C : constant Node_Id := Name (N); + + begin + if Ekind (New_S) = E_Function then + Resolve (C, Etype (New_S)); + + if Is_Body then + Check_Frozen_Renaming (N, New_S); + end if; + + else + Error_Msg_N ("character literal can only be renamed as function", N); + end if; + end Analyze_Renamed_Character; + + --------------------------------- + -- Analyze_Renamed_Dereference -- + --------------------------------- + + procedure Analyze_Renamed_Dereference + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean) + is + Nam : constant Node_Id := Name (N); + P : constant Node_Id := Prefix (Nam); + Typ : Entity_Id; + Ind : Interp_Index; + It : Interp; + + begin + if not Is_Overloaded (P) then + if Ekind (Etype (Nam)) /= E_Subprogram_Type + or else not Type_Conformant (Etype (Nam), New_S) + then + Error_Msg_N ("designated type does not match specification", P); + else + Resolve (P); + end if; + + return; + + else + Typ := Any_Type; + Get_First_Interp (Nam, Ind, It); + + while Present (It.Nam) loop + + if Ekind (It.Nam) = E_Subprogram_Type + and then Type_Conformant (It.Nam, New_S) + then + if Typ /= Any_Id then + Error_Msg_N ("ambiguous renaming", P); + return; + else + Typ := It.Nam; + end if; + end if; + + Get_Next_Interp (Ind, It); + end loop; + + if Typ = Any_Type then + Error_Msg_N ("designated type does not match specification", P); + else + Resolve (N, Typ); + + if Is_Body then + Check_Frozen_Renaming (N, New_S); + end if; + end if; + end if; + end Analyze_Renamed_Dereference; + + --------------------------- + -- Analyze_Renamed_Entry -- + --------------------------- + + procedure Analyze_Renamed_Entry + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean) + is + Nam : constant Node_Id := Name (N); + Sel : constant Node_Id := Selector_Name (Nam); + Is_Actual : constant Boolean := Present (Corresponding_Formal_Spec (N)); + Old_S : Entity_Id; + + begin + if Entity (Sel) = Any_Id then + + -- Selector is undefined on prefix. Error emitted already + + Set_Has_Completion (New_S); + return; + end if; + + -- Otherwise find renamed entity and build body of New_S as a call to it + + Old_S := Find_Renamed_Entity (N, Selector_Name (Nam), New_S); + + if Old_S = Any_Id then + Error_Msg_N (" no subprogram or entry matches specification", N); + else + if Is_Body then + Check_Subtype_Conformant (New_S, Old_S, N); + Generate_Reference (New_S, Defining_Entity (N), 'b'); + Style.Check_Identifier (Defining_Entity (N), New_S); + + else + -- Only mode conformance required for a renaming_as_declaration + + Check_Mode_Conformant (New_S, Old_S, N); + end if; + + Inherit_Renamed_Profile (New_S, Old_S); + + -- The prefix can be an arbitrary expression that yields a task or + -- protected object, so it must be resolved. + + Resolve (Prefix (Nam), Scope (Old_S)); + end if; + + Set_Convention (New_S, Convention (Old_S)); + Set_Has_Completion (New_S, Inside_A_Generic); + + -- AI05-0225: If the renamed entity is a procedure or entry of a + -- protected object, the target object must be a variable. + + if Ekind (Scope (Old_S)) in Protected_Kind + and then Ekind (New_S) = E_Procedure + and then not Is_Variable (Prefix (Nam)) + then + if Is_Actual then + Error_Msg_N + ("target object of protected operation used as actual for " + & "formal procedure must be a variable", Nam); + else + Error_Msg_N + ("target object of protected operation renamed as procedure, " + & "must be a variable", Nam); + end if; + end if; + + if Is_Body then + Check_Frozen_Renaming (N, New_S); + end if; + end Analyze_Renamed_Entry; + + ----------------------------------- + -- Analyze_Renamed_Family_Member -- + ----------------------------------- + + procedure Analyze_Renamed_Family_Member + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean) + is + Nam : constant Node_Id := Name (N); + P : constant Node_Id := Prefix (Nam); + Old_S : Entity_Id; + + begin + if (Is_Entity_Name (P) and then Ekind (Entity (P)) = E_Entry_Family) + or else (Nkind (P) = N_Selected_Component + and then + Ekind (Entity (Selector_Name (P))) = E_Entry_Family) + then + if Is_Entity_Name (P) then + Old_S := Entity (P); + else + Old_S := Entity (Selector_Name (P)); + end if; + + if not Entity_Matches_Spec (Old_S, New_S) then + Error_Msg_N ("entry family does not match specification", N); + + elsif Is_Body then + Check_Subtype_Conformant (New_S, Old_S, N); + Generate_Reference (New_S, Defining_Entity (N), 'b'); + Style.Check_Identifier (Defining_Entity (N), New_S); + end if; + + else + Error_Msg_N ("no entry family matches specification", N); + end if; + + Set_Has_Completion (New_S, Inside_A_Generic); + + if Is_Body then + Check_Frozen_Renaming (N, New_S); + end if; + end Analyze_Renamed_Family_Member; + + ----------------------------------------- + -- Analyze_Renamed_Primitive_Operation -- + ----------------------------------------- + + procedure Analyze_Renamed_Primitive_Operation + (N : Node_Id; + New_S : Entity_Id; + Is_Body : Boolean) + is + Old_S : Entity_Id; + + function Conforms + (Subp : Entity_Id; + Ctyp : Conformance_Type) return Boolean; + -- Verify that the signatures of the renamed entity and the new entity + -- match. The first formal of the renamed entity is skipped because it + -- is the target object in any subsequent call. + + -------------- + -- Conforms -- + -------------- + + function Conforms + (Subp : Entity_Id; + Ctyp : Conformance_Type) return Boolean + is + Old_F : Entity_Id; + New_F : Entity_Id; + + begin + if Ekind (Subp) /= Ekind (New_S) then + return False; + end if; + + Old_F := Next_Formal (First_Formal (Subp)); + New_F := First_Formal (New_S); + while Present (Old_F) and then Present (New_F) loop + if not Conforming_Types (Etype (Old_F), Etype (New_F), Ctyp) then + return False; + end if; + + if Ctyp >= Mode_Conformant + and then Ekind (Old_F) /= Ekind (New_F) + then + return False; + end if; + + Next_Formal (New_F); + Next_Formal (Old_F); + end loop; + + return True; + end Conforms; + + -- Start of processing for Analyze_Renamed_Primitive_Operation + + begin + if not Is_Overloaded (Selector_Name (Name (N))) then + Old_S := Entity (Selector_Name (Name (N))); + + if not Conforms (Old_S, Type_Conformant) then + Old_S := Any_Id; + end if; + + else + -- Find the operation that matches the given signature + + declare + It : Interp; + Ind : Interp_Index; + + begin + Old_S := Any_Id; + Get_First_Interp (Selector_Name (Name (N)), Ind, It); + + while Present (It.Nam) loop + if Conforms (It.Nam, Type_Conformant) then + Old_S := It.Nam; + end if; + + Get_Next_Interp (Ind, It); + end loop; + end; + end if; + + if Old_S = Any_Id then + Error_Msg_N (" no subprogram or entry matches specification", N); + + else + if Is_Body then + if not Conforms (Old_S, Subtype_Conformant) then + Error_Msg_N ("subtype conformance error in renaming", N); + end if; + + Generate_Reference (New_S, Defining_Entity (N), 'b'); + Style.Check_Identifier (Defining_Entity (N), New_S); + + else + -- Only mode conformance required for a renaming_as_declaration + + if not Conforms (Old_S, Mode_Conformant) then + Error_Msg_N ("mode conformance error in renaming", N); + end if; + + -- Enforce the rule given in (RM 6.3.1 (10.1/2)): a prefixed + -- view of a subprogram is intrinsic, because the compiler has + -- to generate a wrapper for any call to it. If the name in a + -- subprogram renaming is a prefixed view, the entity is thus + -- intrinsic, and 'Access cannot be applied to it. + + Set_Convention (New_S, Convention_Intrinsic); + end if; + + -- Inherit_Renamed_Profile (New_S, Old_S); + + -- The prefix can be an arbitrary expression that yields an + -- object, so it must be resolved. + + Resolve (Prefix (Name (N))); + end if; + end Analyze_Renamed_Primitive_Operation; + + --------------------------------- + -- Analyze_Subprogram_Renaming -- + --------------------------------- + + procedure Analyze_Subprogram_Renaming (N : Node_Id) is + Formal_Spec : constant Node_Id := Corresponding_Formal_Spec (N); + Is_Actual : constant Boolean := Present (Formal_Spec); + Inst_Node : Node_Id := Empty; + Nam : constant Node_Id := Name (N); + New_S : Entity_Id; + Old_S : Entity_Id := Empty; + Rename_Spec : Entity_Id; + Save_AV : constant Ada_Version_Type := Ada_Version; + Save_AV_Exp : constant Ada_Version_Type := Ada_Version_Explicit; + Spec : constant Node_Id := Specification (N); + + procedure Check_Null_Exclusion + (Ren : Entity_Id; + Sub : Entity_Id); + -- Ada 2005 (AI-423): Given renaming Ren of subprogram Sub, check the + -- following AI rules: + -- + -- If Ren is a renaming of a formal subprogram and one of its + -- parameters has a null exclusion, then the corresponding formal + -- in Sub must also have one. Otherwise the subtype of the Sub's + -- formal parameter must exclude null. + -- + -- If Ren is a renaming of a formal function and its return + -- profile has a null exclusion, then Sub's return profile must + -- have one. Otherwise the subtype of Sub's return profile must + -- exclude null. + + procedure Freeze_Actual_Profile; + -- In Ada 2012, enforce the freezing rule concerning formal incomplete + -- types: a callable entity freezes its profile, unless it has an + -- incomplete untagged formal (RM 13.14(10.2/3)). + + function Original_Subprogram (Subp : Entity_Id) return Entity_Id; + -- Find renamed entity when the declaration is a renaming_as_body and + -- the renamed entity may itself be a renaming_as_body. Used to enforce + -- rule that a renaming_as_body is illegal if the declaration occurs + -- before the subprogram it completes is frozen, and renaming indirectly + -- renames the subprogram itself.(Defect Report 8652/0027). + + function Check_Class_Wide_Actual return Entity_Id; + -- AI05-0071: In an instance, if the actual for a formal type FT with + -- unknown discriminants is a class-wide type CT, and the generic has + -- a formal subprogram with a box for a primitive operation of FT, + -- then the corresponding actual subprogram denoted by the default is a + -- class-wide operation whose body is a dispatching call. We replace the + -- generated renaming declaration: + -- + -- procedure P (X : CT) renames P; + -- + -- by a different renaming and a class-wide operation: + -- + -- procedure Pr (X : T) renames P; -- renames primitive operation + -- procedure P (X : CT); -- class-wide operation + -- ... + -- procedure P (X : CT) is begin Pr (X); end; -- dispatching call + -- + -- This rule only applies if there is no explicit visible class-wide + -- operation at the point of the instantiation. + + function Has_Class_Wide_Actual return Boolean; + -- Ada 2012 (AI05-071, AI05-0131): True if N is the renaming for a + -- defaulted formal subprogram when the actual for the controlling + -- formal type is class-wide. + + ----------------------------- + -- Check_Class_Wide_Actual -- + ----------------------------- + + function Check_Class_Wide_Actual return Entity_Id is + Loc : constant Source_Ptr := Sloc (N); + + F : Entity_Id; + Formal_Type : Entity_Id; + Actual_Type : Entity_Id; + New_Body : Node_Id; + New_Decl : Node_Id; + Result : Entity_Id; + + function Make_Call (Prim_Op : Entity_Id) return Node_Id; + -- Build dispatching call for body of class-wide operation + + function Make_Spec return Node_Id; + -- Create subprogram specification for declaration and body of + -- class-wide operation, using signature of renaming declaration. + + --------------- + -- Make_Call -- + --------------- + + function Make_Call (Prim_Op : Entity_Id) return Node_Id is + Actuals : List_Id; + F : Node_Id; + + begin + Actuals := New_List; + F := First (Parameter_Specifications (Specification (New_Decl))); + while Present (F) loop + Append_To (Actuals, + Make_Identifier (Loc, Chars (Defining_Identifier (F)))); + Next (F); + end loop; + + if Ekind_In (Prim_Op, E_Function, E_Operator) then + return Make_Simple_Return_Statement (Loc, + Expression => + Make_Function_Call (Loc, + Name => New_Occurrence_Of (Prim_Op, Loc), + Parameter_Associations => Actuals)); + else + return + Make_Procedure_Call_Statement (Loc, + Name => New_Occurrence_Of (Prim_Op, Loc), + Parameter_Associations => Actuals); + end if; + end Make_Call; + + --------------- + -- Make_Spec -- + --------------- + + function Make_Spec return Node_Id is + Param_Specs : constant List_Id := Copy_Parameter_List (New_S); + + begin + if Ekind (New_S) = E_Procedure then + return + Make_Procedure_Specification (Loc, + Defining_Unit_Name => + Make_Defining_Identifier (Loc, + Chars (Defining_Unit_Name (Spec))), + Parameter_Specifications => Param_Specs); + else + return + Make_Function_Specification (Loc, + Defining_Unit_Name => + Make_Defining_Identifier (Loc, + Chars (Defining_Unit_Name (Spec))), + Parameter_Specifications => Param_Specs, + Result_Definition => + New_Copy_Tree (Result_Definition (Spec))); + end if; + end Make_Spec; + + -- Start of processing for Check_Class_Wide_Actual + + begin + Result := Any_Id; + Formal_Type := Empty; + Actual_Type := Empty; + + F := First_Formal (Formal_Spec); + while Present (F) loop + if Has_Unknown_Discriminants (Etype (F)) + and then not Is_Class_Wide_Type (Etype (F)) + and then Is_Class_Wide_Type (Get_Instance_Of (Etype (F))) + then + Formal_Type := Etype (F); + Actual_Type := Etype (Get_Instance_Of (Formal_Type)); + exit; + end if; + + Next_Formal (F); + end loop; + + if Present (Formal_Type) then + + -- Create declaration and body for class-wide operation + + New_Decl := + Make_Subprogram_Declaration (Loc, Specification => Make_Spec); + + New_Body := + Make_Subprogram_Body (Loc, + Specification => Make_Spec, + Declarations => No_List, + Handled_Statement_Sequence => + Make_Handled_Sequence_Of_Statements (Loc, New_List)); + + -- Modify Spec and create internal name for renaming of primitive + -- operation. + + Set_Defining_Unit_Name (Spec, Make_Temporary (Loc, 'R')); + F := First (Parameter_Specifications (Spec)); + while Present (F) loop + if Nkind (Parameter_Type (F)) = N_Identifier + and then Is_Class_Wide_Type (Entity (Parameter_Type (F))) + then + Set_Parameter_Type (F, New_Occurrence_Of (Actual_Type, Loc)); + end if; + Next (F); + end loop; + + New_S := Analyze_Subprogram_Specification (Spec); + Result := Find_Renamed_Entity (N, Name (N), New_S, Is_Actual); + end if; + + if Result /= Any_Id then + Insert_Before (N, New_Decl); + Analyze (New_Decl); + + -- Add dispatching call to body of class-wide operation + + Append (Make_Call (Result), + Statements (Handled_Statement_Sequence (New_Body))); + + -- The generated body does not freeze. It is analyzed when the + -- generated operation is frozen. This body is only needed if + -- expansion is enabled. + + if Expander_Active then + Append_Freeze_Action (Defining_Entity (New_Decl), New_Body); + end if; + + Result := Defining_Entity (New_Decl); + end if; + + -- Return the class-wide operation if one was created + + return Result; + end Check_Class_Wide_Actual; + + -------------------------- + -- Check_Null_Exclusion -- + -------------------------- + + procedure Check_Null_Exclusion + (Ren : Entity_Id; + Sub : Entity_Id) + is + Ren_Formal : Entity_Id; + Sub_Formal : Entity_Id; + + begin + -- Parameter check + + Ren_Formal := First_Formal (Ren); + Sub_Formal := First_Formal (Sub); + while Present (Ren_Formal) + and then Present (Sub_Formal) + loop + if Has_Null_Exclusion (Parent (Ren_Formal)) + and then + not (Has_Null_Exclusion (Parent (Sub_Formal)) + or else Can_Never_Be_Null (Etype (Sub_Formal))) + then + Error_Msg_NE + ("`NOT NULL` required for parameter &", + Parent (Sub_Formal), Sub_Formal); + end if; + + Next_Formal (Ren_Formal); + Next_Formal (Sub_Formal); + end loop; + + -- Return profile check + + if Nkind (Parent (Ren)) = N_Function_Specification + and then Nkind (Parent (Sub)) = N_Function_Specification + and then Has_Null_Exclusion (Parent (Ren)) + and then + not (Has_Null_Exclusion (Parent (Sub)) + or else Can_Never_Be_Null (Etype (Sub))) + then + Error_Msg_N + ("return must specify `NOT NULL`", + Result_Definition (Parent (Sub))); + end if; + end Check_Null_Exclusion; + + --------------------------- + -- Freeze_Actual_Profile -- + --------------------------- + + procedure Freeze_Actual_Profile is + F : Entity_Id; + Has_Untagged_Inc : Boolean; + Instantiation_Node : constant Node_Id := Parent (N); + + begin + if Ada_Version >= Ada_2012 then + F := First_Formal (Formal_Spec); + Has_Untagged_Inc := False; + while Present (F) loop + if Ekind (Etype (F)) = E_Incomplete_Type + and then not Is_Tagged_Type (Etype (F)) + then + Has_Untagged_Inc := True; + exit; + end if; + + F := Next_Formal (F); + end loop; + + if Ekind (Formal_Spec) = E_Function + and then Ekind (Etype (Formal_Spec)) = E_Incomplete_Type + and then not Is_Tagged_Type (Etype (F)) + then + Has_Untagged_Inc := True; + end if; + + if not Has_Untagged_Inc then + F := First_Formal (Old_S); + while Present (F) loop + Freeze_Before (Instantiation_Node, Etype (F)); + + if Is_Incomplete_Or_Private_Type (Etype (F)) + and then No (Underlying_Type (Etype (F))) + and then not Is_Generic_Type (Etype (F)) + then + Error_Msg_NE + ("type& must be frozen before this point", + Instantiation_Node, Etype (F)); + end if; + + F := Next_Formal (F); + end loop; + end if; + end if; + end Freeze_Actual_Profile; + + --------------------------- + -- Has_Class_Wide_Actual -- + --------------------------- + + function Has_Class_Wide_Actual return Boolean is + F_Nam : Entity_Id; + F_Spec : Entity_Id; + + begin + if Is_Actual + and then Nkind (Nam) in N_Has_Entity + and then Present (Entity (Nam)) + and then Is_Dispatching_Operation (Entity (Nam)) + then + F_Nam := First_Entity (Entity (Nam)); + F_Spec := First_Formal (Formal_Spec); + while Present (F_Nam) + and then Present (F_Spec) + loop + if Is_Controlling_Formal (F_Nam) + and then Has_Unknown_Discriminants (Etype (F_Spec)) + and then not Is_Class_Wide_Type (Etype (F_Spec)) + and then Is_Class_Wide_Type (Get_Instance_Of (Etype (F_Spec))) + then + return True; + end if; + + Next_Entity (F_Nam); + Next_Formal (F_Spec); + end loop; + end if; + + return False; + end Has_Class_Wide_Actual; + + ------------------------- + -- Original_Subprogram -- + ------------------------- + + function Original_Subprogram (Subp : Entity_Id) return Entity_Id is + Orig_Decl : Node_Id; + Orig_Subp : Entity_Id; + + begin + -- First case: renamed entity is itself a renaming + + if Present (Alias (Subp)) then + return Alias (Subp); + + elsif + Nkind (Unit_Declaration_Node (Subp)) = N_Subprogram_Declaration + and then Present + (Corresponding_Body (Unit_Declaration_Node (Subp))) + then + -- Check if renamed entity is a renaming_as_body + + Orig_Decl := + Unit_Declaration_Node + (Corresponding_Body (Unit_Declaration_Node (Subp))); + + if Nkind (Orig_Decl) = N_Subprogram_Renaming_Declaration then + Orig_Subp := Entity (Name (Orig_Decl)); + + if Orig_Subp = Rename_Spec then + + -- Circularity detected + + return Orig_Subp; + + else + return (Original_Subprogram (Orig_Subp)); + end if; + else + return Subp; + end if; + else + return Subp; + end if; + end Original_Subprogram; + + CW_Actual : constant Boolean := Has_Class_Wide_Actual; + -- Ada 2012 (AI05-071, AI05-0131): True if the renaming is for a + -- defaulted formal subprogram when the actual for a related formal + -- type is class-wide. + + -- Start of processing for Analyze_Subprogram_Renaming + + begin + -- We must test for the attribute renaming case before the Analyze + -- call because otherwise Sem_Attr will complain that the attribute + -- is missing an argument when it is analyzed. + + if Nkind (Nam) = N_Attribute_Reference then + + -- In the case of an abstract formal subprogram association, rewrite + -- an actual given by a stream attribute as the name of the + -- corresponding stream primitive of the type. + + -- In a generic context the stream operations are not generated, and + -- this must be treated as a normal attribute reference, to be + -- expanded in subsequent instantiations. + + if Is_Actual and then Is_Abstract_Subprogram (Formal_Spec) + and then Full_Expander_Active + then + declare + Stream_Prim : Entity_Id; + Prefix_Type : constant Entity_Id := Entity (Prefix (Nam)); + + begin + -- The class-wide forms of the stream attributes are not + -- primitive dispatching operations (even though they + -- internally dispatch to a stream attribute). + + if Is_Class_Wide_Type (Prefix_Type) then + Error_Msg_N + ("attribute must be a primitive dispatching operation", + Nam); + return; + end if; + + -- Retrieve the primitive subprogram associated with the + -- attribute. This can only be a stream attribute, since those + -- are the only ones that are dispatching (and the actual for + -- an abstract formal subprogram must be dispatching + -- operation). + + begin + case Attribute_Name (Nam) is + when Name_Input => + Stream_Prim := + Find_Prim_Op (Prefix_Type, TSS_Stream_Input); + when Name_Output => + Stream_Prim := + Find_Prim_Op (Prefix_Type, TSS_Stream_Output); + when Name_Read => + Stream_Prim := + Find_Prim_Op (Prefix_Type, TSS_Stream_Read); + when Name_Write => + Stream_Prim := + Find_Prim_Op (Prefix_Type, TSS_Stream_Write); + when others => + Error_Msg_N + ("attribute must be a primitive" + & " dispatching operation", Nam); + return; + end case; + + exception + + -- If no operation was found, and the type is limited, + -- the user should have defined one. + + when Program_Error => + if Is_Limited_Type (Prefix_Type) then + Error_Msg_NE + ("stream operation not defined for type&", + N, Prefix_Type); + return; + + -- Otherwise, compiler should have generated default + + else + raise; + end if; + end; + + -- Rewrite the attribute into the name of its corresponding + -- primitive dispatching subprogram. We can then proceed with + -- the usual processing for subprogram renamings. + + declare + Prim_Name : constant Node_Id := + Make_Identifier (Sloc (Nam), + Chars => Chars (Stream_Prim)); + begin + Set_Entity (Prim_Name, Stream_Prim); + Rewrite (Nam, Prim_Name); + Analyze (Nam); + end; + end; + + -- Normal processing for a renaming of an attribute + + else + Attribute_Renaming (N); + return; + end if; + end if; + + -- Check whether this declaration corresponds to the instantiation + -- of a formal subprogram. + + -- If this is an instantiation, the corresponding actual is frozen and + -- error messages can be made more precise. If this is a default + -- subprogram, the entity is already established in the generic, and is + -- not retrieved by visibility. If it is a default with a box, the + -- candidate interpretations, if any, have been collected when building + -- the renaming declaration. If overloaded, the proper interpretation is + -- determined in Find_Renamed_Entity. If the entity is an operator, + -- Find_Renamed_Entity applies additional visibility checks. + + if Is_Actual then + Inst_Node := Unit_Declaration_Node (Formal_Spec); + + -- Check whether the renaming is for a defaulted actual subprogram + -- with a class-wide actual. + + if CW_Actual then + New_S := Analyze_Subprogram_Specification (Spec); + Old_S := Check_Class_Wide_Actual; + + elsif Is_Entity_Name (Nam) + and then Present (Entity (Nam)) + and then not Comes_From_Source (Nam) + and then not Is_Overloaded (Nam) + then + Old_S := Entity (Nam); + New_S := Analyze_Subprogram_Specification (Spec); + + -- Operator case + + if Ekind (Entity (Nam)) = E_Operator then + + -- Box present + + if Box_Present (Inst_Node) then + Old_S := Find_Renamed_Entity (N, Name (N), New_S, Is_Actual); + + -- If there is an immediately visible homonym of the operator + -- and the declaration has a default, this is worth a warning + -- because the user probably did not intend to get the pre- + -- defined operator, visible in the generic declaration. To + -- find if there is an intended candidate, analyze the renaming + -- again in the current context. + + elsif Scope (Old_S) = Standard_Standard + and then Present (Default_Name (Inst_Node)) + then + declare + Decl : constant Node_Id := New_Copy_Tree (N); + Hidden : Entity_Id; + + begin + Set_Entity (Name (Decl), Empty); + Analyze (Name (Decl)); + Hidden := + Find_Renamed_Entity (Decl, Name (Decl), New_S, True); + + if Present (Hidden) + and then In_Open_Scopes (Scope (Hidden)) + and then Is_Immediately_Visible (Hidden) + and then Comes_From_Source (Hidden) + and then Hidden /= Old_S + then + Error_Msg_Sloc := Sloc (Hidden); + Error_Msg_N ("default subprogram is resolved " & + "in the generic declaration " & + "(RM 12.6(17))??", N); + Error_Msg_NE ("\and will not use & #??", N, Hidden); + end if; + end; + end if; + end if; + + else + Analyze (Nam); + New_S := Analyze_Subprogram_Specification (Spec); + end if; + + else + -- Renamed entity must be analyzed first, to avoid being hidden by + -- new name (which might be the same in a generic instance). + + Analyze (Nam); + + -- The renaming defines a new overloaded entity, which is analyzed + -- like a subprogram declaration. + + New_S := Analyze_Subprogram_Specification (Spec); + end if; + + if Current_Scope /= Standard_Standard then + Set_Is_Pure (New_S, Is_Pure (Current_Scope)); + end if; + + Rename_Spec := Find_Corresponding_Spec (N); + + -- Case of Renaming_As_Body + + if Present (Rename_Spec) then + + -- Renaming declaration is the completion of the declaration of + -- Rename_Spec. We build an actual body for it at the freezing point. + + Set_Corresponding_Spec (N, Rename_Spec); + + -- Deal with special case of stream functions of abstract types + -- and interfaces. + + if Nkind (Unit_Declaration_Node (Rename_Spec)) = + N_Abstract_Subprogram_Declaration + then + -- Input stream functions are abstract if the object type is + -- abstract. Similarly, all default stream functions for an + -- interface type are abstract. However, these subprograms may + -- receive explicit declarations in representation clauses, making + -- the attribute subprograms usable as defaults in subsequent + -- type extensions. + -- In this case we rewrite the declaration to make the subprogram + -- non-abstract. We remove the previous declaration, and insert + -- the new one at the point of the renaming, to prevent premature + -- access to unfrozen types. The new declaration reuses the + -- specification of the previous one, and must not be analyzed. + + pragma Assert + (Is_Primitive (Entity (Nam)) + and then + Is_Abstract_Type (Find_Dispatching_Type (Entity (Nam)))); + declare + Old_Decl : constant Node_Id := + Unit_Declaration_Node (Rename_Spec); + New_Decl : constant Node_Id := + Make_Subprogram_Declaration (Sloc (N), + Specification => + Relocate_Node (Specification (Old_Decl))); + begin + Remove (Old_Decl); + Insert_After (N, New_Decl); + Set_Is_Abstract_Subprogram (Rename_Spec, False); + Set_Analyzed (New_Decl); + end; + end if; + + Set_Corresponding_Body (Unit_Declaration_Node (Rename_Spec), New_S); + + if Ada_Version = Ada_83 and then Comes_From_Source (N) then + Error_Msg_N ("(Ada 83) renaming cannot serve as a body", N); + end if; + + Set_Convention (New_S, Convention (Rename_Spec)); + Check_Fully_Conformant (New_S, Rename_Spec); + Set_Public_Status (New_S); + + -- The specification does not introduce new formals, but only + -- repeats the formals of the original subprogram declaration. + -- For cross-reference purposes, and for refactoring tools, we + -- treat the formals of the renaming declaration as body formals. + + Reference_Body_Formals (Rename_Spec, New_S); + + -- Indicate that the entity in the declaration functions like the + -- corresponding body, and is not a new entity. The body will be + -- constructed later at the freeze point, so indicate that the + -- completion has not been seen yet. + + Set_Ekind (New_S, E_Subprogram_Body); + New_S := Rename_Spec; + Set_Has_Completion (Rename_Spec, False); + + -- Ada 2005: check overriding indicator + + if Present (Overridden_Operation (Rename_Spec)) then + if Must_Not_Override (Specification (N)) then + Error_Msg_NE + ("subprogram& overrides inherited operation", + N, Rename_Spec); + elsif + Style_Check and then not Must_Override (Specification (N)) + then + Style.Missing_Overriding (N, Rename_Spec); + end if; + + elsif Must_Override (Specification (N)) then + Error_Msg_NE ("subprogram& is not overriding", N, Rename_Spec); + end if; + + -- Normal subprogram renaming (not renaming as body) + + else + Generate_Definition (New_S); + New_Overloaded_Entity (New_S); + + if Is_Entity_Name (Nam) + and then Is_Intrinsic_Subprogram (Entity (Nam)) + then + null; + else + Check_Delayed_Subprogram (New_S); + end if; + end if; + + -- There is no need for elaboration checks on the new entity, which may + -- be called before the next freezing point where the body will appear. + -- Elaboration checks refer to the real entity, not the one created by + -- the renaming declaration. + + Set_Kill_Elaboration_Checks (New_S, True); + + if Etype (Nam) = Any_Type then + Set_Has_Completion (New_S); + return; + + elsif Nkind (Nam) = N_Selected_Component then + + -- A prefix of the form A.B can designate an entry of task A, a + -- protected operation of protected object A, or finally a primitive + -- operation of object A. In the later case, A is an object of some + -- tagged type, or an access type that denotes one such. To further + -- distinguish these cases, note that the scope of a task entry or + -- protected operation is type of the prefix. + + -- The prefix could be an overloaded function call that returns both + -- kinds of operations. This overloading pathology is left to the + -- dedicated reader ??? + + declare + T : constant Entity_Id := Etype (Prefix (Nam)); + + begin + if Present (T) + and then + (Is_Tagged_Type (T) + or else + (Is_Access_Type (T) + and then + Is_Tagged_Type (Designated_Type (T)))) + and then Scope (Entity (Selector_Name (Nam))) /= T + then + Analyze_Renamed_Primitive_Operation + (N, New_S, Present (Rename_Spec)); + return; + + else + -- Renamed entity is an entry or protected operation. For those + -- cases an explicit body is built (at the point of freezing of + -- this entity) that contains a call to the renamed entity. + + -- This is not allowed for renaming as body if the renamed + -- spec is already frozen (see RM 8.5.4(5) for details). + + if Present (Rename_Spec) + and then Is_Frozen (Rename_Spec) + then + Error_Msg_N + ("renaming-as-body cannot rename entry as subprogram", N); + Error_Msg_NE + ("\since & is already frozen (RM 8.5.4(5))", + N, Rename_Spec); + else + Analyze_Renamed_Entry (N, New_S, Present (Rename_Spec)); + end if; + + return; + end if; + end; + + elsif Nkind (Nam) = N_Explicit_Dereference then + + -- Renamed entity is designated by access_to_subprogram expression. + -- Must build body to encapsulate call, as in the entry case. + + Analyze_Renamed_Dereference (N, New_S, Present (Rename_Spec)); + return; + + elsif Nkind (Nam) = N_Indexed_Component then + Analyze_Renamed_Family_Member (N, New_S, Present (Rename_Spec)); + return; + + elsif Nkind (Nam) = N_Character_Literal then + Analyze_Renamed_Character (N, New_S, Present (Rename_Spec)); + return; + + elsif not Is_Entity_Name (Nam) + or else not Is_Overloadable (Entity (Nam)) + then + -- Do not mention the renaming if it comes from an instance + + if not Is_Actual then + Error_Msg_N ("expect valid subprogram name in renaming", N); + else + Error_Msg_NE ("no visible subprogram for formal&", N, Nam); + end if; + + return; + end if; + + -- Find the renamed entity that matches the given specification. Disable + -- Ada_83 because there is no requirement of full conformance between + -- renamed entity and new entity, even though the same circuit is used. + + -- This is a bit of a kludge, which introduces a really irregular use of + -- Ada_Version[_Explicit]. Would be nice to find cleaner way to do this + -- ??? + + Ada_Version := Ada_Version_Type'Max (Ada_Version, Ada_95); + Ada_Version_Explicit := Ada_Version; + + if No (Old_S) then + Old_S := Find_Renamed_Entity (N, Name (N), New_S, Is_Actual); + + -- The visible operation may be an inherited abstract operation that + -- was overridden in the private part, in which case a call will + -- dispatch to the overriding operation. Use the overriding one in + -- the renaming declaration, to prevent spurious errors below. + + if Is_Overloadable (Old_S) + and then Is_Abstract_Subprogram (Old_S) + and then No (DTC_Entity (Old_S)) + and then Present (Alias (Old_S)) + and then not Is_Abstract_Subprogram (Alias (Old_S)) + and then Present (Overridden_Operation (Alias (Old_S))) + then + Old_S := Alias (Old_S); + end if; + + -- When the renamed subprogram is overloaded and used as an actual + -- of a generic, its entity is set to the first available homonym. + -- We must first disambiguate the name, then set the proper entity. + + if Is_Actual and then Is_Overloaded (Nam) then + Set_Entity (Nam, Old_S); + end if; + end if; + + -- Most common case: subprogram renames subprogram. No body is generated + -- in this case, so we must indicate the declaration is complete as is. + -- and inherit various attributes of the renamed subprogram. + + if No (Rename_Spec) then + Set_Has_Completion (New_S); + Set_Is_Imported (New_S, Is_Imported (Entity (Nam))); + Set_Is_Pure (New_S, Is_Pure (Entity (Nam))); + Set_Is_Preelaborated (New_S, Is_Preelaborated (Entity (Nam))); + + -- Ada 2005 (AI-423): Check the consistency of null exclusions + -- between a subprogram and its correct renaming. + + -- Note: the Any_Id check is a guard that prevents compiler crashes + -- when performing a null exclusion check between a renaming and a + -- renamed subprogram that has been found to be illegal. + + if Ada_Version >= Ada_2005 + and then Entity (Nam) /= Any_Id + then + Check_Null_Exclusion + (Ren => New_S, + Sub => Entity (Nam)); + end if; + + -- Enforce the Ada 2005 rule that the renamed entity cannot require + -- overriding. The flag Requires_Overriding is set very selectively + -- and misses some other illegal cases. The additional conditions + -- checked below are sufficient but not necessary ??? + + -- The rule does not apply to the renaming generated for an actual + -- subprogram in an instance. + + if Is_Actual then + null; + + -- Guard against previous errors, and omit renamings of predefined + -- operators. + + elsif not Ekind_In (Old_S, E_Function, E_Procedure) then + null; + + elsif Requires_Overriding (Old_S) + or else + (Is_Abstract_Subprogram (Old_S) + and then Present (Find_Dispatching_Type (Old_S)) + and then + not Is_Abstract_Type (Find_Dispatching_Type (Old_S))) + then + Error_Msg_N + ("renamed entity cannot be " + & "subprogram that requires overriding (RM 8.5.4 (5.1))", N); + end if; + end if; + + if Old_S /= Any_Id then + if Is_Actual and then From_Default (N) then + + -- This is an implicit reference to the default actual + + Generate_Reference (Old_S, Nam, Typ => 'i', Force => True); + + else + Generate_Reference (Old_S, Nam); + end if; + + Check_Internal_Protected_Use (N, Old_S); + + -- For a renaming-as-body, require subtype conformance, but if the + -- declaration being completed has not been frozen, then inherit the + -- convention of the renamed subprogram prior to checking conformance + -- (unless the renaming has an explicit convention established; the + -- rule stated in the RM doesn't seem to address this ???). + + if Present (Rename_Spec) then + Generate_Reference (Rename_Spec, Defining_Entity (Spec), 'b'); + Style.Check_Identifier (Defining_Entity (Spec), Rename_Spec); + + if not Is_Frozen (Rename_Spec) then + if not Has_Convention_Pragma (Rename_Spec) then + Set_Convention (New_S, Convention (Old_S)); + end if; + + if Ekind (Old_S) /= E_Operator then + Check_Mode_Conformant (New_S, Old_S, Spec); + end if; + + if Original_Subprogram (Old_S) = Rename_Spec then + Error_Msg_N ("unfrozen subprogram cannot rename itself ", N); + end if; + else + Check_Subtype_Conformant (New_S, Old_S, Spec); + end if; + + Check_Frozen_Renaming (N, Rename_Spec); + + -- Check explicitly that renamed entity is not intrinsic, because + -- in a generic the renamed body is not built. In this case, + -- the renaming_as_body is a completion. + + if Inside_A_Generic then + if Is_Frozen (Rename_Spec) + and then Is_Intrinsic_Subprogram (Old_S) + then + Error_Msg_N + ("subprogram in renaming_as_body cannot be intrinsic", + Name (N)); + end if; + + Set_Has_Completion (Rename_Spec); + end if; + + elsif Ekind (Old_S) /= E_Operator then + + -- If this a defaulted subprogram for a class-wide actual there is + -- no check for mode conformance, given that the signatures don't + -- match (the source mentions T but the actual mentions T'Class). + + if CW_Actual then + null; + else + Check_Mode_Conformant (New_S, Old_S); + end if; + + if Is_Actual + and then Error_Posted (New_S) + then + Error_Msg_NE ("invalid actual subprogram: & #!", N, Old_S); + end if; + end if; + + if No (Rename_Spec) then + + -- The parameter profile of the new entity is that of the renamed + -- entity: the subtypes given in the specification are irrelevant. + + Inherit_Renamed_Profile (New_S, Old_S); + + -- A call to the subprogram is transformed into a call to the + -- renamed entity. This is transitive if the renamed entity is + -- itself a renaming. + + if Present (Alias (Old_S)) then + Set_Alias (New_S, Alias (Old_S)); + else + Set_Alias (New_S, Old_S); + end if; + + -- Note that we do not set Is_Intrinsic_Subprogram if we have a + -- renaming as body, since the entity in this case is not an + -- intrinsic (it calls an intrinsic, but we have a real body for + -- this call, and it is in this body that the required intrinsic + -- processing will take place). + + -- Also, if this is a renaming of inequality, the renamed operator + -- is intrinsic, but what matters is the corresponding equality + -- operator, which may be user-defined. + + Set_Is_Intrinsic_Subprogram + (New_S, + Is_Intrinsic_Subprogram (Old_S) + and then + (Chars (Old_S) /= Name_Op_Ne + or else Ekind (Old_S) = E_Operator + or else + Is_Intrinsic_Subprogram + (Corresponding_Equality (Old_S)))); + + if Ekind (Alias (New_S)) = E_Operator then + Set_Has_Delayed_Freeze (New_S, False); + end if; + + -- If the renaming corresponds to an association for an abstract + -- formal subprogram, then various attributes must be set to + -- indicate that the renaming is an abstract dispatching operation + -- with a controlling type. + + if Is_Actual and then Is_Abstract_Subprogram (Formal_Spec) then + + -- Mark the renaming as abstract here, so Find_Dispatching_Type + -- see it as corresponding to a generic association for a + -- formal abstract subprogram + + Set_Is_Abstract_Subprogram (New_S); + + declare + New_S_Ctrl_Type : constant Entity_Id := + Find_Dispatching_Type (New_S); + Old_S_Ctrl_Type : constant Entity_Id := + Find_Dispatching_Type (Old_S); + + begin + if Old_S_Ctrl_Type /= New_S_Ctrl_Type then + Error_Msg_NE + ("actual must be dispatching subprogram for type&", + Nam, New_S_Ctrl_Type); + + else + Set_Is_Dispatching_Operation (New_S); + Check_Controlling_Formals (New_S_Ctrl_Type, New_S); + + -- If the actual in the formal subprogram is itself a + -- formal abstract subprogram association, there's no + -- dispatch table component or position to inherit. + + if Present (DTC_Entity (Old_S)) then + Set_DTC_Entity (New_S, DTC_Entity (Old_S)); + Set_DT_Position (New_S, DT_Position (Old_S)); + end if; + end if; + end; + end if; + end if; + + if Is_Actual then + null; + + -- The following is illegal, because F hides whatever other F may + -- be around: + -- function F (..) renames F; + + elsif Old_S = New_S + or else (Nkind (Nam) /= N_Expanded_Name + and then Chars (Old_S) = Chars (New_S)) + then + Error_Msg_N ("subprogram cannot rename itself", N); + + elsif Nkind (Nam) = N_Expanded_Name + and then Entity (Prefix (Nam)) = Current_Scope + and then Chars (Selector_Name (Nam)) = Chars (New_S) + then + if Overriding_Renamings then + null; + + else + Error_Msg_NE + ("implicit operation& is not visible (RM 8.3 (15))", + Nam, Old_S); + end if; + end if; + + Set_Convention (New_S, Convention (Old_S)); + + if Is_Abstract_Subprogram (Old_S) then + if Present (Rename_Spec) then + Error_Msg_N + ("a renaming-as-body cannot rename an abstract subprogram", + N); + Set_Has_Completion (Rename_Spec); + else + Set_Is_Abstract_Subprogram (New_S); + end if; + end if; + + Check_Library_Unit_Renaming (N, Old_S); + + -- Pathological case: procedure renames entry in the scope of its + -- task. Entry is given by simple name, but body must be built for + -- procedure. Of course if called it will deadlock. + + if Ekind (Old_S) = E_Entry then + Set_Has_Completion (New_S, False); + Set_Alias (New_S, Empty); + end if; + + if Is_Actual then + Freeze_Before (N, Old_S); + Freeze_Actual_Profile; + Set_Has_Delayed_Freeze (New_S, False); + Freeze_Before (N, New_S); + + -- An abstract subprogram is only allowed as an actual in the case + -- where the formal subprogram is also abstract. + + if (Ekind (Old_S) = E_Procedure or else Ekind (Old_S) = E_Function) + and then Is_Abstract_Subprogram (Old_S) + and then not Is_Abstract_Subprogram (Formal_Spec) + then + Error_Msg_N + ("abstract subprogram not allowed as generic actual", Nam); + end if; + end if; + + else + -- A common error is to assume that implicit operators for types are + -- defined in Standard, or in the scope of a subtype. In those cases + -- where the renamed entity is given with an expanded name, it is + -- worth mentioning that operators for the type are not declared in + -- the scope given by the prefix. + + if Nkind (Nam) = N_Expanded_Name + and then Nkind (Selector_Name (Nam)) = N_Operator_Symbol + and then Scope (Entity (Nam)) = Standard_Standard + then + declare + T : constant Entity_Id := + Base_Type (Etype (First_Formal (New_S))); + begin + Error_Msg_Node_2 := Prefix (Nam); + Error_Msg_NE + ("operator for type& is not declared in&", Prefix (Nam), T); + end; + + else + Error_Msg_NE + ("no visible subprogram matches the specification for&", + Spec, New_S); + end if; + + if Present (Candidate_Renaming) then + declare + F1 : Entity_Id; + F2 : Entity_Id; + T1 : Entity_Id; + + begin + F1 := First_Formal (Candidate_Renaming); + F2 := First_Formal (New_S); + T1 := First_Subtype (Etype (F1)); + + while Present (F1) and then Present (F2) loop + Next_Formal (F1); + Next_Formal (F2); + end loop; + + if Present (F1) and then Present (Default_Value (F1)) then + if Present (Next_Formal (F1)) then + Error_Msg_NE + ("\missing specification for &" & + " and other formals with defaults", Spec, F1); + else + Error_Msg_NE + ("\missing specification for &", Spec, F1); + end if; + end if; + + if Nkind (Nam) = N_Operator_Symbol + and then From_Default (N) + then + Error_Msg_Node_2 := T1; + Error_Msg_NE + ("default & on & is not directly visible", + Nam, Nam); + end if; + end; + end if; + end if; + + -- Ada 2005 AI 404: if the new subprogram is dispatching, verify that + -- controlling access parameters are known non-null for the renamed + -- subprogram. Test also applies to a subprogram instantiation that + -- is dispatching. Test is skipped if some previous error was detected + -- that set Old_S to Any_Id. + + if Ada_Version >= Ada_2005 + and then Old_S /= Any_Id + and then not Is_Dispatching_Operation (Old_S) + and then Is_Dispatching_Operation (New_S) + then + declare + Old_F : Entity_Id; + New_F : Entity_Id; + + begin + Old_F := First_Formal (Old_S); + New_F := First_Formal (New_S); + while Present (Old_F) loop + if Ekind (Etype (Old_F)) = E_Anonymous_Access_Type + and then Is_Controlling_Formal (New_F) + and then not Can_Never_Be_Null (Old_F) + then + Error_Msg_N ("access parameter is controlling,", New_F); + Error_Msg_NE + ("\corresponding parameter of& " + & "must be explicitly null excluding", New_F, Old_S); + end if; + + Next_Formal (Old_F); + Next_Formal (New_F); + end loop; + end; + end if; + + -- A useful warning, suggested by Ada Bug Finder (Ada-Europe 2005) + -- is to warn if an operator is being renamed as a different operator. + -- If the operator is predefined, examine the kind of the entity, not + -- the abbreviated declaration in Standard. + + if Comes_From_Source (N) + and then Present (Old_S) + and then + (Nkind (Old_S) = N_Defining_Operator_Symbol + or else Ekind (Old_S) = E_Operator) + and then Nkind (New_S) = N_Defining_Operator_Symbol + and then Chars (Old_S) /= Chars (New_S) + then + Error_Msg_NE + ("& is being renamed as a different operator??", N, Old_S); + end if; + + -- Check for renaming of obsolescent subprogram + + Check_Obsolescent_2005_Entity (Entity (Nam), Nam); + + -- Another warning or some utility: if the new subprogram as the same + -- name as the old one, the old one is not hidden by an outer homograph, + -- the new one is not a public symbol, and the old one is otherwise + -- directly visible, the renaming is superfluous. + + if Chars (Old_S) = Chars (New_S) + and then Comes_From_Source (N) + and then Scope (Old_S) /= Standard_Standard + and then Warn_On_Redundant_Constructs + and then + (Is_Immediately_Visible (Old_S) + or else Is_Potentially_Use_Visible (Old_S)) + and then Is_Overloadable (Current_Scope) + and then Chars (Current_Scope) /= Chars (Old_S) + then + Error_Msg_N + ("redundant renaming, entity is directly visible?r?", Name (N)); + end if; + + -- Implementation-defined aspect specifications can appear in a renaming + -- declaration, but not language-defined ones. The call to procedure + -- Analyze_Aspect_Specifications will take care of this error check. + + if Has_Aspects (N) then + Analyze_Aspect_Specifications (N, New_S); + end if; + + Ada_Version := Save_AV; + Ada_Version_Explicit := Save_AV_Exp; + end Analyze_Subprogram_Renaming; + + ------------------------- + -- Analyze_Use_Package -- + ------------------------- + + -- Resolve the package names in the use clause, and make all the visible + -- entities defined in the package potentially use-visible. If the package + -- is already in use from a previous use clause, its visible entities are + -- already use-visible. In that case, mark the occurrence as a redundant + -- use. If the package is an open scope, i.e. if the use clause occurs + -- within the package itself, ignore it. + + procedure Analyze_Use_Package (N : Node_Id) is + Pack_Name : Node_Id; + Pack : Entity_Id; + + -- Start of processing for Analyze_Use_Package + + begin + Check_SPARK_Restriction ("use clause is not allowed", N); + + Set_Hidden_By_Use_Clause (N, No_Elist); + + -- Use clause not allowed in a spec of a predefined package declaration + -- except that packages whose file name starts a-n are OK (these are + -- children of Ada.Numerics, which are never loaded by Rtsfind). + + if Is_Predefined_File_Name (Unit_File_Name (Current_Sem_Unit)) + and then Name_Buffer (1 .. 3) /= "a-n" + and then + Nkind (Unit (Cunit (Current_Sem_Unit))) = N_Package_Declaration + then + Error_Msg_N ("use clause not allowed in predefined spec", N); + end if; + + -- Chain clause to list of use clauses in current scope + + if Nkind (Parent (N)) /= N_Compilation_Unit then + Chain_Use_Clause (N); + end if; + + -- Loop through package names to identify referenced packages + + Pack_Name := First (Names (N)); + while Present (Pack_Name) loop + Analyze (Pack_Name); + + if Nkind (Parent (N)) = N_Compilation_Unit + and then Nkind (Pack_Name) = N_Expanded_Name + then + declare + Pref : Node_Id; + + begin + Pref := Prefix (Pack_Name); + while Nkind (Pref) = N_Expanded_Name loop + Pref := Prefix (Pref); + end loop; + + if Entity (Pref) = Standard_Standard then + Error_Msg_N + ("predefined package Standard cannot appear" + & " in a context clause", Pref); + end if; + end; + end if; + + Next (Pack_Name); + end loop; + + -- Loop through package names to mark all entities as potentially + -- use visible. + + Pack_Name := First (Names (N)); + while Present (Pack_Name) loop + if Is_Entity_Name (Pack_Name) then + Pack := Entity (Pack_Name); + + if Ekind (Pack) /= E_Package + and then Etype (Pack) /= Any_Type + then + if Ekind (Pack) = E_Generic_Package then + Error_Msg_N -- CODEFIX + ("a generic package is not allowed in a use clause", + Pack_Name); + else + Error_Msg_N ("& is not a usable package", Pack_Name); + end if; + + else + if Nkind (Parent (N)) = N_Compilation_Unit then + Check_In_Previous_With_Clause (N, Pack_Name); + end if; + + if Applicable_Use (Pack_Name) then + Use_One_Package (Pack, N); + end if; + end if; + + -- Report error because name denotes something other than a package + + else + Error_Msg_N ("& is not a package", Pack_Name); + end if; + + Next (Pack_Name); + end loop; + end Analyze_Use_Package; + + ---------------------- + -- Analyze_Use_Type -- + ---------------------- + + procedure Analyze_Use_Type (N : Node_Id) is + E : Entity_Id; + Id : Node_Id; + + begin + Set_Hidden_By_Use_Clause (N, No_Elist); + + -- Chain clause to list of use clauses in current scope + + if Nkind (Parent (N)) /= N_Compilation_Unit then + Chain_Use_Clause (N); + end if; + + -- If the Used_Operations list is already initialized, the clause has + -- been analyzed previously, and it is begin reinstalled, for example + -- when the clause appears in a package spec and we are compiling the + -- corresponding package body. In that case, make the entities on the + -- existing list use_visible, and mark the corresponding types In_Use. + + if Present (Used_Operations (N)) then + declare + Mark : Node_Id; + Elmt : Elmt_Id; + + begin + Mark := First (Subtype_Marks (N)); + while Present (Mark) loop + Use_One_Type (Mark, Installed => True); + Next (Mark); + end loop; + + Elmt := First_Elmt (Used_Operations (N)); + while Present (Elmt) loop + Set_Is_Potentially_Use_Visible (Node (Elmt)); + Next_Elmt (Elmt); + end loop; + end; + + return; + end if; + + -- Otherwise, create new list and attach to it the operations that + -- are made use-visible by the clause. + + Set_Used_Operations (N, New_Elmt_List); + Id := First (Subtype_Marks (N)); + while Present (Id) loop + Find_Type (Id); + E := Entity (Id); + + if E /= Any_Type then + Use_One_Type (Id); + + if Nkind (Parent (N)) = N_Compilation_Unit then + if Nkind (Id) = N_Identifier then + Error_Msg_N ("type is not directly visible", Id); + + elsif Is_Child_Unit (Scope (E)) + and then Scope (E) /= System_Aux_Id + then + Check_In_Previous_With_Clause (N, Prefix (Id)); + end if; + end if; + + else + -- If the use_type_clause appears in a compilation unit context, + -- check whether it comes from a unit that may appear in a + -- limited_with_clause, for a better error message. + + if Nkind (Parent (N)) = N_Compilation_Unit + and then Nkind (Id) /= N_Identifier + then + declare + Item : Node_Id; + Pref : Node_Id; + + function Mentioned (Nam : Node_Id) return Boolean; + -- Check whether the prefix of expanded name for the type + -- appears in the prefix of some limited_with_clause. + + --------------- + -- Mentioned -- + --------------- + + function Mentioned (Nam : Node_Id) return Boolean is + begin + return Nkind (Name (Item)) = N_Selected_Component + and then + Chars (Prefix (Name (Item))) = Chars (Nam); + end Mentioned; + + begin + Pref := Prefix (Id); + Item := First (Context_Items (Parent (N))); + + while Present (Item) and then Item /= N loop + if Nkind (Item) = N_With_Clause + and then Limited_Present (Item) + and then Mentioned (Pref) + then + Change_Error_Text + (Get_Msg_Id, "premature usage of incomplete type"); + end if; + + Next (Item); + end loop; + end; + end if; + end if; + + Next (Id); + end loop; + end Analyze_Use_Type; + + -------------------- + -- Applicable_Use -- + -------------------- + + function Applicable_Use (Pack_Name : Node_Id) return Boolean is + Pack : constant Entity_Id := Entity (Pack_Name); + + begin + if In_Open_Scopes (Pack) then + if Warn_On_Redundant_Constructs + and then Pack = Current_Scope + then + Error_Msg_NE -- CODEFIX + ("& is already use-visible within itself?r?", Pack_Name, Pack); + end if; + + return False; + + elsif In_Use (Pack) then + Note_Redundant_Use (Pack_Name); + return False; + + elsif Present (Renamed_Object (Pack)) + and then In_Use (Renamed_Object (Pack)) + then + Note_Redundant_Use (Pack_Name); + return False; + + else + return True; + end if; + end Applicable_Use; + + ------------------------ + -- Attribute_Renaming -- + ------------------------ + + procedure Attribute_Renaming (N : Node_Id) is + Loc : constant Source_Ptr := Sloc (N); + Nam : constant Node_Id := Name (N); + Spec : constant Node_Id := Specification (N); + New_S : constant Entity_Id := Defining_Unit_Name (Spec); + Aname : constant Name_Id := Attribute_Name (Nam); + + Form_Num : Nat := 0; + Expr_List : List_Id := No_List; + + Attr_Node : Node_Id; + Body_Node : Node_Id; + Param_Spec : Node_Id; + + begin + Generate_Definition (New_S); + + -- This procedure is called in the context of subprogram renaming, and + -- thus the attribute must be one that is a subprogram. All of those + -- have at least one formal parameter, with the singular exception of + -- AST_Entry (which is a real oddity, it is odd that this can be renamed + -- at all!) + + if not Is_Non_Empty_List (Parameter_Specifications (Spec)) then + if Aname /= Name_AST_Entry then + Error_Msg_N + ("subprogram renaming an attribute must have formals", N); + return; + end if; + + else + Param_Spec := First (Parameter_Specifications (Spec)); + while Present (Param_Spec) loop + Form_Num := Form_Num + 1; + + if Nkind (Parameter_Type (Param_Spec)) /= N_Access_Definition then + Find_Type (Parameter_Type (Param_Spec)); + + -- The profile of the new entity denotes the base type (s) of + -- the types given in the specification. For access parameters + -- there are no subtypes involved. + + Rewrite (Parameter_Type (Param_Spec), + New_Reference_To + (Base_Type (Entity (Parameter_Type (Param_Spec))), Loc)); + end if; + + if No (Expr_List) then + Expr_List := New_List; + end if; + + Append_To (Expr_List, + Make_Identifier (Loc, + Chars => Chars (Defining_Identifier (Param_Spec)))); + + -- The expressions in the attribute reference are not freeze + -- points. Neither is the attribute as a whole, see below. + + Set_Must_Not_Freeze (Last (Expr_List)); + Next (Param_Spec); + end loop; + end if; + + -- Immediate error if too many formals. Other mismatches in number or + -- types of parameters are detected when we analyze the body of the + -- subprogram that we construct. + + if Form_Num > 2 then + Error_Msg_N ("too many formals for attribute", N); + + -- Error if the attribute reference has expressions that look like + -- formal parameters. + + elsif Present (Expressions (Nam)) then + Error_Msg_N ("illegal expressions in attribute reference", Nam); + + elsif + Aname = Name_Compose or else + Aname = Name_Exponent or else + Aname = Name_Leading_Part or else + Aname = Name_Pos or else + Aname = Name_Round or else + Aname = Name_Scaling or else + Aname = Name_Val + then + if Nkind (N) = N_Subprogram_Renaming_Declaration + and then Present (Corresponding_Formal_Spec (N)) + then + Error_Msg_N + ("generic actual cannot be attribute involving universal type", + Nam); + else + Error_Msg_N + ("attribute involving a universal type cannot be renamed", + Nam); + end if; + end if; + + -- AST_Entry is an odd case. It doesn't really make much sense to allow + -- it to be renamed, but that's the DEC rule, so we have to do it right. + -- The point is that the AST_Entry call should be made now, and what the + -- function will return is the returned value. + + -- Note that there is no Expr_List in this case anyway + + if Aname = Name_AST_Entry then + declare + Ent : constant Entity_Id := Make_Temporary (Loc, 'R', Nam); + Decl : Node_Id; + + begin + Decl := + Make_Object_Declaration (Loc, + Defining_Identifier => Ent, + Object_Definition => + New_Occurrence_Of (RTE (RE_AST_Handler), Loc), + Expression => Nam, + Constant_Present => True); + + Set_Assignment_OK (Decl, True); + Insert_Action (N, Decl); + Attr_Node := Make_Identifier (Loc, Chars (Ent)); + end; + + -- For all other attributes, we rewrite the attribute node to have + -- a list of expressions corresponding to the subprogram formals. + -- A renaming declaration is not a freeze point, and the analysis of + -- the attribute reference should not freeze the type of the prefix. + + else + Attr_Node := + Make_Attribute_Reference (Loc, + Prefix => Prefix (Nam), + Attribute_Name => Aname, + Expressions => Expr_List); + + Set_Must_Not_Freeze (Attr_Node); + Set_Must_Not_Freeze (Prefix (Nam)); + end if; + + -- Case of renaming a function + + if Nkind (Spec) = N_Function_Specification then + if Is_Procedure_Attribute_Name (Aname) then + Error_Msg_N ("attribute can only be renamed as procedure", Nam); + return; + end if; + + Find_Type (Result_Definition (Spec)); + Rewrite (Result_Definition (Spec), + New_Reference_To ( + Base_Type (Entity (Result_Definition (Spec))), Loc)); + + Body_Node := + Make_Subprogram_Body (Loc, + Specification => Spec, + Declarations => New_List, + Handled_Statement_Sequence => + Make_Handled_Sequence_Of_Statements (Loc, + Statements => New_List ( + Make_Simple_Return_Statement (Loc, + Expression => Attr_Node)))); + + -- Case of renaming a procedure + + else + if not Is_Procedure_Attribute_Name (Aname) then + Error_Msg_N ("attribute can only be renamed as function", Nam); + return; + end if; + + Body_Node := + Make_Subprogram_Body (Loc, + Specification => Spec, + Declarations => New_List, + Handled_Statement_Sequence => + Make_Handled_Sequence_Of_Statements (Loc, + Statements => New_List (Attr_Node))); + end if; + + -- In case of tagged types we add the body of the generated function to + -- the freezing actions of the type (because in the general case such + -- type is still not frozen). We exclude from this processing generic + -- formal subprograms found in instantiations and AST_Entry renamings. + + -- We must exclude VM targets and restricted run-time libraries because + -- entity AST_Handler is defined in package System.Aux_Dec which is not + -- available in those platforms. Note that we cannot use the function + -- Restricted_Profile (instead of Configurable_Run_Time_Mode) because + -- the ZFP run-time library is not defined as a profile, and we do not + -- want to deal with AST_Handler in ZFP mode. + + if VM_Target = No_VM + and then not Configurable_Run_Time_Mode + and then not Present (Corresponding_Formal_Spec (N)) + and then Etype (Nam) /= RTE (RE_AST_Handler) + then + declare + P : constant Entity_Id := Prefix (Nam); + + begin + Find_Type (P); + + if Is_Tagged_Type (Etype (P)) then + Ensure_Freeze_Node (Etype (P)); + Append_Freeze_Action (Etype (P), Body_Node); + else + Rewrite (N, Body_Node); + Analyze (N); + Set_Etype (New_S, Base_Type (Etype (New_S))); + end if; + end; + + -- Generic formal subprograms or AST_Handler renaming + + else + Rewrite (N, Body_Node); + Analyze (N); + Set_Etype (New_S, Base_Type (Etype (New_S))); + end if; + + if Is_Compilation_Unit (New_S) then + Error_Msg_N + ("a library unit can only rename another library unit", N); + end if; + + -- We suppress elaboration warnings for the resulting entity, since + -- clearly they are not needed, and more particularly, in the case + -- of a generic formal subprogram, the resulting entity can appear + -- after the instantiation itself, and thus look like a bogus case + -- of access before elaboration. + + Set_Suppress_Elaboration_Warnings (New_S); + + end Attribute_Renaming; + + ---------------------- + -- Chain_Use_Clause -- + ---------------------- + + procedure Chain_Use_Clause (N : Node_Id) is + Pack : Entity_Id; + Level : Int := Scope_Stack.Last; + + begin + if not Is_Compilation_Unit (Current_Scope) + or else not Is_Child_Unit (Current_Scope) + then + null; -- Common case + + elsif Defining_Entity (Parent (N)) = Current_Scope then + null; -- Common case for compilation unit + + else + -- If declaration appears in some other scope, it must be in some + -- parent unit when compiling a child. + + Pack := Defining_Entity (Parent (N)); + if not In_Open_Scopes (Pack) then + null; -- default as well + + else + -- Find entry for parent unit in scope stack + + while Scope_Stack.Table (Level).Entity /= Pack loop + Level := Level - 1; + end loop; + end if; + end if; + + Set_Next_Use_Clause (N, + Scope_Stack.Table (Level).First_Use_Clause); + Scope_Stack.Table (Level).First_Use_Clause := N; + end Chain_Use_Clause; + + --------------------------- + -- Check_Frozen_Renaming -- + --------------------------- + + procedure Check_Frozen_Renaming (N : Node_Id; Subp : Entity_Id) is + B_Node : Node_Id; + Old_S : Entity_Id; + + begin + if Is_Frozen (Subp) + and then not Has_Completion (Subp) + then + B_Node := + Build_Renamed_Body + (Parent (Declaration_Node (Subp)), Defining_Entity (N)); + + if Is_Entity_Name (Name (N)) then + Old_S := Entity (Name (N)); + + if not Is_Frozen (Old_S) + and then Operating_Mode /= Check_Semantics + then + Append_Freeze_Action (Old_S, B_Node); + else + Insert_After (N, B_Node); + Analyze (B_Node); + end if; + + if Is_Intrinsic_Subprogram (Old_S) + and then not In_Instance + then + Error_Msg_N + ("subprogram used in renaming_as_body cannot be intrinsic", + Name (N)); + end if; + + else + Insert_After (N, B_Node); + Analyze (B_Node); + end if; + end if; + end Check_Frozen_Renaming; + + ------------------------------- + -- Set_Entity_Or_Discriminal -- + ------------------------------- + + procedure Set_Entity_Or_Discriminal (N : Node_Id; E : Entity_Id) is + P : Node_Id; + + begin + -- If the entity is not a discriminant, or else expansion is disabled, + -- simply set the entity. + + if not In_Spec_Expression + or else Ekind (E) /= E_Discriminant + or else Inside_A_Generic + then + Set_Entity_With_Style_Check (N, E); + + -- The replacement of a discriminant by the corresponding discriminal + -- is not done for a task discriminant that appears in a default + -- expression of an entry parameter. See Exp_Ch2.Expand_Discriminant + -- for details on their handling. + + elsif Is_Concurrent_Type (Scope (E)) then + + P := Parent (N); + while Present (P) + and then not Nkind_In (P, N_Parameter_Specification, + N_Component_Declaration) + loop + P := Parent (P); + end loop; + + if Present (P) + and then Nkind (P) = N_Parameter_Specification + then + null; + + else + Set_Entity (N, Discriminal (E)); + end if; + + -- Otherwise, this is a discriminant in a context in which + -- it is a reference to the corresponding parameter of the + -- init proc for the enclosing type. + + else + Set_Entity (N, Discriminal (E)); + end if; + end Set_Entity_Or_Discriminal; + + ----------------------------------- + -- Check_In_Previous_With_Clause -- + ----------------------------------- + + procedure Check_In_Previous_With_Clause + (N : Node_Id; + Nam : Entity_Id) + is + Pack : constant Entity_Id := Entity (Original_Node (Nam)); + Item : Node_Id; + Par : Node_Id; + + begin + Item := First (Context_Items (Parent (N))); + + while Present (Item) + and then Item /= N + loop + if Nkind (Item) = N_With_Clause + + -- Protect the frontend against previous critical errors + + and then Nkind (Name (Item)) /= N_Selected_Component + and then Entity (Name (Item)) = Pack + then + Par := Nam; + + -- Find root library unit in with_clause + + while Nkind (Par) = N_Expanded_Name loop + Par := Prefix (Par); + end loop; + + if Is_Child_Unit (Entity (Original_Node (Par))) then + Error_Msg_NE ("& is not directly visible", Par, Entity (Par)); + else + return; + end if; + end if; + + Next (Item); + end loop; + + -- On exit, package is not mentioned in a previous with_clause. + -- Check if its prefix is. + + if Nkind (Nam) = N_Expanded_Name then + Check_In_Previous_With_Clause (N, Prefix (Nam)); + + elsif Pack /= Any_Id then + Error_Msg_NE ("& is not visible", Nam, Pack); + end if; + end Check_In_Previous_With_Clause; + + --------------------------------- + -- Check_Library_Unit_Renaming -- + --------------------------------- + + procedure Check_Library_Unit_Renaming (N : Node_Id; Old_E : Entity_Id) is + New_E : Entity_Id; + + begin + if Nkind (Parent (N)) /= N_Compilation_Unit then + return; + + -- Check for library unit. Note that we used to check for the scope + -- being Standard here, but that was wrong for Standard itself. + + elsif not Is_Compilation_Unit (Old_E) + and then not Is_Child_Unit (Old_E) + then + Error_Msg_N ("renamed unit must be a library unit", Name (N)); + + -- Entities defined in Standard (operators and boolean literals) cannot + -- be renamed as library units. + + elsif Scope (Old_E) = Standard_Standard + and then Sloc (Old_E) = Standard_Location + then + Error_Msg_N ("renamed unit must be a library unit", Name (N)); + + elsif Present (Parent_Spec (N)) + and then Nkind (Unit (Parent_Spec (N))) = N_Generic_Package_Declaration + and then not Is_Child_Unit (Old_E) + then + Error_Msg_N + ("renamed unit must be a child unit of generic parent", Name (N)); + + elsif Nkind (N) in N_Generic_Renaming_Declaration + and then Nkind (Name (N)) = N_Expanded_Name + and then Is_Generic_Instance (Entity (Prefix (Name (N)))) + and then Is_Generic_Unit (Old_E) + then + Error_Msg_N + ("renamed generic unit must be a library unit", Name (N)); + + elsif Is_Package_Or_Generic_Package (Old_E) then + + -- Inherit categorization flags + + New_E := Defining_Entity (N); + Set_Is_Pure (New_E, Is_Pure (Old_E)); + Set_Is_Preelaborated (New_E, Is_Preelaborated (Old_E)); + Set_Is_Remote_Call_Interface (New_E, + Is_Remote_Call_Interface (Old_E)); + Set_Is_Remote_Types (New_E, Is_Remote_Types (Old_E)); + Set_Is_Shared_Passive (New_E, Is_Shared_Passive (Old_E)); + end if; + end Check_Library_Unit_Renaming; + + --------------- + -- End_Scope -- + --------------- + + procedure End_Scope is + Id : Entity_Id; + Prev : Entity_Id; + Outer : Entity_Id; + + begin + Id := First_Entity (Current_Scope); + while Present (Id) loop + -- An entity in the current scope is not necessarily the first one + -- on its homonym chain. Find its predecessor if any, + -- If it is an internal entity, it will not be in the visibility + -- chain altogether, and there is nothing to unchain. + + if Id /= Current_Entity (Id) then + Prev := Current_Entity (Id); + while Present (Prev) + and then Present (Homonym (Prev)) + and then Homonym (Prev) /= Id + loop + Prev := Homonym (Prev); + end loop; + + -- Skip to end of loop if Id is not in the visibility chain + + if No (Prev) or else Homonym (Prev) /= Id then + goto Next_Ent; + end if; + + else + Prev := Empty; + end if; + + Set_Is_Immediately_Visible (Id, False); + + Outer := Homonym (Id); + while Present (Outer) and then Scope (Outer) = Current_Scope loop + Outer := Homonym (Outer); + end loop; + + -- Reset homonym link of other entities, but do not modify link + -- between entities in current scope, so that the back-end can have + -- a proper count of local overloadings. + + if No (Prev) then + Set_Name_Entity_Id (Chars (Id), Outer); + + elsif Scope (Prev) /= Scope (Id) then + Set_Homonym (Prev, Outer); + end if; + + <<Next_Ent>> + Next_Entity (Id); + end loop; + + -- If the scope generated freeze actions, place them before the + -- current declaration and analyze them. Type declarations and + -- the bodies of initialization procedures can generate such nodes. + -- We follow the parent chain until we reach a list node, which is + -- the enclosing list of declarations. If the list appears within + -- a protected definition, move freeze nodes outside the protected + -- type altogether. + + if Present + (Scope_Stack.Table (Scope_Stack.Last).Pending_Freeze_Actions) + then + declare + Decl : Node_Id; + L : constant List_Id := Scope_Stack.Table + (Scope_Stack.Last).Pending_Freeze_Actions; + + begin + if Is_Itype (Current_Scope) then + Decl := Associated_Node_For_Itype (Current_Scope); + else + Decl := Parent (Current_Scope); + end if; + + Pop_Scope; + + while not (Is_List_Member (Decl)) + or else Nkind_In (Parent (Decl), N_Protected_Definition, + N_Task_Definition) + loop + Decl := Parent (Decl); + end loop; + + Insert_List_Before_And_Analyze (Decl, L); + end; + + else + Pop_Scope; + end if; + + end End_Scope; + + --------------------- + -- End_Use_Clauses -- + --------------------- + + procedure End_Use_Clauses (Clause : Node_Id) is + U : Node_Id; + + begin + -- Remove Use_Type clauses first, because they affect the + -- visibility of operators in subsequent used packages. + + U := Clause; + while Present (U) loop + if Nkind (U) = N_Use_Type_Clause then + End_Use_Type (U); + end if; + + Next_Use_Clause (U); + end loop; + + U := Clause; + while Present (U) loop + if Nkind (U) = N_Use_Package_Clause then + End_Use_Package (U); + end if; + + Next_Use_Clause (U); + end loop; + end End_Use_Clauses; + + --------------------- + -- End_Use_Package -- + --------------------- + + procedure End_Use_Package (N : Node_Id) is + Pack_Name : Node_Id; + Pack : Entity_Id; + Id : Entity_Id; + Elmt : Elmt_Id; + + function Is_Primitive_Operator_In_Use + (Op : Entity_Id; + F : Entity_Id) return Boolean; + -- Check whether Op is a primitive operator of a use-visible type + + ---------------------------------- + -- Is_Primitive_Operator_In_Use -- + ---------------------------------- + + function Is_Primitive_Operator_In_Use + (Op : Entity_Id; + F : Entity_Id) return Boolean + is + T : constant Entity_Id := Base_Type (Etype (F)); + begin + return In_Use (T) and then Scope (T) = Scope (Op); + end Is_Primitive_Operator_In_Use; + + -- Start of processing for End_Use_Package + + begin + Pack_Name := First (Names (N)); + while Present (Pack_Name) loop + + -- Test that Pack_Name actually denotes a package before processing + + if Is_Entity_Name (Pack_Name) + and then Ekind (Entity (Pack_Name)) = E_Package + then + Pack := Entity (Pack_Name); + + if In_Open_Scopes (Pack) then + null; + + elsif not Redundant_Use (Pack_Name) then + Set_In_Use (Pack, False); + Set_Current_Use_Clause (Pack, Empty); + + Id := First_Entity (Pack); + while Present (Id) loop + + -- Preserve use-visibility of operators that are primitive + -- operators of a type that is use-visible through an active + -- use_type clause. + + if Nkind (Id) = N_Defining_Operator_Symbol + and then + (Is_Primitive_Operator_In_Use + (Id, First_Formal (Id)) + or else + (Present (Next_Formal (First_Formal (Id))) + and then + Is_Primitive_Operator_In_Use + (Id, Next_Formal (First_Formal (Id))))) + then + null; + + else + Set_Is_Potentially_Use_Visible (Id, False); + end if; + + if Is_Private_Type (Id) + and then Present (Full_View (Id)) + then + Set_Is_Potentially_Use_Visible (Full_View (Id), False); + end if; + + Next_Entity (Id); + end loop; + + if Present (Renamed_Object (Pack)) then + Set_In_Use (Renamed_Object (Pack), False); + Set_Current_Use_Clause (Renamed_Object (Pack), Empty); + end if; + + if Chars (Pack) = Name_System + and then Scope (Pack) = Standard_Standard + and then Present_System_Aux + then + Id := First_Entity (System_Aux_Id); + while Present (Id) loop + Set_Is_Potentially_Use_Visible (Id, False); + + if Is_Private_Type (Id) + and then Present (Full_View (Id)) + then + Set_Is_Potentially_Use_Visible (Full_View (Id), False); + end if; + + Next_Entity (Id); + end loop; + + Set_In_Use (System_Aux_Id, False); + end if; + + else + Set_Redundant_Use (Pack_Name, False); + end if; + end if; + + Next (Pack_Name); + end loop; + + if Present (Hidden_By_Use_Clause (N)) then + Elmt := First_Elmt (Hidden_By_Use_Clause (N)); + while Present (Elmt) loop + declare + E : constant Entity_Id := Node (Elmt); + + begin + -- Reset either Use_Visibility or Direct_Visibility, depending + -- on how the entity was hidden by the use clause. + + if In_Use (Scope (E)) + and then Used_As_Generic_Actual (Scope (E)) + then + Set_Is_Potentially_Use_Visible (Node (Elmt)); + else + Set_Is_Immediately_Visible (Node (Elmt)); + end if; + + Next_Elmt (Elmt); + end; + end loop; + + Set_Hidden_By_Use_Clause (N, No_Elist); + end if; + end End_Use_Package; + + ------------------ + -- End_Use_Type -- + ------------------ + + procedure End_Use_Type (N : Node_Id) is + Elmt : Elmt_Id; + Id : Entity_Id; + T : Entity_Id; + + -- Start of processing for End_Use_Type + + begin + Id := First (Subtype_Marks (N)); + while Present (Id) loop + + -- A call to Rtsfind may occur while analyzing a use_type clause, + -- in which case the type marks are not resolved yet, and there is + -- nothing to remove. + + if not Is_Entity_Name (Id) or else No (Entity (Id)) then + goto Continue; + end if; + + T := Entity (Id); + + if T = Any_Type or else From_With_Type (T) then + null; + + -- Note that the use_type clause may mention a subtype of the type + -- whose primitive operations have been made visible. Here as + -- elsewhere, it is the base type that matters for visibility. + + elsif In_Open_Scopes (Scope (Base_Type (T))) then + null; + + elsif not Redundant_Use (Id) then + Set_In_Use (T, False); + Set_In_Use (Base_Type (T), False); + Set_Current_Use_Clause (T, Empty); + Set_Current_Use_Clause (Base_Type (T), Empty); + end if; + + <<Continue>> + Next (Id); + end loop; + + if Is_Empty_Elmt_List (Used_Operations (N)) then + return; + + else + Elmt := First_Elmt (Used_Operations (N)); + while Present (Elmt) loop + Set_Is_Potentially_Use_Visible (Node (Elmt), False); + Next_Elmt (Elmt); + end loop; + end if; + end End_Use_Type; + + ---------------------- + -- Find_Direct_Name -- + ---------------------- + + procedure Find_Direct_Name (N : Node_Id) is + E : Entity_Id; + E2 : Entity_Id; + Msg : Boolean; + + Inst : Entity_Id := Empty; + -- Enclosing instance, if any + + Homonyms : Entity_Id; + -- Saves start of homonym chain + + Nvis_Entity : Boolean; + -- Set True to indicate that there is at least one entity on the homonym + -- chain which, while not visible, is visible enough from the user point + -- of view to warrant an error message of "not visible" rather than + -- undefined. + + Nvis_Is_Private_Subprg : Boolean := False; + -- Ada 2005 (AI-262): Set True to indicate that a form of Beaujolais + -- effect concerning library subprograms has been detected. Used to + -- generate the precise error message. + + function From_Actual_Package (E : Entity_Id) return Boolean; + -- Returns true if the entity is declared in a package that is + -- an actual for a formal package of the current instance. Such an + -- entity requires special handling because it may be use-visible + -- but hides directly visible entities defined outside the instance. + + function Is_Actual_Parameter return Boolean; + -- This function checks if the node N is an identifier that is an actual + -- parameter of a procedure call. If so it returns True, otherwise it + -- return False. The reason for this check is that at this stage we do + -- not know what procedure is being called if the procedure might be + -- overloaded, so it is premature to go setting referenced flags or + -- making calls to Generate_Reference. We will wait till Resolve_Actuals + -- for that processing + + function Known_But_Invisible (E : Entity_Id) return Boolean; + -- This function determines whether the entity E (which is not + -- visible) can reasonably be considered to be known to the writer + -- of the reference. This is a heuristic test, used only for the + -- purposes of figuring out whether we prefer to complain that an + -- entity is undefined or invisible (and identify the declaration + -- of the invisible entity in the latter case). The point here is + -- that we don't want to complain that something is invisible and + -- then point to something entirely mysterious to the writer. + + procedure Nvis_Messages; + -- Called if there are no visible entries for N, but there is at least + -- one non-directly visible, or hidden declaration. This procedure + -- outputs an appropriate set of error messages. + + procedure Undefined (Nvis : Boolean); + -- This function is called if the current node has no corresponding + -- visible entity or entities. The value set in Msg indicates whether + -- an error message was generated (multiple error messages for the + -- same variable are generally suppressed, see body for details). + -- Msg is True if an error message was generated, False if not. This + -- value is used by the caller to determine whether or not to output + -- additional messages where appropriate. The parameter is set False + -- to get the message "X is undefined", and True to get the message + -- "X is not visible". + + ------------------------- + -- From_Actual_Package -- + ------------------------- + + function From_Actual_Package (E : Entity_Id) return Boolean is + Scop : constant Entity_Id := Scope (E); + Act : Entity_Id; + + begin + if not In_Instance then + return False; + else + Inst := Current_Scope; + while Present (Inst) + and then Ekind (Inst) /= E_Package + and then not Is_Generic_Instance (Inst) + loop + Inst := Scope (Inst); + end loop; + + if No (Inst) then + return False; + end if; + + Act := First_Entity (Inst); + while Present (Act) loop + if Ekind (Act) = E_Package then + + -- Check for end of actuals list + + if Renamed_Object (Act) = Inst then + return False; + + elsif Present (Associated_Formal_Package (Act)) + and then Renamed_Object (Act) = Scop + then + -- Entity comes from (instance of) formal package + + return True; + + else + Next_Entity (Act); + end if; + + else + Next_Entity (Act); + end if; + end loop; + + return False; + end if; + end From_Actual_Package; + + ------------------------- + -- Is_Actual_Parameter -- + ------------------------- + + function Is_Actual_Parameter return Boolean is + begin + return + Nkind (N) = N_Identifier + and then + (Nkind (Parent (N)) = N_Procedure_Call_Statement + or else + (Nkind (Parent (N)) = N_Parameter_Association + and then N = Explicit_Actual_Parameter (Parent (N)) + and then Nkind (Parent (Parent (N))) = + N_Procedure_Call_Statement)); + end Is_Actual_Parameter; + + ------------------------- + -- Known_But_Invisible -- + ------------------------- + + function Known_But_Invisible (E : Entity_Id) return Boolean is + Fname : File_Name_Type; + + begin + -- Entities in Standard are always considered to be known + + if Sloc (E) <= Standard_Location then + return True; + + -- An entity that does not come from source is always considered + -- to be unknown, since it is an artifact of code expansion. + + elsif not Comes_From_Source (E) then + return False; + + -- In gnat internal mode, we consider all entities known + + elsif GNAT_Mode then + return True; + end if; + + -- Here we have an entity that is not from package Standard, and + -- which comes from Source. See if it comes from an internal file. + + Fname := Unit_File_Name (Get_Source_Unit (E)); + + -- Case of from internal file + + if Is_Internal_File_Name (Fname) then + + -- Private part entities in internal files are never considered + -- to be known to the writer of normal application code. + + if Is_Hidden (E) then + return False; + end if; + + -- Entities from System packages other than System and + -- System.Storage_Elements are not considered to be known. + -- System.Auxxxx files are also considered known to the user. + + -- Should refine this at some point to generally distinguish + -- between known and unknown internal files ??? + + Get_Name_String (Fname); + + return + Name_Len < 2 + or else + Name_Buffer (1 .. 2) /= "s-" + or else + Name_Buffer (3 .. 8) = "stoele" + or else + Name_Buffer (3 .. 5) = "aux"; + + -- If not an internal file, then entity is definitely known, + -- even if it is in a private part (the message generated will + -- note that it is in a private part) + + else + return True; + end if; + end Known_But_Invisible; + + ------------------- + -- Nvis_Messages -- + ------------------- + + procedure Nvis_Messages is + Comp_Unit : Node_Id; + Ent : Entity_Id; + Found : Boolean := False; + Hidden : Boolean := False; + Item : Node_Id; + + begin + -- Ada 2005 (AI-262): Generate a precise error concerning the + -- Beaujolais effect that was previously detected + + if Nvis_Is_Private_Subprg then + + pragma Assert (Nkind (E2) = N_Defining_Identifier + and then Ekind (E2) = E_Function + and then Scope (E2) = Standard_Standard + and then Has_Private_With (E2)); + + -- Find the sloc corresponding to the private with'ed unit + + Comp_Unit := Cunit (Current_Sem_Unit); + Error_Msg_Sloc := No_Location; + + Item := First (Context_Items (Comp_Unit)); + while Present (Item) loop + if Nkind (Item) = N_With_Clause + and then Private_Present (Item) + and then Entity (Name (Item)) = E2 + then + Error_Msg_Sloc := Sloc (Item); + exit; + end if; + + Next (Item); + end loop; + + pragma Assert (Error_Msg_Sloc /= No_Location); + + Error_Msg_N ("(Ada 2005): hidden by private with clause #", N); + return; + end if; + + Undefined (Nvis => True); + + if Msg then + + -- First loop does hidden declarations + + Ent := Homonyms; + while Present (Ent) loop + if Is_Potentially_Use_Visible (Ent) then + if not Hidden then + Error_Msg_N -- CODEFIX + ("multiple use clauses cause hiding!", N); + Hidden := True; + end if; + + Error_Msg_Sloc := Sloc (Ent); + Error_Msg_N -- CODEFIX + ("hidden declaration#!", N); + end if; + + Ent := Homonym (Ent); + end loop; + + -- If we found hidden declarations, then that's enough, don't + -- bother looking for non-visible declarations as well. + + if Hidden then + return; + end if; + + -- Second loop does non-directly visible declarations + + Ent := Homonyms; + while Present (Ent) loop + if not Is_Potentially_Use_Visible (Ent) then + + -- Do not bother the user with unknown entities + + if not Known_But_Invisible (Ent) then + goto Continue; + end if; + + Error_Msg_Sloc := Sloc (Ent); + + -- Output message noting that there is a non-visible + -- declaration, distinguishing the private part case. + + if Is_Hidden (Ent) then + Error_Msg_N ("non-visible (private) declaration#!", N); + + -- If the entity is declared in a generic package, it + -- cannot be visible, so there is no point in adding it + -- to the list of candidates if another homograph from a + -- non-generic package has been seen. + + elsif Ekind (Scope (Ent)) = E_Generic_Package + and then Found + then + null; + + else + Error_Msg_N -- CODEFIX + ("non-visible declaration#!", N); + + if Ekind (Scope (Ent)) /= E_Generic_Package then + Found := True; + end if; + + if Is_Compilation_Unit (Ent) + and then + Nkind (Parent (Parent (N))) = N_Use_Package_Clause + then + Error_Msg_Qual_Level := 99; + Error_Msg_NE -- CODEFIX + ("\\missing `WITH &;`", N, Ent); + Error_Msg_Qual_Level := 0; + end if; + + if Ekind (Ent) = E_Discriminant + and then Present (Corresponding_Discriminant (Ent)) + and then Scope (Corresponding_Discriminant (Ent)) = + Etype (Scope (Ent)) + then + Error_Msg_N + ("inherited discriminant not allowed here" & + " (RM 3.8 (12), 3.8.1 (6))!", N); + end if; + end if; + + -- Set entity and its containing package as referenced. We + -- can't be sure of this, but this seems a better choice + -- to avoid unused entity messages. + + if Comes_From_Source (Ent) then + Set_Referenced (Ent); + Set_Referenced (Cunit_Entity (Get_Source_Unit (Ent))); + end if; + end if; + + <<Continue>> + Ent := Homonym (Ent); + end loop; + end if; + end Nvis_Messages; + + --------------- + -- Undefined -- + --------------- + + procedure Undefined (Nvis : Boolean) is + Emsg : Error_Msg_Id; + + begin + -- We should never find an undefined internal name. If we do, then + -- see if we have previous errors. If so, ignore on the grounds that + -- it is probably a cascaded message (e.g. a block label from a badly + -- formed block). If no previous errors, then we have a real internal + -- error of some kind so raise an exception. + + if Is_Internal_Name (Chars (N)) then + if Total_Errors_Detected /= 0 then + return; + else + raise Program_Error; + end if; + end if; + + -- A very specialized error check, if the undefined variable is + -- a case tag, and the case type is an enumeration type, check + -- for a possible misspelling, and if so, modify the identifier + + -- Named aggregate should also be handled similarly ??? + + if Nkind (N) = N_Identifier + and then Nkind (Parent (N)) = N_Case_Statement_Alternative + then + declare + Case_Stm : constant Node_Id := Parent (Parent (N)); + Case_Typ : constant Entity_Id := Etype (Expression (Case_Stm)); + + Lit : Node_Id; + + begin + if Is_Enumeration_Type (Case_Typ) + and then not Is_Standard_Character_Type (Case_Typ) + then + Lit := First_Literal (Case_Typ); + Get_Name_String (Chars (Lit)); + + if Chars (Lit) /= Chars (N) + and then Is_Bad_Spelling_Of (Chars (N), Chars (Lit)) then + Error_Msg_Node_2 := Lit; + Error_Msg_N -- CODEFIX + ("& is undefined, assume misspelling of &", N); + Rewrite (N, New_Occurrence_Of (Lit, Sloc (N))); + return; + end if; + + Lit := Next_Literal (Lit); + end if; + end; + end if; + + -- Normal processing + + Set_Entity (N, Any_Id); + Set_Etype (N, Any_Type); + + -- We use the table Urefs to keep track of entities for which we + -- have issued errors for undefined references. Multiple errors + -- for a single name are normally suppressed, however we modify + -- the error message to alert the programmer to this effect. + + for J in Urefs.First .. Urefs.Last loop + if Chars (N) = Chars (Urefs.Table (J).Node) then + if Urefs.Table (J).Err /= No_Error_Msg + and then Sloc (N) /= Urefs.Table (J).Loc + then + Error_Msg_Node_1 := Urefs.Table (J).Node; + + if Urefs.Table (J).Nvis then + Change_Error_Text (Urefs.Table (J).Err, + "& is not visible (more references follow)"); + else + Change_Error_Text (Urefs.Table (J).Err, + "& is undefined (more references follow)"); + end if; + + Urefs.Table (J).Err := No_Error_Msg; + end if; + + -- Although we will set Msg False, and thus suppress the + -- message, we also set Error_Posted True, to avoid any + -- cascaded messages resulting from the undefined reference. + + Msg := False; + Set_Error_Posted (N, True); + return; + end if; + end loop; + + -- If entry not found, this is first undefined occurrence + + if Nvis then + Error_Msg_N ("& is not visible!", N); + Emsg := Get_Msg_Id; + + else + Error_Msg_N ("& is undefined!", N); + Emsg := Get_Msg_Id; + + -- A very bizarre special check, if the undefined identifier + -- is put or put_line, then add a special error message (since + -- this is a very common error for beginners to make). + + if Chars (N) = Name_Put or else Chars (N) = Name_Put_Line then + Error_Msg_N -- CODEFIX + ("\\possible missing `WITH Ada.Text_'I'O; " & + "USE Ada.Text_'I'O`!", N); + + -- Another special check if N is the prefix of a selected + -- component which is a known unit, add message complaining + -- about missing with for this unit. + + elsif Nkind (Parent (N)) = N_Selected_Component + and then N = Prefix (Parent (N)) + and then Is_Known_Unit (Parent (N)) + then + Error_Msg_Node_2 := Selector_Name (Parent (N)); + Error_Msg_N -- CODEFIX + ("\\missing `WITH &.&;`", Prefix (Parent (N))); + end if; + + -- Now check for possible misspellings + + declare + E : Entity_Id; + Ematch : Entity_Id := Empty; + + Last_Name_Id : constant Name_Id := + Name_Id (Nat (First_Name_Id) + + Name_Entries_Count - 1); + + begin + for Nam in First_Name_Id .. Last_Name_Id loop + E := Get_Name_Entity_Id (Nam); + + if Present (E) + and then (Is_Immediately_Visible (E) + or else + Is_Potentially_Use_Visible (E)) + then + if Is_Bad_Spelling_Of (Chars (N), Nam) then + Ematch := E; + exit; + end if; + end if; + end loop; + + if Present (Ematch) then + Error_Msg_NE -- CODEFIX + ("\possible misspelling of&", N, Ematch); + end if; + end; + end if; + + -- Make entry in undefined references table unless the full errors + -- switch is set, in which case by refraining from generating the + -- table entry, we guarantee that we get an error message for every + -- undefined reference. + + if not All_Errors_Mode then + Urefs.Append ( + (Node => N, + Err => Emsg, + Nvis => Nvis, + Loc => Sloc (N))); + end if; + + Msg := True; + end Undefined; + + -- Start of processing for Find_Direct_Name + + begin + -- If the entity pointer is already set, this is an internal node, or + -- a node that is analyzed more than once, after a tree modification. + -- In such a case there is no resolution to perform, just set the type. + + if Present (Entity (N)) then + if Is_Type (Entity (N)) then + Set_Etype (N, Entity (N)); + + else + declare + Entyp : constant Entity_Id := Etype (Entity (N)); + + begin + -- One special case here. If the Etype field is already set, + -- and references the packed array type corresponding to the + -- etype of the referenced entity, then leave it alone. This + -- happens for trees generated from Exp_Pakd, where expressions + -- can be deliberately "mis-typed" to the packed array type. + + if Is_Array_Type (Entyp) + and then Is_Packed (Entyp) + and then Present (Etype (N)) + and then Etype (N) = Packed_Array_Type (Entyp) + then + null; + + -- If not that special case, then just reset the Etype + + else + Set_Etype (N, Etype (Entity (N))); + end if; + end; + end if; + + return; + end if; + + -- Here if Entity pointer was not set, we need full visibility analysis + -- First we generate debugging output if the debug E flag is set. + + if Debug_Flag_E then + Write_Str ("Looking for "); + Write_Name (Chars (N)); + Write_Eol; + end if; + + Homonyms := Current_Entity (N); + Nvis_Entity := False; + + E := Homonyms; + while Present (E) loop + + -- If entity is immediately visible or potentially use visible, then + -- process the entity and we are done. + + if Is_Immediately_Visible (E) then + goto Immediately_Visible_Entity; + + elsif Is_Potentially_Use_Visible (E) then + goto Potentially_Use_Visible_Entity; + + -- Note if a known but invisible entity encountered + + elsif Known_But_Invisible (E) then + Nvis_Entity := True; + end if; + + -- Move to next entity in chain and continue search + + E := Homonym (E); + end loop; + + -- If no entries on homonym chain that were potentially visible, + -- and no entities reasonably considered as non-visible, then + -- we have a plain undefined reference, with no additional + -- explanation required! + + if not Nvis_Entity then + Undefined (Nvis => False); + + -- Otherwise there is at least one entry on the homonym chain that + -- is reasonably considered as being known and non-visible. + + else + Nvis_Messages; + end if; + + return; + + -- Processing for a potentially use visible entry found. We must search + -- the rest of the homonym chain for two reasons. First, if there is a + -- directly visible entry, then none of the potentially use-visible + -- entities are directly visible (RM 8.4(10)). Second, we need to check + -- for the case of multiple potentially use-visible entries hiding one + -- another and as a result being non-directly visible (RM 8.4(11)). + + <<Potentially_Use_Visible_Entity>> declare + Only_One_Visible : Boolean := True; + All_Overloadable : Boolean := Is_Overloadable (E); + + begin + E2 := Homonym (E); + while Present (E2) loop + if Is_Immediately_Visible (E2) then + + -- If the use-visible entity comes from the actual for a + -- formal package, it hides a directly visible entity from + -- outside the instance. + + if From_Actual_Package (E) + and then Scope_Depth (E2) < Scope_Depth (Inst) + then + goto Found; + else + E := E2; + goto Immediately_Visible_Entity; + end if; + + elsif Is_Potentially_Use_Visible (E2) then + Only_One_Visible := False; + All_Overloadable := All_Overloadable and Is_Overloadable (E2); + + -- Ada 2005 (AI-262): Protect against a form of Beaujolais effect + -- that can occur in private_with clauses. Example: + + -- with A; + -- private with B; package A is + -- package C is function B return Integer; + -- use A; end A; + -- V1 : Integer := B; + -- private function B return Integer; + -- V2 : Integer := B; + -- end C; + + -- V1 resolves to A.B, but V2 resolves to library unit B + + elsif Ekind (E2) = E_Function + and then Scope (E2) = Standard_Standard + and then Has_Private_With (E2) + then + Only_One_Visible := False; + All_Overloadable := False; + Nvis_Is_Private_Subprg := True; + exit; + end if; + + E2 := Homonym (E2); + end loop; + + -- On falling through this loop, we have checked that there are no + -- immediately visible entities. Only_One_Visible is set if exactly + -- one potentially use visible entity exists. All_Overloadable is + -- set if all the potentially use visible entities are overloadable. + -- The condition for legality is that either there is one potentially + -- use visible entity, or if there is more than one, then all of them + -- are overloadable. + + if Only_One_Visible or All_Overloadable then + goto Found; + + -- If there is more than one potentially use-visible entity and at + -- least one of them non-overloadable, we have an error (RM 8.4(11)). + -- Note that E points to the first such entity on the homonym list. + -- Special case: if one of the entities is declared in an actual + -- package, it was visible in the generic, and takes precedence over + -- other entities that are potentially use-visible. Same if it is + -- declared in a local instantiation of the current instance. + + else + if In_Instance then + + -- Find current instance + + Inst := Current_Scope; + while Present (Inst) + and then Inst /= Standard_Standard + loop + if Is_Generic_Instance (Inst) then + exit; + end if; + + Inst := Scope (Inst); + end loop; + + E2 := E; + while Present (E2) loop + if From_Actual_Package (E2) + or else + (Is_Generic_Instance (Scope (E2)) + and then Scope_Depth (Scope (E2)) > Scope_Depth (Inst)) + then + E := E2; + goto Found; + end if; + + E2 := Homonym (E2); + end loop; + + Nvis_Messages; + return; + + elsif + Is_Predefined_File_Name (Unit_File_Name (Current_Sem_Unit)) + then + -- A use-clause in the body of a system file creates conflict + -- with some entity in a user scope, while rtsfind is active. + -- Keep only the entity coming from another predefined unit. + + E2 := E; + while Present (E2) loop + if Is_Predefined_File_Name + (Unit_File_Name (Get_Source_Unit (Sloc (E2)))) + then + E := E2; + goto Found; + end if; + + E2 := Homonym (E2); + end loop; + + -- Entity must exist because predefined unit is correct + + raise Program_Error; + + else + Nvis_Messages; + return; + end if; + end if; + end; + + -- Come here with E set to the first immediately visible entity on + -- the homonym chain. This is the one we want unless there is another + -- immediately visible entity further on in the chain for an inner + -- scope (RM 8.3(8)). + + <<Immediately_Visible_Entity>> declare + Level : Int; + Scop : Entity_Id; + + begin + -- Find scope level of initial entity. When compiling through + -- Rtsfind, the previous context is not completely invisible, and + -- an outer entity may appear on the chain, whose scope is below + -- the entry for Standard that delimits the current scope stack. + -- Indicate that the level for this spurious entry is outside of + -- the current scope stack. + + Level := Scope_Stack.Last; + loop + Scop := Scope_Stack.Table (Level).Entity; + exit when Scop = Scope (E); + Level := Level - 1; + exit when Scop = Standard_Standard; + end loop; + + -- Now search remainder of homonym chain for more inner entry + -- If the entity is Standard itself, it has no scope, and we + -- compare it with the stack entry directly. + + E2 := Homonym (E); + while Present (E2) loop + if Is_Immediately_Visible (E2) then + + -- If a generic package contains a local declaration that + -- has the same name as the generic, there may be a visibility + -- conflict in an instance, where the local declaration must + -- also hide the name of the corresponding package renaming. + -- We check explicitly for a package declared by a renaming, + -- whose renamed entity is an instance that is on the scope + -- stack, and that contains a homonym in the same scope. Once + -- we have found it, we know that the package renaming is not + -- immediately visible, and that the identifier denotes the + -- other entity (and its homonyms if overloaded). + + if Scope (E) = Scope (E2) + and then Ekind (E) = E_Package + and then Present (Renamed_Object (E)) + and then Is_Generic_Instance (Renamed_Object (E)) + and then In_Open_Scopes (Renamed_Object (E)) + and then Comes_From_Source (N) + then + Set_Is_Immediately_Visible (E, False); + E := E2; + + else + for J in Level + 1 .. Scope_Stack.Last loop + if Scope_Stack.Table (J).Entity = Scope (E2) + or else Scope_Stack.Table (J).Entity = E2 + then + Level := J; + E := E2; + exit; + end if; + end loop; + end if; + end if; + + E2 := Homonym (E2); + end loop; + + -- At the end of that loop, E is the innermost immediately + -- visible entity, so we are all set. + end; + + -- Come here with entity found, and stored in E + + <<Found>> begin + + -- Check violation of No_Wide_Characters restriction + + Check_Wide_Character_Restriction (E, N); + + -- When distribution features are available (Get_PCS_Name /= + -- Name_No_DSA), a remote access-to-subprogram type is converted + -- into a record type holding whatever information is needed to + -- perform a remote call on an RCI subprogram. In that case we + -- rewrite any occurrence of the RAS type into the equivalent record + -- type here. 'Access attribute references and RAS dereferences are + -- then implemented using specific TSSs. However when distribution is + -- not available (case of Get_PCS_Name = Name_No_DSA), we bypass the + -- generation of these TSSs, and we must keep the RAS type in its + -- original access-to-subprogram form (since all calls through a + -- value of such type will be local anyway in the absence of a PCS). + + if Comes_From_Source (N) + and then Is_Remote_Access_To_Subprogram_Type (E) + and then Expander_Active + and then Get_PCS_Name /= Name_No_DSA + then + Rewrite (N, + New_Occurrence_Of (Equivalent_Type (E), Sloc (N))); + return; + end if; + + -- Set the entity. Note that the reason we call Set_Entity for the + -- overloadable case, as opposed to Set_Entity_With_Style_Check is + -- that in the overloaded case, the initial call can set the wrong + -- homonym. The call that sets the right homonym is in Sem_Res and + -- that call does use Set_Entity_With_Style_Check, so we don't miss + -- a style check. + + if Is_Overloadable (E) then + Set_Entity (N, E); + else + Set_Entity_With_Style_Check (N, E); + end if; + + if Is_Type (E) then + Set_Etype (N, E); + else + Set_Etype (N, Get_Full_View (Etype (E))); + end if; + + if Debug_Flag_E then + Write_Str (" found "); + Write_Entity_Info (E, " "); + end if; + + -- If the Ekind of the entity is Void, it means that all homonyms + -- are hidden from all visibility (RM 8.3(5,14-20)). However, this + -- test is skipped if the current scope is a record and the name is + -- a pragma argument expression (case of Atomic and Volatile pragmas + -- and possibly other similar pragmas added later, which are allowed + -- to reference components in the current record). + + if Ekind (E) = E_Void + and then + (not Is_Record_Type (Current_Scope) + or else Nkind (Parent (N)) /= N_Pragma_Argument_Association) + then + Premature_Usage (N); + + -- If the entity is overloadable, collect all interpretations of the + -- name for subsequent overload resolution. We optimize a bit here to + -- do this only if we have an overloadable entity that is not on its + -- own on the homonym chain. + + elsif Is_Overloadable (E) + and then (Present (Homonym (E)) or else Current_Entity (N) /= E) + then + Collect_Interps (N); + + -- If no homonyms were visible, the entity is unambiguous + + if not Is_Overloaded (N) then + if not Is_Actual_Parameter then + Generate_Reference (E, N); + end if; + end if; + + -- Case of non-overloadable entity, set the entity providing that + -- we do not have the case of a discriminant reference within a + -- default expression. Such references are replaced with the + -- corresponding discriminal, which is the formal corresponding to + -- to the discriminant in the initialization procedure. + + else + -- Entity is unambiguous, indicate that it is referenced here + + -- For a renaming of an object, always generate simple reference, + -- we don't try to keep track of assignments in this case. + + if Is_Object (E) and then Present (Renamed_Object (E)) then + Generate_Reference (E, N); + + -- If the renamed entity is a private protected component, + -- reference the original component as well. This needs to be + -- done because the private renamings are installed before any + -- analysis has occurred. Reference to a private component will + -- resolve to the renaming and the original component will be + -- left unreferenced, hence the following. + + if Is_Prival (E) then + Generate_Reference (Prival_Link (E), N); + end if; + + -- One odd case is that we do not want to set the Referenced flag + -- if the entity is a label, and the identifier is the label in + -- the source, since this is not a reference from the point of + -- view of the user. + + elsif Nkind (Parent (N)) = N_Label then + declare + R : constant Boolean := Referenced (E); + + begin + -- Generate reference unless this is an actual parameter + -- (see comment below) + + if Is_Actual_Parameter then + Generate_Reference (E, N); + Set_Referenced (E, R); + end if; + end; + + -- Normal case, not a label: generate reference + + -- ??? It is too early to generate a reference here even if the + -- entity is unambiguous, because the tree is not sufficiently + -- typed at this point for Generate_Reference to determine + -- whether this reference modifies the denoted object (because + -- implicit dereferences cannot be identified prior to full type + -- resolution). + + -- The Is_Actual_Parameter routine takes care of one of these + -- cases but there are others probably ??? + + -- If the entity is the LHS of an assignment, and is a variable + -- (rather than a package prefix), we can mark it as a + -- modification right away, to avoid duplicate references. + + else + if not Is_Actual_Parameter then + if Is_LHS (N) + and then Ekind (E) /= E_Package + and then Ekind (E) /= E_Generic_Package + then + Generate_Reference (E, N, 'm'); + else + Generate_Reference (E, N); + end if; + end if; + + Check_Nested_Access (E); + end if; + + Set_Entity_Or_Discriminal (N, E); + + -- The name may designate a generalized reference, in which case + -- the dereference interpretation will be included. + + if Ada_Version >= Ada_2012 + and then + (Nkind (Parent (N)) in N_Subexpr + or else Nkind_In (Parent (N), N_Object_Declaration, + N_Assignment_Statement)) + then + Check_Implicit_Dereference (N, Etype (E)); + end if; + end if; + end; + end Find_Direct_Name; + + ------------------------ + -- Find_Expanded_Name -- + ------------------------ + + -- This routine searches the homonym chain of the entity until it finds + -- an entity declared in the scope denoted by the prefix. If the entity + -- is private, it may nevertheless be immediately visible, if we are in + -- the scope of its declaration. + + procedure Find_Expanded_Name (N : Node_Id) is + Selector : constant Node_Id := Selector_Name (N); + Candidate : Entity_Id := Empty; + P_Name : Entity_Id; + O_Name : Entity_Id; + Id : Entity_Id; + + begin + P_Name := Entity (Prefix (N)); + O_Name := P_Name; + + -- If the prefix is a renamed package, look for the entity in the + -- original package. + + if Ekind (P_Name) = E_Package + and then Present (Renamed_Object (P_Name)) + then + P_Name := Renamed_Object (P_Name); + + -- Rewrite node with entity field pointing to renamed object + + Rewrite (Prefix (N), New_Copy (Prefix (N))); + Set_Entity (Prefix (N), P_Name); + + -- If the prefix is an object of a concurrent type, look for + -- the entity in the associated task or protected type. + + elsif Is_Concurrent_Type (Etype (P_Name)) then + P_Name := Etype (P_Name); + end if; + + Id := Current_Entity (Selector); + + declare + Is_New_Candidate : Boolean; + + begin + while Present (Id) loop + if Scope (Id) = P_Name then + Candidate := Id; + Is_New_Candidate := True; + + -- Ada 2005 (AI-217): Handle shadow entities associated with types + -- declared in limited-withed nested packages. We don't need to + -- handle E_Incomplete_Subtype entities because the entities in + -- the limited view are always E_Incomplete_Type entities (see + -- Build_Limited_Views). Regarding the expression used to evaluate + -- the scope, it is important to note that the limited view also + -- has shadow entities associated nested packages. For this reason + -- the correct scope of the entity is the scope of the real entity + -- The non-limited view may itself be incomplete, in which case + -- get the full view if available. + + elsif From_With_Type (Id) + and then Is_Type (Id) + and then Ekind (Id) = E_Incomplete_Type + and then Present (Non_Limited_View (Id)) + and then Scope (Non_Limited_View (Id)) = P_Name + then + Candidate := Get_Full_View (Non_Limited_View (Id)); + Is_New_Candidate := True; + + else + Is_New_Candidate := False; + end if; + + if Is_New_Candidate then + if Is_Child_Unit (Id) or else P_Name = Standard_Standard then + exit when Is_Visible_Lib_Unit (Id); + else + exit when not Is_Hidden (Id); + end if; + + exit when Is_Immediately_Visible (Id); + end if; + + Id := Homonym (Id); + end loop; + end; + + if No (Id) + and then (Ekind (P_Name) = E_Procedure + or else + Ekind (P_Name) = E_Function) + and then Is_Generic_Instance (P_Name) + then + -- Expanded name denotes entity in (instance of) generic subprogram. + -- The entity may be in the subprogram instance, or may denote one of + -- the formals, which is declared in the enclosing wrapper package. + + P_Name := Scope (P_Name); + + Id := Current_Entity (Selector); + while Present (Id) loop + exit when Scope (Id) = P_Name; + Id := Homonym (Id); + end loop; + end if; + + if No (Id) or else Chars (Id) /= Chars (Selector) then + Set_Etype (N, Any_Type); + + -- If we are looking for an entity defined in System, try to find it + -- in the child package that may have been provided as an extension + -- to System. The Extend_System pragma will have supplied the name of + -- the extension, which may have to be loaded. + + if Chars (P_Name) = Name_System + and then Scope (P_Name) = Standard_Standard + and then Present (System_Extend_Unit) + and then Present_System_Aux (N) + then + Set_Entity (Prefix (N), System_Aux_Id); + Find_Expanded_Name (N); + return; + + elsif Nkind (Selector) = N_Operator_Symbol + and then Has_Implicit_Operator (N) + then + -- There is an implicit instance of the predefined operator in + -- the given scope. The operator entity is defined in Standard. + -- Has_Implicit_Operator makes the node into an Expanded_Name. + + return; + + elsif Nkind (Selector) = N_Character_Literal + and then Has_Implicit_Character_Literal (N) + then + -- If there is no literal defined in the scope denoted by the + -- prefix, the literal may belong to (a type derived from) + -- Standard_Character, for which we have no explicit literals. + + return; + + else + -- If the prefix is a single concurrent object, use its name in + -- the error message, rather than that of the anonymous type. + + if Is_Concurrent_Type (P_Name) + and then Is_Internal_Name (Chars (P_Name)) + then + Error_Msg_Node_2 := Entity (Prefix (N)); + else + Error_Msg_Node_2 := P_Name; + end if; + + if P_Name = System_Aux_Id then + P_Name := Scope (P_Name); + Set_Entity (Prefix (N), P_Name); + end if; + + if Present (Candidate) then + + -- If we know that the unit is a child unit we can give a more + -- accurate error message. + + if Is_Child_Unit (Candidate) then + + -- If the candidate is a private child unit and we are in + -- the visible part of a public unit, specialize the error + -- message. There might be a private with_clause for it, + -- but it is not currently active. + + if Is_Private_Descendant (Candidate) + and then Ekind (Current_Scope) = E_Package + and then not In_Private_Part (Current_Scope) + and then not Is_Private_Descendant (Current_Scope) + then + Error_Msg_N ("private child unit& is not visible here", + Selector); + + -- Normal case where we have a missing with for a child unit + + else + Error_Msg_Qual_Level := 99; + Error_Msg_NE -- CODEFIX + ("missing `WITH &;`", Selector, Candidate); + Error_Msg_Qual_Level := 0; + end if; + + -- Here we don't know that this is a child unit + + else + Error_Msg_NE ("& is not a visible entity of&", N, Selector); + end if; + + else + -- Within the instantiation of a child unit, the prefix may + -- denote the parent instance, but the selector has the name + -- of the original child. Find whether we are within the + -- corresponding instance, and get the proper entity, which + -- can only be an enclosing scope. + + if O_Name /= P_Name + and then In_Open_Scopes (P_Name) + and then Is_Generic_Instance (P_Name) + then + declare + S : Entity_Id := Current_Scope; + P : Entity_Id; + + begin + for J in reverse 0 .. Scope_Stack.Last loop + S := Scope_Stack.Table (J).Entity; + + exit when S = Standard_Standard; + + if Ekind_In (S, E_Function, + E_Package, + E_Procedure) + then + P := Generic_Parent (Specification + (Unit_Declaration_Node (S))); + + if Present (P) + and then Chars (Scope (P)) = Chars (O_Name) + and then Chars (P) = Chars (Selector) + then + Id := S; + goto Found; + end if; + end if; + + end loop; + end; + end if; + + -- If this is a selection from Ada, System or Interfaces, then + -- we assume a missing with for the corresponding package. + + if Is_Known_Unit (N) then + if not Error_Posted (N) then + Error_Msg_Node_2 := Selector; + Error_Msg_N -- CODEFIX + ("missing `WITH &.&;`", Prefix (N)); + end if; + + -- If this is a selection from a dummy package, then suppress + -- the error message, of course the entity is missing if the + -- package is missing! + + elsif Sloc (Error_Msg_Node_2) = No_Location then + null; + + -- Here we have the case of an undefined component + + else + + -- The prefix may hide a homonym in the context that + -- declares the desired entity. This error can use a + -- specialized message. + + if In_Open_Scopes (P_Name) then + declare + H : constant Entity_Id := Homonym (P_Name); + + begin + if Present (H) + and then Is_Compilation_Unit (H) + and then + (Is_Immediately_Visible (H) + or else Is_Visible_Lib_Unit (H)) + then + Id := First_Entity (H); + while Present (Id) loop + if Chars (Id) = Chars (Selector) then + Error_Msg_Qual_Level := 99; + Error_Msg_Name_1 := Chars (Selector); + Error_Msg_NE + ("% not declared in&", N, P_Name); + Error_Msg_NE + ("\use fully qualified name starting with " + & "Standard to make& visible", N, H); + Error_Msg_Qual_Level := 0; + goto Done; + end if; + + Next_Entity (Id); + end loop; + end if; + + -- If not found, standard error message + + Error_Msg_NE ("& not declared in&", N, Selector); + + <<Done>> null; + end; + + else + Error_Msg_NE ("& not declared in&", N, Selector); + end if; + + -- Check for misspelling of some entity in prefix + + Id := First_Entity (P_Name); + while Present (Id) loop + if Is_Bad_Spelling_Of (Chars (Id), Chars (Selector)) + and then not Is_Internal_Name (Chars (Id)) + then + Error_Msg_NE -- CODEFIX + ("possible misspelling of&", Selector, Id); + exit; + end if; + + Next_Entity (Id); + end loop; + + -- Specialize the message if this may be an instantiation + -- of a child unit that was not mentioned in the context. + + if Nkind (Parent (N)) = N_Package_Instantiation + and then Is_Generic_Instance (Entity (Prefix (N))) + and then Is_Compilation_Unit + (Generic_Parent (Parent (Entity (Prefix (N))))) + then + Error_Msg_Node_2 := Selector; + Error_Msg_N -- CODEFIX + ("\missing `WITH &.&;`", Prefix (N)); + end if; + end if; + end if; + + Id := Any_Id; + end if; + end if; + + <<Found>> + if Comes_From_Source (N) + and then Is_Remote_Access_To_Subprogram_Type (Id) + and then Present (Equivalent_Type (Id)) + then + -- If we are not actually generating distribution code (i.e. the + -- current PCS is the dummy non-distributed version), then the + -- Equivalent_Type will be missing, and Id should be treated as + -- a regular access-to-subprogram type. + + Id := Equivalent_Type (Id); + Set_Chars (Selector, Chars (Id)); + end if; + + -- Ada 2005 (AI-50217): Check usage of entities in limited withed units + + if Ekind (P_Name) = E_Package + and then From_With_Type (P_Name) + then + if From_With_Type (Id) + or else Is_Type (Id) + or else Ekind (Id) = E_Package + then + null; + else + Error_Msg_N + ("limited withed package can only be used to access " + & "incomplete types", + N); + end if; + end if; + + if Is_Task_Type (P_Name) + and then ((Ekind (Id) = E_Entry + and then Nkind (Parent (N)) /= N_Attribute_Reference) + or else + (Ekind (Id) = E_Entry_Family + and then + Nkind (Parent (Parent (N))) /= N_Attribute_Reference)) + then + -- If both the task type and the entry are in scope, this may still + -- be the expanded name of an entry formal. + + if In_Open_Scopes (Id) + and then Nkind (Parent (N)) = N_Selected_Component + then + null; + + else + -- It is an entry call after all, either to the current task + -- (which will deadlock) or to an enclosing task. + + Analyze_Selected_Component (N); + return; + end if; + end if; + + Change_Selected_Component_To_Expanded_Name (N); + + -- Do style check and generate reference, but skip both steps if this + -- entity has homonyms, since we may not have the right homonym set yet. + -- The proper homonym will be set during the resolve phase. + + if Has_Homonym (Id) then + Set_Entity (N, Id); + else + Set_Entity_Or_Discriminal (N, Id); + + if Is_LHS (N) then + Generate_Reference (Id, N, 'm'); + else + Generate_Reference (Id, N); + end if; + end if; + + if Is_Type (Id) then + Set_Etype (N, Id); + else + Set_Etype (N, Get_Full_View (Etype (Id))); + end if; + + -- Check for violation of No_Wide_Characters + + Check_Wide_Character_Restriction (Id, N); + + -- If the Ekind of the entity is Void, it means that all homonyms are + -- hidden from all visibility (RM 8.3(5,14-20)). + + if Ekind (Id) = E_Void then + Premature_Usage (N); + + elsif Is_Overloadable (Id) + and then Present (Homonym (Id)) + then + declare + H : Entity_Id := Homonym (Id); + + begin + while Present (H) loop + if Scope (H) = Scope (Id) + and then + (not Is_Hidden (H) + or else Is_Immediately_Visible (H)) + then + Collect_Interps (N); + exit; + end if; + + H := Homonym (H); + end loop; + + -- If an extension of System is present, collect possible explicit + -- overloadings declared in the extension. + + if Chars (P_Name) = Name_System + and then Scope (P_Name) = Standard_Standard + and then Present (System_Extend_Unit) + and then Present_System_Aux (N) + then + H := Current_Entity (Id); + + while Present (H) loop + if Scope (H) = System_Aux_Id then + Add_One_Interp (N, H, Etype (H)); + end if; + + H := Homonym (H); + end loop; + end if; + end; + end if; + + if Nkind (Selector_Name (N)) = N_Operator_Symbol + and then Scope (Id) /= Standard_Standard + then + -- In addition to user-defined operators in the given scope, there + -- may be an implicit instance of the predefined operator. The + -- operator (defined in Standard) is found in Has_Implicit_Operator, + -- and added to the interpretations. Procedure Add_One_Interp will + -- determine which hides which. + + if Has_Implicit_Operator (N) then + null; + end if; + end if; + + -- If there is a single interpretation for N we can generate a + -- reference to the unique entity found. + + if Is_Overloadable (Id) and then not Is_Overloaded (N) then + Generate_Reference (Id, N); + end if; + end Find_Expanded_Name; + + ------------------------- + -- Find_Renamed_Entity -- + ------------------------- + + function Find_Renamed_Entity + (N : Node_Id; + Nam : Node_Id; + New_S : Entity_Id; + Is_Actual : Boolean := False) return Entity_Id + is + Ind : Interp_Index; + I1 : Interp_Index := 0; -- Suppress junk warnings + It : Interp; + It1 : Interp; + Old_S : Entity_Id; + Inst : Entity_Id; + + function Enclosing_Instance return Entity_Id; + -- If the renaming determines the entity for the default of a formal + -- subprogram nested within another instance, choose the innermost + -- candidate. This is because if the formal has a box, and we are within + -- an enclosing instance where some candidate interpretations are local + -- to this enclosing instance, we know that the default was properly + -- resolved when analyzing the generic, so we prefer the local + -- candidates to those that are external. This is not always the case + -- but is a reasonable heuristic on the use of nested generics. The + -- proper solution requires a full renaming model. + + function Is_Visible_Operation (Op : Entity_Id) return Boolean; + -- If the renamed entity is an implicit operator, check whether it is + -- visible because its operand type is properly visible. This check + -- applies to explicit renamed entities that appear in the source in a + -- renaming declaration or a formal subprogram instance, but not to + -- default generic actuals with a name. + + function Report_Overload return Entity_Id; + -- List possible interpretations, and specialize message in the + -- case of a generic actual. + + function Within (Inner, Outer : Entity_Id) return Boolean; + -- Determine whether a candidate subprogram is defined within the + -- enclosing instance. If yes, it has precedence over outer candidates. + + ------------------------ + -- Enclosing_Instance -- + ------------------------ + + function Enclosing_Instance return Entity_Id is + S : Entity_Id; + + begin + if not Is_Generic_Instance (Current_Scope) + and then not Is_Actual + then + return Empty; + end if; + + S := Scope (Current_Scope); + while S /= Standard_Standard loop + if Is_Generic_Instance (S) then + return S; + end if; + + S := Scope (S); + end loop; + + return Empty; + end Enclosing_Instance; + + -------------------------- + -- Is_Visible_Operation -- + -------------------------- + + function Is_Visible_Operation (Op : Entity_Id) return Boolean is + Scop : Entity_Id; + Typ : Entity_Id; + Btyp : Entity_Id; + + begin + if Ekind (Op) /= E_Operator + or else Scope (Op) /= Standard_Standard + or else (In_Instance + and then + (not Is_Actual + or else Present (Enclosing_Instance))) + then + return True; + + else + -- For a fixed point type operator, check the resulting type, + -- because it may be a mixed mode integer * fixed operation. + + if Present (Next_Formal (First_Formal (New_S))) + and then Is_Fixed_Point_Type (Etype (New_S)) + then + Typ := Etype (New_S); + else + Typ := Etype (First_Formal (New_S)); + end if; + + Btyp := Base_Type (Typ); + + if Nkind (Nam) /= N_Expanded_Name then + return (In_Open_Scopes (Scope (Btyp)) + or else Is_Potentially_Use_Visible (Btyp) + or else In_Use (Btyp) + or else In_Use (Scope (Btyp))); + + else + Scop := Entity (Prefix (Nam)); + + if Ekind (Scop) = E_Package + and then Present (Renamed_Object (Scop)) + then + Scop := Renamed_Object (Scop); + end if; + + -- Operator is visible if prefix of expanded name denotes + -- scope of type, or else type is defined in System_Aux + -- and the prefix denotes System. + + return Scope (Btyp) = Scop + or else (Scope (Btyp) = System_Aux_Id + and then Scope (Scope (Btyp)) = Scop); + end if; + end if; + end Is_Visible_Operation; + + ------------ + -- Within -- + ------------ + + function Within (Inner, Outer : Entity_Id) return Boolean is + Sc : Entity_Id; + + begin + Sc := Scope (Inner); + while Sc /= Standard_Standard loop + if Sc = Outer then + return True; + else + Sc := Scope (Sc); + end if; + end loop; + + return False; + end Within; + + --------------------- + -- Report_Overload -- + --------------------- + + function Report_Overload return Entity_Id is + begin + if Is_Actual then + Error_Msg_NE -- CODEFIX + ("ambiguous actual subprogram&, " & + "possible interpretations:", N, Nam); + else + Error_Msg_N -- CODEFIX + ("ambiguous subprogram, " & + "possible interpretations:", N); + end if; + + List_Interps (Nam, N); + return Old_S; + end Report_Overload; + + -- Start of processing for Find_Renamed_Entity + + begin + Old_S := Any_Id; + Candidate_Renaming := Empty; + + if not Is_Overloaded (Nam) then + if Entity_Matches_Spec (Entity (Nam), New_S) then + Candidate_Renaming := New_S; + + if Is_Visible_Operation (Entity (Nam)) then + Old_S := Entity (Nam); + end if; + + elsif + Present (First_Formal (Entity (Nam))) + and then Present (First_Formal (New_S)) + and then (Base_Type (Etype (First_Formal (Entity (Nam)))) + = Base_Type (Etype (First_Formal (New_S)))) + then + Candidate_Renaming := Entity (Nam); + end if; + + else + Get_First_Interp (Nam, Ind, It); + while Present (It.Nam) loop + if Entity_Matches_Spec (It.Nam, New_S) + and then Is_Visible_Operation (It.Nam) + then + if Old_S /= Any_Id then + + -- Note: The call to Disambiguate only happens if a + -- previous interpretation was found, in which case I1 + -- has received a value. + + It1 := Disambiguate (Nam, I1, Ind, Etype (Old_S)); + + if It1 = No_Interp then + Inst := Enclosing_Instance; + + if Present (Inst) then + if Within (It.Nam, Inst) then + if Within (Old_S, Inst) then + + -- Choose the innermost subprogram, which would + -- have hidden the outer one in the generic. + + if Scope_Depth (It.Nam) < + Scope_Depth (Old_S) + then + return Old_S; + else + return It.Nam; + end if; + end if; + + elsif Within (Old_S, Inst) then + return (Old_S); + + else + return Report_Overload; + end if; + + -- If not within an instance, ambiguity is real + + else + return Report_Overload; + end if; + + else + Old_S := It1.Nam; + exit; + end if; + + else + I1 := Ind; + Old_S := It.Nam; + end if; + + elsif + Present (First_Formal (It.Nam)) + and then Present (First_Formal (New_S)) + and then (Base_Type (Etype (First_Formal (It.Nam))) + = Base_Type (Etype (First_Formal (New_S)))) + then + Candidate_Renaming := It.Nam; + end if; + + Get_Next_Interp (Ind, It); + end loop; + + Set_Entity (Nam, Old_S); + + if Old_S /= Any_Id then + Set_Is_Overloaded (Nam, False); + end if; + end if; + + return Old_S; + end Find_Renamed_Entity; + + ----------------------------- + -- Find_Selected_Component -- + ----------------------------- + + procedure Find_Selected_Component (N : Node_Id) is + P : constant Node_Id := Prefix (N); + + P_Name : Entity_Id; + -- Entity denoted by prefix + + P_Type : Entity_Id; + -- and its type + + Nam : Node_Id; + + begin + Analyze (P); + + if Nkind (P) = N_Error then + return; + end if; + + -- Selector name cannot be a character literal or an operator symbol in + -- SPARK, except for the operator symbol in a renaming. + + if Restriction_Check_Required (SPARK) then + if Nkind (Selector_Name (N)) = N_Character_Literal then + Check_SPARK_Restriction + ("character literal cannot be prefixed", N); + elsif Nkind (Selector_Name (N)) = N_Operator_Symbol + and then Nkind (Parent (N)) /= N_Subprogram_Renaming_Declaration + then + Check_SPARK_Restriction ("operator symbol cannot be prefixed", N); + end if; + end if; + + -- If the selector already has an entity, the node has been constructed + -- in the course of expansion, and is known to be valid. Do not verify + -- that it is defined for the type (it may be a private component used + -- in the expansion of record equality). + + if Present (Entity (Selector_Name (N))) then + if No (Etype (N)) + or else Etype (N) = Any_Type + then + declare + Sel_Name : constant Node_Id := Selector_Name (N); + Selector : constant Entity_Id := Entity (Sel_Name); + C_Etype : Node_Id; + + begin + Set_Etype (Sel_Name, Etype (Selector)); + + if not Is_Entity_Name (P) then + Resolve (P); + end if; + + -- Build an actual subtype except for the first parameter + -- of an init proc, where this actual subtype is by + -- definition incorrect, since the object is uninitialized + -- (and does not even have defined discriminants etc.) + + if Is_Entity_Name (P) + and then Ekind (Entity (P)) = E_Function + then + Nam := New_Copy (P); + + if Is_Overloaded (P) then + Save_Interps (P, Nam); + end if; + + Rewrite (P, + Make_Function_Call (Sloc (P), Name => Nam)); + Analyze_Call (P); + Analyze_Selected_Component (N); + return; + + elsif Ekind (Selector) = E_Component + and then (not Is_Entity_Name (P) + or else Chars (Entity (P)) /= Name_uInit) + then + -- Do not build the subtype when referencing components of + -- dispatch table wrappers. Required to avoid generating + -- elaboration code with HI runtimes. JVM and .NET use a + -- modified version of Ada.Tags which does not contain RE_ + -- Dispatch_Table_Wrapper and RE_No_Dispatch_Table_Wrapper. + -- Avoid raising RE_Not_Available exception in those cases. + + if VM_Target = No_VM + and then RTU_Loaded (Ada_Tags) + and then + ((RTE_Available (RE_Dispatch_Table_Wrapper) + and then Scope (Selector) = + RTE (RE_Dispatch_Table_Wrapper)) + or else + (RTE_Available (RE_No_Dispatch_Table_Wrapper) + and then Scope (Selector) = + RTE (RE_No_Dispatch_Table_Wrapper))) + then + C_Etype := Empty; + + else + C_Etype := + Build_Actual_Subtype_Of_Component + (Etype (Selector), N); + end if; + + else + C_Etype := Empty; + end if; + + if No (C_Etype) then + C_Etype := Etype (Selector); + else + Insert_Action (N, C_Etype); + C_Etype := Defining_Identifier (C_Etype); + end if; + + Set_Etype (N, C_Etype); + end; + + -- If this is the name of an entry or protected operation, and + -- the prefix is an access type, insert an explicit dereference, + -- so that entry calls are treated uniformly. + + if Is_Access_Type (Etype (P)) + and then Is_Concurrent_Type (Designated_Type (Etype (P))) + then + declare + New_P : constant Node_Id := + Make_Explicit_Dereference (Sloc (P), + Prefix => Relocate_Node (P)); + begin + Rewrite (P, New_P); + Set_Etype (P, Designated_Type (Etype (Prefix (P)))); + end; + end if; + + -- If the selected component appears within a default expression + -- and it has an actual subtype, the pre-analysis has not yet + -- completed its analysis, because Insert_Actions is disabled in + -- that context. Within the init proc of the enclosing type we + -- must complete this analysis, if an actual subtype was created. + + elsif Inside_Init_Proc then + declare + Typ : constant Entity_Id := Etype (N); + Decl : constant Node_Id := Declaration_Node (Typ); + begin + if Nkind (Decl) = N_Subtype_Declaration + and then not Analyzed (Decl) + and then Is_List_Member (Decl) + and then No (Parent (Decl)) + then + Remove (Decl); + Insert_Action (N, Decl); + end if; + end; + end if; + + return; + + elsif Is_Entity_Name (P) then + P_Name := Entity (P); + + -- The prefix may denote an enclosing type which is the completion + -- of an incomplete type declaration. + + if Is_Type (P_Name) then + Set_Entity (P, Get_Full_View (P_Name)); + Set_Etype (P, Entity (P)); + P_Name := Entity (P); + end if; + + P_Type := Base_Type (Etype (P)); + + if Debug_Flag_E then + Write_Str ("Found prefix type to be "); + Write_Entity_Info (P_Type, " "); Write_Eol; + end if; + + -- First check for components of a record object (not the + -- result of a call, which is handled below). + + if Is_Appropriate_For_Record (P_Type) + and then not Is_Overloadable (P_Name) + and then not Is_Type (P_Name) + then + -- Selected component of record. Type checking will validate + -- name of selector. + + -- ??? Could we rewrite an implicit dereference into an explicit + -- one here? + + Analyze_Selected_Component (N); + + -- Reference to type name in predicate/invariant expression + + elsif Is_Appropriate_For_Entry_Prefix (P_Type) + and then not In_Open_Scopes (P_Name) + and then (not Is_Concurrent_Type (Etype (P_Name)) + or else not In_Open_Scopes (Etype (P_Name))) + then + -- Call to protected operation or entry. Type checking is + -- needed on the prefix. + + Analyze_Selected_Component (N); + + elsif (In_Open_Scopes (P_Name) + and then Ekind (P_Name) /= E_Void + and then not Is_Overloadable (P_Name)) + or else (Is_Concurrent_Type (Etype (P_Name)) + and then In_Open_Scopes (Etype (P_Name))) + then + -- Prefix denotes an enclosing loop, block, or task, i.e. an + -- enclosing construct that is not a subprogram or accept. + + Find_Expanded_Name (N); + + elsif Ekind (P_Name) = E_Package then + Find_Expanded_Name (N); + + elsif Is_Overloadable (P_Name) then + + -- The subprogram may be a renaming (of an enclosing scope) as + -- in the case of the name of the generic within an instantiation. + + if Ekind_In (P_Name, E_Procedure, E_Function) + and then Present (Alias (P_Name)) + and then Is_Generic_Instance (Alias (P_Name)) + then + P_Name := Alias (P_Name); + end if; + + if Is_Overloaded (P) then + + -- The prefix must resolve to a unique enclosing construct + + declare + Found : Boolean := False; + Ind : Interp_Index; + It : Interp; + + begin + Get_First_Interp (P, Ind, It); + while Present (It.Nam) loop + if In_Open_Scopes (It.Nam) then + if Found then + Error_Msg_N ( + "prefix must be unique enclosing scope", N); + Set_Entity (N, Any_Id); + Set_Etype (N, Any_Type); + return; + + else + Found := True; + P_Name := It.Nam; + end if; + end if; + + Get_Next_Interp (Ind, It); + end loop; + end; + end if; + + if In_Open_Scopes (P_Name) then + Set_Entity (P, P_Name); + Set_Is_Overloaded (P, False); + Find_Expanded_Name (N); + + else + -- If no interpretation as an expanded name is possible, it + -- must be a selected component of a record returned by a + -- function call. Reformat prefix as a function call, the rest + -- is done by type resolution. If the prefix is procedure or + -- entry, as is P.X; this is an error. + + if Ekind (P_Name) /= E_Function + and then (not Is_Overloaded (P) + or else + Nkind (Parent (N)) = N_Procedure_Call_Statement) + then + -- Prefix may mention a package that is hidden by a local + -- declaration: let the user know. Scan the full homonym + -- chain, the candidate package may be anywhere on it. + + if Present (Homonym (Current_Entity (P_Name))) then + + P_Name := Current_Entity (P_Name); + + while Present (P_Name) loop + exit when Ekind (P_Name) = E_Package; + P_Name := Homonym (P_Name); + end loop; + + if Present (P_Name) then + Error_Msg_Sloc := Sloc (Entity (Prefix (N))); + + Error_Msg_NE + ("package& is hidden by declaration#", + N, P_Name); + + Set_Entity (Prefix (N), P_Name); + Find_Expanded_Name (N); + return; + else + P_Name := Entity (Prefix (N)); + end if; + end if; + + Error_Msg_NE + ("invalid prefix in selected component&", N, P_Name); + Change_Selected_Component_To_Expanded_Name (N); + Set_Entity (N, Any_Id); + Set_Etype (N, Any_Type); + + else + Nam := New_Copy (P); + Save_Interps (P, Nam); + Rewrite (P, + Make_Function_Call (Sloc (P), Name => Nam)); + Analyze_Call (P); + Analyze_Selected_Component (N); + end if; + end if; + + -- Remaining cases generate various error messages + + else + -- Format node as expanded name, to avoid cascaded errors + + Change_Selected_Component_To_Expanded_Name (N); + Set_Entity (N, Any_Id); + Set_Etype (N, Any_Type); + + -- Issue error message, but avoid this if error issued already. + -- Use identifier of prefix if one is available. + + if P_Name = Any_Id then + null; + + elsif Ekind (P_Name) = E_Void then + Premature_Usage (P); + + elsif Nkind (P) /= N_Attribute_Reference then + Error_Msg_N ( + "invalid prefix in selected component&", P); + + if Is_Access_Type (P_Type) + and then Ekind (Designated_Type (P_Type)) = E_Incomplete_Type + then + Error_Msg_N + ("\dereference must not be of an incomplete type " & + "(RM 3.10.1)", P); + end if; + + else + Error_Msg_N ( + "invalid prefix in selected component", P); + end if; + end if; + + -- Selector name is restricted in SPARK + + if Nkind (N) = N_Expanded_Name + and then Restriction_Check_Required (SPARK) + then + if Is_Subprogram (P_Name) then + Check_SPARK_Restriction + ("prefix of expanded name cannot be a subprogram", P); + elsif Ekind (P_Name) = E_Loop then + Check_SPARK_Restriction + ("prefix of expanded name cannot be a loop statement", P); + end if; + end if; + + else + -- If prefix is not the name of an entity, it must be an expression, + -- whose type is appropriate for a record. This is determined by + -- type resolution. + + Analyze_Selected_Component (N); + end if; + + Analyze_Dimension (N); + end Find_Selected_Component; + + --------------- + -- Find_Type -- + --------------- + + procedure Find_Type (N : Node_Id) is + C : Entity_Id; + Typ : Entity_Id; + T : Entity_Id; + T_Name : Entity_Id; + + begin + if N = Error then + return; + + elsif Nkind (N) = N_Attribute_Reference then + + -- Class attribute. This is not valid in Ada 83 mode, but we do not + -- need to enforce that at this point, since the declaration of the + -- tagged type in the prefix would have been flagged already. + + if Attribute_Name (N) = Name_Class then + Check_Restriction (No_Dispatch, N); + Find_Type (Prefix (N)); + + -- Propagate error from bad prefix + + if Etype (Prefix (N)) = Any_Type then + Set_Entity (N, Any_Type); + Set_Etype (N, Any_Type); + return; + end if; + + T := Base_Type (Entity (Prefix (N))); + + -- Case where type is not known to be tagged. Its appearance in + -- the prefix of the 'Class attribute indicates that the full view + -- will be tagged. + + if not Is_Tagged_Type (T) then + if Ekind (T) = E_Incomplete_Type then + + -- It is legal to denote the class type of an incomplete + -- type. The full type will have to be tagged, of course. + -- In Ada 2005 this usage is declared obsolescent, so we + -- warn accordingly. This usage is only legal if the type + -- is completed in the current scope, and not for a limited + -- view of a type. + + if Ada_Version >= Ada_2005 then + + -- Test whether the Available_View of a limited type view + -- is tagged, since the limited view may not be marked as + -- tagged if the type itself has an untagged incomplete + -- type view in its package. + + if From_With_Type (T) + and then not Is_Tagged_Type (Available_View (T)) + then + Error_Msg_N + ("prefix of Class attribute must be tagged", N); + Set_Etype (N, Any_Type); + Set_Entity (N, Any_Type); + return; + + -- ??? This test is temporarily disabled (always + -- False) because it causes an unwanted warning on + -- GNAT sources (built with -gnatg, which includes + -- Warn_On_Obsolescent_ Feature). Once this issue + -- is cleared in the sources, it can be enabled. + + elsif Warn_On_Obsolescent_Feature + and then False + then + Error_Msg_N + ("applying 'Class to an untagged incomplete type" + & " is an obsolescent feature (RM J.11)?r?", N); + end if; + end if; + + Set_Is_Tagged_Type (T); + Set_Direct_Primitive_Operations (T, New_Elmt_List); + Make_Class_Wide_Type (T); + Set_Entity (N, Class_Wide_Type (T)); + Set_Etype (N, Class_Wide_Type (T)); + + elsif Ekind (T) = E_Private_Type + and then not Is_Generic_Type (T) + and then In_Private_Part (Scope (T)) + then + -- The Class attribute can be applied to an untagged private + -- type fulfilled by a tagged type prior to the full type + -- declaration (but only within the parent package's private + -- part). Create the class-wide type now and check that the + -- full type is tagged later during its analysis. Note that + -- we do not mark the private type as tagged, unlike the + -- case of incomplete types, because the type must still + -- appear untagged to outside units. + + if No (Class_Wide_Type (T)) then + Make_Class_Wide_Type (T); + end if; + + Set_Entity (N, Class_Wide_Type (T)); + Set_Etype (N, Class_Wide_Type (T)); + + else + -- Should we introduce a type Any_Tagged and use Wrong_Type + -- here, it would be a bit more consistent??? + + Error_Msg_NE + ("tagged type required, found}", + Prefix (N), First_Subtype (T)); + Set_Entity (N, Any_Type); + return; + end if; + + -- Case of tagged type + + else + if Is_Concurrent_Type (T) then + if No (Corresponding_Record_Type (Entity (Prefix (N)))) then + + -- Previous error. Use current type, which at least + -- provides some operations. + + C := Entity (Prefix (N)); + + else + C := Class_Wide_Type + (Corresponding_Record_Type (Entity (Prefix (N)))); + end if; + + else + C := Class_Wide_Type (Entity (Prefix (N))); + end if; + + Set_Entity_With_Style_Check (N, C); + Generate_Reference (C, N); + Set_Etype (N, C); + end if; + + -- Base attribute, not allowed in Ada 83 + + elsif Attribute_Name (N) = Name_Base then + Error_Msg_Name_1 := Name_Base; + Check_SPARK_Restriction + ("attribute% is only allowed as prefix of another attribute", N); + + if Ada_Version = Ada_83 and then Comes_From_Source (N) then + Error_Msg_N + ("(Ada 83) Base attribute not allowed in subtype mark", N); + + else + Find_Type (Prefix (N)); + Typ := Entity (Prefix (N)); + + if Ada_Version >= Ada_95 + and then not Is_Scalar_Type (Typ) + and then not Is_Generic_Type (Typ) + then + Error_Msg_N + ("prefix of Base attribute must be scalar type", + Prefix (N)); + + elsif Warn_On_Redundant_Constructs + and then Base_Type (Typ) = Typ + then + Error_Msg_NE -- CODEFIX + ("redundant attribute, & is its own base type?r?", N, Typ); + end if; + + T := Base_Type (Typ); + + -- Rewrite attribute reference with type itself (see similar + -- processing in Analyze_Attribute, case Base). Preserve prefix + -- if present, for other legality checks. + + if Nkind (Prefix (N)) = N_Expanded_Name then + Rewrite (N, + Make_Expanded_Name (Sloc (N), + Chars => Chars (T), + Prefix => New_Copy (Prefix (Prefix (N))), + Selector_Name => New_Reference_To (T, Sloc (N)))); + + else + Rewrite (N, New_Reference_To (T, Sloc (N))); + end if; + + Set_Entity (N, T); + Set_Etype (N, T); + end if; + + elsif Attribute_Name (N) = Name_Stub_Type then + + -- This is handled in Analyze_Attribute + + Analyze (N); + + -- All other attributes are invalid in a subtype mark + + else + Error_Msg_N ("invalid attribute in subtype mark", N); + end if; + + else + Analyze (N); + + if Is_Entity_Name (N) then + T_Name := Entity (N); + else + Error_Msg_N ("subtype mark required in this context", N); + Set_Etype (N, Any_Type); + return; + end if; + + if T_Name = Any_Id or else Etype (N) = Any_Type then + + -- Undefined id. Make it into a valid type + + Set_Entity (N, Any_Type); + + elsif not Is_Type (T_Name) + and then T_Name /= Standard_Void_Type + then + Error_Msg_Sloc := Sloc (T_Name); + Error_Msg_N ("subtype mark required in this context", N); + Error_Msg_NE ("\\found & declared#", N, T_Name); + Set_Entity (N, Any_Type); + + else + -- If the type is an incomplete type created to handle + -- anonymous access components of a record type, then the + -- incomplete type is the visible entity and subsequent + -- references will point to it. Mark the original full + -- type as referenced, to prevent spurious warnings. + + if Is_Incomplete_Type (T_Name) + and then Present (Full_View (T_Name)) + and then not Comes_From_Source (T_Name) + then + Set_Referenced (Full_View (T_Name)); + end if; + + T_Name := Get_Full_View (T_Name); + + -- Ada 2005 (AI-251, AI-50217): Handle interfaces visible through + -- limited-with clauses + + if From_With_Type (T_Name) + and then Ekind (T_Name) in Incomplete_Kind + and then Present (Non_Limited_View (T_Name)) + and then Is_Interface (Non_Limited_View (T_Name)) + then + T_Name := Non_Limited_View (T_Name); + end if; + + if In_Open_Scopes (T_Name) then + if Ekind (Base_Type (T_Name)) = E_Task_Type then + + -- In Ada 2005, a task name can be used in an access + -- definition within its own body. It cannot be used + -- in the discriminant part of the task declaration, + -- nor anywhere else in the declaration because entries + -- cannot have access parameters. + + if Ada_Version >= Ada_2005 + and then Nkind (Parent (N)) = N_Access_Definition + then + Set_Entity (N, T_Name); + Set_Etype (N, T_Name); + + if Has_Completion (T_Name) then + return; + + else + Error_Msg_N + ("task type cannot be used as type mark " & + "within its own declaration", N); + end if; + + else + Error_Msg_N + ("task type cannot be used as type mark " & + "within its own spec or body", N); + end if; + + elsif Ekind (Base_Type (T_Name)) = E_Protected_Type then + + -- In Ada 2005, a protected name can be used in an access + -- definition within its own body. + + if Ada_Version >= Ada_2005 + and then Nkind (Parent (N)) = N_Access_Definition + then + Set_Entity (N, T_Name); + Set_Etype (N, T_Name); + return; + + else + Error_Msg_N + ("protected type cannot be used as type mark " & + "within its own spec or body", N); + end if; + + else + Error_Msg_N ("type declaration cannot refer to itself", N); + end if; + + Set_Etype (N, Any_Type); + Set_Entity (N, Any_Type); + Set_Error_Posted (T_Name); + return; + end if; + + Set_Entity (N, T_Name); + Set_Etype (N, T_Name); + end if; + end if; + + if Present (Etype (N)) and then Comes_From_Source (N) then + if Is_Fixed_Point_Type (Etype (N)) then + Check_Restriction (No_Fixed_Point, N); + elsif Is_Floating_Point_Type (Etype (N)) then + Check_Restriction (No_Floating_Point, N); + end if; + end if; + end Find_Type; + + ------------------------------------ + -- Has_Implicit_Character_Literal -- + ------------------------------------ + + function Has_Implicit_Character_Literal (N : Node_Id) return Boolean is + Id : Entity_Id; + Found : Boolean := False; + P : constant Entity_Id := Entity (Prefix (N)); + Priv_Id : Entity_Id := Empty; + + begin + if Ekind (P) = E_Package + and then not In_Open_Scopes (P) + then + Priv_Id := First_Private_Entity (P); + end if; + + if P = Standard_Standard then + Change_Selected_Component_To_Expanded_Name (N); + Rewrite (N, Selector_Name (N)); + Analyze (N); + Set_Etype (Original_Node (N), Standard_Character); + return True; + end if; + + Id := First_Entity (P); + while Present (Id) + and then Id /= Priv_Id + loop + if Is_Standard_Character_Type (Id) and then Is_Base_Type (Id) then + + -- We replace the node with the literal itself, resolve as a + -- character, and set the type correctly. + + if not Found then + Change_Selected_Component_To_Expanded_Name (N); + Rewrite (N, Selector_Name (N)); + Analyze (N); + Set_Etype (N, Id); + Set_Etype (Original_Node (N), Id); + Found := True; + + else + -- More than one type derived from Character in given scope. + -- Collect all possible interpretations. + + Add_One_Interp (N, Id, Id); + end if; + end if; + + Next_Entity (Id); + end loop; + + return Found; + end Has_Implicit_Character_Literal; + + ---------------------- + -- Has_Private_With -- + ---------------------- + + function Has_Private_With (E : Entity_Id) return Boolean is + Comp_Unit : constant Node_Id := Cunit (Current_Sem_Unit); + Item : Node_Id; + + begin + Item := First (Context_Items (Comp_Unit)); + while Present (Item) loop + if Nkind (Item) = N_With_Clause + and then Private_Present (Item) + and then Entity (Name (Item)) = E + then + return True; + end if; + + Next (Item); + end loop; + + return False; + end Has_Private_With; + + --------------------------- + -- Has_Implicit_Operator -- + --------------------------- + + function Has_Implicit_Operator (N : Node_Id) return Boolean is + Op_Id : constant Name_Id := Chars (Selector_Name (N)); + P : constant Entity_Id := Entity (Prefix (N)); + Id : Entity_Id; + Priv_Id : Entity_Id := Empty; + + procedure Add_Implicit_Operator + (T : Entity_Id; + Op_Type : Entity_Id := Empty); + -- Add implicit interpretation to node N, using the type for which a + -- predefined operator exists. If the operator yields a boolean type, + -- the Operand_Type is implicitly referenced by the operator, and a + -- reference to it must be generated. + + --------------------------- + -- Add_Implicit_Operator -- + --------------------------- + + procedure Add_Implicit_Operator + (T : Entity_Id; + Op_Type : Entity_Id := Empty) + is + Predef_Op : Entity_Id; + + begin + Predef_Op := Current_Entity (Selector_Name (N)); + + while Present (Predef_Op) + and then Scope (Predef_Op) /= Standard_Standard + loop + Predef_Op := Homonym (Predef_Op); + end loop; + + if Nkind (N) = N_Selected_Component then + Change_Selected_Component_To_Expanded_Name (N); + end if; + + -- If the context is an unanalyzed function call, determine whether + -- a binary or unary interpretation is required. + + if Nkind (Parent (N)) = N_Indexed_Component then + declare + Is_Binary_Call : constant Boolean := + Present + (Next (First (Expressions (Parent (N))))); + Is_Binary_Op : constant Boolean := + First_Entity + (Predef_Op) /= Last_Entity (Predef_Op); + Predef_Op2 : constant Entity_Id := Homonym (Predef_Op); + + begin + if Is_Binary_Call then + if Is_Binary_Op then + Add_One_Interp (N, Predef_Op, T); + else + Add_One_Interp (N, Predef_Op2, T); + end if; + + else + if not Is_Binary_Op then + Add_One_Interp (N, Predef_Op, T); + else + Add_One_Interp (N, Predef_Op2, T); + end if; + end if; + end; + + else + Add_One_Interp (N, Predef_Op, T); + + -- For operators with unary and binary interpretations, if + -- context is not a call, add both + + if Present (Homonym (Predef_Op)) then + Add_One_Interp (N, Homonym (Predef_Op), T); + end if; + end if; + + -- The node is a reference to a predefined operator, and + -- an implicit reference to the type of its operands. + + if Present (Op_Type) then + Generate_Operator_Reference (N, Op_Type); + else + Generate_Operator_Reference (N, T); + end if; + end Add_Implicit_Operator; + + -- Start of processing for Has_Implicit_Operator + + begin + if Ekind (P) = E_Package + and then not In_Open_Scopes (P) + then + Priv_Id := First_Private_Entity (P); + end if; + + Id := First_Entity (P); + + case Op_Id is + + -- Boolean operators: an implicit declaration exists if the scope + -- contains a declaration for a derived Boolean type, or for an + -- array of Boolean type. + + when Name_Op_And | Name_Op_Not | Name_Op_Or | Name_Op_Xor => + while Id /= Priv_Id loop + if Valid_Boolean_Arg (Id) and then Is_Base_Type (Id) then + Add_Implicit_Operator (Id); + return True; + end if; + + Next_Entity (Id); + end loop; + + -- Equality: look for any non-limited type (result is Boolean) + + when Name_Op_Eq | Name_Op_Ne => + while Id /= Priv_Id loop + if Is_Type (Id) + and then not Is_Limited_Type (Id) + and then Is_Base_Type (Id) + then + Add_Implicit_Operator (Standard_Boolean, Id); + return True; + end if; + + Next_Entity (Id); + end loop; + + -- Comparison operators: scalar type, or array of scalar + + when Name_Op_Lt | Name_Op_Le | Name_Op_Gt | Name_Op_Ge => + while Id /= Priv_Id loop + if (Is_Scalar_Type (Id) + or else (Is_Array_Type (Id) + and then Is_Scalar_Type (Component_Type (Id)))) + and then Is_Base_Type (Id) + then + Add_Implicit_Operator (Standard_Boolean, Id); + return True; + end if; + + Next_Entity (Id); + end loop; + + -- Arithmetic operators: any numeric type + + when Name_Op_Abs | + Name_Op_Add | + Name_Op_Mod | + Name_Op_Rem | + Name_Op_Subtract | + Name_Op_Multiply | + Name_Op_Divide | + Name_Op_Expon => + while Id /= Priv_Id loop + if Is_Numeric_Type (Id) and then Is_Base_Type (Id) then + Add_Implicit_Operator (Id); + return True; + end if; + + Next_Entity (Id); + end loop; + + -- Concatenation: any one-dimensional array type + + when Name_Op_Concat => + while Id /= Priv_Id loop + if Is_Array_Type (Id) + and then Number_Dimensions (Id) = 1 + and then Is_Base_Type (Id) + then + Add_Implicit_Operator (Id); + return True; + end if; + + Next_Entity (Id); + end loop; + + -- What is the others condition here? Should we be using a + -- subtype of Name_Id that would restrict to operators ??? + + when others => null; + end case; + + -- If we fall through, then we do not have an implicit operator + + return False; + + end Has_Implicit_Operator; + + ----------------------------------- + -- Has_Loop_In_Inner_Open_Scopes -- + ----------------------------------- + + function Has_Loop_In_Inner_Open_Scopes (S : Entity_Id) return Boolean is + begin + -- Several scope stacks are maintained by Scope_Stack. The base of the + -- currently active scope stack is denoted by the Is_Active_Stack_Base + -- flag in the scope stack entry. Note that the scope stacks used to + -- simply be delimited implicitly by the presence of Standard_Standard + -- at their base, but there now are cases where this is not sufficient + -- because Standard_Standard actually may appear in the middle of the + -- active set of scopes. + + for J in reverse 0 .. Scope_Stack.Last loop + + -- S was reached without seing a loop scope first + + if Scope_Stack.Table (J).Entity = S then + return False; + + -- S was not yet reached, so it contains at least one inner loop + + elsif Ekind (Scope_Stack.Table (J).Entity) = E_Loop then + return True; + end if; + + -- Check Is_Active_Stack_Base to tell us when to stop, as there are + -- cases where Standard_Standard appears in the middle of the active + -- set of scopes. This affects the declaration and overriding of + -- private inherited operations in instantiations of generic child + -- units. + + pragma Assert (not Scope_Stack.Table (J).Is_Active_Stack_Base); + end loop; + + raise Program_Error; -- unreachable + end Has_Loop_In_Inner_Open_Scopes; + + -------------------- + -- In_Open_Scopes -- + -------------------- + + function In_Open_Scopes (S : Entity_Id) return Boolean is + begin + -- Several scope stacks are maintained by Scope_Stack. The base of the + -- currently active scope stack is denoted by the Is_Active_Stack_Base + -- flag in the scope stack entry. Note that the scope stacks used to + -- simply be delimited implicitly by the presence of Standard_Standard + -- at their base, but there now are cases where this is not sufficient + -- because Standard_Standard actually may appear in the middle of the + -- active set of scopes. + + for J in reverse 0 .. Scope_Stack.Last loop + if Scope_Stack.Table (J).Entity = S then + return True; + end if; + + -- Check Is_Active_Stack_Base to tell us when to stop, as there are + -- cases where Standard_Standard appears in the middle of the active + -- set of scopes. This affects the declaration and overriding of + -- private inherited operations in instantiations of generic child + -- units. + + exit when Scope_Stack.Table (J).Is_Active_Stack_Base; + end loop; + + return False; + end In_Open_Scopes; + + ----------------------------- + -- Inherit_Renamed_Profile -- + ----------------------------- + + procedure Inherit_Renamed_Profile (New_S : Entity_Id; Old_S : Entity_Id) is + New_F : Entity_Id; + Old_F : Entity_Id; + Old_T : Entity_Id; + New_T : Entity_Id; + + begin + if Ekind (Old_S) = E_Operator then + New_F := First_Formal (New_S); + + while Present (New_F) loop + Set_Etype (New_F, Base_Type (Etype (New_F))); + Next_Formal (New_F); + end loop; + + Set_Etype (New_S, Base_Type (Etype (New_S))); + + else + New_F := First_Formal (New_S); + Old_F := First_Formal (Old_S); + + while Present (New_F) loop + New_T := Etype (New_F); + Old_T := Etype (Old_F); + + -- If the new type is a renaming of the old one, as is the + -- case for actuals in instances, retain its name, to simplify + -- later disambiguation. + + if Nkind (Parent (New_T)) = N_Subtype_Declaration + and then Is_Entity_Name (Subtype_Indication (Parent (New_T))) + and then Entity (Subtype_Indication (Parent (New_T))) = Old_T + then + null; + else + Set_Etype (New_F, Old_T); + end if; + + Next_Formal (New_F); + Next_Formal (Old_F); + end loop; + + if Ekind_In (Old_S, E_Function, E_Enumeration_Literal) then + Set_Etype (New_S, Etype (Old_S)); + end if; + end if; + end Inherit_Renamed_Profile; + + ---------------- + -- Initialize -- + ---------------- + + procedure Initialize is + begin + Urefs.Init; + end Initialize; + + ------------------------- + -- Install_Use_Clauses -- + ------------------------- + + procedure Install_Use_Clauses + (Clause : Node_Id; + Force_Installation : Boolean := False) + is + U : Node_Id; + P : Node_Id; + Id : Entity_Id; + + begin + U := Clause; + while Present (U) loop + + -- Case of USE package + + if Nkind (U) = N_Use_Package_Clause then + P := First (Names (U)); + while Present (P) loop + Id := Entity (P); + + if Ekind (Id) = E_Package then + if In_Use (Id) then + Note_Redundant_Use (P); + + elsif Present (Renamed_Object (Id)) + and then In_Use (Renamed_Object (Id)) + then + Note_Redundant_Use (P); + + elsif Force_Installation or else Applicable_Use (P) then + Use_One_Package (Id, U); + + end if; + end if; + + Next (P); + end loop; + + -- Case of USE TYPE + + else + P := First (Subtype_Marks (U)); + while Present (P) loop + if not Is_Entity_Name (P) + or else No (Entity (P)) + then + null; + + elsif Entity (P) /= Any_Type then + Use_One_Type (P); + end if; + + Next (P); + end loop; + end if; + + Next_Use_Clause (U); + end loop; + end Install_Use_Clauses; + + ------------------------------------- + -- Is_Appropriate_For_Entry_Prefix -- + ------------------------------------- + + function Is_Appropriate_For_Entry_Prefix (T : Entity_Id) return Boolean is + P_Type : Entity_Id := T; + + begin + if Is_Access_Type (P_Type) then + P_Type := Designated_Type (P_Type); + end if; + + return Is_Task_Type (P_Type) or else Is_Protected_Type (P_Type); + end Is_Appropriate_For_Entry_Prefix; + + ------------------------------- + -- Is_Appropriate_For_Record -- + ------------------------------- + + function Is_Appropriate_For_Record (T : Entity_Id) return Boolean is + + function Has_Components (T1 : Entity_Id) return Boolean; + -- Determine if given type has components (i.e. is either a record + -- type or a type that has discriminants). + + -------------------- + -- Has_Components -- + -------------------- + + function Has_Components (T1 : Entity_Id) return Boolean is + begin + return Is_Record_Type (T1) + or else (Is_Private_Type (T1) and then Has_Discriminants (T1)) + or else (Is_Task_Type (T1) and then Has_Discriminants (T1)) + or else (Is_Incomplete_Type (T1) + and then From_With_Type (T1) + and then Present (Non_Limited_View (T1)) + and then Is_Record_Type + (Get_Full_View (Non_Limited_View (T1)))); + end Has_Components; + + -- Start of processing for Is_Appropriate_For_Record + + begin + return + Present (T) + and then (Has_Components (T) + or else (Is_Access_Type (T) + and then Has_Components (Designated_Type (T)))); + end Is_Appropriate_For_Record; + + ------------------------ + -- Note_Redundant_Use -- + ------------------------ + + procedure Note_Redundant_Use (Clause : Node_Id) is + Pack_Name : constant Entity_Id := Entity (Clause); + Cur_Use : constant Node_Id := Current_Use_Clause (Pack_Name); + Decl : constant Node_Id := Parent (Clause); + + Prev_Use : Node_Id := Empty; + Redundant : Node_Id := Empty; + -- The Use_Clause which is actually redundant. In the simplest case it + -- is Pack itself, but when we compile a body we install its context + -- before that of its spec, in which case it is the use_clause in the + -- spec that will appear to be redundant, and we want the warning to be + -- placed on the body. Similar complications appear when the redundancy + -- is between a child unit and one of its ancestors. + + begin + Set_Redundant_Use (Clause, True); + + if not Comes_From_Source (Clause) + or else In_Instance + or else not Warn_On_Redundant_Constructs + then + return; + end if; + + if not Is_Compilation_Unit (Current_Scope) then + + -- If the use_clause is in an inner scope, it is made redundant by + -- some clause in the current context, with one exception: If we're + -- compiling a nested package body, and the use_clause comes from the + -- corresponding spec, the clause is not necessarily fully redundant, + -- so we should not warn. If a warning was warranted, it would have + -- been given when the spec was processed. + + if Nkind (Parent (Decl)) = N_Package_Specification then + declare + Package_Spec_Entity : constant Entity_Id := + Defining_Unit_Name (Parent (Decl)); + begin + if In_Package_Body (Package_Spec_Entity) then + return; + end if; + end; + end if; + + Redundant := Clause; + Prev_Use := Cur_Use; + + elsif Nkind (Unit (Cunit (Current_Sem_Unit))) = N_Package_Body then + declare + Cur_Unit : constant Unit_Number_Type := Get_Source_Unit (Cur_Use); + New_Unit : constant Unit_Number_Type := Get_Source_Unit (Clause); + Scop : Entity_Id; + + begin + if Cur_Unit = New_Unit then + + -- Redundant clause in same body + + Redundant := Clause; + Prev_Use := Cur_Use; + + elsif Cur_Unit = Current_Sem_Unit then + + -- If the new clause is not in the current unit it has been + -- analyzed first, and it makes the other one redundant. + -- However, if the new clause appears in a subunit, Cur_Unit + -- is still the parent, and in that case the redundant one + -- is the one appearing in the subunit. + + if Nkind (Unit (Cunit (New_Unit))) = N_Subunit then + Redundant := Clause; + Prev_Use := Cur_Use; + + -- Most common case: redundant clause in body, + -- original clause in spec. Current scope is spec entity. + + elsif + Current_Scope = + Defining_Entity ( + Unit (Library_Unit (Cunit (Current_Sem_Unit)))) + then + Redundant := Cur_Use; + Prev_Use := Clause; + + else + -- The new clause may appear in an unrelated unit, when + -- the parents of a generic are being installed prior to + -- instantiation. In this case there must be no warning. + -- We detect this case by checking whether the current top + -- of the stack is related to the current compilation. + + Scop := Current_Scope; + while Present (Scop) + and then Scop /= Standard_Standard + loop + if Is_Compilation_Unit (Scop) + and then not Is_Child_Unit (Scop) + then + return; + + elsif Scop = Cunit_Entity (Current_Sem_Unit) then + exit; + end if; + + Scop := Scope (Scop); + end loop; + + Redundant := Cur_Use; + Prev_Use := Clause; + end if; + + elsif New_Unit = Current_Sem_Unit then + Redundant := Clause; + Prev_Use := Cur_Use; + + else + -- Neither is the current unit, so they appear in parent or + -- sibling units. Warning will be emitted elsewhere. + + return; + end if; + end; + + elsif Nkind (Unit (Cunit (Current_Sem_Unit))) = N_Package_Declaration + and then Present (Parent_Spec (Unit (Cunit (Current_Sem_Unit)))) + then + -- Use_clause is in child unit of current unit, and the child unit + -- appears in the context of the body of the parent, so it has been + -- installed first, even though it is the redundant one. Depending on + -- their placement in the context, the visible or the private parts + -- of the two units, either might appear as redundant, but the + -- message has to be on the current unit. + + if Get_Source_Unit (Cur_Use) = Current_Sem_Unit then + Redundant := Cur_Use; + Prev_Use := Clause; + else + Redundant := Clause; + Prev_Use := Cur_Use; + end if; + + -- If the new use clause appears in the private part of a parent unit + -- it may appear to be redundant w.r.t. a use clause in a child unit, + -- but the previous use clause was needed in the visible part of the + -- child, and no warning should be emitted. + + if Nkind (Parent (Decl)) = N_Package_Specification + and then + List_Containing (Decl) = Private_Declarations (Parent (Decl)) + then + declare + Par : constant Entity_Id := Defining_Entity (Parent (Decl)); + Spec : constant Node_Id := + Specification (Unit (Cunit (Current_Sem_Unit))); + + begin + if Is_Compilation_Unit (Par) + and then Par /= Cunit_Entity (Current_Sem_Unit) + and then Parent (Cur_Use) = Spec + and then + List_Containing (Cur_Use) = Visible_Declarations (Spec) + then + return; + end if; + end; + end if; + + -- Finally, if the current use clause is in the context then + -- the clause is redundant when it is nested within the unit. + + elsif Nkind (Parent (Cur_Use)) = N_Compilation_Unit + and then Nkind (Parent (Parent (Clause))) /= N_Compilation_Unit + and then Get_Source_Unit (Cur_Use) = Get_Source_Unit (Clause) + then + Redundant := Clause; + Prev_Use := Cur_Use; + + else + null; + end if; + + if Present (Redundant) then + Error_Msg_Sloc := Sloc (Prev_Use); + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous use clause #??", + Redundant, Pack_Name); + end if; + end Note_Redundant_Use; + + --------------- + -- Pop_Scope -- + --------------- + + procedure Pop_Scope is + SST : Scope_Stack_Entry renames Scope_Stack.Table (Scope_Stack.Last); + S : constant Entity_Id := SST.Entity; + + begin + if Debug_Flag_E then + Write_Info; + end if; + + -- Set Default_Storage_Pool field of the library unit if necessary + + if Ekind_In (S, E_Package, E_Generic_Package) + and then + Nkind (Parent (Unit_Declaration_Node (S))) = N_Compilation_Unit + then + declare + Aux : constant Node_Id := + Aux_Decls_Node (Parent (Unit_Declaration_Node (S))); + begin + if No (Default_Storage_Pool (Aux)) then + Set_Default_Storage_Pool (Aux, Default_Pool); + end if; + end; + end if; + + Scope_Suppress := SST.Save_Scope_Suppress; + Local_Suppress_Stack_Top := SST.Save_Local_Suppress_Stack_Top; + Check_Policy_List := SST.Save_Check_Policy_List; + Default_Pool := SST.Save_Default_Storage_Pool; + + if Debug_Flag_W then + Write_Str ("<-- exiting scope: "); + Write_Name (Chars (Current_Scope)); + Write_Str (", Depth="); + Write_Int (Int (Scope_Stack.Last)); + Write_Eol; + end if; + + End_Use_Clauses (SST.First_Use_Clause); + + -- If the actions to be wrapped are still there they will get lost + -- causing incomplete code to be generated. It is better to abort in + -- this case (and we do the abort even with assertions off since the + -- penalty is incorrect code generation). + + if SST.Actions_To_Be_Wrapped_Before /= No_List + or else + SST.Actions_To_Be_Wrapped_After /= No_List + then + raise Program_Error; + end if; + + -- Free last subprogram name if allocated, and pop scope + + Free (SST.Last_Subprogram_Name); + Scope_Stack.Decrement_Last; + end Pop_Scope; + + --------------- + -- Push_Scope -- + --------------- + + procedure Push_Scope (S : Entity_Id) is + E : constant Entity_Id := Scope (S); + + begin + if Ekind (S) = E_Void then + null; + + -- Set scope depth if not a non-concurrent type, and we have not yet set + -- the scope depth. This means that we have the first occurrence of the + -- scope, and this is where the depth is set. + + elsif (not Is_Type (S) or else Is_Concurrent_Type (S)) + and then not Scope_Depth_Set (S) + then + if S = Standard_Standard then + Set_Scope_Depth_Value (S, Uint_0); + + elsif Is_Child_Unit (S) then + Set_Scope_Depth_Value (S, Uint_1); + + elsif not Is_Record_Type (Current_Scope) then + if Ekind (S) = E_Loop then + Set_Scope_Depth_Value (S, Scope_Depth (Current_Scope)); + else + Set_Scope_Depth_Value (S, Scope_Depth (Current_Scope) + 1); + end if; + end if; + end if; + + Scope_Stack.Increment_Last; + + declare + SST : Scope_Stack_Entry renames Scope_Stack.Table (Scope_Stack.Last); + + begin + SST.Entity := S; + SST.Save_Scope_Suppress := Scope_Suppress; + SST.Save_Local_Suppress_Stack_Top := Local_Suppress_Stack_Top; + SST.Save_Check_Policy_List := Check_Policy_List; + SST.Save_Default_Storage_Pool := Default_Pool; + + if Scope_Stack.Last > Scope_Stack.First then + SST.Component_Alignment_Default := Scope_Stack.Table + (Scope_Stack.Last - 1). + Component_Alignment_Default; + end if; + + SST.Last_Subprogram_Name := null; + SST.Is_Transient := False; + SST.Node_To_Be_Wrapped := Empty; + SST.Pending_Freeze_Actions := No_List; + SST.Actions_To_Be_Wrapped_Before := No_List; + SST.Actions_To_Be_Wrapped_After := No_List; + SST.First_Use_Clause := Empty; + SST.Is_Active_Stack_Base := False; + SST.Previous_Visibility := False; + end; + + if Debug_Flag_W then + Write_Str ("--> new scope: "); + Write_Name (Chars (Current_Scope)); + Write_Str (", Id="); + Write_Int (Int (Current_Scope)); + Write_Str (", Depth="); + Write_Int (Int (Scope_Stack.Last)); + Write_Eol; + end if; + + -- Deal with copying flags from the previous scope to this one. This is + -- not necessary if either scope is standard, or if the new scope is a + -- child unit. + + if S /= Standard_Standard + and then Scope (S) /= Standard_Standard + and then not Is_Child_Unit (S) + then + if Nkind (E) not in N_Entity then + return; + end if; + + -- Copy categorization flags from Scope (S) to S, this is not done + -- when Scope (S) is Standard_Standard since propagation is from + -- library unit entity inwards. Copy other relevant attributes as + -- well (Discard_Names in particular). + + -- We only propagate inwards for library level entities, + -- inner level subprograms do not inherit the categorization. + + if Is_Library_Level_Entity (S) then + Set_Is_Preelaborated (S, Is_Preelaborated (E)); + Set_Is_Shared_Passive (S, Is_Shared_Passive (E)); + Set_Discard_Names (S, Discard_Names (E)); + Set_Suppress_Value_Tracking_On_Call + (S, Suppress_Value_Tracking_On_Call (E)); + Set_Categorization_From_Scope (E => S, Scop => E); + end if; + end if; + + if Is_Child_Unit (S) + and then Present (E) + and then Ekind_In (E, E_Package, E_Generic_Package) + and then + Nkind (Parent (Unit_Declaration_Node (E))) = N_Compilation_Unit + then + declare + Aux : constant Node_Id := + Aux_Decls_Node (Parent (Unit_Declaration_Node (E))); + begin + if Present (Default_Storage_Pool (Aux)) then + Default_Pool := Default_Storage_Pool (Aux); + end if; + end; + end if; + end Push_Scope; + + --------------------- + -- Premature_Usage -- + --------------------- + + procedure Premature_Usage (N : Node_Id) is + Kind : constant Node_Kind := Nkind (Parent (Entity (N))); + E : Entity_Id := Entity (N); + + begin + -- Within an instance, the analysis of the actual for a formal object + -- does not see the name of the object itself. This is significant only + -- if the object is an aggregate, where its analysis does not do any + -- name resolution on component associations. (see 4717-008). In such a + -- case, look for the visible homonym on the chain. + + if In_Instance + and then Present (Homonym (E)) + then + E := Homonym (E); + + while Present (E) + and then not In_Open_Scopes (Scope (E)) + loop + E := Homonym (E); + end loop; + + if Present (E) then + Set_Entity (N, E); + Set_Etype (N, Etype (E)); + return; + end if; + end if; + + if Kind = N_Component_Declaration then + Error_Msg_N + ("component&! cannot be used before end of record declaration", N); + + elsif Kind = N_Parameter_Specification then + Error_Msg_N + ("formal parameter&! cannot be used before end of specification", + N); + + elsif Kind = N_Discriminant_Specification then + Error_Msg_N + ("discriminant&! cannot be used before end of discriminant part", + N); + + elsif Kind = N_Procedure_Specification + or else Kind = N_Function_Specification + then + Error_Msg_N + ("subprogram&! cannot be used before end of its declaration", + N); + + elsif Kind = N_Full_Type_Declaration then + Error_Msg_N + ("type& cannot be used before end of its declaration!", N); + + else + Error_Msg_N + ("object& cannot be used before end of its declaration!", N); + end if; + end Premature_Usage; + + ------------------------ + -- Present_System_Aux -- + ------------------------ + + function Present_System_Aux (N : Node_Id := Empty) return Boolean is + Loc : Source_Ptr; + Aux_Name : Unit_Name_Type; + Unum : Unit_Number_Type; + Withn : Node_Id; + With_Sys : Node_Id; + The_Unit : Node_Id; + + function Find_System (C_Unit : Node_Id) return Entity_Id; + -- Scan context clause of compilation unit to find with_clause + -- for System. + + ----------------- + -- Find_System -- + ----------------- + + function Find_System (C_Unit : Node_Id) return Entity_Id is + With_Clause : Node_Id; + + begin + With_Clause := First (Context_Items (C_Unit)); + while Present (With_Clause) loop + if (Nkind (With_Clause) = N_With_Clause + and then Chars (Name (With_Clause)) = Name_System) + and then Comes_From_Source (With_Clause) + then + return With_Clause; + end if; + + Next (With_Clause); + end loop; + + return Empty; + end Find_System; + + -- Start of processing for Present_System_Aux + + begin + -- The child unit may have been loaded and analyzed already + + if Present (System_Aux_Id) then + return True; + + -- If no previous pragma for System.Aux, nothing to load + + elsif No (System_Extend_Unit) then + return False; + + -- Use the unit name given in the pragma to retrieve the unit. + -- Verify that System itself appears in the context clause of the + -- current compilation. If System is not present, an error will + -- have been reported already. + + else + With_Sys := Find_System (Cunit (Current_Sem_Unit)); + + The_Unit := Unit (Cunit (Current_Sem_Unit)); + + if No (With_Sys) + and then + (Nkind (The_Unit) = N_Package_Body + or else (Nkind (The_Unit) = N_Subprogram_Body + and then + not Acts_As_Spec (Cunit (Current_Sem_Unit)))) + then + With_Sys := Find_System (Library_Unit (Cunit (Current_Sem_Unit))); + end if; + + if No (With_Sys) + and then Present (N) + then + -- If we are compiling a subunit, we need to examine its + -- context as well (Current_Sem_Unit is the parent unit); + + The_Unit := Parent (N); + while Nkind (The_Unit) /= N_Compilation_Unit loop + The_Unit := Parent (The_Unit); + end loop; + + if Nkind (Unit (The_Unit)) = N_Subunit then + With_Sys := Find_System (The_Unit); + end if; + end if; + + if No (With_Sys) then + return False; + end if; + + Loc := Sloc (With_Sys); + Get_Name_String (Chars (Expression (System_Extend_Unit))); + Name_Buffer (8 .. Name_Len + 7) := Name_Buffer (1 .. Name_Len); + Name_Buffer (1 .. 7) := "system."; + Name_Buffer (Name_Len + 8) := '%'; + Name_Buffer (Name_Len + 9) := 's'; + Name_Len := Name_Len + 9; + Aux_Name := Name_Find; + + Unum := + Load_Unit + (Load_Name => Aux_Name, + Required => False, + Subunit => False, + Error_Node => With_Sys); + + if Unum /= No_Unit then + Semantics (Cunit (Unum)); + System_Aux_Id := + Defining_Entity (Specification (Unit (Cunit (Unum)))); + + Withn := + Make_With_Clause (Loc, + Name => + Make_Expanded_Name (Loc, + Chars => Chars (System_Aux_Id), + Prefix => New_Reference_To (Scope (System_Aux_Id), Loc), + Selector_Name => New_Reference_To (System_Aux_Id, Loc))); + + Set_Entity (Name (Withn), System_Aux_Id); + + Set_Library_Unit (Withn, Cunit (Unum)); + Set_Corresponding_Spec (Withn, System_Aux_Id); + Set_First_Name (Withn, True); + Set_Implicit_With (Withn, True); + + Insert_After (With_Sys, Withn); + Mark_Rewrite_Insertion (Withn); + Set_Context_Installed (Withn); + + return True; + + -- Here if unit load failed + + else + Error_Msg_Name_1 := Name_System; + Error_Msg_Name_2 := Chars (Expression (System_Extend_Unit)); + Error_Msg_N + ("extension package `%.%` does not exist", + Opt.System_Extend_Unit); + return False; + end if; + end if; + end Present_System_Aux; + + ------------------------- + -- Restore_Scope_Stack -- + ------------------------- + + procedure Restore_Scope_Stack (Handle_Use : Boolean := True) is + E : Entity_Id; + S : Entity_Id; + Comp_Unit : Node_Id; + In_Child : Boolean := False; + Full_Vis : Boolean := True; + SS_Last : constant Int := Scope_Stack.Last; + + begin + -- Restore visibility of previous scope stack, if any + + for J in reverse 0 .. Scope_Stack.Last loop + exit when Scope_Stack.Table (J).Entity = Standard_Standard + or else No (Scope_Stack.Table (J).Entity); + + S := Scope_Stack.Table (J).Entity; + + if not Is_Hidden_Open_Scope (S) then + + -- If the parent scope is hidden, its entities are hidden as + -- well, unless the entity is the instantiation currently + -- being analyzed. + + if not Is_Hidden_Open_Scope (Scope (S)) + or else not Analyzed (Parent (S)) + or else Scope (S) = Standard_Standard + then + Set_Is_Immediately_Visible (S, True); + end if; + + E := First_Entity (S); + while Present (E) loop + if Is_Child_Unit (E) then + if not From_With_Type (E) then + Set_Is_Immediately_Visible (E, + Is_Visible_Lib_Unit (E) or else In_Open_Scopes (E)); + + else + pragma Assert + (Nkind (Parent (E)) = N_Defining_Program_Unit_Name + and then + Nkind (Parent (Parent (E))) = N_Package_Specification); + Set_Is_Immediately_Visible (E, + Limited_View_Installed (Parent (Parent (E)))); + end if; + else + Set_Is_Immediately_Visible (E, True); + end if; + + Next_Entity (E); + + if not Full_Vis + and then Is_Package_Or_Generic_Package (S) + then + -- We are in the visible part of the package scope + + exit when E = First_Private_Entity (S); + end if; + end loop; + + -- The visibility of child units (siblings of current compilation) + -- must be restored in any case. Their declarations may appear + -- after the private part of the parent. + + if not Full_Vis then + while Present (E) loop + if Is_Child_Unit (E) then + Set_Is_Immediately_Visible (E, + Is_Visible_Lib_Unit (E) or else In_Open_Scopes (E)); + end if; + + Next_Entity (E); + end loop; + end if; + end if; + + if Is_Child_Unit (S) + and not In_Child -- check only for current unit + then + In_Child := True; + + -- Restore visibility of parents according to whether the child + -- is private and whether we are in its visible part. + + Comp_Unit := Parent (Unit_Declaration_Node (S)); + + if Nkind (Comp_Unit) = N_Compilation_Unit + and then Private_Present (Comp_Unit) + then + Full_Vis := True; + + elsif Is_Package_Or_Generic_Package (S) + and then (In_Private_Part (S) or else In_Package_Body (S)) + then + Full_Vis := True; + + -- if S is the scope of some instance (which has already been + -- seen on the stack) it does not affect the visibility of + -- other scopes. + + elsif Is_Hidden_Open_Scope (S) then + null; + + elsif (Ekind (S) = E_Procedure + or else Ekind (S) = E_Function) + and then Has_Completion (S) + then + Full_Vis := True; + else + Full_Vis := False; + end if; + else + Full_Vis := True; + end if; + end loop; + + if SS_Last >= Scope_Stack.First + and then Scope_Stack.Table (SS_Last).Entity /= Standard_Standard + and then Handle_Use + then + Install_Use_Clauses (Scope_Stack.Table (SS_Last).First_Use_Clause); + end if; + end Restore_Scope_Stack; + + ---------------------- + -- Save_Scope_Stack -- + ---------------------- + + procedure Save_Scope_Stack (Handle_Use : Boolean := True) is + E : Entity_Id; + S : Entity_Id; + SS_Last : constant Int := Scope_Stack.Last; + + begin + if SS_Last >= Scope_Stack.First + and then Scope_Stack.Table (SS_Last).Entity /= Standard_Standard + then + if Handle_Use then + End_Use_Clauses (Scope_Stack.Table (SS_Last).First_Use_Clause); + end if; + + -- If the call is from within a compilation unit, as when called from + -- Rtsfind, make current entries in scope stack invisible while we + -- analyze the new unit. + + for J in reverse 0 .. SS_Last loop + exit when Scope_Stack.Table (J).Entity = Standard_Standard + or else No (Scope_Stack.Table (J).Entity); + + S := Scope_Stack.Table (J).Entity; + Set_Is_Immediately_Visible (S, False); + + E := First_Entity (S); + while Present (E) loop + Set_Is_Immediately_Visible (E, False); + Next_Entity (E); + end loop; + end loop; + + end if; + end Save_Scope_Stack; + + ------------- + -- Set_Use -- + ------------- + + procedure Set_Use (L : List_Id) is + Decl : Node_Id; + Pack_Name : Node_Id; + Pack : Entity_Id; + Id : Entity_Id; + + begin + if Present (L) then + Decl := First (L); + while Present (Decl) loop + if Nkind (Decl) = N_Use_Package_Clause then + Chain_Use_Clause (Decl); + + Pack_Name := First (Names (Decl)); + while Present (Pack_Name) loop + Pack := Entity (Pack_Name); + + if Ekind (Pack) = E_Package + and then Applicable_Use (Pack_Name) + then + Use_One_Package (Pack, Decl); + end if; + + Next (Pack_Name); + end loop; + + elsif Nkind (Decl) = N_Use_Type_Clause then + Chain_Use_Clause (Decl); + + Id := First (Subtype_Marks (Decl)); + while Present (Id) loop + if Entity (Id) /= Any_Type then + Use_One_Type (Id); + end if; + + Next (Id); + end loop; + end if; + + Next (Decl); + end loop; + end if; + end Set_Use; + + --------------------- + -- Use_One_Package -- + --------------------- + + procedure Use_One_Package (P : Entity_Id; N : Node_Id) is + Id : Entity_Id; + Prev : Entity_Id; + Current_Instance : Entity_Id := Empty; + Real_P : Entity_Id; + Private_With_OK : Boolean := False; + + begin + if Ekind (P) /= E_Package then + return; + end if; + + Set_In_Use (P); + Set_Current_Use_Clause (P, N); + + -- Ada 2005 (AI-50217): Check restriction + + if From_With_Type (P) then + Error_Msg_N ("limited withed package cannot appear in use clause", N); + end if; + + -- Find enclosing instance, if any + + if In_Instance then + Current_Instance := Current_Scope; + while not Is_Generic_Instance (Current_Instance) loop + Current_Instance := Scope (Current_Instance); + end loop; + + if No (Hidden_By_Use_Clause (N)) then + Set_Hidden_By_Use_Clause (N, New_Elmt_List); + end if; + end if; + + -- If unit is a package renaming, indicate that the renamed + -- package is also in use (the flags on both entities must + -- remain consistent, and a subsequent use of either of them + -- should be recognized as redundant). + + if Present (Renamed_Object (P)) then + Set_In_Use (Renamed_Object (P)); + Set_Current_Use_Clause (Renamed_Object (P), N); + Real_P := Renamed_Object (P); + else + Real_P := P; + end if; + + -- Ada 2005 (AI-262): Check the use_clause of a private withed package + -- found in the private part of a package specification + + if In_Private_Part (Current_Scope) + and then Has_Private_With (P) + and then Is_Child_Unit (Current_Scope) + and then Is_Child_Unit (P) + and then Is_Ancestor_Package (Scope (Current_Scope), P) + then + Private_With_OK := True; + end if; + + -- Loop through entities in one package making them potentially + -- use-visible. + + Id := First_Entity (P); + while Present (Id) + and then (Id /= First_Private_Entity (P) + or else Private_With_OK) -- Ada 2005 (AI-262) + loop + Prev := Current_Entity (Id); + while Present (Prev) loop + if Is_Immediately_Visible (Prev) + and then (not Is_Overloadable (Prev) + or else not Is_Overloadable (Id) + or else (Type_Conformant (Id, Prev))) + then + if No (Current_Instance) then + + -- Potentially use-visible entity remains hidden + + goto Next_Usable_Entity; + + -- A use clause within an instance hides outer global entities, + -- which are not used to resolve local entities in the + -- instance. Note that the predefined entities in Standard + -- could not have been hidden in the generic by a use clause, + -- and therefore remain visible. Other compilation units whose + -- entities appear in Standard must be hidden in an instance. + + -- To determine whether an entity is external to the instance + -- we compare the scope depth of its scope with that of the + -- current instance. However, a generic actual of a subprogram + -- instance is declared in the wrapper package but will not be + -- hidden by a use-visible entity. similarly, an entity that is + -- declared in an enclosing instance will not be hidden by an + -- an entity declared in a generic actual, which can only have + -- been use-visible in the generic and will not have hidden the + -- entity in the generic parent. + + -- If Id is called Standard, the predefined package with the + -- same name is in the homonym chain. It has to be ignored + -- because it has no defined scope (being the only entity in + -- the system with this mandated behavior). + + elsif not Is_Hidden (Id) + and then Present (Scope (Prev)) + and then not Is_Wrapper_Package (Scope (Prev)) + and then Scope_Depth (Scope (Prev)) < + Scope_Depth (Current_Instance) + and then (Scope (Prev) /= Standard_Standard + or else Sloc (Prev) > Standard_Location) + then + if In_Open_Scopes (Scope (Prev)) + and then Is_Generic_Instance (Scope (Prev)) + and then Present (Associated_Formal_Package (P)) + then + null; + + else + Set_Is_Potentially_Use_Visible (Id); + Set_Is_Immediately_Visible (Prev, False); + Append_Elmt (Prev, Hidden_By_Use_Clause (N)); + end if; + end if; + + -- A user-defined operator is not use-visible if the predefined + -- operator for the type is immediately visible, which is the case + -- if the type of the operand is in an open scope. This does not + -- apply to user-defined operators that have operands of different + -- types, because the predefined mixed mode operations (multiply + -- and divide) apply to universal types and do not hide anything. + + elsif Ekind (Prev) = E_Operator + and then Operator_Matches_Spec (Prev, Id) + and then In_Open_Scopes + (Scope (Base_Type (Etype (First_Formal (Id))))) + and then (No (Next_Formal (First_Formal (Id))) + or else Etype (First_Formal (Id)) + = Etype (Next_Formal (First_Formal (Id))) + or else Chars (Prev) = Name_Op_Expon) + then + goto Next_Usable_Entity; + + -- In an instance, two homonyms may become use_visible through the + -- actuals of distinct formal packages. In the generic, only the + -- current one would have been visible, so make the other one + -- not use_visible. + + elsif Present (Current_Instance) + and then Is_Potentially_Use_Visible (Prev) + and then not Is_Overloadable (Prev) + and then Scope (Id) /= Scope (Prev) + and then Used_As_Generic_Actual (Scope (Prev)) + and then Used_As_Generic_Actual (Scope (Id)) + and then not In_Same_List (Current_Use_Clause (Scope (Prev)), + Current_Use_Clause (Scope (Id))) + then + Set_Is_Potentially_Use_Visible (Prev, False); + Append_Elmt (Prev, Hidden_By_Use_Clause (N)); + end if; + + Prev := Homonym (Prev); + end loop; + + -- On exit, we know entity is not hidden, unless it is private + + if not Is_Hidden (Id) + and then ((not Is_Child_Unit (Id)) + or else Is_Visible_Lib_Unit (Id)) + then + Set_Is_Potentially_Use_Visible (Id); + + if Is_Private_Type (Id) + and then Present (Full_View (Id)) + then + Set_Is_Potentially_Use_Visible (Full_View (Id)); + end if; + end if; + + <<Next_Usable_Entity>> + Next_Entity (Id); + end loop; + + -- Child units are also made use-visible by a use clause, but they may + -- appear after all visible declarations in the parent entity list. + + while Present (Id) loop + if Is_Child_Unit (Id) and then Is_Visible_Lib_Unit (Id) then + Set_Is_Potentially_Use_Visible (Id); + end if; + + Next_Entity (Id); + end loop; + + if Chars (Real_P) = Name_System + and then Scope (Real_P) = Standard_Standard + and then Present_System_Aux (N) + then + Use_One_Package (System_Aux_Id, N); + end if; + + end Use_One_Package; + + ------------------ + -- Use_One_Type -- + ------------------ + + procedure Use_One_Type (Id : Node_Id; Installed : Boolean := False) is + Elmt : Elmt_Id; + Is_Known_Used : Boolean; + Op_List : Elist_Id; + T : Entity_Id; + + function Spec_Reloaded_For_Body return Boolean; + -- Determine whether the compilation unit is a package body and the use + -- type clause is in the spec of the same package. Even though the spec + -- was analyzed first, its context is reloaded when analysing the body. + + procedure Use_Class_Wide_Operations (Typ : Entity_Id); + -- AI05-150: if the use_type_clause carries the "all" qualifier, + -- class-wide operations of ancestor types are use-visible if the + -- ancestor type is visible. + + ---------------------------- + -- Spec_Reloaded_For_Body -- + ---------------------------- + + function Spec_Reloaded_For_Body return Boolean is + begin + if Nkind (Unit (Cunit (Current_Sem_Unit))) = N_Package_Body then + declare + Spec : constant Node_Id := + Parent (List_Containing (Parent (Id))); + + begin + -- Check whether type is declared in a package specification, + -- and current unit is the corresponding package body. The + -- use clauses themselves may be within a nested package. + + return + Nkind (Spec) = N_Package_Specification + and then + In_Same_Source_Unit (Corresponding_Body (Parent (Spec)), + Cunit_Entity (Current_Sem_Unit)); + end; + end if; + + return False; + end Spec_Reloaded_For_Body; + + ------------------------------- + -- Use_Class_Wide_Operations -- + ------------------------------- + + procedure Use_Class_Wide_Operations (Typ : Entity_Id) is + Scop : Entity_Id; + Ent : Entity_Id; + + function Is_Class_Wide_Operation_Of + (Op : Entity_Id; + T : Entity_Id) return Boolean; + -- Determine whether a subprogram has a class-wide parameter or + -- result that is T'Class. + + --------------------------------- + -- Is_Class_Wide_Operation_Of -- + --------------------------------- + + function Is_Class_Wide_Operation_Of + (Op : Entity_Id; + T : Entity_Id) return Boolean + is + Formal : Entity_Id; + + begin + Formal := First_Formal (Op); + while Present (Formal) loop + if Etype (Formal) = Class_Wide_Type (T) then + return True; + end if; + Next_Formal (Formal); + end loop; + + if Etype (Op) = Class_Wide_Type (T) then + return True; + end if; + + return False; + end Is_Class_Wide_Operation_Of; + + -- Start of processing for Use_Class_Wide_Operations + + begin + Scop := Scope (Typ); + if not Is_Hidden (Scop) then + Ent := First_Entity (Scop); + while Present (Ent) loop + if Is_Overloadable (Ent) + and then Is_Class_Wide_Operation_Of (Ent, Typ) + and then not Is_Potentially_Use_Visible (Ent) + then + Set_Is_Potentially_Use_Visible (Ent); + Append_Elmt (Ent, Used_Operations (Parent (Id))); + end if; + + Next_Entity (Ent); + end loop; + end if; + + if Is_Derived_Type (Typ) then + Use_Class_Wide_Operations (Etype (Base_Type (Typ))); + end if; + end Use_Class_Wide_Operations; + + -- Start of processing for Use_One_Type + + begin + -- It is the type determined by the subtype mark (8.4(8)) whose + -- operations become potentially use-visible. + + T := Base_Type (Entity (Id)); + + -- Either the type itself is used, the package where it is declared + -- is in use or the entity is declared in the current package, thus + -- use-visible. + + Is_Known_Used := + In_Use (T) + or else In_Use (Scope (T)) + or else Scope (T) = Current_Scope; + + Set_Redundant_Use (Id, + Is_Known_Used or else Is_Potentially_Use_Visible (T)); + + if Ekind (T) = E_Incomplete_Type then + Error_Msg_N ("premature usage of incomplete type", Id); + + elsif In_Open_Scopes (Scope (T)) then + null; + + -- A limited view cannot appear in a use_type clause. However, an access + -- type whose designated type is limited has the flag but is not itself + -- a limited view unless we only have a limited view of its enclosing + -- package. + + elsif From_With_Type (T) + and then From_With_Type (Scope (T)) + then + Error_Msg_N + ("incomplete type from limited view " + & "cannot appear in use clause", Id); + + -- If the subtype mark designates a subtype in a different package, + -- we have to check that the parent type is visible, otherwise the + -- use type clause is a noop. Not clear how to do that??? + + elsif not Redundant_Use (Id) then + Set_In_Use (T); + + -- If T is tagged, primitive operators on class-wide operands + -- are also available. + + if Is_Tagged_Type (T) then + Set_In_Use (Class_Wide_Type (T)); + end if; + + Set_Current_Use_Clause (T, Parent (Id)); + + -- Iterate over primitive operations of the type. If an operation is + -- already use_visible, it is the result of a previous use_clause, + -- and already appears on the corresponding entity chain. If the + -- clause is being reinstalled, operations are already use-visible. + + if Installed then + null; + + else + Op_List := Collect_Primitive_Operations (T); + Elmt := First_Elmt (Op_List); + while Present (Elmt) loop + if (Nkind (Node (Elmt)) = N_Defining_Operator_Symbol + or else Chars (Node (Elmt)) in Any_Operator_Name) + and then not Is_Hidden (Node (Elmt)) + and then not Is_Potentially_Use_Visible (Node (Elmt)) + then + Set_Is_Potentially_Use_Visible (Node (Elmt)); + Append_Elmt (Node (Elmt), Used_Operations (Parent (Id))); + + elsif Ada_Version >= Ada_2012 + and then All_Present (Parent (Id)) + and then not Is_Hidden (Node (Elmt)) + and then not Is_Potentially_Use_Visible (Node (Elmt)) + then + Set_Is_Potentially_Use_Visible (Node (Elmt)); + Append_Elmt (Node (Elmt), Used_Operations (Parent (Id))); + end if; + + Next_Elmt (Elmt); + end loop; + end if; + + if Ada_Version >= Ada_2012 + and then All_Present (Parent (Id)) + and then Is_Tagged_Type (T) + then + Use_Class_Wide_Operations (T); + end if; + end if; + + -- If warning on redundant constructs, check for unnecessary WITH + + if Warn_On_Redundant_Constructs + and then Is_Known_Used + + -- with P; with P; use P; + -- package P is package X is package body X is + -- type T ... use P.T; + + -- The compilation unit is the body of X. GNAT first compiles the + -- spec of X, then proceeds to the body. At that point P is marked + -- as use visible. The analysis then reinstalls the spec along with + -- its context. The use clause P.T is now recognized as redundant, + -- but in the wrong context. Do not emit a warning in such cases. + -- Do not emit a warning either if we are in an instance, there is + -- no redundancy between an outer use_clause and one that appears + -- within the generic. + + and then not Spec_Reloaded_For_Body + and then not In_Instance + then + -- The type already has a use clause + + if In_Use (T) then + + -- Case where we know the current use clause for the type + + if Present (Current_Use_Clause (T)) then + Use_Clause_Known : declare + Clause1 : constant Node_Id := Parent (Id); + Clause2 : constant Node_Id := Current_Use_Clause (T); + Ent1 : Entity_Id; + Ent2 : Entity_Id; + Err_No : Node_Id; + Unit1 : Node_Id; + Unit2 : Node_Id; + + function Entity_Of_Unit (U : Node_Id) return Entity_Id; + -- Return the appropriate entity for determining which unit + -- has a deeper scope: the defining entity for U, unless U + -- is a package instance, in which case we retrieve the + -- entity of the instance spec. + + -------------------- + -- Entity_Of_Unit -- + -------------------- + + function Entity_Of_Unit (U : Node_Id) return Entity_Id is + begin + if Nkind (U) = N_Package_Instantiation + and then Analyzed (U) + then + return Defining_Entity (Instance_Spec (U)); + else + return Defining_Entity (U); + end if; + end Entity_Of_Unit; + + -- Start of processing for Use_Clause_Known + + begin + -- If both current use type clause and the use type clause + -- for the type are at the compilation unit level, one of + -- the units must be an ancestor of the other, and the + -- warning belongs on the descendant. + + if Nkind (Parent (Clause1)) = N_Compilation_Unit + and then + Nkind (Parent (Clause2)) = N_Compilation_Unit + then + + -- If the unit is a subprogram body that acts as spec, + -- the context clause is shared with the constructed + -- subprogram spec. Clearly there is no redundancy. + + if Clause1 = Clause2 then + return; + end if; + + Unit1 := Unit (Parent (Clause1)); + Unit2 := Unit (Parent (Clause2)); + + -- If both clauses are on same unit, or one is the body + -- of the other, or one of them is in a subunit, report + -- redundancy on the later one. + + if Unit1 = Unit2 then + Error_Msg_Sloc := Sloc (Current_Use_Clause (T)); + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use_type_clause #??", Clause1, T); + return; + + elsif Nkind (Unit1) = N_Subunit then + Error_Msg_Sloc := Sloc (Current_Use_Clause (T)); + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use_type_clause #??", Clause1, T); + return; + + elsif Nkind_In (Unit2, N_Package_Body, N_Subprogram_Body) + and then Nkind (Unit1) /= Nkind (Unit2) + and then Nkind (Unit1) /= N_Subunit + then + Error_Msg_Sloc := Sloc (Clause1); + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use_type_clause #??", Current_Use_Clause (T), T); + return; + end if; + + -- There is a redundant use type clause in a child unit. + -- Determine which of the units is more deeply nested. + -- If a unit is a package instance, retrieve the entity + -- and its scope from the instance spec. + + Ent1 := Entity_Of_Unit (Unit1); + Ent2 := Entity_Of_Unit (Unit2); + + if Scope (Ent2) = Standard_Standard then + Error_Msg_Sloc := Sloc (Current_Use_Clause (T)); + Err_No := Clause1; + + elsif Scope (Ent1) = Standard_Standard then + Error_Msg_Sloc := Sloc (Id); + Err_No := Clause2; + + -- If both units are child units, we determine which one + -- is the descendant by the scope distance to the + -- ultimate parent unit. + + else + declare + S1, S2 : Entity_Id; + + begin + S1 := Scope (Ent1); + S2 := Scope (Ent2); + while Present (S1) + and then Present (S2) + and then S1 /= Standard_Standard + and then S2 /= Standard_Standard + loop + S1 := Scope (S1); + S2 := Scope (S2); + end loop; + + if S1 = Standard_Standard then + Error_Msg_Sloc := Sloc (Id); + Err_No := Clause2; + else + Error_Msg_Sloc := Sloc (Current_Use_Clause (T)); + Err_No := Clause1; + end if; + end; + end if; + + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use_type_clause #??", Err_No, Id); + + -- Case where current use type clause and the use type + -- clause for the type are not both at the compilation unit + -- level. In this case we don't have location information. + + else + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use type clause??", Id, T); + end if; + end Use_Clause_Known; + + -- Here if Current_Use_Clause is not set for T, another case + -- where we do not have the location information available. + + else + Error_Msg_NE -- CODEFIX + ("& is already use-visible through previous " + & "use type clause??", Id, T); + end if; + + -- The package where T is declared is already used + + elsif In_Use (Scope (T)) then + Error_Msg_Sloc := Sloc (Current_Use_Clause (Scope (T))); + Error_Msg_NE -- CODEFIX + ("& is already use-visible through package use clause #??", + Id, T); + + -- The current scope is the package where T is declared + + else + Error_Msg_Node_2 := Scope (T); + Error_Msg_NE -- CODEFIX + ("& is already use-visible inside package &??", Id, T); + end if; + end if; + end Use_One_Type; + + ---------------- + -- Write_Info -- + ---------------- + + procedure Write_Info is + Id : Entity_Id := First_Entity (Current_Scope); + + begin + -- No point in dumping standard entities + + if Current_Scope = Standard_Standard then + return; + end if; + + Write_Str ("========================================================"); + Write_Eol; + Write_Str (" Defined Entities in "); + Write_Name (Chars (Current_Scope)); + Write_Eol; + Write_Str ("========================================================"); + Write_Eol; + + if No (Id) then + Write_Str ("-- none --"); + Write_Eol; + + else + while Present (Id) loop + Write_Entity_Info (Id, " "); + Next_Entity (Id); + end loop; + end if; + + if Scope (Current_Scope) = Standard_Standard then + + -- Print information on the current unit itself + + Write_Entity_Info (Current_Scope, " "); + end if; + + Write_Eol; + end Write_Info; + + -------- + -- ws -- + -------- + + procedure ws is + S : Entity_Id; + begin + for J in reverse 1 .. Scope_Stack.Last loop + S := Scope_Stack.Table (J).Entity; + Write_Int (Int (S)); + Write_Str (" === "); + Write_Name (Chars (S)); + Write_Eol; + end loop; + end ws; + + -------- + -- we -- + -------- + + procedure we (S : Entity_Id) is + E : Entity_Id; + begin + E := First_Entity (S); + while Present (E) loop + Write_Int (Int (E)); + Write_Str (" === "); + Write_Name (Chars (E)); + Write_Eol; + Next_Entity (E); + end loop; + end we; +end Sem_Ch8; |