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|
------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- S E M _ C H 1 2 --
-- --
-- B o d y --
-- --
-- Copyright (C) 1992-2014, 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 Aspects; use Aspects;
with Atree; use Atree;
with Einfo; use Einfo;
with Elists; use Elists;
with Errout; use Errout;
with Expander; use Expander;
with Exp_Disp; use Exp_Disp;
with Exp_Util; use Exp_Util;
with Fname; use Fname;
with Fname.UF; use Fname.UF;
with Freeze; use Freeze;
with Itypes; use Itypes;
with Lib; use Lib;
with Lib.Load; use Lib.Load;
with Lib.Xref; use Lib.Xref;
with Nlists; use Nlists;
with Namet; use Namet;
with Nmake; use Nmake;
with Opt; use Opt;
with Rident; use Rident;
with Restrict; use Restrict;
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_Ch6; use Sem_Ch6;
with Sem_Ch7; use Sem_Ch7;
with Sem_Ch8; use Sem_Ch8;
with Sem_Ch10; use Sem_Ch10;
with Sem_Ch13; use Sem_Ch13;
with Sem_Dim; use Sem_Dim;
with Sem_Disp; use Sem_Disp;
with Sem_Elab; use Sem_Elab;
with Sem_Elim; use Sem_Elim;
with Sem_Eval; use Sem_Eval;
with Sem_Prag; use Sem_Prag;
with Sem_Res; use Sem_Res;
with Sem_Type; use Sem_Type;
with Sem_Util; use Sem_Util;
with Sem_Warn; use Sem_Warn;
with Stand; use Stand;
with Sinfo; use Sinfo;
with Sinfo.CN; use Sinfo.CN;
with Sinput; use Sinput;
with Sinput.L; use Sinput.L;
with Snames; use Snames;
with Stringt; use Stringt;
with Uname; use Uname;
with Table;
with Tbuild; use Tbuild;
with Uintp; use Uintp;
with Urealp; use Urealp;
with Warnsw; use Warnsw;
with GNAT.HTable;
package body Sem_Ch12 is
----------------------------------------------------------
-- Implementation of Generic Analysis and Instantiation --
----------------------------------------------------------
-- GNAT implements generics by macro expansion. No attempt is made to share
-- generic instantiations (for now). Analysis of a generic definition does
-- not perform any expansion action, but the expander must be called on the
-- tree for each instantiation, because the expansion may of course depend
-- on the generic actuals. All of this is best achieved as follows:
--
-- a) Semantic analysis of a generic unit is performed on a copy of the
-- tree for the generic unit. All tree modifications that follow analysis
-- do not affect the original tree. Links are kept between the original
-- tree and the copy, in order to recognize non-local references within
-- the generic, and propagate them to each instance (recall that name
-- resolution is done on the generic declaration: generics are not really
-- macros). This is summarized in the following diagram:
-- .-----------. .----------.
-- | semantic |<--------------| generic |
-- | copy | | unit |
-- | |==============>| |
-- |___________| global |__________|
-- references | | |
-- | | |
-- .-----|--|.
-- | .-----|---.
-- | | .----------.
-- | | | generic |
-- |__| | |
-- |__| instance |
-- |__________|
-- b) Each instantiation copies the original tree, and inserts into it a
-- series of declarations that describe the mapping between generic formals
-- and actuals. For example, a generic In OUT parameter is an object
-- renaming of the corresponding actual, etc. Generic IN parameters are
-- constant declarations.
-- c) In order to give the right visibility for these renamings, we use
-- a different scheme for package and subprogram instantiations. For
-- packages, the list of renamings is inserted into the package
-- specification, before the visible declarations of the package. The
-- renamings are analyzed before any of the text of the instance, and are
-- thus visible at the right place. Furthermore, outside of the instance,
-- the generic parameters are visible and denote their corresponding
-- actuals.
-- For subprograms, we create a container package to hold the renamings
-- and the subprogram instance itself. Analysis of the package makes the
-- renaming declarations visible to the subprogram. After analyzing the
-- package, the defining entity for the subprogram is touched-up so that
-- it appears declared in the current scope, and not inside the container
-- package.
-- If the instantiation is a compilation unit, the container package is
-- given the same name as the subprogram instance. This ensures that
-- the elaboration procedure called by the binder, using the compilation
-- unit name, calls in fact the elaboration procedure for the package.
-- Not surprisingly, private types complicate this approach. By saving in
-- the original generic object the non-local references, we guarantee that
-- the proper entities are referenced at the point of instantiation.
-- However, for private types, this by itself does not insure that the
-- proper VIEW of the entity is used (the full type may be visible at the
-- point of generic definition, but not at instantiation, or vice-versa).
-- In order to reference the proper view, we special-case any reference
-- to private types in the generic object, by saving both views, one in
-- the generic and one in the semantic copy. At time of instantiation, we
-- check whether the two views are consistent, and exchange declarations if
-- necessary, in order to restore the correct visibility. Similarly, if
-- the instance view is private when the generic view was not, we perform
-- the exchange. After completing the instantiation, we restore the
-- current visibility. The flag Has_Private_View marks identifiers in the
-- the generic unit that require checking.
-- Visibility within nested generic units requires special handling.
-- Consider the following scheme:
-- type Global is ... -- outside of generic unit.
-- generic ...
-- package Outer is
-- ...
-- type Semi_Global is ... -- global to inner.
-- generic ... -- 1
-- procedure inner (X1 : Global; X2 : Semi_Global);
-- procedure in2 is new inner (...); -- 4
-- end Outer;
-- package New_Outer is new Outer (...); -- 2
-- procedure New_Inner is new New_Outer.Inner (...); -- 3
-- The semantic analysis of Outer captures all occurrences of Global.
-- The semantic analysis of Inner (at 1) captures both occurrences of
-- Global and Semi_Global.
-- At point 2 (instantiation of Outer), we also produce a generic copy
-- of Inner, even though Inner is, at that point, not being instantiated.
-- (This is just part of the semantic analysis of New_Outer).
-- Critically, references to Global within Inner must be preserved, while
-- references to Semi_Global should not preserved, because they must now
-- resolve to an entity within New_Outer. To distinguish between these, we
-- use a global variable, Current_Instantiated_Parent, which is set when
-- performing a generic copy during instantiation (at 2). This variable is
-- used when performing a generic copy that is not an instantiation, but
-- that is nested within one, as the occurrence of 1 within 2. The analysis
-- of a nested generic only preserves references that are global to the
-- enclosing Current_Instantiated_Parent. We use the Scope_Depth value to
-- determine whether a reference is external to the given parent.
-- The instantiation at point 3 requires no special treatment. The method
-- works as well for further nestings of generic units, but of course the
-- variable Current_Instantiated_Parent must be stacked because nested
-- instantiations can occur, e.g. the occurrence of 4 within 2.
-- The instantiation of package and subprogram bodies is handled in a
-- similar manner, except that it is delayed until after semantic
-- analysis is complete. In this fashion complex cross-dependencies
-- between several package declarations and bodies containing generics
-- can be compiled which otherwise would diagnose spurious circularities.
-- For example, it is possible to compile two packages A and B that
-- have the following structure:
-- package A is package B is
-- generic ... generic ...
-- package G_A is package G_B is
-- with B; with A;
-- package body A is package body B is
-- package N_B is new G_B (..) package N_A is new G_A (..)
-- The table Pending_Instantiations in package Inline is used to keep
-- track of body instantiations that are delayed in this manner. Inline
-- handles the actual calls to do the body instantiations. This activity
-- is part of Inline, since the processing occurs at the same point, and
-- for essentially the same reason, as the handling of inlined routines.
----------------------------------------------
-- Detection of Instantiation Circularities --
----------------------------------------------
-- If we have a chain of instantiations that is circular, this is static
-- error which must be detected at compile time. The detection of these
-- circularities is carried out at the point that we insert a generic
-- instance spec or body. If there is a circularity, then the analysis of
-- the offending spec or body will eventually result in trying to load the
-- same unit again, and we detect this problem as we analyze the package
-- instantiation for the second time.
-- At least in some cases after we have detected the circularity, we get
-- into trouble if we try to keep going. The following flag is set if a
-- circularity is detected, and used to abandon compilation after the
-- messages have been posted.
Circularity_Detected : Boolean := False;
-- This should really be reset on encountering a new main unit, but in
-- practice we are not using multiple main units so it is not critical.
--------------------------------------------------
-- Formal packages and partial parameterization --
--------------------------------------------------
-- When compiling a generic, a formal package is a local instantiation. If
-- declared with a box, its generic formals are visible in the enclosing
-- generic. If declared with a partial list of actuals, those actuals that
-- are defaulted (covered by an Others clause, or given an explicit box
-- initialization) are also visible in the enclosing generic, while those
-- that have a corresponding actual are not.
-- In our source model of instantiation, the same visibility must be
-- present in the spec and body of an instance: the names of the formals
-- that are defaulted must be made visible within the instance, and made
-- invisible (hidden) after the instantiation is complete, so that they
-- are not accessible outside of the instance.
-- In a generic, a formal package is treated like a special instantiation.
-- Our Ada 95 compiler handled formals with and without box in different
-- ways. With partial parameterization, we use a single model for both.
-- We create a package declaration that consists of the specification of
-- the generic package, and a set of declarations that map the actuals
-- into local renamings, just as we do for bona fide instantiations. For
-- defaulted parameters and formals with a box, we copy directly the
-- declarations of the formal into this local package. The result is a
-- a package whose visible declarations may include generic formals. This
-- package is only used for type checking and visibility analysis, and
-- never reaches the back-end, so it can freely violate the placement
-- rules for generic formal declarations.
-- The list of declarations (renamings and copies of formals) is built
-- by Analyze_Associations, just as for regular instantiations.
-- At the point of instantiation, conformance checking must be applied only
-- to those parameters that were specified in the formal. We perform this
-- checking by creating another internal instantiation, this one including
-- only the renamings and the formals (the rest of the package spec is not
-- relevant to conformance checking). We can then traverse two lists: the
-- list of actuals in the instance that corresponds to the formal package,
-- and the list of actuals produced for this bogus instantiation. We apply
-- the conformance rules to those actuals that are not defaulted (i.e.
-- which still appear as generic formals.
-- When we compile an instance body we must make the right parameters
-- visible again. The predicate Is_Generic_Formal indicates which of the
-- formals should have its Is_Hidden flag reset.
-----------------------
-- Local subprograms --
-----------------------
procedure Abandon_Instantiation (N : Node_Id);
pragma No_Return (Abandon_Instantiation);
-- Posts an error message "instantiation abandoned" at the indicated node
-- and then raises the exception Instantiation_Error to do it.
procedure Analyze_Formal_Array_Type
(T : in out Entity_Id;
Def : Node_Id);
-- A formal array type is treated like an array type declaration, and
-- invokes Array_Type_Declaration (sem_ch3) whose first parameter is
-- in-out, because in the case of an anonymous type the entity is
-- actually created in the procedure.
-- The following procedures treat other kinds of formal parameters
procedure Analyze_Formal_Derived_Interface_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id);
procedure Analyze_Formal_Derived_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id);
procedure Analyze_Formal_Interface_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id);
-- The following subprograms create abbreviated declarations for formal
-- scalar types. We introduce an anonymous base of the proper class for
-- each of them, and define the formals as constrained first subtypes of
-- their bases. The bounds are expressions that are non-static in the
-- generic.
procedure Analyze_Formal_Decimal_Fixed_Point_Type
(T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Discrete_Type (T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Floating_Type (T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Signed_Integer_Type (T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Modular_Type (T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Ordinary_Fixed_Point_Type
(T : Entity_Id; Def : Node_Id);
procedure Analyze_Formal_Private_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id);
-- Creates a new private type, which does not require completion
procedure Analyze_Formal_Incomplete_Type (T : Entity_Id; Def : Node_Id);
-- Ada 2012: Creates a new incomplete type whose actual does not freeze
procedure Analyze_Generic_Formal_Part (N : Node_Id);
-- Analyze generic formal part
procedure Analyze_Generic_Access_Type (T : Entity_Id; Def : Node_Id);
-- Create a new access type with the given designated type
function Analyze_Associations
(I_Node : Node_Id;
Formals : List_Id;
F_Copy : List_Id) return List_Id;
-- At instantiation time, build the list of associations between formals
-- and actuals. Each association becomes a renaming declaration for the
-- formal entity. F_Copy is the analyzed list of formals in the generic
-- copy. It is used to apply legality checks to the actuals. I_Node is the
-- instantiation node itself.
procedure Analyze_Subprogram_Instantiation
(N : Node_Id;
K : Entity_Kind);
procedure Build_Instance_Compilation_Unit_Nodes
(N : Node_Id;
Act_Body : Node_Id;
Act_Decl : Node_Id);
-- This procedure is used in the case where the generic instance of a
-- subprogram body or package body is a library unit. In this case, the
-- original library unit node for the generic instantiation must be
-- replaced by the resulting generic body, and a link made to a new
-- compilation unit node for the generic declaration. The argument N is
-- the original generic instantiation. Act_Body and Act_Decl are the body
-- and declaration of the instance (either package body and declaration
-- nodes or subprogram body and declaration nodes depending on the case).
-- On return, the node N has been rewritten with the actual body.
procedure Check_Access_Definition (N : Node_Id);
-- Subsidiary routine to null exclusion processing. Perform an assertion
-- check on Ada version and the presence of an access definition in N.
procedure Check_Formal_Packages (P_Id : Entity_Id);
-- Apply the following to all formal packages in generic associations
procedure Check_Formal_Package_Instance
(Formal_Pack : Entity_Id;
Actual_Pack : Entity_Id);
-- Verify that the actuals of the actual instance match the actuals of
-- the template for a formal package that is not declared with a box.
procedure Check_Forward_Instantiation (Decl : Node_Id);
-- If the generic is a local entity and the corresponding body has not
-- been seen yet, flag enclosing packages to indicate that it will be
-- elaborated after the generic body. Subprograms declared in the same
-- package cannot be inlined by the front-end because front-end inlining
-- requires a strict linear order of elaboration.
function Check_Hidden_Primitives (Assoc_List : List_Id) return Elist_Id;
-- Check if some association between formals and actuals requires to make
-- visible primitives of a tagged type, and make those primitives visible.
-- Return the list of primitives whose visibility is modified (to restore
-- their visibility later through Restore_Hidden_Primitives). If no
-- candidate is found then return No_Elist.
procedure Check_Hidden_Child_Unit
(N : Node_Id;
Gen_Unit : Entity_Id;
Act_Decl_Id : Entity_Id);
-- If the generic unit is an implicit child instance within a parent
-- instance, we need to make an explicit test that it is not hidden by
-- a child instance of the same name and parent.
procedure Check_Generic_Actuals
(Instance : Entity_Id;
Is_Formal_Box : Boolean);
-- Similar to previous one. Check the actuals in the instantiation,
-- whose views can change between the point of instantiation and the point
-- of instantiation of the body. In addition, mark the generic renamings
-- as generic actuals, so that they are not compatible with other actuals.
-- Recurse on an actual that is a formal package whose declaration has
-- a box.
function Contains_Instance_Of
(Inner : Entity_Id;
Outer : Entity_Id;
N : Node_Id) return Boolean;
-- Inner is instantiated within the generic Outer. Check whether Inner
-- directly or indirectly contains an instance of Outer or of one of its
-- parents, in the case of a subunit. Each generic unit holds a list of
-- the entities instantiated within (at any depth). This procedure
-- determines whether the set of such lists contains a cycle, i.e. an
-- illegal circular instantiation.
function Denotes_Formal_Package
(Pack : Entity_Id;
On_Exit : Boolean := False;
Instance : Entity_Id := Empty) return Boolean;
-- Returns True if E is a formal package of an enclosing generic, or
-- the actual for such a formal in an enclosing instantiation. If such
-- a package is used as a formal in an nested generic, or as an actual
-- in a nested instantiation, the visibility of ITS formals should not
-- be modified. When called from within Restore_Private_Views, the flag
-- On_Exit is true, to indicate that the search for a possible enclosing
-- instance should ignore the current one. In that case Instance denotes
-- the declaration for which this is an actual. This declaration may be
-- an instantiation in the source, or the internal instantiation that
-- corresponds to the actual for a formal package.
function Earlier (N1, N2 : Node_Id) return Boolean;
-- Yields True if N1 and N2 appear in the same compilation unit,
-- ignoring subunits, and if N1 is to the left of N2 in a left-to-right
-- traversal of the tree for the unit. Used to determine the placement
-- of freeze nodes for instance bodies that may depend on other instances.
function Find_Actual_Type
(Typ : Entity_Id;
Gen_Type : Entity_Id) return Entity_Id;
-- When validating the actual types of a child instance, check whether
-- the formal is a formal type of the parent unit, and retrieve the current
-- actual for it. Typ is the entity in the analyzed formal type declaration
-- (component or index type of an array type, or designated type of an
-- access formal) and Gen_Type is the enclosing analyzed formal array
-- or access type. The desired actual may be a formal of a parent, or may
-- be declared in a formal package of a parent. In both cases it is a
-- generic actual type because it appears within a visible instance.
-- Finally, it may be declared in a parent unit without being a formal
-- of that unit, in which case it must be retrieved by visibility.
-- Ambiguities may still arise if two homonyms are declared in two formal
-- packages, and the prefix of the formal type may be needed to resolve
-- the ambiguity in the instance ???
function In_Same_Declarative_Part
(F_Node : Node_Id;
Inst : Node_Id) return Boolean;
-- True if the instantiation Inst and the given freeze_node F_Node appear
-- within the same declarative part, ignoring subunits, but with no inter-
-- vening subprograms or concurrent units. Used to find the proper plave
-- for the freeze node of an instance, when the generic is declared in a
-- previous instance. If predicate is true, the freeze node of the instance
-- can be placed after the freeze node of the previous instance, Otherwise
-- it has to be placed at the end of the current declarative part.
function In_Main_Context (E : Entity_Id) return Boolean;
-- Check whether an instantiation is in the context of the main unit.
-- Used to determine whether its body should be elaborated to allow
-- front-end inlining.
procedure Set_Instance_Env
(Gen_Unit : Entity_Id;
Act_Unit : Entity_Id);
-- Save current instance on saved environment, to be used to determine
-- the global status of entities in nested instances. Part of Save_Env.
-- called after verifying that the generic unit is legal for the instance,
-- The procedure also examines whether the generic unit is a predefined
-- unit, in order to set configuration switches accordingly. As a result
-- the procedure must be called after analyzing and freezing the actuals.
procedure Set_Instance_Of (A : Entity_Id; B : Entity_Id);
-- Associate analyzed generic parameter with corresponding
-- instance. Used for semantic checks at instantiation time.
function Has_Been_Exchanged (E : Entity_Id) return Boolean;
-- Traverse the Exchanged_Views list to see if a type was private
-- and has already been flipped during this phase of instantiation.
procedure Hide_Current_Scope;
-- When instantiating a generic child unit, the parent context must be
-- present, but the instance and all entities that may be generated
-- must be inserted in the current scope. We leave the current scope
-- on the stack, but make its entities invisible to avoid visibility
-- problems. This is reversed at the end of the instantiation. This is
-- not done for the instantiation of the bodies, which only require the
-- instances of the generic parents to be in scope.
procedure Install_Body
(Act_Body : Node_Id;
N : Node_Id;
Gen_Body : Node_Id;
Gen_Decl : Node_Id);
-- If the instantiation happens textually before the body of the generic,
-- the instantiation of the body must be analyzed after the generic body,
-- and not at the point of instantiation. Such early instantiations can
-- happen if the generic and the instance appear in a package declaration
-- because the generic body can only appear in the corresponding package
-- body. Early instantiations can also appear if generic, instance and
-- body are all in the declarative part of a subprogram or entry. Entities
-- of packages that are early instantiations are delayed, and their freeze
-- node appears after the generic body.
procedure Insert_Freeze_Node_For_Instance
(N : Node_Id;
F_Node : Node_Id);
-- N denotes a package or a subprogram instantiation and F_Node is the
-- associated freeze node. Insert the freeze node before the first source
-- body which follows immediately after N. If no such body is found, the
-- freeze node is inserted at the end of the declarative region which
-- contains N.
procedure Freeze_Subprogram_Body
(Inst_Node : Node_Id;
Gen_Body : Node_Id;
Pack_Id : Entity_Id);
-- The generic body may appear textually after the instance, including
-- in the proper body of a stub, or within a different package instance.
-- Given that the instance can only be elaborated after the generic, we
-- place freeze_nodes for the instance and/or for packages that may enclose
-- the instance and the generic, so that the back-end can establish the
-- proper order of elaboration.
procedure Init_Env;
-- Establish environment for subsequent instantiation. Separated from
-- Save_Env because data-structures for visibility handling must be
-- initialized before call to Check_Generic_Child_Unit.
procedure Install_Formal_Packages (Par : Entity_Id);
-- Install the visible part of any formal of the parent that is a formal
-- package. Note that for the case of a formal package with a box, this
-- includes the formal part of the formal package (12.7(10/2)).
procedure Install_Parent (P : Entity_Id; In_Body : Boolean := False);
-- When compiling an instance of a child unit the parent (which is
-- itself an instance) is an enclosing scope that must be made
-- immediately visible. This procedure is also used to install the non-
-- generic parent of a generic child unit when compiling its body, so
-- that full views of types in the parent are made visible.
procedure Remove_Parent (In_Body : Boolean := False);
-- Reverse effect after instantiation of child is complete
procedure Install_Hidden_Primitives
(Prims_List : in out Elist_Id;
Gen_T : Entity_Id;
Act_T : Entity_Id);
-- Remove suffix 'P' from hidden primitives of Act_T to match the
-- visibility of primitives of Gen_T. The list of primitives to which
-- the suffix is removed is added to Prims_List to restore them later.
procedure Restore_Hidden_Primitives (Prims_List : in out Elist_Id);
-- Restore suffix 'P' to primitives of Prims_List and leave Prims_List
-- set to No_Elist.
procedure Inline_Instance_Body
(N : Node_Id;
Gen_Unit : Entity_Id;
Act_Decl : Node_Id);
-- If front-end inlining is requested, instantiate the package body,
-- and preserve the visibility of its compilation unit, to insure
-- that successive instantiations succeed.
-- The functions Instantiate_XXX perform various legality checks and build
-- the declarations for instantiated generic parameters. In all of these
-- Formal is the entity in the generic unit, Actual is the entity of
-- expression in the generic associations, and Analyzed_Formal is the
-- formal in the generic copy, which contains the semantic information to
-- be used to validate the actual.
function Instantiate_Object
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return List_Id;
function Instantiate_Type
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id;
Actual_Decls : List_Id) return List_Id;
function Instantiate_Formal_Subprogram
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return Node_Id;
function Instantiate_Formal_Package
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return List_Id;
-- If the formal package is declared with a box, special visibility rules
-- apply to its formals: they are in the visible part of the package. This
-- is true in the declarative region of the formal package, that is to say
-- in the enclosing generic or instantiation. For an instantiation, the
-- parameters of the formal package are made visible in an explicit step.
-- Furthermore, if the actual has a visible USE clause, these formals must
-- be made potentially use-visible as well. On exit from the enclosing
-- instantiation, the reverse must be done.
-- For a formal package declared without a box, there are conformance rules
-- that apply to the actuals in the generic declaration and the actuals of
-- the actual package in the enclosing instantiation. The simplest way to
-- apply these rules is to repeat the instantiation of the formal package
-- in the context of the enclosing instance, and compare the generic
-- associations of this instantiation with those of the actual package.
-- This internal instantiation only needs to contain the renamings of the
-- formals: the visible and private declarations themselves need not be
-- created.
-- In Ada 2005, the formal package may be only partially parameterized.
-- In that case the visibility step must make visible those actuals whose
-- corresponding formals were given with a box. A final complication
-- involves inherited operations from formal derived types, which must
-- be visible if the type is.
function Is_In_Main_Unit (N : Node_Id) return Boolean;
-- Test if given node is in the main unit
procedure Load_Parent_Of_Generic
(N : Node_Id;
Spec : Node_Id;
Body_Optional : Boolean := False);
-- If the generic appears in a separate non-generic library unit, load the
-- corresponding body to retrieve the body of the generic. N is the node
-- for the generic instantiation, Spec is the generic package declaration.
--
-- Body_Optional is a flag that indicates that the body is being loaded to
-- ensure that temporaries are generated consistently when there are other
-- instances in the current declarative part that precede the one being
-- loaded. In that case a missing body is acceptable.
procedure Inherit_Context (Gen_Decl : Node_Id; Inst : Node_Id);
-- Add the context clause of the unit containing a generic unit to a
-- compilation unit that is, or contains, an instantiation.
function Get_Associated_Node (N : Node_Id) return Node_Id;
-- In order to propagate semantic information back from the analyzed copy
-- to the original generic, we maintain links between selected nodes in the
-- generic and their corresponding copies. At the end of generic analysis,
-- the routine Save_Global_References traverses the generic tree, examines
-- the semantic information, and preserves the links to those nodes that
-- contain global information. At instantiation, the information from the
-- associated node is placed on the new copy, so that name resolution is
-- not repeated.
--
-- Three kinds of source nodes have associated nodes:
--
-- a) those that can reference (denote) entities, that is identifiers,
-- character literals, expanded_names, operator symbols, operators,
-- and attribute reference nodes. These nodes have an Entity field
-- and are the set of nodes that are in N_Has_Entity.
--
-- b) aggregates (N_Aggregate and N_Extension_Aggregate)
--
-- c) selected components (N_Selected_Component)
--
-- For the first class, the associated node preserves the entity if it is
-- global. If the generic contains nested instantiations, the associated
-- node itself has been recopied, and a chain of them must be followed.
--
-- For aggregates, the associated node allows retrieval of the type, which
-- may otherwise not appear in the generic. The view of this type may be
-- different between generic and instantiation, and the full view can be
-- installed before the instantiation is analyzed. For aggregates of type
-- extensions, the same view exchange may have to be performed for some of
-- the ancestor types, if their view is private at the point of
-- instantiation.
--
-- Nodes that are selected components in the parse tree may be rewritten
-- as expanded names after resolution, and must be treated as potential
-- entity holders, which is why they also have an Associated_Node.
--
-- Nodes that do not come from source, such as freeze nodes, do not appear
-- in the generic tree, and need not have an associated node.
--
-- The associated node is stored in the Associated_Node field. Note that
-- this field overlaps Entity, which is fine, because the whole point is
-- that we don't need or want the normal Entity field in this situation.
procedure Map_Formal_Package_Entities (Form : Entity_Id; Act : Entity_Id);
-- Within the generic part, entities in the formal package are
-- visible. To validate subsequent type declarations, indicate
-- the correspondence between the entities in the analyzed formal,
-- and the entities in the actual package. There are three packages
-- involved in the instantiation of a formal package: the parent
-- generic P1 which appears in the generic declaration, the fake
-- instantiation P2 which appears in the analyzed generic, and whose
-- visible entities may be used in subsequent formals, and the actual
-- P3 in the instance. To validate subsequent formals, me indicate
-- that the entities in P2 are mapped into those of P3. The mapping of
-- entities has to be done recursively for nested packages.
procedure Move_Freeze_Nodes
(Out_Of : Entity_Id;
After : Node_Id;
L : List_Id);
-- Freeze nodes can be generated in the analysis of a generic unit, but
-- will not be seen by the back-end. It is necessary to move those nodes
-- to the enclosing scope if they freeze an outer entity. We place them
-- at the end of the enclosing generic package, which is semantically
-- neutral.
procedure Preanalyze_Actuals (N : Node_Id);
-- Analyze actuals to perform name resolution. Full resolution is done
-- later, when the expected types are known, but names have to be captured
-- before installing parents of generics, that are not visible for the
-- actuals themselves.
function True_Parent (N : Node_Id) return Node_Id;
-- For a subunit, return parent of corresponding stub, else return
-- parent of node.
procedure Valid_Default_Attribute (Nam : Entity_Id; Def : Node_Id);
-- Verify that an attribute that appears as the default for a formal
-- subprogram is a function or procedure with the correct profile.
-------------------------------------------
-- Data Structures for Generic Renamings --
-------------------------------------------
-- The map Generic_Renamings associates generic entities with their
-- corresponding actuals. Currently used to validate type instances. It
-- will eventually be used for all generic parameters to eliminate the
-- need for overload resolution in the instance.
type Assoc_Ptr is new Int;
Assoc_Null : constant Assoc_Ptr := -1;
type Assoc is record
Gen_Id : Entity_Id;
Act_Id : Entity_Id;
Next_In_HTable : Assoc_Ptr;
end record;
package Generic_Renamings is new Table.Table
(Table_Component_Type => Assoc,
Table_Index_Type => Assoc_Ptr,
Table_Low_Bound => 0,
Table_Initial => 10,
Table_Increment => 100,
Table_Name => "Generic_Renamings");
-- Variable to hold enclosing instantiation. When the environment is
-- saved for a subprogram inlining, the corresponding Act_Id is empty.
Current_Instantiated_Parent : Assoc := (Empty, Empty, Assoc_Null);
-- Hash table for associations
HTable_Size : constant := 37;
type HTable_Range is range 0 .. HTable_Size - 1;
procedure Set_Next_Assoc (E : Assoc_Ptr; Next : Assoc_Ptr);
function Next_Assoc (E : Assoc_Ptr) return Assoc_Ptr;
function Get_Gen_Id (E : Assoc_Ptr) return Entity_Id;
function Hash (F : Entity_Id) return HTable_Range;
package Generic_Renamings_HTable is new GNAT.HTable.Static_HTable (
Header_Num => HTable_Range,
Element => Assoc,
Elmt_Ptr => Assoc_Ptr,
Null_Ptr => Assoc_Null,
Set_Next => Set_Next_Assoc,
Next => Next_Assoc,
Key => Entity_Id,
Get_Key => Get_Gen_Id,
Hash => Hash,
Equal => "=");
Exchanged_Views : Elist_Id;
-- This list holds the private views that have been exchanged during
-- instantiation to restore the visibility of the generic declaration.
-- (see comments above). After instantiation, the current visibility is
-- reestablished by means of a traversal of this list.
Hidden_Entities : Elist_Id;
-- This list holds the entities of the current scope that are removed
-- from immediate visibility when instantiating a child unit. Their
-- visibility is restored in Remove_Parent.
-- Because instantiations can be recursive, the following must be saved
-- on entry and restored on exit from an instantiation (spec or body).
-- This is done by the two procedures Save_Env and Restore_Env. For
-- package and subprogram instantiations (but not for the body instances)
-- the action of Save_Env is done in two steps: Init_Env is called before
-- Check_Generic_Child_Unit, because setting the parent instances requires
-- that the visibility data structures be properly initialized. Once the
-- generic is unit is validated, Set_Instance_Env completes Save_Env.
Parent_Unit_Visible : Boolean := False;
-- Parent_Unit_Visible is used when the generic is a child unit, and
-- indicates whether the ultimate parent of the generic is visible in the
-- instantiation environment. It is used to reset the visibility of the
-- parent at the end of the instantiation (see Remove_Parent).
Instance_Parent_Unit : Entity_Id := Empty;
-- This records the ultimate parent unit of an instance of a generic
-- child unit and is used in conjunction with Parent_Unit_Visible to
-- indicate the unit to which the Parent_Unit_Visible flag corresponds.
type Instance_Env is record
Instantiated_Parent : Assoc;
Exchanged_Views : Elist_Id;
Hidden_Entities : Elist_Id;
Current_Sem_Unit : Unit_Number_Type;
Parent_Unit_Visible : Boolean := False;
Instance_Parent_Unit : Entity_Id := Empty;
Switches : Config_Switches_Type;
end record;
package Instance_Envs is new Table.Table (
Table_Component_Type => Instance_Env,
Table_Index_Type => Int,
Table_Low_Bound => 0,
Table_Initial => 32,
Table_Increment => 100,
Table_Name => "Instance_Envs");
procedure Restore_Private_Views
(Pack_Id : Entity_Id;
Is_Package : Boolean := True);
-- Restore the private views of external types, and unmark the generic
-- renamings of actuals, so that they become compatible subtypes again.
-- For subprograms, Pack_Id is the package constructed to hold the
-- renamings.
procedure Switch_View (T : Entity_Id);
-- Switch the partial and full views of a type and its private
-- dependents (i.e. its subtypes and derived types).
------------------------------------
-- Structures for Error Reporting --
------------------------------------
Instantiation_Node : Node_Id;
-- Used by subprograms that validate instantiation of formal parameters
-- where there might be no actual on which to place the error message.
-- Also used to locate the instantiation node for generic subunits.
Instantiation_Error : exception;
-- When there is a semantic error in the generic parameter matching,
-- there is no point in continuing the instantiation, because the
-- number of cascaded errors is unpredictable. This exception aborts
-- the instantiation process altogether.
S_Adjustment : Sloc_Adjustment;
-- Offset created for each node in an instantiation, in order to keep
-- track of the source position of the instantiation in each of its nodes.
-- A subsequent semantic error or warning on a construct of the instance
-- points to both places: the original generic node, and the point of
-- instantiation. See Sinput and Sinput.L for additional details.
------------------------------------------------------------
-- Data structure for keeping track when inside a Generic --
------------------------------------------------------------
-- The following table is used to save values of the Inside_A_Generic
-- flag (see spec of Sem) when they are saved by Start_Generic.
package Generic_Flags is new Table.Table (
Table_Component_Type => Boolean,
Table_Index_Type => Int,
Table_Low_Bound => 0,
Table_Initial => 32,
Table_Increment => 200,
Table_Name => "Generic_Flags");
---------------------------
-- Abandon_Instantiation --
---------------------------
procedure Abandon_Instantiation (N : Node_Id) is
begin
Error_Msg_N ("\instantiation abandoned!", N);
raise Instantiation_Error;
end Abandon_Instantiation;
--------------------------
-- Analyze_Associations --
--------------------------
function Analyze_Associations
(I_Node : Node_Id;
Formals : List_Id;
F_Copy : List_Id) return List_Id
is
Actuals_To_Freeze : constant Elist_Id := New_Elmt_List;
Assoc : constant List_Id := New_List;
Default_Actuals : constant Elist_Id := New_Elmt_List;
Gen_Unit : constant Entity_Id :=
Defining_Entity (Parent (F_Copy));
Actuals : List_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id;
First_Named : Node_Id := Empty;
Formal : Node_Id;
Match : Node_Id;
Named : Node_Id;
Saved_Formal : Node_Id;
Default_Formals : constant List_Id := New_List;
-- If an Others_Choice is present, some of the formals may be defaulted.
-- To simplify the treatment of visibility in an instance, we introduce
-- individual defaults for each such formal. These defaults are
-- appended to the list of associations and replace the Others_Choice.
Found_Assoc : Node_Id;
-- Association for the current formal being match. Empty if there are
-- no remaining actuals, or if there is no named association with the
-- name of the formal.
Is_Named_Assoc : Boolean;
Num_Matched : Int := 0;
Num_Actuals : Int := 0;
Others_Present : Boolean := False;
Others_Choice : Node_Id := Empty;
-- In Ada 2005, indicates partial parameterization of a formal
-- package. As usual an other association must be last in the list.
function Build_Wrapper
(Formal : Entity_Id;
Actual : Entity_Id := Empty) return Node_Id;
-- In GNATProve mode, create a wrapper function for actuals that are
-- operators, in order to propagate their contract to the renaming
-- declarations generated for them. If the actual is absent, this is
-- a formal with a default, and the name of the operator is that of the
-- formal.
procedure Check_Overloaded_Formal_Subprogram (Formal : Entity_Id);
-- Apply RM 12.3 (9): if a formal subprogram is overloaded, the instance
-- cannot have a named association for it. AI05-0025 extends this rule
-- to formals of formal packages by AI05-0025, and it also applies to
-- box-initialized formals.
function Has_Fully_Defined_Profile (Subp : Entity_Id) return Boolean;
-- Determine whether the parameter types and the return type of Subp
-- are fully defined at the point of instantiation.
function Matching_Actual
(F : Entity_Id;
A_F : Entity_Id) return Node_Id;
-- Find actual that corresponds to a given a formal parameter. If the
-- actuals are positional, return the next one, if any. If the actuals
-- are named, scan the parameter associations to find the right one.
-- A_F is the corresponding entity in the analyzed generic,which is
-- placed on the selector name for ASIS use.
--
-- In Ada 2005, a named association may be given with a box, in which
-- case Matching_Actual sets Found_Assoc to the generic association,
-- but return Empty for the actual itself. In this case the code below
-- creates a corresponding declaration for the formal.
function Partial_Parameterization return Boolean;
-- Ada 2005: if no match is found for a given formal, check if the
-- association for it includes a box, or whether the associations
-- include an Others clause.
procedure Process_Default (F : Entity_Id);
-- Add a copy of the declaration of generic formal F to the list of
-- associations, and add an explicit box association for F if there
-- is none yet, and the default comes from an Others_Choice.
function Renames_Standard_Subprogram (Subp : Entity_Id) return Boolean;
-- Determine whether Subp renames one of the subprograms defined in the
-- generated package Standard.
procedure Set_Analyzed_Formal;
-- Find the node in the generic copy that corresponds to a given formal.
-- The semantic information on this node is used to perform legality
-- checks on the actuals. Because semantic analysis can introduce some
-- anonymous entities or modify the declaration node itself, the
-- correspondence between the two lists is not one-one. In addition to
-- anonymous types, the presence a formal equality will introduce an
-- implicit declaration for the corresponding inequality.
-------------------
-- Build_Wrapper --
-------------------
function Build_Wrapper
(Formal : Entity_Id;
Actual : Entity_Id := Empty) return Node_Id
is
Loc : constant Source_Ptr := Sloc (I_Node);
Typ : constant Entity_Id := Etype (Formal);
Is_Binary : constant Boolean :=
Present (Next_Formal (First_Formal (Formal)));
Decl : Node_Id;
Expr : Node_Id;
F1, F2 : Entity_Id;
Func : Entity_Id;
Op_Name : Name_Id;
Spec : Node_Id;
L, R : Node_Id;
begin
if No (Actual) then
Op_Name := Chars (Formal);
else
Op_Name := Chars (Actual);
end if;
-- Create entities for wrapper function and its formals
F1 := Make_Temporary (Loc, 'A');
F2 := Make_Temporary (Loc, 'B');
L := New_Occurrence_Of (F1, Loc);
R := New_Occurrence_Of (F2, Loc);
Func := Make_Defining_Identifier (Loc, Chars (Formal));
Set_Ekind (Func, E_Function);
Set_Is_Generic_Actual_Subprogram (Func);
Spec :=
Make_Function_Specification (Loc,
Defining_Unit_Name => Func,
Parameter_Specifications => New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier => F1,
Parameter_Type =>
Make_Identifier (Loc,
Chars => Chars (Etype (First_Formal (Formal)))))),
Result_Definition => Make_Identifier (Loc, Chars (Typ)));
if Is_Binary then
Append_To (Parameter_Specifications (Spec),
Make_Parameter_Specification (Loc,
Defining_Identifier => F2,
Parameter_Type =>
Make_Identifier (Loc,
Chars (Etype (Next_Formal (First_Formal (Formal)))))));
end if;
-- Build expression as a function call, or as an operator node
-- that corresponds to the name of the actual, starting with binary
-- operators.
if Present (Actual) and then Op_Name not in Any_Operator_Name then
Expr :=
Make_Function_Call (Loc,
Name =>
New_Occurrence_Of (Entity (Actual), Loc),
Parameter_Associations => New_List (L));
if Is_Binary then
Append_To (Parameter_Associations (Expr), R);
end if;
-- Binary operators
elsif Is_Binary then
if Op_Name = Name_Op_And then
Expr := Make_Op_And (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Or then
Expr := Make_Op_Or (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Xor then
Expr := Make_Op_Xor (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Eq then
Expr := Make_Op_Eq (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Ne then
Expr := Make_Op_Ne (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Le then
Expr := Make_Op_Le (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Gt then
Expr := Make_Op_Gt (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Ge then
Expr := Make_Op_Ge (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Lt then
Expr := Make_Op_Lt (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Add then
Expr := Make_Op_Add (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Subtract then
Expr := Make_Op_Subtract (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Concat then
Expr := Make_Op_Concat (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Multiply then
Expr := Make_Op_Multiply (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Divide then
Expr := Make_Op_Divide (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Mod then
Expr := Make_Op_Mod (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Rem then
Expr := Make_Op_Rem (Loc, Left_Opnd => L, Right_Opnd => R);
elsif Op_Name = Name_Op_Expon then
Expr := Make_Op_Expon (Loc, Left_Opnd => L, Right_Opnd => R);
end if;
-- Unary operators
else
if Op_Name = Name_Op_Add then
Expr := Make_Op_Plus (Loc, Right_Opnd => L);
elsif Op_Name = Name_Op_Subtract then
Expr := Make_Op_Minus (Loc, Right_Opnd => L);
elsif Op_Name = Name_Op_Abs then
Expr := Make_Op_Abs (Loc, Right_Opnd => L);
elsif Op_Name = Name_Op_Not then
Expr := Make_Op_Not (Loc, Right_Opnd => L);
end if;
end if;
-- Propagate visible entity to operator node, either from a
-- given actual or from a default.
if Is_Entity_Name (Actual) and then Nkind (Expr) in N_Op then
Set_Entity (Expr, Entity (Actual));
end if;
Decl :=
Make_Expression_Function (Loc,
Specification => Spec,
Expression => Expr);
return Decl;
end Build_Wrapper;
----------------------------------------
-- Check_Overloaded_Formal_Subprogram --
----------------------------------------
procedure Check_Overloaded_Formal_Subprogram (Formal : Entity_Id) is
Temp_Formal : Entity_Id;
begin
Temp_Formal := First (Formals);
while Present (Temp_Formal) loop
if Nkind (Temp_Formal) in N_Formal_Subprogram_Declaration
and then Temp_Formal /= Formal
and then
Chars (Defining_Unit_Name (Specification (Formal))) =
Chars (Defining_Unit_Name (Specification (Temp_Formal)))
then
if Present (Found_Assoc) then
Error_Msg_N
("named association not allowed for overloaded formal",
Found_Assoc);
else
Error_Msg_N
("named association not allowed for overloaded formal",
Others_Choice);
end if;
Abandon_Instantiation (Instantiation_Node);
end if;
Next (Temp_Formal);
end loop;
end Check_Overloaded_Formal_Subprogram;
-------------------------------
-- Has_Fully_Defined_Profile --
-------------------------------
function Has_Fully_Defined_Profile (Subp : Entity_Id) return Boolean is
function Is_Fully_Defined_Type (Typ : Entity_Id) return Boolean;
-- Determine whethet type Typ is fully defined
---------------------------
-- Is_Fully_Defined_Type --
---------------------------
function Is_Fully_Defined_Type (Typ : Entity_Id) return Boolean is
begin
-- A private type without a full view is not fully defined
if Is_Private_Type (Typ)
and then No (Full_View (Typ))
then
return False;
-- An incomplete type is never fully defined
elsif Is_Incomplete_Type (Typ) then
return False;
-- All other types are fully defined
else
return True;
end if;
end Is_Fully_Defined_Type;
-- Local declarations
Param : Entity_Id;
-- Start of processing for Has_Fully_Defined_Profile
begin
-- Check the parameters
Param := First_Formal (Subp);
while Present (Param) loop
if not Is_Fully_Defined_Type (Etype (Param)) then
return False;
end if;
Next_Formal (Param);
end loop;
-- Check the return type
return Is_Fully_Defined_Type (Etype (Subp));
end Has_Fully_Defined_Profile;
---------------------
-- Matching_Actual --
---------------------
function Matching_Actual
(F : Entity_Id;
A_F : Entity_Id) return Node_Id
is
Prev : Node_Id;
Act : Node_Id;
begin
Is_Named_Assoc := False;
-- End of list of purely positional parameters
if No (Actual) or else Nkind (Actual) = N_Others_Choice then
Found_Assoc := Empty;
Act := Empty;
-- Case of positional parameter corresponding to current formal
elsif No (Selector_Name (Actual)) then
Found_Assoc := Actual;
Act := Explicit_Generic_Actual_Parameter (Actual);
Num_Matched := Num_Matched + 1;
Next (Actual);
-- Otherwise scan list of named actuals to find the one with the
-- desired name. All remaining actuals have explicit names.
else
Is_Named_Assoc := True;
Found_Assoc := Empty;
Act := Empty;
Prev := Empty;
while Present (Actual) loop
if Chars (Selector_Name (Actual)) = Chars (F) then
Set_Entity (Selector_Name (Actual), A_F);
Set_Etype (Selector_Name (Actual), Etype (A_F));
Generate_Reference (A_F, Selector_Name (Actual));
Found_Assoc := Actual;
Act := Explicit_Generic_Actual_Parameter (Actual);
Num_Matched := Num_Matched + 1;
exit;
end if;
Prev := Actual;
Next (Actual);
end loop;
-- Reset for subsequent searches. In most cases the named
-- associations are in order. If they are not, we reorder them
-- to avoid scanning twice the same actual. This is not just a
-- question of efficiency: there may be multiple defaults with
-- boxes that have the same name. In a nested instantiation we
-- insert actuals for those defaults, and cannot rely on their
-- names to disambiguate them.
if Actual = First_Named then
Next (First_Named);
elsif Present (Actual) then
Insert_Before (First_Named, Remove_Next (Prev));
end if;
Actual := First_Named;
end if;
if Is_Entity_Name (Act) and then Present (Entity (Act)) then
Set_Used_As_Generic_Actual (Entity (Act));
end if;
return Act;
end Matching_Actual;
------------------------------
-- Partial_Parameterization --
------------------------------
function Partial_Parameterization return Boolean is
begin
return Others_Present
or else (Present (Found_Assoc) and then Box_Present (Found_Assoc));
end Partial_Parameterization;
---------------------
-- Process_Default --
---------------------
procedure Process_Default (F : Entity_Id) is
Loc : constant Source_Ptr := Sloc (I_Node);
F_Id : constant Entity_Id := Defining_Entity (F);
Decl : Node_Id;
Default : Node_Id;
Id : Entity_Id;
begin
-- Append copy of formal declaration to associations, and create new
-- defining identifier for it.
Decl := New_Copy_Tree (F);
Id := Make_Defining_Identifier (Sloc (F_Id), Chars (F_Id));
if Nkind (F) in N_Formal_Subprogram_Declaration then
Set_Defining_Unit_Name (Specification (Decl), Id);
else
Set_Defining_Identifier (Decl, Id);
end if;
Append (Decl, Assoc);
if No (Found_Assoc) then
Default :=
Make_Generic_Association (Loc,
Selector_Name => New_Occurrence_Of (Id, Loc),
Explicit_Generic_Actual_Parameter => Empty);
Set_Box_Present (Default);
Append (Default, Default_Formals);
end if;
end Process_Default;
---------------------------------
-- Renames_Standard_Subprogram --
---------------------------------
function Renames_Standard_Subprogram (Subp : Entity_Id) return Boolean is
Id : Entity_Id;
begin
Id := Alias (Subp);
while Present (Id) loop
if Scope (Id) = Standard_Standard then
return True;
end if;
Id := Alias (Id);
end loop;
return False;
end Renames_Standard_Subprogram;
-------------------------
-- Set_Analyzed_Formal --
-------------------------
procedure Set_Analyzed_Formal is
Kind : Node_Kind;
begin
while Present (Analyzed_Formal) loop
Kind := Nkind (Analyzed_Formal);
case Nkind (Formal) is
when N_Formal_Subprogram_Declaration =>
exit when Kind in N_Formal_Subprogram_Declaration
and then
Chars
(Defining_Unit_Name (Specification (Formal))) =
Chars
(Defining_Unit_Name (Specification (Analyzed_Formal)));
when N_Formal_Package_Declaration =>
exit when Nkind_In (Kind, N_Formal_Package_Declaration,
N_Generic_Package_Declaration,
N_Package_Declaration);
when N_Use_Package_Clause | N_Use_Type_Clause => exit;
when others =>
-- Skip freeze nodes, and nodes inserted to replace
-- unrecognized pragmas.
exit when
Kind not in N_Formal_Subprogram_Declaration
and then not Nkind_In (Kind, N_Subprogram_Declaration,
N_Freeze_Entity,
N_Null_Statement,
N_Itype_Reference)
and then Chars (Defining_Identifier (Formal)) =
Chars (Defining_Identifier (Analyzed_Formal));
end case;
Next (Analyzed_Formal);
end loop;
end Set_Analyzed_Formal;
-- Start of processing for Analyze_Associations
begin
Actuals := Generic_Associations (I_Node);
if Present (Actuals) then
-- Check for an Others choice, indicating a partial parameterization
-- for a formal package.
Actual := First (Actuals);
while Present (Actual) loop
if Nkind (Actual) = N_Others_Choice then
Others_Present := True;
Others_Choice := Actual;
if Present (Next (Actual)) then
Error_Msg_N ("others must be last association", Actual);
end if;
-- This subprogram is used both for formal packages and for
-- instantiations. For the latter, associations must all be
-- explicit.
if Nkind (I_Node) /= N_Formal_Package_Declaration
and then Comes_From_Source (I_Node)
then
Error_Msg_N
("others association not allowed in an instance",
Actual);
end if;
-- In any case, nothing to do after the others association
exit;
elsif Box_Present (Actual)
and then Comes_From_Source (I_Node)
and then Nkind (I_Node) /= N_Formal_Package_Declaration
then
Error_Msg_N
("box association not allowed in an instance", Actual);
end if;
Next (Actual);
end loop;
-- If named associations are present, save first named association
-- (it may of course be Empty) to facilitate subsequent name search.
First_Named := First (Actuals);
while Present (First_Named)
and then Nkind (First_Named) /= N_Others_Choice
and then No (Selector_Name (First_Named))
loop
Num_Actuals := Num_Actuals + 1;
Next (First_Named);
end loop;
end if;
Named := First_Named;
while Present (Named) loop
if Nkind (Named) /= N_Others_Choice
and then No (Selector_Name (Named))
then
Error_Msg_N ("invalid positional actual after named one", Named);
Abandon_Instantiation (Named);
end if;
-- A named association may lack an actual parameter, if it was
-- introduced for a default subprogram that turns out to be local
-- to the outer instantiation.
if Nkind (Named) /= N_Others_Choice
and then Present (Explicit_Generic_Actual_Parameter (Named))
then
Num_Actuals := Num_Actuals + 1;
end if;
Next (Named);
end loop;
if Present (Formals) then
Formal := First_Non_Pragma (Formals);
Analyzed_Formal := First_Non_Pragma (F_Copy);
if Present (Actuals) then
Actual := First (Actuals);
-- All formals should have default values
else
Actual := Empty;
end if;
while Present (Formal) loop
Set_Analyzed_Formal;
Saved_Formal := Next_Non_Pragma (Formal);
case Nkind (Formal) is
when N_Formal_Object_Declaration =>
Match :=
Matching_Actual (
Defining_Identifier (Formal),
Defining_Identifier (Analyzed_Formal));
if No (Match) and then Partial_Parameterization then
Process_Default (Formal);
else
Append_List
(Instantiate_Object (Formal, Match, Analyzed_Formal),
Assoc);
end if;
when N_Formal_Type_Declaration =>
Match :=
Matching_Actual (
Defining_Identifier (Formal),
Defining_Identifier (Analyzed_Formal));
if No (Match) then
if Partial_Parameterization then
Process_Default (Formal);
else
Error_Msg_Sloc := Sloc (Gen_Unit);
Error_Msg_NE
("missing actual&",
Instantiation_Node,
Defining_Identifier (Formal));
Error_Msg_NE ("\in instantiation of & declared#",
Instantiation_Node, Gen_Unit);
Abandon_Instantiation (Instantiation_Node);
end if;
else
Analyze (Match);
Append_List
(Instantiate_Type
(Formal, Match, Analyzed_Formal, Assoc),
Assoc);
-- An instantiation is a freeze point for the actuals,
-- unless this is a rewritten formal package, or the
-- formal is an Ada 2012 formal incomplete type.
if Nkind (I_Node) = N_Formal_Package_Declaration
or else
(Ada_Version >= Ada_2012
and then
Ekind (Defining_Identifier (Analyzed_Formal)) =
E_Incomplete_Type)
then
null;
else
Append_Elmt (Entity (Match), Actuals_To_Freeze);
end if;
end if;
-- A remote access-to-class-wide type is not a legal actual
-- for a generic formal of an access type (E.2.2(17/2)).
-- In GNAT an exception to this rule is introduced when
-- the formal is marked as remote using implementation
-- defined aspect/pragma Remote_Access_Type. In that case
-- the actual must be remote as well.
-- If the current instantiation is the construction of a
-- local copy for a formal package the actuals may be
-- defaulted, and there is no matching actual to check.
if Nkind (Analyzed_Formal) = N_Formal_Type_Declaration
and then
Nkind (Formal_Type_Definition (Analyzed_Formal)) =
N_Access_To_Object_Definition
and then Present (Match)
then
declare
Formal_Ent : constant Entity_Id :=
Defining_Identifier (Analyzed_Formal);
begin
if Is_Remote_Access_To_Class_Wide_Type (Entity (Match))
= Is_Remote_Types (Formal_Ent)
then
-- Remoteness of formal and actual match
null;
elsif Is_Remote_Types (Formal_Ent) then
-- Remote formal, non-remote actual
Error_Msg_NE
("actual for& must be remote", Match, Formal_Ent);
else
-- Non-remote formal, remote actual
Error_Msg_NE
("actual for& may not be remote",
Match, Formal_Ent);
end if;
end;
end if;
when N_Formal_Subprogram_Declaration =>
Match :=
Matching_Actual
(Defining_Unit_Name (Specification (Formal)),
Defining_Unit_Name (Specification (Analyzed_Formal)));
-- If the formal subprogram has the same name as another
-- formal subprogram of the generic, then a named
-- association is illegal (12.3(9)). Exclude named
-- associations that are generated for a nested instance.
if Present (Match)
and then Is_Named_Assoc
and then Comes_From_Source (Found_Assoc)
then
Check_Overloaded_Formal_Subprogram (Formal);
end if;
-- If there is no corresponding actual, this may be case
-- of partial parameterization, or else the formal has a
-- default or a box.
if No (Match) and then Partial_Parameterization then
Process_Default (Formal);
if Nkind (I_Node) = N_Formal_Package_Declaration then
Check_Overloaded_Formal_Subprogram (Formal);
end if;
else
if GNATprove_Mode
and then
Present
(Get_First_Parent_With_Ext_Axioms_For_Entity
(Defining_Entity (Analyzed_Formal)))
and then Ekind (Defining_Entity (Analyzed_Formal)) =
E_Function
then
-- If actual is an entity (function or operator),
-- build wrapper for it.
if Present (Match)
and then Nkind (Match) = N_Operator_Symbol
then
-- If the name is a default, find its visible
-- entity at the point of instantiation.
if Is_Entity_Name (Match)
and then No (Entity (Match))
then
Find_Direct_Name (Match);
end if;
Append_To (Assoc,
Build_Wrapper
(Defining_Entity (Analyzed_Formal), Match));
-- Ditto if formal is an operator with a default.
elsif Box_Present (Formal)
and then Nkind (Defining_Entity (Analyzed_Formal)) =
N_Defining_Operator_Symbol
then
Append_To (Assoc,
Build_Wrapper
(Defining_Entity (Analyzed_Formal)));
-- Otherwise create renaming declaration.
else
Append_To (Assoc,
Instantiate_Formal_Subprogram
(Formal, Match, Analyzed_Formal));
end if;
else
Append_To (Assoc,
Instantiate_Formal_Subprogram
(Formal, Match, Analyzed_Formal));
end if;
-- An instantiation is a freeze point for the actuals,
-- unless this is a rewritten formal package.
if Nkind (I_Node) /= N_Formal_Package_Declaration
and then Nkind (Match) = N_Identifier
and then Is_Subprogram (Entity (Match))
-- The actual subprogram may rename a routine defined
-- in Standard. Avoid freezing such renamings because
-- subprograms coming from Standard cannot be frozen.
and then
not Renames_Standard_Subprogram (Entity (Match))
-- If the actual subprogram comes from a different
-- unit, it is already frozen, either by a body in
-- that unit or by the end of the declarative part
-- of the unit. This check avoids the freezing of
-- subprograms defined in Standard which are used
-- as generic actuals.
and then In_Same_Code_Unit (Entity (Match), I_Node)
and then Has_Fully_Defined_Profile (Entity (Match))
then
-- Mark the subprogram as having a delayed freeze
-- since this may be an out-of-order action.
Set_Has_Delayed_Freeze (Entity (Match));
Append_Elmt (Entity (Match), Actuals_To_Freeze);
end if;
end if;
-- If this is a nested generic, preserve default for later
-- instantiations.
if No (Match) and then Box_Present (Formal) then
Append_Elmt
(Defining_Unit_Name (Specification (Last (Assoc))),
Default_Actuals);
end if;
when N_Formal_Package_Declaration =>
Match :=
Matching_Actual (
Defining_Identifier (Formal),
Defining_Identifier (Original_Node (Analyzed_Formal)));
if No (Match) then
if Partial_Parameterization then
Process_Default (Formal);
else
Error_Msg_Sloc := Sloc (Gen_Unit);
Error_Msg_NE
("missing actual&",
Instantiation_Node, Defining_Identifier (Formal));
Error_Msg_NE ("\in instantiation of & declared#",
Instantiation_Node, Gen_Unit);
Abandon_Instantiation (Instantiation_Node);
end if;
else
Analyze (Match);
Append_List
(Instantiate_Formal_Package
(Formal, Match, Analyzed_Formal),
Assoc);
end if;
-- For use type and use package appearing in the generic part,
-- we have already copied them, so we can just move them where
-- they belong (we mustn't recopy them since this would mess up
-- the Sloc values).
when N_Use_Package_Clause |
N_Use_Type_Clause =>
if Nkind (Original_Node (I_Node)) =
N_Formal_Package_Declaration
then
Append (New_Copy_Tree (Formal), Assoc);
else
Remove (Formal);
Append (Formal, Assoc);
end if;
when others =>
raise Program_Error;
end case;
Formal := Saved_Formal;
Next_Non_Pragma (Analyzed_Formal);
end loop;
if Num_Actuals > Num_Matched then
Error_Msg_Sloc := Sloc (Gen_Unit);
if Present (Selector_Name (Actual)) then
Error_Msg_NE
("unmatched actual&",
Actual, Selector_Name (Actual));
Error_Msg_NE ("\in instantiation of& declared#",
Actual, Gen_Unit);
else
Error_Msg_NE
("unmatched actual in instantiation of& declared#",
Actual, Gen_Unit);
end if;
end if;
elsif Present (Actuals) then
Error_Msg_N
("too many actuals in generic instantiation", Instantiation_Node);
end if;
-- An instantiation freezes all generic actuals. The only exceptions
-- to this are incomplete types and subprograms which are not fully
-- defined at the point of instantiation.
declare
Elmt : Elmt_Id := First_Elmt (Actuals_To_Freeze);
begin
while Present (Elmt) loop
Freeze_Before (I_Node, Node (Elmt));
Next_Elmt (Elmt);
end loop;
end;
-- If there are default subprograms, normalize the tree by adding
-- explicit associations for them. This is required if the instance
-- appears within a generic.
declare
Elmt : Elmt_Id;
Subp : Entity_Id;
New_D : Node_Id;
begin
Elmt := First_Elmt (Default_Actuals);
while Present (Elmt) loop
if No (Actuals) then
Actuals := New_List;
Set_Generic_Associations (I_Node, Actuals);
end if;
Subp := Node (Elmt);
New_D :=
Make_Generic_Association (Sloc (Subp),
Selector_Name => New_Occurrence_Of (Subp, Sloc (Subp)),
Explicit_Generic_Actual_Parameter =>
New_Occurrence_Of (Subp, Sloc (Subp)));
Mark_Rewrite_Insertion (New_D);
Append_To (Actuals, New_D);
Next_Elmt (Elmt);
end loop;
end;
-- If this is a formal package, normalize the parameter list by adding
-- explicit box associations for the formals that are covered by an
-- Others_Choice.
if not Is_Empty_List (Default_Formals) then
Append_List (Default_Formals, Formals);
end if;
return Assoc;
end Analyze_Associations;
-------------------------------
-- Analyze_Formal_Array_Type --
-------------------------------
procedure Analyze_Formal_Array_Type
(T : in out Entity_Id;
Def : Node_Id)
is
DSS : Node_Id;
begin
-- Treated like a non-generic array declaration, with additional
-- semantic checks.
Enter_Name (T);
if Nkind (Def) = N_Constrained_Array_Definition then
DSS := First (Discrete_Subtype_Definitions (Def));
while Present (DSS) loop
if Nkind_In (DSS, N_Subtype_Indication,
N_Range,
N_Attribute_Reference)
then
Error_Msg_N ("only a subtype mark is allowed in a formal", DSS);
end if;
Next (DSS);
end loop;
end if;
Array_Type_Declaration (T, Def);
Set_Is_Generic_Type (Base_Type (T));
if Ekind (Component_Type (T)) = E_Incomplete_Type
and then No (Full_View (Component_Type (T)))
then
Error_Msg_N ("premature usage of incomplete type", Def);
-- Check that range constraint is not allowed on the component type
-- of a generic formal array type (AARM 12.5.3(3))
elsif Is_Internal (Component_Type (T))
and then Present (Subtype_Indication (Component_Definition (Def)))
and then Nkind (Original_Node
(Subtype_Indication (Component_Definition (Def)))) =
N_Subtype_Indication
then
Error_Msg_N
("in a formal, a subtype indication can only be "
& "a subtype mark (RM 12.5.3(3))",
Subtype_Indication (Component_Definition (Def)));
end if;
end Analyze_Formal_Array_Type;
---------------------------------------------
-- Analyze_Formal_Decimal_Fixed_Point_Type --
---------------------------------------------
-- As for other generic types, we create a valid type representation with
-- legal but arbitrary attributes, whose values are never considered
-- static. For all scalar types we introduce an anonymous base type, with
-- the same attributes. We choose the corresponding integer type to be
-- Standard_Integer.
-- Here and in other similar routines, the Sloc of the generated internal
-- type must be the same as the sloc of the defining identifier of the
-- formal type declaration, to provide proper source navigation.
procedure Analyze_Formal_Decimal_Fixed_Point_Type
(T : Entity_Id;
Def : Node_Id)
is
Loc : constant Source_Ptr := Sloc (Def);
Base : constant Entity_Id :=
New_Internal_Entity
(E_Decimal_Fixed_Point_Type,
Current_Scope,
Sloc (Defining_Identifier (Parent (Def))), 'G');
Int_Base : constant Entity_Id := Standard_Integer;
Delta_Val : constant Ureal := Ureal_1;
Digs_Val : constant Uint := Uint_6;
function Make_Dummy_Bound return Node_Id;
-- Return a properly typed universal real literal to use as a bound
----------------------
-- Make_Dummy_Bound --
----------------------
function Make_Dummy_Bound return Node_Id is
Bound : constant Node_Id := Make_Real_Literal (Loc, Ureal_1);
begin
Set_Etype (Bound, Universal_Real);
return Bound;
end Make_Dummy_Bound;
-- Start of processing for Analyze_Formal_Decimal_Fixed_Point_Type
begin
Enter_Name (T);
Set_Etype (Base, Base);
Set_Size_Info (Base, Int_Base);
Set_RM_Size (Base, RM_Size (Int_Base));
Set_First_Rep_Item (Base, First_Rep_Item (Int_Base));
Set_Digits_Value (Base, Digs_Val);
Set_Delta_Value (Base, Delta_Val);
Set_Small_Value (Base, Delta_Val);
Set_Scalar_Range (Base,
Make_Range (Loc,
Low_Bound => Make_Dummy_Bound,
High_Bound => Make_Dummy_Bound));
Set_Is_Generic_Type (Base);
Set_Parent (Base, Parent (Def));
Set_Ekind (T, E_Decimal_Fixed_Point_Subtype);
Set_Etype (T, Base);
Set_Size_Info (T, Int_Base);
Set_RM_Size (T, RM_Size (Int_Base));
Set_First_Rep_Item (T, First_Rep_Item (Int_Base));
Set_Digits_Value (T, Digs_Val);
Set_Delta_Value (T, Delta_Val);
Set_Small_Value (T, Delta_Val);
Set_Scalar_Range (T, Scalar_Range (Base));
Set_Is_Constrained (T);
Check_Restriction (No_Fixed_Point, Def);
end Analyze_Formal_Decimal_Fixed_Point_Type;
-------------------------------------------
-- Analyze_Formal_Derived_Interface_Type --
-------------------------------------------
procedure Analyze_Formal_Derived_Interface_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id)
is
Loc : constant Source_Ptr := Sloc (Def);
begin
-- Rewrite as a type declaration of a derived type. This ensures that
-- the interface list and primitive operations are properly captured.
Rewrite (N,
Make_Full_Type_Declaration (Loc,
Defining_Identifier => T,
Type_Definition => Def));
Analyze (N);
Set_Is_Generic_Type (T);
end Analyze_Formal_Derived_Interface_Type;
---------------------------------
-- Analyze_Formal_Derived_Type --
---------------------------------
procedure Analyze_Formal_Derived_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id)
is
Loc : constant Source_Ptr := Sloc (Def);
Unk_Disc : constant Boolean := Unknown_Discriminants_Present (N);
New_N : Node_Id;
begin
Set_Is_Generic_Type (T);
if Private_Present (Def) then
New_N :=
Make_Private_Extension_Declaration (Loc,
Defining_Identifier => T,
Discriminant_Specifications => Discriminant_Specifications (N),
Unknown_Discriminants_Present => Unk_Disc,
Subtype_Indication => Subtype_Mark (Def),
Interface_List => Interface_List (Def));
Set_Abstract_Present (New_N, Abstract_Present (Def));
Set_Limited_Present (New_N, Limited_Present (Def));
Set_Synchronized_Present (New_N, Synchronized_Present (Def));
else
New_N :=
Make_Full_Type_Declaration (Loc,
Defining_Identifier => T,
Discriminant_Specifications =>
Discriminant_Specifications (Parent (T)),
Type_Definition =>
Make_Derived_Type_Definition (Loc,
Subtype_Indication => Subtype_Mark (Def)));
Set_Abstract_Present
(Type_Definition (New_N), Abstract_Present (Def));
Set_Limited_Present
(Type_Definition (New_N), Limited_Present (Def));
end if;
Rewrite (N, New_N);
Analyze (N);
if Unk_Disc then
if not Is_Composite_Type (T) then
Error_Msg_N
("unknown discriminants not allowed for elementary types", N);
else
Set_Has_Unknown_Discriminants (T);
Set_Is_Constrained (T, False);
end if;
end if;
-- If the parent type has a known size, so does the formal, which makes
-- legal representation clauses that involve the formal.
Set_Size_Known_At_Compile_Time
(T, Size_Known_At_Compile_Time (Entity (Subtype_Mark (Def))));
end Analyze_Formal_Derived_Type;
----------------------------------
-- Analyze_Formal_Discrete_Type --
----------------------------------
-- The operations defined for a discrete types are those of an enumeration
-- type. The size is set to an arbitrary value, for use in analyzing the
-- generic unit.
procedure Analyze_Formal_Discrete_Type (T : Entity_Id; Def : Node_Id) is
Loc : constant Source_Ptr := Sloc (Def);
Lo : Node_Id;
Hi : Node_Id;
Base : constant Entity_Id :=
New_Internal_Entity
(E_Floating_Point_Type, Current_Scope,
Sloc (Defining_Identifier (Parent (Def))), 'G');
begin
Enter_Name (T);
Set_Ekind (T, E_Enumeration_Subtype);
Set_Etype (T, Base);
Init_Size (T, 8);
Init_Alignment (T);
Set_Is_Generic_Type (T);
Set_Is_Constrained (T);
-- For semantic analysis, the bounds of the type must be set to some
-- non-static value. The simplest is to create attribute nodes for those
-- bounds, that refer to the type itself. These bounds are never
-- analyzed but serve as place-holders.
Lo :=
Make_Attribute_Reference (Loc,
Attribute_Name => Name_First,
Prefix => New_Occurrence_Of (T, Loc));
Set_Etype (Lo, T);
Hi :=
Make_Attribute_Reference (Loc,
Attribute_Name => Name_Last,
Prefix => New_Occurrence_Of (T, Loc));
Set_Etype (Hi, T);
Set_Scalar_Range (T,
Make_Range (Loc,
Low_Bound => Lo,
High_Bound => Hi));
Set_Ekind (Base, E_Enumeration_Type);
Set_Etype (Base, Base);
Init_Size (Base, 8);
Init_Alignment (Base);
Set_Is_Generic_Type (Base);
Set_Scalar_Range (Base, Scalar_Range (T));
Set_Parent (Base, Parent (Def));
end Analyze_Formal_Discrete_Type;
----------------------------------
-- Analyze_Formal_Floating_Type --
---------------------------------
procedure Analyze_Formal_Floating_Type (T : Entity_Id; Def : Node_Id) is
Base : constant Entity_Id :=
New_Internal_Entity
(E_Floating_Point_Type, Current_Scope,
Sloc (Defining_Identifier (Parent (Def))), 'G');
begin
-- The various semantic attributes are taken from the predefined type
-- Float, just so that all of them are initialized. Their values are
-- never used because no constant folding or expansion takes place in
-- the generic itself.
Enter_Name (T);
Set_Ekind (T, E_Floating_Point_Subtype);
Set_Etype (T, Base);
Set_Size_Info (T, (Standard_Float));
Set_RM_Size (T, RM_Size (Standard_Float));
Set_Digits_Value (T, Digits_Value (Standard_Float));
Set_Scalar_Range (T, Scalar_Range (Standard_Float));
Set_Is_Constrained (T);
Set_Is_Generic_Type (Base);
Set_Etype (Base, Base);
Set_Size_Info (Base, (Standard_Float));
Set_RM_Size (Base, RM_Size (Standard_Float));
Set_Digits_Value (Base, Digits_Value (Standard_Float));
Set_Scalar_Range (Base, Scalar_Range (Standard_Float));
Set_Parent (Base, Parent (Def));
Check_Restriction (No_Floating_Point, Def);
end Analyze_Formal_Floating_Type;
-----------------------------------
-- Analyze_Formal_Interface_Type;--
-----------------------------------
procedure Analyze_Formal_Interface_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id)
is
Loc : constant Source_Ptr := Sloc (N);
New_N : Node_Id;
begin
New_N :=
Make_Full_Type_Declaration (Loc,
Defining_Identifier => T,
Type_Definition => Def);
Rewrite (N, New_N);
Analyze (N);
Set_Is_Generic_Type (T);
end Analyze_Formal_Interface_Type;
---------------------------------
-- Analyze_Formal_Modular_Type --
---------------------------------
procedure Analyze_Formal_Modular_Type (T : Entity_Id; Def : Node_Id) is
begin
-- Apart from their entity kind, generic modular types are treated like
-- signed integer types, and have the same attributes.
Analyze_Formal_Signed_Integer_Type (T, Def);
Set_Ekind (T, E_Modular_Integer_Subtype);
Set_Ekind (Etype (T), E_Modular_Integer_Type);
end Analyze_Formal_Modular_Type;
---------------------------------------
-- Analyze_Formal_Object_Declaration --
---------------------------------------
procedure Analyze_Formal_Object_Declaration (N : Node_Id) is
E : constant Node_Id := Default_Expression (N);
Id : constant Node_Id := Defining_Identifier (N);
K : Entity_Kind;
T : Node_Id;
begin
Enter_Name (Id);
-- Determine the mode of the formal object
if Out_Present (N) then
K := E_Generic_In_Out_Parameter;
if not In_Present (N) then
Error_Msg_N ("formal generic objects cannot have mode OUT", N);
end if;
else
K := E_Generic_In_Parameter;
end if;
if Present (Subtype_Mark (N)) then
Find_Type (Subtype_Mark (N));
T := Entity (Subtype_Mark (N));
-- Verify that there is no redundant null exclusion
if Null_Exclusion_Present (N) then
if not Is_Access_Type (T) then
Error_Msg_N
("null exclusion can only apply to an access type", N);
elsif Can_Never_Be_Null (T) then
Error_Msg_NE
("`NOT NULL` not allowed (& already excludes null)",
N, T);
end if;
end if;
-- Ada 2005 (AI-423): Formal object with an access definition
else
Check_Access_Definition (N);
T := Access_Definition
(Related_Nod => N,
N => Access_Definition (N));
end if;
if Ekind (T) = E_Incomplete_Type then
declare
Error_Node : Node_Id;
begin
if Present (Subtype_Mark (N)) then
Error_Node := Subtype_Mark (N);
else
Check_Access_Definition (N);
Error_Node := Access_Definition (N);
end if;
Error_Msg_N ("premature usage of incomplete type", Error_Node);
end;
end if;
if K = E_Generic_In_Parameter then
-- Ada 2005 (AI-287): Limited aggregates allowed in generic formals
if Ada_Version < Ada_2005 and then Is_Limited_Type (T) then
Error_Msg_N
("generic formal of mode IN must not be of limited type", N);
Explain_Limited_Type (T, N);
end if;
if Is_Abstract_Type (T) then
Error_Msg_N
("generic formal of mode IN must not be of abstract type", N);
end if;
if Present (E) then
Preanalyze_Spec_Expression (E, T);
if Is_Limited_Type (T) and then not OK_For_Limited_Init (T, E) then
Error_Msg_N
("initialization not allowed for limited types", E);
Explain_Limited_Type (T, E);
end if;
end if;
Set_Ekind (Id, K);
Set_Etype (Id, T);
-- Case of generic IN OUT parameter
else
-- If the formal has an unconstrained type, construct its actual
-- subtype, as is done for subprogram formals. In this fashion, all
-- its uses can refer to specific bounds.
Set_Ekind (Id, K);
Set_Etype (Id, T);
if (Is_Array_Type (T)
and then not Is_Constrained (T))
or else
(Ekind (T) = E_Record_Type
and then Has_Discriminants (T))
then
declare
Non_Freezing_Ref : constant Node_Id :=
New_Occurrence_Of (Id, Sloc (Id));
Decl : Node_Id;
begin
-- Make sure the actual subtype doesn't generate bogus freezing
Set_Must_Not_Freeze (Non_Freezing_Ref);
Decl := Build_Actual_Subtype (T, Non_Freezing_Ref);
Insert_Before_And_Analyze (N, Decl);
Set_Actual_Subtype (Id, Defining_Identifier (Decl));
end;
else
Set_Actual_Subtype (Id, T);
end if;
if Present (E) then
Error_Msg_N
("initialization not allowed for `IN OUT` formals", N);
end if;
end if;
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Id);
end if;
end Analyze_Formal_Object_Declaration;
----------------------------------------------
-- Analyze_Formal_Ordinary_Fixed_Point_Type --
----------------------------------------------
procedure Analyze_Formal_Ordinary_Fixed_Point_Type
(T : Entity_Id;
Def : Node_Id)
is
Loc : constant Source_Ptr := Sloc (Def);
Base : constant Entity_Id :=
New_Internal_Entity
(E_Ordinary_Fixed_Point_Type, Current_Scope,
Sloc (Defining_Identifier (Parent (Def))), 'G');
begin
-- The semantic attributes are set for completeness only, their values
-- will never be used, since all properties of the type are non-static.
Enter_Name (T);
Set_Ekind (T, E_Ordinary_Fixed_Point_Subtype);
Set_Etype (T, Base);
Set_Size_Info (T, Standard_Integer);
Set_RM_Size (T, RM_Size (Standard_Integer));
Set_Small_Value (T, Ureal_1);
Set_Delta_Value (T, Ureal_1);
Set_Scalar_Range (T,
Make_Range (Loc,
Low_Bound => Make_Real_Literal (Loc, Ureal_1),
High_Bound => Make_Real_Literal (Loc, Ureal_1)));
Set_Is_Constrained (T);
Set_Is_Generic_Type (Base);
Set_Etype (Base, Base);
Set_Size_Info (Base, Standard_Integer);
Set_RM_Size (Base, RM_Size (Standard_Integer));
Set_Small_Value (Base, Ureal_1);
Set_Delta_Value (Base, Ureal_1);
Set_Scalar_Range (Base, Scalar_Range (T));
Set_Parent (Base, Parent (Def));
Check_Restriction (No_Fixed_Point, Def);
end Analyze_Formal_Ordinary_Fixed_Point_Type;
----------------------------------------
-- Analyze_Formal_Package_Declaration --
----------------------------------------
procedure Analyze_Formal_Package_Declaration (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
Pack_Id : constant Entity_Id := Defining_Identifier (N);
Formal : Entity_Id;
Gen_Id : constant Node_Id := Name (N);
Gen_Decl : Node_Id;
Gen_Unit : Entity_Id;
New_N : Node_Id;
Parent_Installed : Boolean := False;
Renaming : Node_Id;
Parent_Instance : Entity_Id;
Renaming_In_Par : Entity_Id;
Associations : Boolean := True;
Vis_Prims_List : Elist_Id := No_Elist;
-- List of primitives made temporarily visible in the instantiation
-- to match the visibility of the formal type
function Build_Local_Package return Node_Id;
-- The formal package is rewritten so that its parameters are replaced
-- with corresponding declarations. For parameters with bona fide
-- associations these declarations are created by Analyze_Associations
-- as for a regular instantiation. For boxed parameters, we preserve
-- the formal declarations and analyze them, in order to introduce
-- entities of the right kind in the environment of the formal.
-------------------------
-- Build_Local_Package --
-------------------------
function Build_Local_Package return Node_Id is
Decls : List_Id;
Pack_Decl : Node_Id;
begin
-- Within the formal, the name of the generic package is a renaming
-- of the formal (as for a regular instantiation).
Pack_Decl :=
Make_Package_Declaration (Loc,
Specification =>
Copy_Generic_Node
(Specification (Original_Node (Gen_Decl)),
Empty, Instantiating => True));
Renaming := Make_Package_Renaming_Declaration (Loc,
Defining_Unit_Name =>
Make_Defining_Identifier (Loc, Chars (Gen_Unit)),
Name => New_Occurrence_Of (Formal, Loc));
if Nkind (Gen_Id) = N_Identifier
and then Chars (Gen_Id) = Chars (Pack_Id)
then
Error_Msg_NE
("& is hidden within declaration of instance", Gen_Id, Gen_Unit);
end if;
-- If the formal is declared with a box, or with an others choice,
-- create corresponding declarations for all entities in the formal
-- part, so that names with the proper types are available in the
-- specification of the formal package.
-- On the other hand, if there are no associations, then all the
-- formals must have defaults, and this will be checked by the
-- call to Analyze_Associations.
if Box_Present (N)
or else Nkind (First (Generic_Associations (N))) = N_Others_Choice
then
declare
Formal_Decl : Node_Id;
begin
-- TBA : for a formal package, need to recurse ???
Decls := New_List;
Formal_Decl :=
First
(Generic_Formal_Declarations (Original_Node (Gen_Decl)));
while Present (Formal_Decl) loop
Append_To
(Decls, Copy_Generic_Node (Formal_Decl, Empty, True));
Next (Formal_Decl);
end loop;
end;
-- If generic associations are present, use Analyze_Associations to
-- create the proper renaming declarations.
else
declare
Act_Tree : constant Node_Id :=
Copy_Generic_Node
(Original_Node (Gen_Decl), Empty,
Instantiating => True);
begin
Generic_Renamings.Set_Last (0);
Generic_Renamings_HTable.Reset;
Instantiation_Node := N;
Decls :=
Analyze_Associations
(I_Node => Original_Node (N),
Formals => Generic_Formal_Declarations (Act_Tree),
F_Copy => Generic_Formal_Declarations (Gen_Decl));
Vis_Prims_List := Check_Hidden_Primitives (Decls);
end;
end if;
Append (Renaming, To => Decls);
-- Add generated declarations ahead of local declarations in
-- the package.
if No (Visible_Declarations (Specification (Pack_Decl))) then
Set_Visible_Declarations (Specification (Pack_Decl), Decls);
else
Insert_List_Before
(First (Visible_Declarations (Specification (Pack_Decl))),
Decls);
end if;
return Pack_Decl;
end Build_Local_Package;
-- Start of processing for Analyze_Formal_Package_Declaration
begin
Check_Text_IO_Special_Unit (Gen_Id);
Init_Env;
Check_Generic_Child_Unit (Gen_Id, Parent_Installed);
Gen_Unit := Entity (Gen_Id);
-- Check for a formal package that is a package renaming
if Present (Renamed_Object (Gen_Unit)) then
-- Indicate that unit is used, before replacing it with renamed
-- entity for use below.
if In_Extended_Main_Source_Unit (N) then
Set_Is_Instantiated (Gen_Unit);
Generate_Reference (Gen_Unit, N);
end if;
Gen_Unit := Renamed_Object (Gen_Unit);
end if;
if Ekind (Gen_Unit) /= E_Generic_Package then
Error_Msg_N ("expect generic package name", Gen_Id);
Restore_Env;
goto Leave;
elsif Gen_Unit = Current_Scope then
Error_Msg_N
("generic package cannot be used as a formal package of itself",
Gen_Id);
Restore_Env;
goto Leave;
elsif In_Open_Scopes (Gen_Unit) then
if Is_Compilation_Unit (Gen_Unit)
and then Is_Child_Unit (Current_Scope)
then
-- Special-case the error when the formal is a parent, and
-- continue analysis to minimize cascaded errors.
Error_Msg_N
("generic parent cannot be used as formal package "
& "of a child unit",
Gen_Id);
else
Error_Msg_N
("generic package cannot be used as a formal package "
& "within itself",
Gen_Id);
Restore_Env;
goto Leave;
end if;
end if;
-- Check that name of formal package does not hide name of generic,
-- or its leading prefix. This check must be done separately because
-- the name of the generic has already been analyzed.
declare
Gen_Name : Entity_Id;
begin
Gen_Name := Gen_Id;
while Nkind (Gen_Name) = N_Expanded_Name loop
Gen_Name := Prefix (Gen_Name);
end loop;
if Chars (Gen_Name) = Chars (Pack_Id) then
Error_Msg_NE
("& is hidden within declaration of formal package",
Gen_Id, Gen_Name);
end if;
end;
if Box_Present (N)
or else No (Generic_Associations (N))
or else Nkind (First (Generic_Associations (N))) = N_Others_Choice
then
Associations := False;
end if;
-- If there are no generic associations, the generic parameters appear
-- as local entities and are instantiated like them. We copy the generic
-- package declaration as if it were an instantiation, and analyze it
-- like a regular package, except that we treat the formals as
-- additional visible components.
Gen_Decl := Unit_Declaration_Node (Gen_Unit);
if In_Extended_Main_Source_Unit (N) then
Set_Is_Instantiated (Gen_Unit);
Generate_Reference (Gen_Unit, N);
end if;
Formal := New_Copy (Pack_Id);
Create_Instantiation_Source (N, Gen_Unit, False, S_Adjustment);
begin
-- Make local generic without formals. The formals will be replaced
-- with internal declarations.
New_N := Build_Local_Package;
-- If there are errors in the parameter list, Analyze_Associations
-- raises Instantiation_Error. Patch the declaration to prevent
-- further exception propagation.
exception
when Instantiation_Error =>
Enter_Name (Formal);
Set_Ekind (Formal, E_Variable);
Set_Etype (Formal, Any_Type);
Restore_Hidden_Primitives (Vis_Prims_List);
if Parent_Installed then
Remove_Parent;
end if;
goto Leave;
end;
Rewrite (N, New_N);
Set_Defining_Unit_Name (Specification (New_N), Formal);
Set_Generic_Parent (Specification (N), Gen_Unit);
Set_Instance_Env (Gen_Unit, Formal);
Set_Is_Generic_Instance (Formal);
Enter_Name (Formal);
Set_Ekind (Formal, E_Package);
Set_Etype (Formal, Standard_Void_Type);
Set_Inner_Instances (Formal, New_Elmt_List);
Push_Scope (Formal);
if Is_Child_Unit (Gen_Unit)
and then Parent_Installed
then
-- Similarly, we have to make the name of the formal visible in the
-- parent instance, to resolve properly fully qualified names that
-- may appear in the generic unit. The parent instance has been
-- placed on the scope stack ahead of the current scope.
Parent_Instance := Scope_Stack.Table (Scope_Stack.Last - 1).Entity;
Renaming_In_Par :=
Make_Defining_Identifier (Loc, Chars (Gen_Unit));
Set_Ekind (Renaming_In_Par, E_Package);
Set_Etype (Renaming_In_Par, Standard_Void_Type);
Set_Scope (Renaming_In_Par, Parent_Instance);
Set_Parent (Renaming_In_Par, Parent (Formal));
Set_Renamed_Object (Renaming_In_Par, Formal);
Append_Entity (Renaming_In_Par, Parent_Instance);
end if;
Analyze (Specification (N));
-- The formals for which associations are provided are not visible
-- outside of the formal package. The others are still declared by a
-- formal parameter declaration.
-- If there are no associations, the only local entity to hide is the
-- generated package renaming itself.
declare
E : Entity_Id;
begin
E := First_Entity (Formal);
while Present (E) loop
if Associations
and then not Is_Generic_Formal (E)
then
Set_Is_Hidden (E);
end if;
if Ekind (E) = E_Package
and then Renamed_Entity (E) = Formal
then
Set_Is_Hidden (E);
exit;
end if;
Next_Entity (E);
end loop;
end;
End_Package_Scope (Formal);
Restore_Hidden_Primitives (Vis_Prims_List);
if Parent_Installed then
Remove_Parent;
end if;
Restore_Env;
-- Inside the generic unit, the formal package is a regular package, but
-- no body is needed for it. Note that after instantiation, the defining
-- unit name we need is in the new tree and not in the original (see
-- Package_Instantiation). A generic formal package is an instance, and
-- can be used as an actual for an inner instance.
Set_Has_Completion (Formal, True);
-- Add semantic information to the original defining identifier.
-- for ASIS use.
Set_Ekind (Pack_Id, E_Package);
Set_Etype (Pack_Id, Standard_Void_Type);
Set_Scope (Pack_Id, Scope (Formal));
Set_Has_Completion (Pack_Id, True);
<<Leave>>
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Pack_Id);
end if;
end Analyze_Formal_Package_Declaration;
---------------------------------
-- Analyze_Formal_Private_Type --
---------------------------------
procedure Analyze_Formal_Private_Type
(N : Node_Id;
T : Entity_Id;
Def : Node_Id)
is
begin
New_Private_Type (N, T, Def);
-- Set the size to an arbitrary but legal value
Set_Size_Info (T, Standard_Integer);
Set_RM_Size (T, RM_Size (Standard_Integer));
end Analyze_Formal_Private_Type;
------------------------------------
-- Analyze_Formal_Incomplete_Type --
------------------------------------
procedure Analyze_Formal_Incomplete_Type
(T : Entity_Id;
Def : Node_Id)
is
begin
Enter_Name (T);
Set_Ekind (T, E_Incomplete_Type);
Set_Etype (T, T);
Set_Private_Dependents (T, New_Elmt_List);
if Tagged_Present (Def) then
Set_Is_Tagged_Type (T);
Make_Class_Wide_Type (T);
Set_Direct_Primitive_Operations (T, New_Elmt_List);
end if;
end Analyze_Formal_Incomplete_Type;
----------------------------------------
-- Analyze_Formal_Signed_Integer_Type --
----------------------------------------
procedure Analyze_Formal_Signed_Integer_Type
(T : Entity_Id;
Def : Node_Id)
is
Base : constant Entity_Id :=
New_Internal_Entity
(E_Signed_Integer_Type,
Current_Scope,
Sloc (Defining_Identifier (Parent (Def))), 'G');
begin
Enter_Name (T);
Set_Ekind (T, E_Signed_Integer_Subtype);
Set_Etype (T, Base);
Set_Size_Info (T, Standard_Integer);
Set_RM_Size (T, RM_Size (Standard_Integer));
Set_Scalar_Range (T, Scalar_Range (Standard_Integer));
Set_Is_Constrained (T);
Set_Is_Generic_Type (Base);
Set_Size_Info (Base, Standard_Integer);
Set_RM_Size (Base, RM_Size (Standard_Integer));
Set_Etype (Base, Base);
Set_Scalar_Range (Base, Scalar_Range (Standard_Integer));
Set_Parent (Base, Parent (Def));
end Analyze_Formal_Signed_Integer_Type;
-------------------------------------------
-- Analyze_Formal_Subprogram_Declaration --
-------------------------------------------
procedure Analyze_Formal_Subprogram_Declaration (N : Node_Id) is
Spec : constant Node_Id := Specification (N);
Def : constant Node_Id := Default_Name (N);
Nam : constant Entity_Id := Defining_Unit_Name (Spec);
Subp : Entity_Id;
begin
if Nam = Error then
return;
end if;
if Nkind (Nam) = N_Defining_Program_Unit_Name then
Error_Msg_N ("name of formal subprogram must be a direct name", Nam);
goto Leave;
end if;
Analyze_Subprogram_Declaration (N);
Set_Is_Formal_Subprogram (Nam);
Set_Has_Completion (Nam);
if Nkind (N) = N_Formal_Abstract_Subprogram_Declaration then
Set_Is_Abstract_Subprogram (Nam);
Set_Is_Dispatching_Operation (Nam);
declare
Ctrl_Type : constant Entity_Id := Find_Dispatching_Type (Nam);
begin
if No (Ctrl_Type) then
Error_Msg_N
("abstract formal subprogram must have a controlling type",
N);
elsif Ada_Version >= Ada_2012
and then Is_Incomplete_Type (Ctrl_Type)
then
Error_Msg_NE
("controlling type of abstract formal subprogram cannot " &
"be incomplete type", N, Ctrl_Type);
else
Check_Controlling_Formals (Ctrl_Type, Nam);
end if;
end;
end if;
-- Default name is resolved at the point of instantiation
if Box_Present (N) then
null;
-- Else default is bound at the point of generic declaration
elsif Present (Def) then
if Nkind (Def) = N_Operator_Symbol then
Find_Direct_Name (Def);
elsif Nkind (Def) /= N_Attribute_Reference then
Analyze (Def);
else
-- For an attribute reference, analyze the prefix and verify
-- that it has the proper profile for the subprogram.
Analyze (Prefix (Def));
Valid_Default_Attribute (Nam, Def);
goto Leave;
end if;
-- Default name may be overloaded, in which case the interpretation
-- with the correct profile must be selected, as for a renaming.
-- If the definition is an indexed component, it must denote a
-- member of an entry family. If it is a selected component, it
-- can be a protected operation.
if Etype (Def) = Any_Type then
goto Leave;
elsif Nkind (Def) = N_Selected_Component then
if not Is_Overloadable (Entity (Selector_Name (Def))) then
Error_Msg_N ("expect valid subprogram name as default", Def);
end if;
elsif Nkind (Def) = N_Indexed_Component then
if Is_Entity_Name (Prefix (Def)) then
if Ekind (Entity (Prefix (Def))) /= E_Entry_Family then
Error_Msg_N ("expect valid subprogram name as default", Def);
end if;
elsif Nkind (Prefix (Def)) = N_Selected_Component then
if Ekind (Entity (Selector_Name (Prefix (Def)))) /=
E_Entry_Family
then
Error_Msg_N ("expect valid subprogram name as default", Def);
end if;
else
Error_Msg_N ("expect valid subprogram name as default", Def);
goto Leave;
end if;
elsif Nkind (Def) = N_Character_Literal then
-- Needs some type checks: subprogram should be parameterless???
Resolve (Def, (Etype (Nam)));
elsif not Is_Entity_Name (Def)
or else not Is_Overloadable (Entity (Def))
then
Error_Msg_N ("expect valid subprogram name as default", Def);
goto Leave;
elsif not Is_Overloaded (Def) then
Subp := Entity (Def);
if Subp = Nam then
Error_Msg_N ("premature usage of formal subprogram", Def);
elsif not Entity_Matches_Spec (Subp, Nam) then
Error_Msg_N ("no visible entity matches specification", Def);
end if;
-- More than one interpretation, so disambiguate as for a renaming
else
declare
I : Interp_Index;
I1 : Interp_Index := 0;
It : Interp;
It1 : Interp;
begin
Subp := Any_Id;
Get_First_Interp (Def, I, It);
while Present (It.Nam) loop
if Entity_Matches_Spec (It.Nam, Nam) then
if Subp /= Any_Id then
It1 := Disambiguate (Def, I1, I, Etype (Subp));
if It1 = No_Interp then
Error_Msg_N ("ambiguous default subprogram", Def);
else
Subp := It1.Nam;
end if;
exit;
else
I1 := I;
Subp := It.Nam;
end if;
end if;
Get_Next_Interp (I, It);
end loop;
end;
if Subp /= Any_Id then
-- Subprogram found, generate reference to it
Set_Entity (Def, Subp);
Generate_Reference (Subp, Def);
if Subp = Nam then
Error_Msg_N ("premature usage of formal subprogram", Def);
elsif Ekind (Subp) /= E_Operator then
Check_Mode_Conformant (Subp, Nam);
end if;
else
Error_Msg_N ("no visible subprogram matches specification", N);
end if;
end if;
end if;
<<Leave>>
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Nam);
end if;
end Analyze_Formal_Subprogram_Declaration;
-------------------------------------
-- Analyze_Formal_Type_Declaration --
-------------------------------------
procedure Analyze_Formal_Type_Declaration (N : Node_Id) is
Def : constant Node_Id := Formal_Type_Definition (N);
T : Entity_Id;
begin
T := Defining_Identifier (N);
if Present (Discriminant_Specifications (N))
and then Nkind (Def) /= N_Formal_Private_Type_Definition
then
Error_Msg_N
("discriminants not allowed for this formal type", T);
end if;
-- Enter the new name, and branch to specific routine
case Nkind (Def) is
when N_Formal_Private_Type_Definition =>
Analyze_Formal_Private_Type (N, T, Def);
when N_Formal_Derived_Type_Definition =>
Analyze_Formal_Derived_Type (N, T, Def);
when N_Formal_Incomplete_Type_Definition =>
Analyze_Formal_Incomplete_Type (T, Def);
when N_Formal_Discrete_Type_Definition =>
Analyze_Formal_Discrete_Type (T, Def);
when N_Formal_Signed_Integer_Type_Definition =>
Analyze_Formal_Signed_Integer_Type (T, Def);
when N_Formal_Modular_Type_Definition =>
Analyze_Formal_Modular_Type (T, Def);
when N_Formal_Floating_Point_Definition =>
Analyze_Formal_Floating_Type (T, Def);
when N_Formal_Ordinary_Fixed_Point_Definition =>
Analyze_Formal_Ordinary_Fixed_Point_Type (T, Def);
when N_Formal_Decimal_Fixed_Point_Definition =>
Analyze_Formal_Decimal_Fixed_Point_Type (T, Def);
when N_Array_Type_Definition =>
Analyze_Formal_Array_Type (T, Def);
when N_Access_To_Object_Definition |
N_Access_Function_Definition |
N_Access_Procedure_Definition =>
Analyze_Generic_Access_Type (T, Def);
-- Ada 2005: a interface declaration is encoded as an abstract
-- record declaration or a abstract type derivation.
when N_Record_Definition =>
Analyze_Formal_Interface_Type (N, T, Def);
when N_Derived_Type_Definition =>
Analyze_Formal_Derived_Interface_Type (N, T, Def);
when N_Error =>
null;
when others =>
raise Program_Error;
end case;
Set_Is_Generic_Type (T);
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, T);
end if;
end Analyze_Formal_Type_Declaration;
------------------------------------
-- Analyze_Function_Instantiation --
------------------------------------
procedure Analyze_Function_Instantiation (N : Node_Id) is
begin
Analyze_Subprogram_Instantiation (N, E_Function);
end Analyze_Function_Instantiation;
---------------------------------
-- Analyze_Generic_Access_Type --
---------------------------------
procedure Analyze_Generic_Access_Type (T : Entity_Id; Def : Node_Id) is
begin
Enter_Name (T);
if Nkind (Def) = N_Access_To_Object_Definition then
Access_Type_Declaration (T, Def);
if Is_Incomplete_Or_Private_Type (Designated_Type (T))
and then No (Full_View (Designated_Type (T)))
and then not Is_Generic_Type (Designated_Type (T))
then
Error_Msg_N ("premature usage of incomplete type", Def);
elsif not Is_Entity_Name (Subtype_Indication (Def)) then
Error_Msg_N
("only a subtype mark is allowed in a formal", Def);
end if;
else
Access_Subprogram_Declaration (T, Def);
end if;
end Analyze_Generic_Access_Type;
---------------------------------
-- Analyze_Generic_Formal_Part --
---------------------------------
procedure Analyze_Generic_Formal_Part (N : Node_Id) is
Gen_Parm_Decl : Node_Id;
begin
-- The generic formals are processed in the scope of the generic unit,
-- where they are immediately visible. The scope is installed by the
-- caller.
Gen_Parm_Decl := First (Generic_Formal_Declarations (N));
while Present (Gen_Parm_Decl) loop
Analyze (Gen_Parm_Decl);
Next (Gen_Parm_Decl);
end loop;
Generate_Reference_To_Generic_Formals (Current_Scope);
end Analyze_Generic_Formal_Part;
------------------------------------------
-- Analyze_Generic_Package_Declaration --
------------------------------------------
procedure Analyze_Generic_Package_Declaration (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
Id : Entity_Id;
New_N : Node_Id;
Save_Parent : Node_Id;
Renaming : Node_Id;
Decls : constant List_Id :=
Visible_Declarations (Specification (N));
Decl : Node_Id;
begin
Check_SPARK_Restriction ("generic is not allowed", N);
-- We introduce a renaming of the enclosing package, to have a usable
-- entity as the prefix of an expanded name for a local entity of the
-- form Par.P.Q, where P is the generic package. This is because a local
-- entity named P may hide it, so that the usual visibility rules in
-- the instance will not resolve properly.
Renaming :=
Make_Package_Renaming_Declaration (Loc,
Defining_Unit_Name =>
Make_Defining_Identifier (Loc,
Chars => New_External_Name (Chars (Defining_Entity (N)), "GH")),
Name => Make_Identifier (Loc, Chars (Defining_Entity (N))));
if Present (Decls) then
Decl := First (Decls);
while Present (Decl)
and then Nkind (Decl) = N_Pragma
loop
Next (Decl);
end loop;
if Present (Decl) then
Insert_Before (Decl, Renaming);
else
Append (Renaming, Visible_Declarations (Specification (N)));
end if;
else
Set_Visible_Declarations (Specification (N), New_List (Renaming));
end if;
-- Create copy of generic unit, and save for instantiation. If the unit
-- is a child unit, do not copy the specifications for the parent, which
-- are not part of the generic tree.
Save_Parent := Parent_Spec (N);
Set_Parent_Spec (N, Empty);
New_N := Copy_Generic_Node (N, Empty, Instantiating => False);
Set_Parent_Spec (New_N, Save_Parent);
Rewrite (N, New_N);
-- Once the contents of the generic copy and the template are swapped,
-- do the same for their respective aspect specifications.
Exchange_Aspects (N, New_N);
Id := Defining_Entity (N);
Generate_Definition (Id);
-- Expansion is not applied to generic units
Start_Generic;
Enter_Name (Id);
Set_Ekind (Id, E_Generic_Package);
Set_Etype (Id, Standard_Void_Type);
Set_Contract (Id, Make_Contract (Sloc (Id)));
-- Analyze aspects now, so that generated pragmas appear in the
-- declarations before building and analyzing the generic copy.
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Id);
end if;
Push_Scope (Id);
Enter_Generic_Scope (Id);
Set_Inner_Instances (Id, New_Elmt_List);
Set_Categorization_From_Pragmas (N);
Set_Is_Pure (Id, Is_Pure (Current_Scope));
-- Link the declaration of the generic homonym in the generic copy to
-- the package it renames, so that it is always resolved properly.
Set_Generic_Homonym (Id, Defining_Unit_Name (Renaming));
Set_Entity (Associated_Node (Name (Renaming)), Id);
-- For a library unit, we have reconstructed the entity for the unit,
-- and must reset it in the library tables.
if Nkind (Parent (N)) = N_Compilation_Unit then
Set_Cunit_Entity (Current_Sem_Unit, Id);
end if;
Analyze_Generic_Formal_Part (N);
-- After processing the generic formals, analysis proceeds as for a
-- non-generic package.
Analyze (Specification (N));
Validate_Categorization_Dependency (N, Id);
End_Generic;
End_Package_Scope (Id);
Exit_Generic_Scope (Id);
if Nkind (Parent (N)) /= N_Compilation_Unit then
Move_Freeze_Nodes (Id, N, Visible_Declarations (Specification (N)));
Move_Freeze_Nodes (Id, N, Private_Declarations (Specification (N)));
Move_Freeze_Nodes (Id, N, Generic_Formal_Declarations (N));
else
Set_Body_Required (Parent (N), Unit_Requires_Body (Id));
Validate_RT_RAT_Component (N);
-- If this is a spec without a body, check that generic parameters
-- are referenced.
if not Body_Required (Parent (N)) then
Check_References (Id);
end if;
end if;
end Analyze_Generic_Package_Declaration;
--------------------------------------------
-- Analyze_Generic_Subprogram_Declaration --
--------------------------------------------
procedure Analyze_Generic_Subprogram_Declaration (N : Node_Id) is
Spec : Node_Id;
Id : Entity_Id;
Formals : List_Id;
New_N : Node_Id;
Result_Type : Entity_Id;
Save_Parent : Node_Id;
Typ : Entity_Id;
begin
Check_SPARK_Restriction ("generic is not allowed", N);
-- Create copy of generic unit, and save for instantiation. If the unit
-- is a child unit, do not copy the specifications for the parent, which
-- are not part of the generic tree.
Save_Parent := Parent_Spec (N);
Set_Parent_Spec (N, Empty);
New_N := Copy_Generic_Node (N, Empty, Instantiating => False);
Set_Parent_Spec (New_N, Save_Parent);
Rewrite (N, New_N);
Check_SPARK_Mode_In_Generic (N);
-- The aspect specifications are not attached to the tree, and must
-- be copied and attached to the generic copy explicitly.
if Present (Aspect_Specifications (New_N)) then
declare
Aspects : constant List_Id := Aspect_Specifications (N);
begin
Set_Has_Aspects (N, False);
Move_Aspects (New_N, To => N);
Set_Has_Aspects (Original_Node (N), False);
Set_Aspect_Specifications (Original_Node (N), Aspects);
end;
end if;
Spec := Specification (N);
Id := Defining_Entity (Spec);
Generate_Definition (Id);
Set_Contract (Id, Make_Contract (Sloc (Id)));
if Nkind (Id) = N_Defining_Operator_Symbol then
Error_Msg_N
("operator symbol not allowed for generic subprogram", Id);
end if;
Start_Generic;
Enter_Name (Id);
Set_Scope_Depth_Value (Id, Scope_Depth (Current_Scope) + 1);
Push_Scope (Id);
Enter_Generic_Scope (Id);
Set_Inner_Instances (Id, New_Elmt_List);
Set_Is_Pure (Id, Is_Pure (Current_Scope));
Analyze_Generic_Formal_Part (N);
Formals := Parameter_Specifications (Spec);
if Present (Formals) then
Process_Formals (Formals, Spec);
end if;
if Nkind (Spec) = N_Function_Specification then
Set_Ekind (Id, E_Generic_Function);
if Nkind (Result_Definition (Spec)) = N_Access_Definition then
Result_Type := Access_Definition (Spec, Result_Definition (Spec));
Set_Etype (Id, Result_Type);
-- Check restriction imposed by AI05-073: a generic function
-- cannot return an abstract type or an access to such.
-- This is a binding interpretation should it apply to earlier
-- versions of Ada as well as Ada 2012???
if Is_Abstract_Type (Designated_Type (Result_Type))
and then Ada_Version >= Ada_2012
then
Error_Msg_N ("generic function cannot have an access result"
& " that designates an abstract type", Spec);
end if;
else
Find_Type (Result_Definition (Spec));
Typ := Entity (Result_Definition (Spec));
if Is_Abstract_Type (Typ)
and then Ada_Version >= Ada_2012
then
Error_Msg_N
("generic function cannot have abstract result type", Spec);
end if;
-- If a null exclusion is imposed on the result type, then create
-- a null-excluding itype (an access subtype) and use it as the
-- function's Etype.
if Is_Access_Type (Typ)
and then Null_Exclusion_Present (Spec)
then
Set_Etype (Id,
Create_Null_Excluding_Itype
(T => Typ,
Related_Nod => Spec,
Scope_Id => Defining_Unit_Name (Spec)));
else
Set_Etype (Id, Typ);
end if;
end if;
else
Set_Ekind (Id, E_Generic_Procedure);
Set_Etype (Id, Standard_Void_Type);
end if;
-- For a library unit, we have reconstructed the entity for the unit,
-- and must reset it in the library tables. We also make sure that
-- Body_Required is set properly in the original compilation unit node.
if Nkind (Parent (N)) = N_Compilation_Unit then
Set_Cunit_Entity (Current_Sem_Unit, Id);
Set_Body_Required (Parent (N), Unit_Requires_Body (Id));
end if;
Set_Categorization_From_Pragmas (N);
Validate_Categorization_Dependency (N, Id);
Save_Global_References (Original_Node (N));
-- For ASIS purposes, convert any postcondition, precondition pragmas
-- into aspects, if N is not a compilation unit by itself, in order to
-- enable the analysis of expressions inside the corresponding PPC
-- pragmas.
if ASIS_Mode and then Is_List_Member (N) then
Make_Aspect_For_PPC_In_Gen_Sub_Decl (N);
end if;
-- To capture global references, analyze the expressions of aspects,
-- and propagate information to original tree. Note that in this case
-- analysis of attributes is not delayed until the freeze point.
-- It seems very hard to recreate the proper visibility of the generic
-- subprogram at a later point because the analysis of an aspect may
-- create pragmas after the generic copies have been made ???
if Has_Aspects (N) then
declare
Aspect : Node_Id;
begin
Aspect := First (Aspect_Specifications (N));
while Present (Aspect) loop
if Get_Aspect_Id (Aspect) /= Aspect_Warnings
and then Present (Expression (Aspect))
then
Analyze (Expression (Aspect));
end if;
Next (Aspect);
end loop;
Aspect := First (Aspect_Specifications (Original_Node (N)));
while Present (Aspect) loop
if Present (Expression (Aspect)) then
Save_Global_References (Expression (Aspect));
end if;
Next (Aspect);
end loop;
end;
end if;
End_Generic;
End_Scope;
Exit_Generic_Scope (Id);
Generate_Reference_To_Formals (Id);
List_Inherited_Pre_Post_Aspects (Id);
end Analyze_Generic_Subprogram_Declaration;
-----------------------------------
-- Analyze_Package_Instantiation --
-----------------------------------
procedure Analyze_Package_Instantiation (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
Gen_Id : constant Node_Id := Name (N);
Act_Decl : Node_Id;
Act_Decl_Name : Node_Id;
Act_Decl_Id : Entity_Id;
Act_Spec : Node_Id;
Act_Tree : Node_Id;
Gen_Decl : Node_Id;
Gen_Unit : Entity_Id;
Is_Actual_Pack : constant Boolean :=
Is_Internal (Defining_Entity (N));
Env_Installed : Boolean := False;
Parent_Installed : Boolean := False;
Renaming_List : List_Id;
Unit_Renaming : Node_Id;
Needs_Body : Boolean;
Inline_Now : Boolean := False;
Save_Style_Check : constant Boolean := Style_Check;
-- Save style check mode for restore on exit
procedure Delay_Descriptors (E : Entity_Id);
-- Delay generation of subprogram descriptors for given entity
function Might_Inline_Subp return Boolean;
-- If inlining is active and the generic contains inlined subprograms,
-- we instantiate the body. This may cause superfluous instantiations,
-- but it is simpler than detecting the need for the body at the point
-- of inlining, when the context of the instance is not available.
function Must_Inline_Subp return Boolean;
-- If inlining is active and the generic contains inlined subprograms,
-- return True if some of the inlined subprograms must be inlined by
-- the frontend.
-----------------------
-- Delay_Descriptors --
-----------------------
procedure Delay_Descriptors (E : Entity_Id) is
begin
if not Delay_Subprogram_Descriptors (E) then
Set_Delay_Subprogram_Descriptors (E);
Pending_Descriptor.Append (E);
end if;
end Delay_Descriptors;
-----------------------
-- Might_Inline_Subp --
-----------------------
function Might_Inline_Subp return Boolean is
E : Entity_Id;
begin
if not Inline_Processing_Required then
return False;
else
E := First_Entity (Gen_Unit);
while Present (E) loop
if Is_Subprogram (E)
and then Is_Inlined (E)
then
return True;
end if;
Next_Entity (E);
end loop;
end if;
return False;
end Might_Inline_Subp;
----------------------
-- Must_Inline_Subp --
----------------------
function Must_Inline_Subp return Boolean is
E : Entity_Id;
begin
if not Inline_Processing_Required then
return False;
else
E := First_Entity (Gen_Unit);
while Present (E) loop
if Is_Subprogram (E)
and then Is_Inlined (E)
and then Must_Inline (E)
then
return True;
end if;
Next_Entity (E);
end loop;
end if;
return False;
end Must_Inline_Subp;
-- Local declarations
Vis_Prims_List : Elist_Id := No_Elist;
-- List of primitives made temporarily visible in the instantiation
-- to match the visibility of the formal type
-- Start of processing for Analyze_Package_Instantiation
begin
Check_SPARK_Restriction ("generic is not allowed", N);
-- Very first thing: check for Text_IO sp[ecial unit in case we are
-- instantiating one of the children of [[Wide_]Wide_]Text_IO.
Check_Text_IO_Special_Unit (Name (N));
-- Make node global for error reporting
Instantiation_Node := N;
-- Turn off style checking in instances. If the check is enabled on the
-- generic unit, a warning in an instance would just be noise. If not
-- enabled on the generic, then a warning in an instance is just wrong.
Style_Check := False;
-- Case of instantiation of a generic package
if Nkind (N) = N_Package_Instantiation then
Act_Decl_Id := New_Copy (Defining_Entity (N));
Set_Comes_From_Source (Act_Decl_Id, True);
if Nkind (Defining_Unit_Name (N)) = N_Defining_Program_Unit_Name then
Act_Decl_Name :=
Make_Defining_Program_Unit_Name (Loc,
Name => New_Copy_Tree (Name (Defining_Unit_Name (N))),
Defining_Identifier => Act_Decl_Id);
else
Act_Decl_Name := Act_Decl_Id;
end if;
-- Case of instantiation of a formal package
else
Act_Decl_Id := Defining_Identifier (N);
Act_Decl_Name := Act_Decl_Id;
end if;
Generate_Definition (Act_Decl_Id);
Preanalyze_Actuals (N);
Init_Env;
Env_Installed := True;
-- Reset renaming map for formal types. The mapping is established
-- when analyzing the generic associations, but some mappings are
-- inherited from formal packages of parent units, and these are
-- constructed when the parents are installed.
Generic_Renamings.Set_Last (0);
Generic_Renamings_HTable.Reset;
Check_Generic_Child_Unit (Gen_Id, Parent_Installed);
Gen_Unit := Entity (Gen_Id);
-- Verify that it is the name of a generic package
-- A visibility glitch: if the instance is a child unit and the generic
-- is the generic unit of a parent instance (i.e. both the parent and
-- the child units are instances of the same package) the name now
-- denotes the renaming within the parent, not the intended generic
-- unit. See if there is a homonym that is the desired generic. The
-- renaming declaration must be visible inside the instance of the
-- child, but not when analyzing the name in the instantiation itself.
if Ekind (Gen_Unit) = E_Package
and then Present (Renamed_Entity (Gen_Unit))
and then In_Open_Scopes (Renamed_Entity (Gen_Unit))
and then Is_Generic_Instance (Renamed_Entity (Gen_Unit))
and then Present (Homonym (Gen_Unit))
then
Gen_Unit := Homonym (Gen_Unit);
end if;
if Etype (Gen_Unit) = Any_Type then
Restore_Env;
goto Leave;
elsif Ekind (Gen_Unit) /= E_Generic_Package then
-- Ada 2005 (AI-50217): Cannot use instance in limited with_clause
if From_Limited_With (Gen_Unit) then
Error_Msg_N
("cannot instantiate a limited withed package", Gen_Id);
else
Error_Msg_NE
("& is not the name of a generic package", Gen_Id, Gen_Unit);
end if;
Restore_Env;
goto Leave;
end if;
if In_Extended_Main_Source_Unit (N) then
Set_Is_Instantiated (Gen_Unit);
Generate_Reference (Gen_Unit, N);
if Present (Renamed_Object (Gen_Unit)) then
Set_Is_Instantiated (Renamed_Object (Gen_Unit));
Generate_Reference (Renamed_Object (Gen_Unit), N);
end if;
end if;
if Nkind (Gen_Id) = N_Identifier
and then Chars (Gen_Unit) = Chars (Defining_Entity (N))
then
Error_Msg_NE
("& is hidden within declaration of instance", Gen_Id, Gen_Unit);
elsif Nkind (Gen_Id) = N_Expanded_Name
and then Is_Child_Unit (Gen_Unit)
and then Nkind (Prefix (Gen_Id)) = N_Identifier
and then Chars (Act_Decl_Id) = Chars (Prefix (Gen_Id))
then
Error_Msg_N
("& is hidden within declaration of instance ", Prefix (Gen_Id));
end if;
Set_Entity (Gen_Id, Gen_Unit);
-- If generic is a renaming, get original generic unit
if Present (Renamed_Object (Gen_Unit))
and then Ekind (Renamed_Object (Gen_Unit)) = E_Generic_Package
then
Gen_Unit := Renamed_Object (Gen_Unit);
end if;
-- Verify that there are no circular instantiations
if In_Open_Scopes (Gen_Unit) then
Error_Msg_NE ("instantiation of & within itself", N, Gen_Unit);
Restore_Env;
goto Leave;
elsif Contains_Instance_Of (Gen_Unit, Current_Scope, Gen_Id) then
Error_Msg_Node_2 := Current_Scope;
Error_Msg_NE
("circular Instantiation: & instantiated in &!", N, Gen_Unit);
Circularity_Detected := True;
Restore_Env;
goto Leave;
else
Gen_Decl := Unit_Declaration_Node (Gen_Unit);
-- Initialize renamings map, for error checking, and the list that
-- holds private entities whose views have changed between generic
-- definition and instantiation. If this is the instance created to
-- validate an actual package, the instantiation environment is that
-- of the enclosing instance.
Create_Instantiation_Source (N, Gen_Unit, False, S_Adjustment);
-- Copy original generic tree, to produce text for instantiation
Act_Tree :=
Copy_Generic_Node
(Original_Node (Gen_Decl), Empty, Instantiating => True);
Act_Spec := Specification (Act_Tree);
-- If this is the instance created to validate an actual package,
-- only the formals matter, do not examine the package spec itself.
if Is_Actual_Pack then
Set_Visible_Declarations (Act_Spec, New_List);
Set_Private_Declarations (Act_Spec, New_List);
end if;
Renaming_List :=
Analyze_Associations
(I_Node => N,
Formals => Generic_Formal_Declarations (Act_Tree),
F_Copy => Generic_Formal_Declarations (Gen_Decl));
Vis_Prims_List := Check_Hidden_Primitives (Renaming_List);
Set_Instance_Env (Gen_Unit, Act_Decl_Id);
Set_Defining_Unit_Name (Act_Spec, Act_Decl_Name);
Set_Is_Generic_Instance (Act_Decl_Id);
Set_Generic_Parent (Act_Spec, Gen_Unit);
-- References to the generic in its own declaration or its body are
-- references to the instance. Add a renaming declaration for the
-- generic unit itself. This declaration, as well as the renaming
-- declarations for the generic formals, must remain private to the
-- unit: the formals, because this is the language semantics, and
-- the unit because its use is an artifact of the implementation.
Unit_Renaming :=
Make_Package_Renaming_Declaration (Loc,
Defining_Unit_Name =>
Make_Defining_Identifier (Loc, Chars (Gen_Unit)),
Name => New_Occurrence_Of (Act_Decl_Id, Loc));
Append (Unit_Renaming, Renaming_List);
-- The renaming declarations are the first local declarations of the
-- new unit.
if Is_Non_Empty_List (Visible_Declarations (Act_Spec)) then
Insert_List_Before
(First (Visible_Declarations (Act_Spec)), Renaming_List);
else
Set_Visible_Declarations (Act_Spec, Renaming_List);
end if;
Act_Decl :=
Make_Package_Declaration (Loc,
Specification => Act_Spec);
-- Propagate the aspect specifications from the package declaration
-- template to the instantiated version of the package declaration.
if Has_Aspects (Act_Tree) then
Set_Aspect_Specifications (Act_Decl,
New_Copy_List_Tree (Aspect_Specifications (Act_Tree)));
end if;
-- Save the instantiation node, for subsequent instantiation of the
-- body, if there is one and we are generating code for the current
-- unit. Mark unit as having a body (avoids premature error message).
-- We instantiate the body if we are generating code, if we are
-- generating cross-reference information, or if we are building
-- trees for ASIS use or GNATprove use.
declare
Enclosing_Body_Present : Boolean := False;
-- If the generic unit is not a compilation unit, then a body may
-- be present in its parent even if none is required. We create a
-- tentative pending instantiation for the body, which will be
-- discarded if none is actually present.
Scop : Entity_Id;
begin
if Scope (Gen_Unit) /= Standard_Standard
and then not Is_Child_Unit (Gen_Unit)
then
Scop := Scope (Gen_Unit);
while Present (Scop)
and then Scop /= Standard_Standard
loop
if Unit_Requires_Body (Scop) then
Enclosing_Body_Present := True;
exit;
elsif In_Open_Scopes (Scop)
and then In_Package_Body (Scop)
then
Enclosing_Body_Present := True;
exit;
end if;
exit when Is_Compilation_Unit (Scop);
Scop := Scope (Scop);
end loop;
end if;
-- If front-end inlining is enabled, and this is a unit for which
-- code will be generated, we instantiate the body at once.
-- This is done if the instance is not the main unit, and if the
-- generic is not a child unit of another generic, to avoid scope
-- problems and the reinstallation of parent instances.
if Expander_Active
and then (not Is_Child_Unit (Gen_Unit)
or else not Is_Generic_Unit (Scope (Gen_Unit)))
and then Might_Inline_Subp
and then not Is_Actual_Pack
then
if not Back_End_Inlining
and then Front_End_Inlining
and then (Is_In_Main_Unit (N)
or else In_Main_Context (Current_Scope))
and then Nkind (Parent (N)) /= N_Compilation_Unit
then
Inline_Now := True;
elsif Back_End_Inlining
and then Must_Inline_Subp
and then (Is_In_Main_Unit (N)
or else In_Main_Context (Current_Scope))
and then Nkind (Parent (N)) /= N_Compilation_Unit
then
Inline_Now := True;
-- In configurable_run_time mode we force the inlining of
-- predefined subprograms marked Inline_Always, to minimize
-- the use of the run-time library.
elsif Is_Predefined_File_Name
(Unit_File_Name (Get_Source_Unit (Gen_Decl)))
and then Configurable_Run_Time_Mode
and then Nkind (Parent (N)) /= N_Compilation_Unit
then
Inline_Now := True;
end if;
-- If the current scope is itself an instance within a child
-- unit, there will be duplications in the scope stack, and the
-- unstacking mechanism in Inline_Instance_Body will fail.
-- This loses some rare cases of optimization, and might be
-- improved some day, if we can find a proper abstraction for
-- "the complete compilation context" that can be saved and
-- restored. ???
if Is_Generic_Instance (Current_Scope) then
declare
Curr_Unit : constant Entity_Id :=
Cunit_Entity (Current_Sem_Unit);
begin
if Curr_Unit /= Current_Scope
and then Is_Child_Unit (Curr_Unit)
then
Inline_Now := False;
end if;
end;
end if;
end if;
Needs_Body :=
(Unit_Requires_Body (Gen_Unit)
or else Enclosing_Body_Present
or else Present (Corresponding_Body (Gen_Decl)))
and then (Is_In_Main_Unit (N) or else Might_Inline_Subp)
and then not Is_Actual_Pack
and then not Inline_Now
and then (Operating_Mode = Generate_Code
-- Need comment for this check ???
or else (Operating_Mode = Check_Semantics
and then (ASIS_Mode or GNATprove_Mode)));
-- If front_end_inlining is enabled, do not instantiate body if
-- within a generic context.
if (Front_End_Inlining and then not Expander_Active)
or else Is_Generic_Unit (Cunit_Entity (Main_Unit))
then
Needs_Body := False;
end if;
-- If the current context is generic, and the package being
-- instantiated is declared within a formal package, there is no
-- body to instantiate until the enclosing generic is instantiated
-- and there is an actual for the formal package. If the formal
-- package has parameters, we build a regular package instance for
-- it, that precedes the original formal package declaration.
if In_Open_Scopes (Scope (Scope (Gen_Unit))) then
declare
Decl : constant Node_Id :=
Original_Node
(Unit_Declaration_Node (Scope (Gen_Unit)));
begin
if Nkind (Decl) = N_Formal_Package_Declaration
or else (Nkind (Decl) = N_Package_Declaration
and then Is_List_Member (Decl)
and then Present (Next (Decl))
and then
Nkind (Next (Decl)) =
N_Formal_Package_Declaration)
then
Needs_Body := False;
end if;
end;
end if;
end;
-- For RCI unit calling stubs, we omit the instance body if the
-- instance is the RCI library unit itself.
-- However there is a special case for nested instances: in this case
-- we do generate the instance body, as it might be required, e.g.
-- because it provides stream attributes for some type used in the
-- profile of a remote subprogram. This is consistent with 12.3(12),
-- which indicates that the instance body occurs at the place of the
-- instantiation, and thus is part of the RCI declaration, which is
-- present on all client partitions (this is E.2.3(18)).
-- Note that AI12-0002 may make it illegal at some point to have
-- stream attributes defined in an RCI unit, in which case this
-- special case will become unnecessary. In the meantime, there
-- is known application code in production that depends on this
-- being possible, so we definitely cannot eliminate the body in
-- the case of nested instances for the time being.
-- When we generate a nested instance body, calling stubs for any
-- relevant subprogram will be be inserted immediately after the
-- subprogram declarations, and will take precedence over the
-- subsequent (original) body. (The stub and original body will be
-- complete homographs, but this is permitted in an instance).
-- (Could we do better and remove the original body???)
if Distribution_Stub_Mode = Generate_Caller_Stub_Body
and then Comes_From_Source (N)
and then Nkind (Parent (N)) = N_Compilation_Unit
then
Needs_Body := False;
end if;
if Needs_Body then
-- Here is a defence against a ludicrous number of instantiations
-- caused by a circular set of instantiation attempts.
if Pending_Instantiations.Last > Maximum_Instantiations then
Error_Msg_Uint_1 := UI_From_Int (Maximum_Instantiations);
Error_Msg_N ("too many instantiations, exceeds max of^", N);
Error_Msg_N ("\limit can be changed using -gnateinn switch", N);
raise Unrecoverable_Error;
end if;
-- Indicate that the enclosing scopes contain an instantiation,
-- and that cleanup actions should be delayed until after the
-- instance body is expanded.
Check_Forward_Instantiation (Gen_Decl);
if Nkind (N) = N_Package_Instantiation then
declare
Enclosing_Master : Entity_Id;
begin
-- Loop to search enclosing masters
Enclosing_Master := Current_Scope;
Scope_Loop : while Enclosing_Master /= Standard_Standard loop
if Ekind (Enclosing_Master) = E_Package then
if Is_Compilation_Unit (Enclosing_Master) then
if In_Package_Body (Enclosing_Master) then
Delay_Descriptors
(Body_Entity (Enclosing_Master));
else
Delay_Descriptors
(Enclosing_Master);
end if;
exit Scope_Loop;
else
Enclosing_Master := Scope (Enclosing_Master);
end if;
elsif Is_Generic_Unit (Enclosing_Master)
or else Ekind (Enclosing_Master) = E_Void
then
-- Cleanup actions will eventually be performed on the
-- enclosing subprogram or package instance, if any.
-- Enclosing scope is void in the formal part of a
-- generic subprogram.
exit Scope_Loop;
else
if Ekind (Enclosing_Master) = E_Entry
and then
Ekind (Scope (Enclosing_Master)) = E_Protected_Type
then
if not Expander_Active then
exit Scope_Loop;
else
Enclosing_Master :=
Protected_Body_Subprogram (Enclosing_Master);
end if;
end if;
Set_Delay_Cleanups (Enclosing_Master);
while Ekind (Enclosing_Master) = E_Block loop
Enclosing_Master := Scope (Enclosing_Master);
end loop;
if Is_Subprogram (Enclosing_Master) then
Delay_Descriptors (Enclosing_Master);
elsif Is_Task_Type (Enclosing_Master) then
declare
TBP : constant Node_Id :=
Get_Task_Body_Procedure
(Enclosing_Master);
begin
if Present (TBP) then
Delay_Descriptors (TBP);
Set_Delay_Cleanups (TBP);
end if;
end;
end if;
exit Scope_Loop;
end if;
end loop Scope_Loop;
end;
-- Make entry in table
Pending_Instantiations.Append
((Inst_Node => N,
Act_Decl => Act_Decl,
Expander_Status => Expander_Active,
Current_Sem_Unit => Current_Sem_Unit,
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top => Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma));
end if;
end if;
Set_Categorization_From_Pragmas (Act_Decl);
if Parent_Installed then
Hide_Current_Scope;
end if;
Set_Instance_Spec (N, Act_Decl);
-- If not a compilation unit, insert the package declaration before
-- the original instantiation node.
if Nkind (Parent (N)) /= N_Compilation_Unit then
Mark_Rewrite_Insertion (Act_Decl);
Insert_Before (N, Act_Decl);
Analyze (Act_Decl);
-- For an instantiation that is a compilation unit, place
-- declaration on current node so context is complete for analysis
-- (including nested instantiations). If this is the main unit,
-- the declaration eventually replaces the instantiation node.
-- If the instance body is created later, it replaces the
-- instance node, and the declaration is attached to it
-- (see Build_Instance_Compilation_Unit_Nodes).
else
if Cunit_Entity (Current_Sem_Unit) = Defining_Entity (N) then
-- The entity for the current unit is the newly created one,
-- and all semantic information is attached to it.
Set_Cunit_Entity (Current_Sem_Unit, Act_Decl_Id);
-- If this is the main unit, replace the main entity as well
if Current_Sem_Unit = Main_Unit then
Main_Unit_Entity := Act_Decl_Id;
end if;
end if;
Set_Unit (Parent (N), Act_Decl);
Set_Parent_Spec (Act_Decl, Parent_Spec (N));
Set_Package_Instantiation (Act_Decl_Id, N);
-- Process aspect specifications of the instance node, if any, to
-- take into account categorization pragmas before analyzing the
-- instance.
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Act_Decl_Id);
end if;
Analyze (Act_Decl);
Set_Unit (Parent (N), N);
Set_Body_Required (Parent (N), False);
-- We never need elaboration checks on instantiations, since by
-- definition, the body instantiation is elaborated at the same
-- time as the spec instantiation.
Set_Suppress_Elaboration_Warnings (Act_Decl_Id);
Set_Kill_Elaboration_Checks (Act_Decl_Id);
end if;
Check_Elab_Instantiation (N);
if ABE_Is_Certain (N) and then Needs_Body then
Pending_Instantiations.Decrement_Last;
end if;
Check_Hidden_Child_Unit (N, Gen_Unit, Act_Decl_Id);
Set_First_Private_Entity (Defining_Unit_Name (Unit_Renaming),
First_Private_Entity (Act_Decl_Id));
-- If the instantiation will receive a body, the unit will be
-- transformed into a package body, and receive its own elaboration
-- entity. Otherwise, the nature of the unit is now a package
-- declaration.
if Nkind (Parent (N)) = N_Compilation_Unit
and then not Needs_Body
then
Rewrite (N, Act_Decl);
end if;
if Present (Corresponding_Body (Gen_Decl))
or else Unit_Requires_Body (Gen_Unit)
then
Set_Has_Completion (Act_Decl_Id);
end if;
Check_Formal_Packages (Act_Decl_Id);
Restore_Hidden_Primitives (Vis_Prims_List);
Restore_Private_Views (Act_Decl_Id);
Inherit_Context (Gen_Decl, N);
if Parent_Installed then
Remove_Parent;
end if;
Restore_Env;
Env_Installed := False;
end if;
Validate_Categorization_Dependency (N, Act_Decl_Id);
-- There used to be a check here to prevent instantiations in local
-- contexts if the No_Local_Allocators restriction was active. This
-- check was removed by a binding interpretation in AI-95-00130/07,
-- but we retain the code for documentation purposes.
-- if Ekind (Act_Decl_Id) /= E_Void
-- and then not Is_Library_Level_Entity (Act_Decl_Id)
-- then
-- Check_Restriction (No_Local_Allocators, N);
-- end if;
if Inline_Now then
Inline_Instance_Body (N, Gen_Unit, Act_Decl);
end if;
-- The following is a tree patch for ASIS: ASIS needs separate nodes to
-- be used as defining identifiers for a formal package and for the
-- corresponding expanded package.
if Nkind (N) = N_Formal_Package_Declaration then
Act_Decl_Id := New_Copy (Defining_Entity (N));
Set_Comes_From_Source (Act_Decl_Id, True);
Set_Is_Generic_Instance (Act_Decl_Id, False);
Set_Defining_Identifier (N, Act_Decl_Id);
end if;
Style_Check := Save_Style_Check;
-- Check that if N is an instantiation of System.Dim_Float_IO or
-- System.Dim_Integer_IO, the formal type has a dimension system.
if Nkind (N) = N_Package_Instantiation
and then Is_Dim_IO_Package_Instantiation (N)
then
declare
Assoc : constant Node_Id := First (Generic_Associations (N));
begin
if not Has_Dimension_System
(Etype (Explicit_Generic_Actual_Parameter (Assoc)))
then
Error_Msg_N ("type with a dimension system expected", Assoc);
end if;
end;
end if;
<<Leave>>
if Has_Aspects (N) and then Nkind (Parent (N)) /= N_Compilation_Unit then
Analyze_Aspect_Specifications (N, Act_Decl_Id);
end if;
exception
when Instantiation_Error =>
if Parent_Installed then
Remove_Parent;
end if;
if Env_Installed then
Restore_Env;
end if;
Style_Check := Save_Style_Check;
end Analyze_Package_Instantiation;
--------------------------
-- Inline_Instance_Body --
--------------------------
procedure Inline_Instance_Body
(N : Node_Id;
Gen_Unit : Entity_Id;
Act_Decl : Node_Id)
is
Vis : Boolean;
Gen_Comp : constant Entity_Id :=
Cunit_Entity (Get_Source_Unit (Gen_Unit));
Curr_Comp : constant Node_Id := Cunit (Current_Sem_Unit);
Curr_Scope : Entity_Id := Empty;
Curr_Unit : constant Entity_Id := Cunit_Entity (Current_Sem_Unit);
Removed : Boolean := False;
Num_Scopes : Int := 0;
Scope_Stack_Depth : constant Int :=
Scope_Stack.Last - Scope_Stack.First + 1;
Use_Clauses : array (1 .. Scope_Stack_Depth) of Node_Id;
Instances : array (1 .. Scope_Stack_Depth) of Entity_Id;
Inner_Scopes : array (1 .. Scope_Stack_Depth) of Entity_Id;
List : Elist_Id;
Num_Inner : Int := 0;
N_Instances : Int := 0;
S : Entity_Id;
begin
-- Case of generic unit defined in another unit. We must remove the
-- complete context of the current unit to install that of the generic.
if Gen_Comp /= Cunit_Entity (Current_Sem_Unit) then
-- Add some comments for the following two loops ???
S := Current_Scope;
while Present (S) and then S /= Standard_Standard loop
loop
Num_Scopes := Num_Scopes + 1;
Use_Clauses (Num_Scopes) :=
(Scope_Stack.Table
(Scope_Stack.Last - Num_Scopes + 1).
First_Use_Clause);
End_Use_Clauses (Use_Clauses (Num_Scopes));
exit when Scope_Stack.Last - Num_Scopes + 1 = Scope_Stack.First
or else Scope_Stack.Table
(Scope_Stack.Last - Num_Scopes).Entity
= Scope (S);
end loop;
exit when Is_Generic_Instance (S)
and then (In_Package_Body (S)
or else Ekind (S) = E_Procedure
or else Ekind (S) = E_Function);
S := Scope (S);
end loop;
Vis := Is_Immediately_Visible (Gen_Comp);
-- Find and save all enclosing instances
S := Current_Scope;
while Present (S)
and then S /= Standard_Standard
loop
if Is_Generic_Instance (S) then
N_Instances := N_Instances + 1;
Instances (N_Instances) := S;
exit when In_Package_Body (S);
end if;
S := Scope (S);
end loop;
-- Remove context of current compilation unit, unless we are within a
-- nested package instantiation, in which case the context has been
-- removed previously.
-- If current scope is the body of a child unit, remove context of
-- spec as well. If an enclosing scope is an instance body, the
-- context has already been removed, but the entities in the body
-- must be made invisible as well.
S := Current_Scope;
while Present (S)
and then S /= Standard_Standard
loop
if Is_Generic_Instance (S)
and then (In_Package_Body (S)
or else Ekind (S) = E_Procedure
or else Ekind (S) = E_Function)
then
-- We still have to remove the entities of the enclosing
-- instance from direct visibility.
declare
E : Entity_Id;
begin
E := First_Entity (S);
while Present (E) loop
Set_Is_Immediately_Visible (E, False);
Next_Entity (E);
end loop;
end;
exit;
end if;
if S = Curr_Unit
or else (Ekind (Curr_Unit) = E_Package_Body
and then S = Spec_Entity (Curr_Unit))
or else (Ekind (Curr_Unit) = E_Subprogram_Body
and then S =
Corresponding_Spec
(Unit_Declaration_Node (Curr_Unit)))
then
Removed := True;
-- Remove entities in current scopes from visibility, so that
-- instance body is compiled in a clean environment.
List := Save_Scope_Stack (Handle_Use => False);
if Is_Child_Unit (S) then
-- Remove child unit from stack, as well as inner scopes.
-- Removing the context of a child unit removes parent units
-- as well.
while Current_Scope /= S loop
Num_Inner := Num_Inner + 1;
Inner_Scopes (Num_Inner) := Current_Scope;
Pop_Scope;
end loop;
Pop_Scope;
Remove_Context (Curr_Comp);
Curr_Scope := S;
else
Remove_Context (Curr_Comp);
end if;
if Ekind (Curr_Unit) = E_Package_Body then
Remove_Context (Library_Unit (Curr_Comp));
end if;
end if;
S := Scope (S);
end loop;
pragma Assert (Num_Inner < Num_Scopes);
Push_Scope (Standard_Standard);
Scope_Stack.Table (Scope_Stack.Last).Is_Active_Stack_Base := True;
Instantiate_Package_Body
(Body_Info =>
((Inst_Node => N,
Act_Decl => Act_Decl,
Expander_Status => Expander_Active,
Current_Sem_Unit => Current_Sem_Unit,
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top => Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma)),
Inlined_Body => True);
Pop_Scope;
-- Restore context
Set_Is_Immediately_Visible (Gen_Comp, Vis);
-- Reset Generic_Instance flag so that use clauses can be installed
-- in the proper order. (See Use_One_Package for effect of enclosing
-- instances on processing of use clauses).
for J in 1 .. N_Instances loop
Set_Is_Generic_Instance (Instances (J), False);
end loop;
if Removed then
Install_Context (Curr_Comp);
if Present (Curr_Scope)
and then Is_Child_Unit (Curr_Scope)
then
Push_Scope (Curr_Scope);
Set_Is_Immediately_Visible (Curr_Scope);
-- Finally, restore inner scopes as well
for J in reverse 1 .. Num_Inner loop
Push_Scope (Inner_Scopes (J));
end loop;
end if;
Restore_Scope_Stack (List, Handle_Use => False);
if Present (Curr_Scope)
and then
(In_Private_Part (Curr_Scope)
or else In_Package_Body (Curr_Scope))
then
-- Install private declaration of ancestor units, which are
-- currently available. Restore_Scope_Stack and Install_Context
-- only install the visible part of parents.
declare
Par : Entity_Id;
begin
Par := Scope (Curr_Scope);
while (Present (Par))
and then Par /= Standard_Standard
loop
Install_Private_Declarations (Par);
Par := Scope (Par);
end loop;
end;
end if;
end if;
-- Restore use clauses. For a child unit, use clauses in the parents
-- are restored when installing the context, so only those in inner
-- scopes (and those local to the child unit itself) need to be
-- installed explicitly.
if Is_Child_Unit (Curr_Unit)
and then Removed
then
for J in reverse 1 .. Num_Inner + 1 loop
Scope_Stack.Table (Scope_Stack.Last - J + 1).First_Use_Clause :=
Use_Clauses (J);
Install_Use_Clauses (Use_Clauses (J));
end loop;
else
for J in reverse 1 .. Num_Scopes loop
Scope_Stack.Table (Scope_Stack.Last - J + 1).First_Use_Clause :=
Use_Clauses (J);
Install_Use_Clauses (Use_Clauses (J));
end loop;
end if;
-- Restore status of instances. If one of them is a body, make its
-- local entities visible again.
declare
E : Entity_Id;
Inst : Entity_Id;
begin
for J in 1 .. N_Instances loop
Inst := Instances (J);
Set_Is_Generic_Instance (Inst, True);
if In_Package_Body (Inst)
or else Ekind (S) = E_Procedure
or else Ekind (S) = E_Function
then
E := First_Entity (Instances (J));
while Present (E) loop
Set_Is_Immediately_Visible (E);
Next_Entity (E);
end loop;
end if;
end loop;
end;
-- If generic unit is in current unit, current context is correct
else
Instantiate_Package_Body
(Body_Info =>
((Inst_Node => N,
Act_Decl => Act_Decl,
Expander_Status => Expander_Active,
Current_Sem_Unit => Current_Sem_Unit,
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top => Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma)),
Inlined_Body => True);
end if;
end Inline_Instance_Body;
-------------------------------------
-- Analyze_Procedure_Instantiation --
-------------------------------------
procedure Analyze_Procedure_Instantiation (N : Node_Id) is
begin
Analyze_Subprogram_Instantiation (N, E_Procedure);
end Analyze_Procedure_Instantiation;
-----------------------------------
-- Need_Subprogram_Instance_Body --
-----------------------------------
function Need_Subprogram_Instance_Body
(N : Node_Id;
Subp : Entity_Id) return Boolean
is
begin
-- Must be inlined (or inlined renaming)
if (Is_In_Main_Unit (N)
or else Is_Inlined (Subp)
or else Is_Inlined (Alias (Subp)))
-- Must be generating code or analyzing code in ASIS/GNATprove mode
and then (Operating_Mode = Generate_Code
or else (Operating_Mode = Check_Semantics
and then (ASIS_Mode or GNATprove_Mode)))
-- The body is needed when generating code (full expansion), in ASIS
-- mode for other tools, and in GNATprove mode (special expansion) for
-- formal verification of the body itself.
and then (Expander_Active or ASIS_Mode or GNATprove_Mode)
-- No point in inlining if ABE is inevitable
and then not ABE_Is_Certain (N)
-- Or if subprogram is eliminated
and then not Is_Eliminated (Subp)
then
Pending_Instantiations.Append
((Inst_Node => N,
Act_Decl => Unit_Declaration_Node (Subp),
Expander_Status => Expander_Active,
Current_Sem_Unit => Current_Sem_Unit,
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top => Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma));
return True;
-- Here if not inlined, or we ignore the inlining
else
return False;
end if;
end Need_Subprogram_Instance_Body;
--------------------------------------
-- Analyze_Subprogram_Instantiation --
--------------------------------------
procedure Analyze_Subprogram_Instantiation
(N : Node_Id;
K : Entity_Kind)
is
Loc : constant Source_Ptr := Sloc (N);
Gen_Id : constant Node_Id := Name (N);
Anon_Id : constant Entity_Id :=
Make_Defining_Identifier (Sloc (Defining_Entity (N)),
Chars => New_External_Name
(Chars (Defining_Entity (N)), 'R'));
Act_Decl_Id : Entity_Id;
Act_Decl : Node_Id;
Act_Spec : Node_Id;
Act_Tree : Node_Id;
Env_Installed : Boolean := False;
Gen_Unit : Entity_Id;
Gen_Decl : Node_Id;
Pack_Id : Entity_Id;
Parent_Installed : Boolean := False;
Renaming_List : List_Id;
procedure Analyze_Instance_And_Renamings;
-- The instance must be analyzed in a context that includes the mappings
-- of generic parameters into actuals. We create a package declaration
-- for this purpose, and a subprogram with an internal name within the
-- package. The subprogram instance is simply an alias for the internal
-- subprogram, declared in the current scope.
------------------------------------
-- Analyze_Instance_And_Renamings --
------------------------------------
procedure Analyze_Instance_And_Renamings is
Def_Ent : constant Entity_Id := Defining_Entity (N);
Pack_Decl : Node_Id;
begin
if Nkind (Parent (N)) = N_Compilation_Unit then
-- For the case of a compilation unit, the container package has
-- the same name as the instantiation, to insure that the binder
-- calls the elaboration procedure with the right name. Copy the
-- entity of the instance, which may have compilation level flags
-- (e.g. Is_Child_Unit) set.
Pack_Id := New_Copy (Def_Ent);
else
-- Otherwise we use the name of the instantiation concatenated
-- with its source position to ensure uniqueness if there are
-- several instantiations with the same name.
Pack_Id :=
Make_Defining_Identifier (Loc,
Chars => New_External_Name
(Related_Id => Chars (Def_Ent),
Suffix => "GP",
Suffix_Index => Source_Offset (Sloc (Def_Ent))));
end if;
Pack_Decl := Make_Package_Declaration (Loc,
Specification => Make_Package_Specification (Loc,
Defining_Unit_Name => Pack_Id,
Visible_Declarations => Renaming_List,
End_Label => Empty));
Set_Instance_Spec (N, Pack_Decl);
Set_Is_Generic_Instance (Pack_Id);
Set_Debug_Info_Needed (Pack_Id);
-- Case of not a compilation unit
if Nkind (Parent (N)) /= N_Compilation_Unit then
Mark_Rewrite_Insertion (Pack_Decl);
Insert_Before (N, Pack_Decl);
Set_Has_Completion (Pack_Id);
-- Case of an instantiation that is a compilation unit
-- Place declaration on current node so context is complete for
-- analysis (including nested instantiations), and for use in a
-- context_clause (see Analyze_With_Clause).
else
Set_Unit (Parent (N), Pack_Decl);
Set_Parent_Spec (Pack_Decl, Parent_Spec (N));
end if;
Analyze (Pack_Decl);
Check_Formal_Packages (Pack_Id);
Set_Is_Generic_Instance (Pack_Id, False);
-- Why do we clear Is_Generic_Instance??? We set it 20 lines
-- above???
-- Body of the enclosing package is supplied when instantiating the
-- subprogram body, after semantic analysis is completed.
if Nkind (Parent (N)) = N_Compilation_Unit then
-- Remove package itself from visibility, so it does not
-- conflict with subprogram.
Set_Name_Entity_Id (Chars (Pack_Id), Homonym (Pack_Id));
-- Set name and scope of internal subprogram so that the proper
-- external name will be generated. The proper scope is the scope
-- of the wrapper package. We need to generate debugging info for
-- the internal subprogram, so set flag accordingly.
Set_Chars (Anon_Id, Chars (Defining_Entity (N)));
Set_Scope (Anon_Id, Scope (Pack_Id));
-- Mark wrapper package as referenced, to avoid spurious warnings
-- if the instantiation appears in various with_ clauses of
-- subunits of the main unit.
Set_Referenced (Pack_Id);
end if;
Set_Is_Generic_Instance (Anon_Id);
Set_Debug_Info_Needed (Anon_Id);
Act_Decl_Id := New_Copy (Anon_Id);
Set_Parent (Act_Decl_Id, Parent (Anon_Id));
Set_Chars (Act_Decl_Id, Chars (Defining_Entity (N)));
Set_Sloc (Act_Decl_Id, Sloc (Defining_Entity (N)));
Set_Comes_From_Source (Act_Decl_Id, True);
-- The signature may involve types that are not frozen yet, but the
-- subprogram will be frozen at the point the wrapper package is
-- frozen, so it does not need its own freeze node. In fact, if one
-- is created, it might conflict with the freezing actions from the
-- wrapper package.
Set_Has_Delayed_Freeze (Anon_Id, False);
-- If the instance is a child unit, mark the Id accordingly. Mark
-- the anonymous entity as well, which is the real subprogram and
-- which is used when the instance appears in a context clause.
-- Similarly, propagate the Is_Eliminated flag to handle properly
-- nested eliminated subprograms.
Set_Is_Child_Unit (Act_Decl_Id, Is_Child_Unit (Defining_Entity (N)));
Set_Is_Child_Unit (Anon_Id, Is_Child_Unit (Defining_Entity (N)));
New_Overloaded_Entity (Act_Decl_Id);
Check_Eliminated (Act_Decl_Id);
Set_Is_Eliminated (Anon_Id, Is_Eliminated (Act_Decl_Id));
-- In compilation unit case, kill elaboration checks on the
-- instantiation, since they are never needed -- the body is
-- instantiated at the same point as the spec.
if Nkind (Parent (N)) = N_Compilation_Unit then
Set_Suppress_Elaboration_Warnings (Act_Decl_Id);
Set_Kill_Elaboration_Checks (Act_Decl_Id);
Set_Is_Compilation_Unit (Anon_Id);
Set_Cunit_Entity (Current_Sem_Unit, Pack_Id);
end if;
-- The instance is not a freezing point for the new subprogram
Set_Is_Frozen (Act_Decl_Id, False);
if Nkind (Defining_Entity (N)) = N_Defining_Operator_Symbol then
Valid_Operator_Definition (Act_Decl_Id);
end if;
Set_Alias (Act_Decl_Id, Anon_Id);
Set_Parent (Act_Decl_Id, Parent (Anon_Id));
Set_Has_Completion (Act_Decl_Id);
Set_Related_Instance (Pack_Id, Act_Decl_Id);
if Nkind (Parent (N)) = N_Compilation_Unit then
Set_Body_Required (Parent (N), False);
end if;
end Analyze_Instance_And_Renamings;
-- Local variables
Vis_Prims_List : Elist_Id := No_Elist;
-- List of primitives made temporarily visible in the instantiation
-- to match the visibility of the formal type
-- Start of processing for Analyze_Subprogram_Instantiation
begin
Check_SPARK_Restriction ("generic is not allowed", N);
-- Very first thing: check for special Text_IO unit in case we are
-- instantiating one of the children of [[Wide_]Wide_]Text_IO. Of course
-- such an instantiation is bogus (these are packages, not subprograms),
-- but we get a better error message if we do this.
Check_Text_IO_Special_Unit (Gen_Id);
-- Make node global for error reporting
Instantiation_Node := N;
-- For package instantiations we turn off style checks, because they
-- will have been emitted in the generic. For subprogram instantiations
-- we want to apply at least the check on overriding indicators so we
-- do not modify the style check status.
-- The renaming declarations for the actuals do not come from source and
-- will not generate spurious warnings.
Preanalyze_Actuals (N);
Init_Env;
Env_Installed := True;
Check_Generic_Child_Unit (Gen_Id, Parent_Installed);
Gen_Unit := Entity (Gen_Id);
Generate_Reference (Gen_Unit, Gen_Id);
if Nkind (Gen_Id) = N_Identifier
and then Chars (Gen_Unit) = Chars (Defining_Entity (N))
then
Error_Msg_NE
("& is hidden within declaration of instance", Gen_Id, Gen_Unit);
end if;
if Etype (Gen_Unit) = Any_Type then
Restore_Env;
return;
end if;
-- Verify that it is a generic subprogram of the right kind, and that
-- it does not lead to a circular instantiation.
if K = E_Procedure and then Ekind (Gen_Unit) /= E_Generic_Procedure then
Error_Msg_NE
("& is not the name of a generic procedure", Gen_Id, Gen_Unit);
elsif K = E_Function and then Ekind (Gen_Unit) /= E_Generic_Function then
Error_Msg_NE
("& is not the name of a generic function", Gen_Id, Gen_Unit);
elsif In_Open_Scopes (Gen_Unit) then
Error_Msg_NE ("instantiation of & within itself", N, Gen_Unit);
else
Set_Entity (Gen_Id, Gen_Unit);
Set_Is_Instantiated (Gen_Unit);
if In_Extended_Main_Source_Unit (N) then
Generate_Reference (Gen_Unit, N);
end if;
-- If renaming, get original unit
if Present (Renamed_Object (Gen_Unit))
and then (Ekind (Renamed_Object (Gen_Unit)) = E_Generic_Procedure
or else
Ekind (Renamed_Object (Gen_Unit)) = E_Generic_Function)
then
Gen_Unit := Renamed_Object (Gen_Unit);
Set_Is_Instantiated (Gen_Unit);
Generate_Reference (Gen_Unit, N);
end if;
if Contains_Instance_Of (Gen_Unit, Current_Scope, Gen_Id) then
Error_Msg_Node_2 := Current_Scope;
Error_Msg_NE
("circular Instantiation: & instantiated in &!", N, Gen_Unit);
Circularity_Detected := True;
Restore_Hidden_Primitives (Vis_Prims_List);
goto Leave;
end if;
Gen_Decl := Unit_Declaration_Node (Gen_Unit);
-- Initialize renamings map, for error checking
Generic_Renamings.Set_Last (0);
Generic_Renamings_HTable.Reset;
Create_Instantiation_Source (N, Gen_Unit, False, S_Adjustment);
-- Copy original generic tree, to produce text for instantiation
Act_Tree :=
Copy_Generic_Node
(Original_Node (Gen_Decl), Empty, Instantiating => True);
-- Inherit overriding indicator from instance node
Act_Spec := Specification (Act_Tree);
Set_Must_Override (Act_Spec, Must_Override (N));
Set_Must_Not_Override (Act_Spec, Must_Not_Override (N));
Renaming_List :=
Analyze_Associations
(I_Node => N,
Formals => Generic_Formal_Declarations (Act_Tree),
F_Copy => Generic_Formal_Declarations (Gen_Decl));
Vis_Prims_List := Check_Hidden_Primitives (Renaming_List);
-- The subprogram itself cannot contain a nested instance, so the
-- current parent is left empty.
Set_Instance_Env (Gen_Unit, Empty);
-- Build the subprogram declaration, which does not appear in the
-- generic template, and give it a sloc consistent with that of the
-- template.
Set_Defining_Unit_Name (Act_Spec, Anon_Id);
Set_Generic_Parent (Act_Spec, Gen_Unit);
Act_Decl :=
Make_Subprogram_Declaration (Sloc (Act_Spec),
Specification => Act_Spec);
-- The aspects have been copied previously, but they have to be
-- linked explicitly to the new subprogram declaration. Explicit
-- pre/postconditions on the instance are analyzed below, in a
-- separate step.
Move_Aspects (Act_Tree, To => Act_Decl);
Set_Categorization_From_Pragmas (Act_Decl);
if Parent_Installed then
Hide_Current_Scope;
end if;
Append (Act_Decl, Renaming_List);
Analyze_Instance_And_Renamings;
-- If the generic is marked Import (Intrinsic), then so is the
-- instance. This indicates that there is no body to instantiate. If
-- generic is marked inline, so it the instance, and the anonymous
-- subprogram it renames. If inlined, or else if inlining is enabled
-- for the compilation, we generate the instance body even if it is
-- not within the main unit.
if Is_Intrinsic_Subprogram (Gen_Unit) then
Set_Is_Intrinsic_Subprogram (Anon_Id);
Set_Is_Intrinsic_Subprogram (Act_Decl_Id);
if Chars (Gen_Unit) = Name_Unchecked_Conversion then
Validate_Unchecked_Conversion (N, Act_Decl_Id);
end if;
end if;
-- Inherit convention from generic unit. Intrinsic convention, as for
-- an instance of unchecked conversion, is not inherited because an
-- explicit Ada instance has been created.
if Has_Convention_Pragma (Gen_Unit)
and then Convention (Gen_Unit) /= Convention_Intrinsic
then
Set_Convention (Act_Decl_Id, Convention (Gen_Unit));
Set_Is_Exported (Act_Decl_Id, Is_Exported (Gen_Unit));
end if;
Generate_Definition (Act_Decl_Id);
-- Set_Contract (Anon_Id, Make_Contract (Sloc (Anon_Id)));
-- ??? needed?
Set_Contract (Act_Decl_Id, Make_Contract (Sloc (Act_Decl_Id)));
-- Inherit all inlining-related flags which apply to the generic in
-- the subprogram and its declaration.
Set_Is_Inlined (Act_Decl_Id, Is_Inlined (Gen_Unit));
Set_Is_Inlined (Anon_Id, Is_Inlined (Gen_Unit));
Set_Has_Pragma_Inline (Act_Decl_Id, Has_Pragma_Inline (Gen_Unit));
Set_Has_Pragma_Inline (Anon_Id, Has_Pragma_Inline (Gen_Unit));
Set_Has_Pragma_Inline_Always
(Act_Decl_Id, Has_Pragma_Inline_Always (Gen_Unit));
Set_Has_Pragma_Inline_Always
(Anon_Id, Has_Pragma_Inline_Always (Gen_Unit));
if not Is_Intrinsic_Subprogram (Gen_Unit) then
Check_Elab_Instantiation (N);
end if;
if Is_Dispatching_Operation (Act_Decl_Id)
and then Ada_Version >= Ada_2005
then
declare
Formal : Entity_Id;
begin
Formal := First_Formal (Act_Decl_Id);
while Present (Formal) loop
if Ekind (Etype (Formal)) = E_Anonymous_Access_Type
and then Is_Controlling_Formal (Formal)
and then not Can_Never_Be_Null (Formal)
then
Error_Msg_NE ("access parameter& is controlling,",
N, Formal);
Error_Msg_NE
("\corresponding parameter of & must be"
& " explicitly null-excluding", N, Gen_Id);
end if;
Next_Formal (Formal);
end loop;
end;
end if;
Check_Hidden_Child_Unit (N, Gen_Unit, Act_Decl_Id);
Validate_Categorization_Dependency (N, Act_Decl_Id);
if not Is_Intrinsic_Subprogram (Act_Decl_Id) then
Inherit_Context (Gen_Decl, N);
Restore_Private_Views (Pack_Id, False);
-- If the context requires a full instantiation, mark node for
-- subsequent construction of the body.
if Need_Subprogram_Instance_Body (N, Act_Decl_Id) then
Check_Forward_Instantiation (Gen_Decl);
-- The wrapper package is always delayed, because it does not
-- constitute a freeze point, but to insure that the freeze
-- node is placed properly, it is created directly when
-- instantiating the body (otherwise the freeze node might
-- appear to early for nested instantiations).
elsif Nkind (Parent (N)) = N_Compilation_Unit then
-- For ASIS purposes, indicate that the wrapper package has
-- replaced the instantiation node.
Rewrite (N, Unit (Parent (N)));
Set_Unit (Parent (N), N);
end if;
elsif Nkind (Parent (N)) = N_Compilation_Unit then
-- Replace instance node for library-level instantiations of
-- intrinsic subprograms, for ASIS use.
Rewrite (N, Unit (Parent (N)));
Set_Unit (Parent (N), N);
end if;
if Parent_Installed then
Remove_Parent;
end if;
Restore_Hidden_Primitives (Vis_Prims_List);
Restore_Env;
Env_Installed := False;
Generic_Renamings.Set_Last (0);
Generic_Renamings_HTable.Reset;
end if;
<<Leave>>
if Has_Aspects (N) then
Analyze_Aspect_Specifications (N, Act_Decl_Id);
end if;
exception
when Instantiation_Error =>
if Parent_Installed then
Remove_Parent;
end if;
if Env_Installed then
Restore_Env;
end if;
end Analyze_Subprogram_Instantiation;
-------------------------
-- Get_Associated_Node --
-------------------------
function Get_Associated_Node (N : Node_Id) return Node_Id is
Assoc : Node_Id;
begin
Assoc := Associated_Node (N);
if Nkind (Assoc) /= Nkind (N) then
return Assoc;
elsif Nkind_In (Assoc, N_Aggregate, N_Extension_Aggregate) then
return Assoc;
else
-- If the node is part of an inner generic, it may itself have been
-- remapped into a further generic copy. Associated_Node is otherwise
-- used for the entity of the node, and will be of a different node
-- kind, or else N has been rewritten as a literal or function call.
while Present (Associated_Node (Assoc))
and then Nkind (Associated_Node (Assoc)) = Nkind (Assoc)
loop
Assoc := Associated_Node (Assoc);
end loop;
-- Follow and additional link in case the final node was rewritten.
-- This can only happen with nested generic units.
if (Nkind (Assoc) = N_Identifier or else Nkind (Assoc) in N_Op)
and then Present (Associated_Node (Assoc))
and then (Nkind_In (Associated_Node (Assoc), N_Function_Call,
N_Explicit_Dereference,
N_Integer_Literal,
N_Real_Literal,
N_String_Literal))
then
Assoc := Associated_Node (Assoc);
end if;
-- An additional special case: an unconstrained type in an object
-- declaration may have been rewritten as a local subtype constrained
-- by the expression in the declaration. We need to recover the
-- original entity which may be global.
if Present (Original_Node (Assoc))
and then Nkind (Parent (N)) = N_Object_Declaration
then
Assoc := Original_Node (Assoc);
end if;
return Assoc;
end if;
end Get_Associated_Node;
-------------------------------------------
-- Build_Instance_Compilation_Unit_Nodes --
-------------------------------------------
procedure Build_Instance_Compilation_Unit_Nodes
(N : Node_Id;
Act_Body : Node_Id;
Act_Decl : Node_Id)
is
Decl_Cunit : Node_Id;
Body_Cunit : Node_Id;
Citem : Node_Id;
New_Main : constant Entity_Id := Defining_Entity (Act_Decl);
Old_Main : constant Entity_Id := Cunit_Entity (Main_Unit);
begin
-- A new compilation unit node is built for the instance declaration
Decl_Cunit :=
Make_Compilation_Unit (Sloc (N),
Context_Items => Empty_List,
Unit => Act_Decl,
Aux_Decls_Node => Make_Compilation_Unit_Aux (Sloc (N)));
Set_Parent_Spec (Act_Decl, Parent_Spec (N));
-- The new compilation unit is linked to its body, but both share the
-- same file, so we do not set Body_Required on the new unit so as not
-- to create a spurious dependency on a non-existent body in the ali.
-- This simplifies CodePeer unit traversal.
-- We use the original instantiation compilation unit as the resulting
-- compilation unit of the instance, since this is the main unit.
Rewrite (N, Act_Body);
-- Propagate the aspect specifications from the package body template to
-- the instantiated version of the package body.
if Has_Aspects (Act_Body) then
Set_Aspect_Specifications
(N, New_Copy_List_Tree (Aspect_Specifications (Act_Body)));
end if;
Body_Cunit := Parent (N);
-- The two compilation unit nodes are linked by the Library_Unit field
Set_Library_Unit (Decl_Cunit, Body_Cunit);
Set_Library_Unit (Body_Cunit, Decl_Cunit);
-- Preserve the private nature of the package if needed
Set_Private_Present (Decl_Cunit, Private_Present (Body_Cunit));
-- If the instance is not the main unit, its context, categorization
-- and elaboration entity are not relevant to the compilation.
if Body_Cunit /= Cunit (Main_Unit) then
Make_Instance_Unit (Body_Cunit, In_Main => False);
return;
end if;
-- The context clause items on the instantiation, which are now attached
-- to the body compilation unit (since the body overwrote the original
-- instantiation node), semantically belong on the spec, so copy them
-- there. It's harmless to leave them on the body as well. In fact one
-- could argue that they belong in both places.
Citem := First (Context_Items (Body_Cunit));
while Present (Citem) loop
Append (New_Copy (Citem), Context_Items (Decl_Cunit));
Next (Citem);
end loop;
-- Propagate categorization flags on packages, so that they appear in
-- the ali file for the spec of the unit.
if Ekind (New_Main) = E_Package then
Set_Is_Pure (Old_Main, Is_Pure (New_Main));
Set_Is_Preelaborated (Old_Main, Is_Preelaborated (New_Main));
Set_Is_Remote_Types (Old_Main, Is_Remote_Types (New_Main));
Set_Is_Shared_Passive (Old_Main, Is_Shared_Passive (New_Main));
Set_Is_Remote_Call_Interface
(Old_Main, Is_Remote_Call_Interface (New_Main));
end if;
-- Make entry in Units table, so that binder can generate call to
-- elaboration procedure for body, if any.
Make_Instance_Unit (Body_Cunit, In_Main => True);
Main_Unit_Entity := New_Main;
Set_Cunit_Entity (Main_Unit, Main_Unit_Entity);
-- Build elaboration entity, since the instance may certainly generate
-- elaboration code requiring a flag for protection.
Build_Elaboration_Entity (Decl_Cunit, New_Main);
end Build_Instance_Compilation_Unit_Nodes;
-----------------------------
-- Check_Access_Definition --
-----------------------------
procedure Check_Access_Definition (N : Node_Id) is
begin
pragma Assert
(Ada_Version >= Ada_2005 and then Present (Access_Definition (N)));
null;
end Check_Access_Definition;
-----------------------------------
-- Check_Formal_Package_Instance --
-----------------------------------
-- If the formal has specific parameters, they must match those of the
-- actual. Both of them are instances, and the renaming declarations for
-- their formal parameters appear in the same order in both. The analyzed
-- formal has been analyzed in the context of the current instance.
procedure Check_Formal_Package_Instance
(Formal_Pack : Entity_Id;
Actual_Pack : Entity_Id)
is
E1 : Entity_Id := First_Entity (Actual_Pack);
E2 : Entity_Id := First_Entity (Formal_Pack);
Expr1 : Node_Id;
Expr2 : Node_Id;
procedure Check_Mismatch (B : Boolean);
-- Common error routine for mismatch between the parameters of the
-- actual instance and those of the formal package.
function Same_Instantiated_Constant (E1, E2 : Entity_Id) return Boolean;
-- The formal may come from a nested formal package, and the actual may
-- have been constant-folded. To determine whether the two denote the
-- same entity we may have to traverse several definitions to recover
-- the ultimate entity that they refer to.
function Same_Instantiated_Variable (E1, E2 : Entity_Id) return Boolean;
-- Similarly, if the formal comes from a nested formal package, the
-- actual may designate the formal through multiple renamings, which
-- have to be followed to determine the original variable in question.
--------------------
-- Check_Mismatch --
--------------------
procedure Check_Mismatch (B : Boolean) is
Kind : constant Node_Kind := Nkind (Parent (E2));
begin
if Kind = N_Formal_Type_Declaration then
return;
elsif Nkind_In (Kind, N_Formal_Object_Declaration,
N_Formal_Package_Declaration)
or else Kind in N_Formal_Subprogram_Declaration
then
null;
elsif B then
Error_Msg_NE
("actual for & in actual instance does not match formal",
Parent (Actual_Pack), E1);
end if;
end Check_Mismatch;
--------------------------------
-- Same_Instantiated_Constant --
--------------------------------
function Same_Instantiated_Constant
(E1, E2 : Entity_Id) return Boolean
is
Ent : Entity_Id;
begin
Ent := E2;
while Present (Ent) loop
if E1 = Ent then
return True;
elsif Ekind (Ent) /= E_Constant then
return False;
elsif Is_Entity_Name (Constant_Value (Ent)) then
if Entity (Constant_Value (Ent)) = E1 then
return True;
else
Ent := Entity (Constant_Value (Ent));
end if;
-- The actual may be a constant that has been folded. Recover
-- original name.
elsif Is_Entity_Name (Original_Node (Constant_Value (Ent))) then
Ent := Entity (Original_Node (Constant_Value (Ent)));
else
return False;
end if;
end loop;
return False;
end Same_Instantiated_Constant;
--------------------------------
-- Same_Instantiated_Variable --
--------------------------------
function Same_Instantiated_Variable
(E1, E2 : Entity_Id) return Boolean
is
function Original_Entity (E : Entity_Id) return Entity_Id;
-- Follow chain of renamings to the ultimate ancestor
---------------------
-- Original_Entity --
---------------------
function Original_Entity (E : Entity_Id) return Entity_Id is
Orig : Entity_Id;
begin
Orig := E;
while Nkind (Parent (Orig)) = N_Object_Renaming_Declaration
and then Present (Renamed_Object (Orig))
and then Is_Entity_Name (Renamed_Object (Orig))
loop
Orig := Entity (Renamed_Object (Orig));
end loop;
return Orig;
end Original_Entity;
-- Start of processing for Same_Instantiated_Variable
begin
return Ekind (E1) = Ekind (E2)
and then Original_Entity (E1) = Original_Entity (E2);
end Same_Instantiated_Variable;
-- Start of processing for Check_Formal_Package_Instance
begin
while Present (E1)
and then Present (E2)
loop
exit when Ekind (E1) = E_Package
and then Renamed_Entity (E1) = Renamed_Entity (Actual_Pack);
-- If the formal is the renaming of the formal package, this
-- is the end of its formal part, which may occur before the
-- end of the formal part in the actual in the presence of
-- defaulted parameters in the formal package.
exit when Nkind (Parent (E2)) = N_Package_Renaming_Declaration
and then Renamed_Entity (E2) = Scope (E2);
-- The analysis of the actual may generate additional internal
-- entities. If the formal is defaulted, there is no corresponding
-- analysis and the internal entities must be skipped, until we
-- find corresponding entities again.
if Comes_From_Source (E2)
and then not Comes_From_Source (E1)
and then Chars (E1) /= Chars (E2)
then
while Present (E1)
and then Chars (E1) /= Chars (E2)
loop
Next_Entity (E1);
end loop;
end if;
if No (E1) then
return;
-- If the formal entity comes from a formal declaration, it was
-- defaulted in the formal package, and no check is needed on it.
elsif Nkind (Parent (E2)) = N_Formal_Object_Declaration then
goto Next_E;
-- Ditto for defaulted formal subprograms.
elsif Is_Overloadable (E1)
and then Nkind (Unit_Declaration_Node (E2)) in
N_Formal_Subprogram_Declaration
then
goto Next_E;
elsif Is_Type (E1) then
-- Subtypes must statically match. E1, E2 are the local entities
-- that are subtypes of the actuals. Itypes generated for other
-- parameters need not be checked, the check will be performed
-- on the parameters themselves.
-- If E2 is a formal type declaration, it is a defaulted parameter
-- and needs no checking.
if not Is_Itype (E1)
and then not Is_Itype (E2)
then
Check_Mismatch
(not Is_Type (E2)
or else Etype (E1) /= Etype (E2)
or else not Subtypes_Statically_Match (E1, E2));
end if;
elsif Ekind (E1) = E_Constant then
-- IN parameters must denote the same static value, or the same
-- constant, or the literal null.
Expr1 := Expression (Parent (E1));
if Ekind (E2) /= E_Constant then
Check_Mismatch (True);
goto Next_E;
else
Expr2 := Expression (Parent (E2));
end if;
if Is_OK_Static_Expression (Expr1) then
if not Is_OK_Static_Expression (Expr2) then
Check_Mismatch (True);
elsif Is_Discrete_Type (Etype (E1)) then
declare
V1 : constant Uint := Expr_Value (Expr1);
V2 : constant Uint := Expr_Value (Expr2);
begin
Check_Mismatch (V1 /= V2);
end;
elsif Is_Real_Type (Etype (E1)) then
declare
V1 : constant Ureal := Expr_Value_R (Expr1);
V2 : constant Ureal := Expr_Value_R (Expr2);
begin
Check_Mismatch (V1 /= V2);
end;
elsif Is_String_Type (Etype (E1))
and then Nkind (Expr1) = N_String_Literal
then
if Nkind (Expr2) /= N_String_Literal then
Check_Mismatch (True);
else
Check_Mismatch
(not String_Equal (Strval (Expr1), Strval (Expr2)));
end if;
end if;
elsif Is_Entity_Name (Expr1) then
if Is_Entity_Name (Expr2) then
if Entity (Expr1) = Entity (Expr2) then
null;
else
Check_Mismatch
(not Same_Instantiated_Constant
(Entity (Expr1), Entity (Expr2)));
end if;
else
Check_Mismatch (True);
end if;
elsif Is_Entity_Name (Original_Node (Expr1))
and then Is_Entity_Name (Expr2)
and then
Same_Instantiated_Constant
(Entity (Original_Node (Expr1)), Entity (Expr2))
then
null;
elsif Nkind (Expr1) = N_Null then
Check_Mismatch (Nkind (Expr1) /= N_Null);
else
Check_Mismatch (True);
end if;
elsif Ekind (E1) = E_Variable then
Check_Mismatch (not Same_Instantiated_Variable (E1, E2));
elsif Ekind (E1) = E_Package then
Check_Mismatch
(Ekind (E1) /= Ekind (E2)
or else Renamed_Object (E1) /= Renamed_Object (E2));
elsif Is_Overloadable (E1) then
-- Verify that the actual subprograms match. Note that actuals
-- that are attributes are rewritten as subprograms. If the
-- subprogram in the formal package is defaulted, no check is
-- needed. Note that this can only happen in Ada 2005 when the
-- formal package can be partially parameterized.
if Nkind (Unit_Declaration_Node (E1)) =
N_Subprogram_Renaming_Declaration
and then From_Default (Unit_Declaration_Node (E1))
then
null;
-- If the formal package has an "others" box association that
-- covers this formal, there is no need for a check either.
elsif Nkind (Unit_Declaration_Node (E2)) in
N_Formal_Subprogram_Declaration
and then Box_Present (Unit_Declaration_Node (E2))
then
null;
-- No check needed if subprogram is a defaulted null procedure
elsif No (Alias (E2))
and then Ekind (E2) = E_Procedure
and then
Null_Present (Specification (Unit_Declaration_Node (E2)))
then
null;
-- Otherwise the actual in the formal and the actual in the
-- instantiation of the formal must match, up to renamings.
else
Check_Mismatch
(Ekind (E2) /= Ekind (E1) or else (Alias (E1)) /= Alias (E2));
end if;
else
raise Program_Error;
end if;
<<Next_E>>
Next_Entity (E1);
Next_Entity (E2);
end loop;
end Check_Formal_Package_Instance;
---------------------------
-- Check_Formal_Packages --
---------------------------
procedure Check_Formal_Packages (P_Id : Entity_Id) is
E : Entity_Id;
Formal_P : Entity_Id;
begin
-- Iterate through the declarations in the instance, looking for package
-- renaming declarations that denote instances of formal packages. Stop
-- when we find the renaming of the current package itself. The
-- declaration for a formal package without a box is followed by an
-- internal entity that repeats the instantiation.
E := First_Entity (P_Id);
while Present (E) loop
if Ekind (E) = E_Package then
if Renamed_Object (E) = P_Id then
exit;
elsif Nkind (Parent (E)) /= N_Package_Renaming_Declaration then
null;
elsif not Box_Present (Parent (Associated_Formal_Package (E))) then
Formal_P := Next_Entity (E);
Check_Formal_Package_Instance (Formal_P, E);
-- After checking, remove the internal validating package. It
-- is only needed for semantic checks, and as it may contain
-- generic formal declarations it should not reach gigi.
Remove (Unit_Declaration_Node (Formal_P));
end if;
end if;
Next_Entity (E);
end loop;
end Check_Formal_Packages;
---------------------------------
-- Check_Forward_Instantiation --
---------------------------------
procedure Check_Forward_Instantiation (Decl : Node_Id) is
S : Entity_Id;
Gen_Comp : Entity_Id := Cunit_Entity (Get_Source_Unit (Decl));
begin
-- The instantiation appears before the generic body if we are in the
-- scope of the unit containing the generic, either in its spec or in
-- the package body, and before the generic body.
if Ekind (Gen_Comp) = E_Package_Body then
Gen_Comp := Spec_Entity (Gen_Comp);
end if;
if In_Open_Scopes (Gen_Comp)
and then No (Corresponding_Body (Decl))
then
S := Current_Scope;
while Present (S)
and then not Is_Compilation_Unit (S)
and then not Is_Child_Unit (S)
loop
if Ekind (S) = E_Package then
Set_Has_Forward_Instantiation (S);
end if;
S := Scope (S);
end loop;
end if;
end Check_Forward_Instantiation;
---------------------------
-- Check_Generic_Actuals --
---------------------------
-- The visibility of the actuals may be different between the point of
-- generic instantiation and the instantiation of the body.
procedure Check_Generic_Actuals
(Instance : Entity_Id;
Is_Formal_Box : Boolean)
is
E : Entity_Id;
Astype : Entity_Id;
function Denotes_Previous_Actual (Typ : Entity_Id) return Boolean;
-- For a formal that is an array type, the component type is often a
-- previous formal in the same unit. The privacy status of the component
-- type will have been examined earlier in the traversal of the
-- corresponding actuals, and this status should not be modified for
-- the array (sub)type itself. However, if the base type of the array
-- (sub)type is private, its full view must be restored in the body to
-- be consistent with subsequent index subtypes, etc.
--
-- To detect this case we have to rescan the list of formals, which is
-- usually short enough to ignore the resulting inefficiency.
-----------------------------
-- Denotes_Previous_Actual --
-----------------------------
function Denotes_Previous_Actual (Typ : Entity_Id) return Boolean is
Prev : Entity_Id;
begin
Prev := First_Entity (Instance);
while Present (Prev) loop
if Is_Type (Prev)
and then Nkind (Parent (Prev)) = N_Subtype_Declaration
and then Is_Entity_Name (Subtype_Indication (Parent (Prev)))
and then Entity (Subtype_Indication (Parent (Prev))) = Typ
then
return True;
elsif Prev = E then
return False;
else
Next_Entity (Prev);
end if;
end loop;
return False;
end Denotes_Previous_Actual;
-- Start of processing for Check_Generic_Actuals
begin
E := First_Entity (Instance);
while Present (E) loop
if Is_Type (E)
and then Nkind (Parent (E)) = N_Subtype_Declaration
and then Scope (Etype (E)) /= Instance
and then Is_Entity_Name (Subtype_Indication (Parent (E)))
then
if Is_Array_Type (E)
and then not Is_Private_Type (Etype (E))
and then Denotes_Previous_Actual (Component_Type (E))
then
null;
else
Check_Private_View (Subtype_Indication (Parent (E)));
end if;
Set_Is_Generic_Actual_Type (E, True);
Set_Is_Hidden (E, False);
Set_Is_Potentially_Use_Visible (E,
In_Use (Instance));
-- We constructed the generic actual type as a subtype of the
-- supplied type. This means that it normally would not inherit
-- subtype specific attributes of the actual, which is wrong for
-- the generic case.
Astype := Ancestor_Subtype (E);
if No (Astype) then
-- This can happen when E is an itype that is the full view of
-- a private type completed, e.g. with a constrained array. In
-- that case, use the first subtype, which will carry size
-- information. The base type itself is unconstrained and will
-- not carry it.
Astype := First_Subtype (E);
end if;
Set_Size_Info (E, (Astype));
Set_RM_Size (E, RM_Size (Astype));
Set_First_Rep_Item (E, First_Rep_Item (Astype));
if Is_Discrete_Or_Fixed_Point_Type (E) then
Set_RM_Size (E, RM_Size (Astype));
-- In nested instances, the base type of an access actual may
-- itself be private, and need to be exchanged.
elsif Is_Access_Type (E)
and then Is_Private_Type (Etype (E))
then
Check_Private_View
(New_Occurrence_Of (Etype (E), Sloc (Instance)));
end if;
elsif Ekind (E) = E_Package then
-- If this is the renaming for the current instance, we're done.
-- Otherwise it is a formal package. If the corresponding formal
-- was declared with a box, the (instantiations of the) generic
-- formal part are also visible. Otherwise, ignore the entity
-- created to validate the actuals.
if Renamed_Object (E) = Instance then
exit;
elsif Nkind (Parent (E)) /= N_Package_Renaming_Declaration then
null;
-- The visibility of a formal of an enclosing generic is already
-- correct.
elsif Denotes_Formal_Package (E) then
null;
elsif Present (Associated_Formal_Package (E))
and then not Is_Generic_Formal (E)
then
if Box_Present (Parent (Associated_Formal_Package (E))) then
Check_Generic_Actuals (Renamed_Object (E), True);
else
Check_Generic_Actuals (Renamed_Object (E), False);
end if;
Set_Is_Hidden (E, False);
end if;
-- If this is a subprogram instance (in a wrapper package) the
-- actual is fully visible.
elsif Is_Wrapper_Package (Instance) then
Set_Is_Hidden (E, False);
-- If the formal package is declared with a box, or if the formal
-- parameter is defaulted, it is visible in the body.
elsif Is_Formal_Box
or else Is_Visible_Formal (E)
then
Set_Is_Hidden (E, False);
end if;
if Ekind (E) = E_Constant then
-- If the type of the actual is a private type declared in the
-- enclosing scope of the generic unit, the body of the generic
-- sees the full view of the type (because it has to appear in
-- the corresponding package body). If the type is private now,
-- exchange views to restore the proper visiblity in the instance.
declare
Typ : constant Entity_Id := Base_Type (Etype (E));
-- The type of the actual
Gen_Id : Entity_Id;
-- The generic unit
Parent_Scope : Entity_Id;
-- The enclosing scope of the generic unit
begin
if Is_Wrapper_Package (Instance) then
Gen_Id :=
Generic_Parent
(Specification
(Unit_Declaration_Node
(Related_Instance (Instance))));
else
Gen_Id :=
Generic_Parent (Package_Specification (Instance));
end if;
Parent_Scope := Scope (Gen_Id);
-- The exchange is only needed if the generic is defined
-- within a package which is not a common ancestor of the
-- scope of the instance, and is not already in scope.
if Is_Private_Type (Typ)
and then Scope (Typ) = Parent_Scope
and then Scope (Instance) /= Parent_Scope
and then Ekind (Parent_Scope) = E_Package
and then not Is_Child_Unit (Gen_Id)
then
Switch_View (Typ);
-- If the type of the entity is a subtype, it may also have
-- to be made visible, together with the base type of its
-- full view, after exchange.
if Is_Private_Type (Etype (E)) then
Switch_View (Etype (E));
Switch_View (Base_Type (Etype (E)));
end if;
end if;
end;
end if;
Next_Entity (E);
end loop;
end Check_Generic_Actuals;
------------------------------
-- Check_Generic_Child_Unit --
------------------------------
procedure Check_Generic_Child_Unit
(Gen_Id : Node_Id;
Parent_Installed : in out Boolean)
is
Loc : constant Source_Ptr := Sloc (Gen_Id);
Gen_Par : Entity_Id := Empty;
E : Entity_Id;
Inst_Par : Entity_Id;
S : Node_Id;
function Find_Generic_Child
(Scop : Entity_Id;
Id : Node_Id) return Entity_Id;
-- Search generic parent for possible child unit with the given name
function In_Enclosing_Instance return Boolean;
-- Within an instance of the parent, the child unit may be denoted by
-- a simple name, or an abbreviated expanded name. Examine enclosing
-- scopes to locate a possible parent instantiation.
------------------------
-- Find_Generic_Child --
------------------------
function Find_Generic_Child
(Scop : Entity_Id;
Id : Node_Id) return Entity_Id
is
E : Entity_Id;
begin
-- If entity of name is already set, instance has already been
-- resolved, e.g. in an enclosing instantiation.
if Present (Entity (Id)) then
if Scope (Entity (Id)) = Scop then
return Entity (Id);
else
return Empty;
end if;
else
E := First_Entity (Scop);
while Present (E) loop
if Chars (E) = Chars (Id)
and then Is_Child_Unit (E)
then
if Is_Child_Unit (E)
and then not Is_Visible_Lib_Unit (E)
then
Error_Msg_NE
("generic child unit& is not visible", Gen_Id, E);
end if;
Set_Entity (Id, E);
return E;
end if;
Next_Entity (E);
end loop;
return Empty;
end if;
end Find_Generic_Child;
---------------------------
-- In_Enclosing_Instance --
---------------------------
function In_Enclosing_Instance return Boolean is
Enclosing_Instance : Node_Id;
Instance_Decl : Node_Id;
begin
-- We do not inline any call that contains instantiations, except
-- for instantiations of Unchecked_Conversion, so if we are within
-- an inlined body the current instance does not require parents.
if In_Inlined_Body then
pragma Assert (Chars (Gen_Id) = Name_Unchecked_Conversion);
return False;
end if;
-- Loop to check enclosing scopes
Enclosing_Instance := Current_Scope;
while Present (Enclosing_Instance) loop
Instance_Decl := Unit_Declaration_Node (Enclosing_Instance);
if Ekind (Enclosing_Instance) = E_Package
and then Is_Generic_Instance (Enclosing_Instance)
and then Present
(Generic_Parent (Specification (Instance_Decl)))
then
-- Check whether the generic we are looking for is a child of
-- this instance.
E := Find_Generic_Child
(Generic_Parent (Specification (Instance_Decl)), Gen_Id);
exit when Present (E);
else
E := Empty;
end if;
Enclosing_Instance := Scope (Enclosing_Instance);
end loop;
if No (E) then
-- Not a child unit
Analyze (Gen_Id);
return False;
else
Rewrite (Gen_Id,
Make_Expanded_Name (Loc,
Chars => Chars (E),
Prefix => New_Occurrence_Of (Enclosing_Instance, Loc),
Selector_Name => New_Occurrence_Of (E, Loc)));
Set_Entity (Gen_Id, E);
Set_Etype (Gen_Id, Etype (E));
Parent_Installed := False; -- Already in scope.
return True;
end if;
end In_Enclosing_Instance;
-- Start of processing for Check_Generic_Child_Unit
begin
-- If the name of the generic is given by a selected component, it may
-- be the name of a generic child unit, and the prefix is the name of an
-- instance of the parent, in which case the child unit must be visible.
-- If this instance is not in scope, it must be placed there and removed
-- after instantiation, because what is being instantiated is not the
-- original child, but the corresponding child present in the instance
-- of the parent.
-- If the child is instantiated within the parent, it can be given by
-- a simple name. In this case the instance is already in scope, but
-- the child generic must be recovered from the generic parent as well.
if Nkind (Gen_Id) = N_Selected_Component then
S := Selector_Name (Gen_Id);
Analyze (Prefix (Gen_Id));
Inst_Par := Entity (Prefix (Gen_Id));
if Ekind (Inst_Par) = E_Package
and then Present (Renamed_Object (Inst_Par))
then
Inst_Par := Renamed_Object (Inst_Par);
end if;
if Ekind (Inst_Par) = E_Package then
if Nkind (Parent (Inst_Par)) = N_Package_Specification then
Gen_Par := Generic_Parent (Parent (Inst_Par));
elsif Nkind (Parent (Inst_Par)) = N_Defining_Program_Unit_Name
and then
Nkind (Parent (Parent (Inst_Par))) = N_Package_Specification
then
Gen_Par := Generic_Parent (Parent (Parent (Inst_Par)));
end if;
elsif Ekind (Inst_Par) = E_Generic_Package
and then Nkind (Parent (Gen_Id)) = N_Formal_Package_Declaration
then
-- A formal package may be a real child package, and not the
-- implicit instance within a parent. In this case the child is
-- not visible and has to be retrieved explicitly as well.
Gen_Par := Inst_Par;
end if;
if Present (Gen_Par) then
-- The prefix denotes an instantiation. The entity itself may be a
-- nested generic, or a child unit.
E := Find_Generic_Child (Gen_Par, S);
if Present (E) then
Change_Selected_Component_To_Expanded_Name (Gen_Id);
Set_Entity (Gen_Id, E);
Set_Etype (Gen_Id, Etype (E));
Set_Entity (S, E);
Set_Etype (S, Etype (E));
-- Indicate that this is a reference to the parent
if In_Extended_Main_Source_Unit (Gen_Id) then
Set_Is_Instantiated (Inst_Par);
end if;
-- A common mistake is to replicate the naming scheme of a
-- hierarchy by instantiating a generic child directly, rather
-- than the implicit child in a parent instance:
-- generic .. package Gpar is ..
-- generic .. package Gpar.Child is ..
-- package Par is new Gpar ();
-- with Gpar.Child;
-- package Par.Child is new Gpar.Child ();
-- rather than Par.Child
-- In this case the instantiation is within Par, which is an
-- instance, but Gpar does not denote Par because we are not IN
-- the instance of Gpar, so this is illegal. The test below
-- recognizes this particular case.
if Is_Child_Unit (E)
and then not Comes_From_Source (Entity (Prefix (Gen_Id)))
and then (not In_Instance
or else Nkind (Parent (Parent (Gen_Id))) =
N_Compilation_Unit)
then
Error_Msg_N
("prefix of generic child unit must be instance of parent",
Gen_Id);
end if;
if not In_Open_Scopes (Inst_Par)
and then Nkind (Parent (Gen_Id)) not in
N_Generic_Renaming_Declaration
then
Install_Parent (Inst_Par);
Parent_Installed := True;
elsif In_Open_Scopes (Inst_Par) then
-- If the parent is already installed, install the actuals
-- for its formal packages. This is necessary when the child
-- instance is a child of the parent instance: in this case,
-- the parent is placed on the scope stack but the formal
-- packages are not made visible.
Install_Formal_Packages (Inst_Par);
end if;
else
-- If the generic parent does not contain an entity that
-- corresponds to the selector, the instance doesn't either.
-- Analyzing the node will yield the appropriate error message.
-- If the entity is not a child unit, then it is an inner
-- generic in the parent.
Analyze (Gen_Id);
end if;
else
Analyze (Gen_Id);
if Is_Child_Unit (Entity (Gen_Id))
and then
Nkind (Parent (Gen_Id)) not in N_Generic_Renaming_Declaration
and then not In_Open_Scopes (Inst_Par)
then
Install_Parent (Inst_Par);
Parent_Installed := True;
-- The generic unit may be the renaming of the implicit child
-- present in an instance. In that case the parent instance is
-- obtained from the name of the renamed entity.
elsif Ekind (Entity (Gen_Id)) = E_Generic_Package
and then Present (Renamed_Entity (Entity (Gen_Id)))
and then Is_Child_Unit (Renamed_Entity (Entity (Gen_Id)))
then
declare
Renamed_Package : constant Node_Id :=
Name (Parent (Entity (Gen_Id)));
begin
if Nkind (Renamed_Package) = N_Expanded_Name then
Inst_Par := Entity (Prefix (Renamed_Package));
Install_Parent (Inst_Par);
Parent_Installed := True;
end if;
end;
end if;
end if;
elsif Nkind (Gen_Id) = N_Expanded_Name then
-- Entity already present, analyze prefix, whose meaning may be
-- an instance in the current context. If it is an instance of
-- a relative within another, the proper parent may still have
-- to be installed, if they are not of the same generation.
Analyze (Prefix (Gen_Id));
-- In the unlikely case that a local declaration hides the name
-- of the parent package, locate it on the homonym chain. If the
-- context is an instance of the parent, the renaming entity is
-- flagged as such.
Inst_Par := Entity (Prefix (Gen_Id));
while Present (Inst_Par)
and then not Is_Package_Or_Generic_Package (Inst_Par)
loop
Inst_Par := Homonym (Inst_Par);
end loop;
pragma Assert (Present (Inst_Par));
Set_Entity (Prefix (Gen_Id), Inst_Par);
if In_Enclosing_Instance then
null;
elsif Present (Entity (Gen_Id))
and then Is_Child_Unit (Entity (Gen_Id))
and then not In_Open_Scopes (Inst_Par)
then
Install_Parent (Inst_Par);
Parent_Installed := True;
end if;
elsif In_Enclosing_Instance then
-- The child unit is found in some enclosing scope
null;
else
Analyze (Gen_Id);
-- If this is the renaming of the implicit child in a parent
-- instance, recover the parent name and install it.
if Is_Entity_Name (Gen_Id) then
E := Entity (Gen_Id);
if Is_Generic_Unit (E)
and then Nkind (Parent (E)) in N_Generic_Renaming_Declaration
and then Is_Child_Unit (Renamed_Object (E))
and then Is_Generic_Unit (Scope (Renamed_Object (E)))
and then Nkind (Name (Parent (E))) = N_Expanded_Name
then
Rewrite (Gen_Id,
New_Copy_Tree (Name (Parent (E))));
Inst_Par := Entity (Prefix (Gen_Id));
if not In_Open_Scopes (Inst_Par) then
Install_Parent (Inst_Par);
Parent_Installed := True;
end if;
-- If it is a child unit of a non-generic parent, it may be
-- use-visible and given by a direct name. Install parent as
-- for other cases.
elsif Is_Generic_Unit (E)
and then Is_Child_Unit (E)
and then
Nkind (Parent (Gen_Id)) not in N_Generic_Renaming_Declaration
and then not Is_Generic_Unit (Scope (E))
then
if not In_Open_Scopes (Scope (E)) then
Install_Parent (Scope (E));
Parent_Installed := True;
end if;
end if;
end if;
end if;
end Check_Generic_Child_Unit;
-----------------------------
-- Check_Hidden_Child_Unit --
-----------------------------
procedure Check_Hidden_Child_Unit
(N : Node_Id;
Gen_Unit : Entity_Id;
Act_Decl_Id : Entity_Id)
is
Gen_Id : constant Node_Id := Name (N);
begin
if Is_Child_Unit (Gen_Unit)
and then Is_Child_Unit (Act_Decl_Id)
and then Nkind (Gen_Id) = N_Expanded_Name
and then Entity (Prefix (Gen_Id)) = Scope (Act_Decl_Id)
and then Chars (Gen_Unit) = Chars (Act_Decl_Id)
then
Error_Msg_Node_2 := Scope (Act_Decl_Id);
Error_Msg_NE
("generic unit & is implicitly declared in &",
Defining_Unit_Name (N), Gen_Unit);
Error_Msg_N ("\instance must have different name",
Defining_Unit_Name (N));
end if;
end Check_Hidden_Child_Unit;
------------------------
-- Check_Private_View --
------------------------
procedure Check_Private_View (N : Node_Id) is
T : constant Entity_Id := Etype (N);
BT : Entity_Id;
begin
-- Exchange views if the type was not private in the generic but is
-- private at the point of instantiation. Do not exchange views if
-- the scope of the type is in scope. This can happen if both generic
-- and instance are sibling units, or if type is defined in a parent.
-- In this case the visibility of the type will be correct for all
-- semantic checks.
if Present (T) then
BT := Base_Type (T);
if Is_Private_Type (T)
and then not Has_Private_View (N)
and then Present (Full_View (T))
and then not In_Open_Scopes (Scope (T))
then
-- In the generic, the full type was visible. Save the private
-- entity, for subsequent exchange.
Switch_View (T);
elsif Has_Private_View (N)
and then not Is_Private_Type (T)
and then not Has_Been_Exchanged (T)
and then Etype (Get_Associated_Node (N)) /= T
then
-- Only the private declaration was visible in the generic. If
-- the type appears in a subtype declaration, the subtype in the
-- instance must have a view compatible with that of its parent,
-- which must be exchanged (see corresponding code in Restore_
-- Private_Views). Otherwise, if the type is defined in a parent
-- unit, leave full visibility within instance, which is safe.
if In_Open_Scopes (Scope (Base_Type (T)))
and then not Is_Private_Type (Base_Type (T))
and then Comes_From_Source (Base_Type (T))
then
null;
elsif Nkind (Parent (N)) = N_Subtype_Declaration
or else not In_Private_Part (Scope (Base_Type (T)))
then
Prepend_Elmt (T, Exchanged_Views);
Exchange_Declarations (Etype (Get_Associated_Node (N)));
end if;
-- For composite types with inconsistent representation exchange
-- component types accordingly.
elsif Is_Access_Type (T)
and then Is_Private_Type (Designated_Type (T))
and then not Has_Private_View (N)
and then Present (Full_View (Designated_Type (T)))
then
Switch_View (Designated_Type (T));
elsif Is_Array_Type (T) then
if Is_Private_Type (Component_Type (T))
and then not Has_Private_View (N)
and then Present (Full_View (Component_Type (T)))
then
Switch_View (Component_Type (T));
end if;
-- The normal exchange mechanism relies on the setting of a
-- flag on the reference in the generic. However, an additional
-- mechanism is needed for types that are not explicitly
-- mentioned in the generic, but may be needed in expanded code
-- in the instance. This includes component types of arrays and
-- designated types of access types. This processing must also
-- include the index types of arrays which we take care of here.
declare
Indx : Node_Id;
Typ : Entity_Id;
begin
Indx := First_Index (T);
while Present (Indx) loop
Typ := Base_Type (Etype (Indx));
if Is_Private_Type (Typ)
and then Present (Full_View (Typ))
then
Switch_View (Typ);
end if;
Next_Index (Indx);
end loop;
end;
elsif Is_Private_Type (T)
and then Present (Full_View (T))
and then Is_Array_Type (Full_View (T))
and then Is_Private_Type (Component_Type (Full_View (T)))
then
Switch_View (T);
-- Finally, a non-private subtype may have a private base type, which
-- must be exchanged for consistency. This can happen when a package
-- body is instantiated, when the scope stack is empty but in fact
-- the subtype and the base type are declared in an enclosing scope.
-- Note that in this case we introduce an inconsistency in the view
-- set, because we switch the base type BT, but there could be some
-- private dependent subtypes of BT which remain unswitched. Such
-- subtypes might need to be switched at a later point (see specific
-- provision for that case in Switch_View).
elsif not Is_Private_Type (T)
and then not Has_Private_View (N)
and then Is_Private_Type (BT)
and then Present (Full_View (BT))
and then not Is_Generic_Type (BT)
and then not In_Open_Scopes (BT)
then
Prepend_Elmt (Full_View (BT), Exchanged_Views);
Exchange_Declarations (BT);
end if;
end if;
end Check_Private_View;
-----------------------------
-- Check_Hidden_Primitives --
-----------------------------
function Check_Hidden_Primitives (Assoc_List : List_Id) return Elist_Id is
Actual : Node_Id;
Gen_T : Entity_Id;
Result : Elist_Id := No_Elist;
begin
if No (Assoc_List) then
return No_Elist;
end if;
-- Traverse the list of associations between formals and actuals
-- searching for renamings of tagged types
Actual := First (Assoc_List);
while Present (Actual) loop
if Nkind (Actual) = N_Subtype_Declaration then
Gen_T := Generic_Parent_Type (Actual);
if Present (Gen_T)
and then Is_Tagged_Type (Gen_T)
then
-- Traverse the list of primitives of the actual types
-- searching for hidden primitives that are visible in the
-- corresponding generic formal; leave them visible and
-- append them to Result to restore their decoration later.
Install_Hidden_Primitives
(Prims_List => Result,
Gen_T => Gen_T,
Act_T => Entity (Subtype_Indication (Actual)));
end if;
end if;
Next (Actual);
end loop;
return Result;
end Check_Hidden_Primitives;
--------------------------
-- Contains_Instance_Of --
--------------------------
function Contains_Instance_Of
(Inner : Entity_Id;
Outer : Entity_Id;
N : Node_Id) return Boolean
is
Elmt : Elmt_Id;
Scop : Entity_Id;
begin
Scop := Outer;
-- Verify that there are no circular instantiations. We check whether
-- the unit contains an instance of the current scope or some enclosing
-- scope (in case one of the instances appears in a subunit). Longer
-- circularities involving subunits might seem too pathological to
-- consider, but they were not too pathological for the authors of
-- DEC bc30vsq, so we loop over all enclosing scopes, and mark all
-- enclosing generic scopes as containing an instance.
loop
-- Within a generic subprogram body, the scope is not generic, to
-- allow for recursive subprograms. Use the declaration to determine
-- whether this is a generic unit.
if Ekind (Scop) = E_Generic_Package
or else (Is_Subprogram (Scop)
and then Nkind (Unit_Declaration_Node (Scop)) =
N_Generic_Subprogram_Declaration)
then
Elmt := First_Elmt (Inner_Instances (Inner));
while Present (Elmt) loop
if Node (Elmt) = Scop then
Error_Msg_Node_2 := Inner;
Error_Msg_NE
("circular Instantiation: & instantiated within &!",
N, Scop);
return True;
elsif Node (Elmt) = Inner then
return True;
elsif Contains_Instance_Of (Node (Elmt), Scop, N) then
Error_Msg_Node_2 := Inner;
Error_Msg_NE
("circular Instantiation: & instantiated within &!",
N, Node (Elmt));
return True;
end if;
Next_Elmt (Elmt);
end loop;
-- Indicate that Inner is being instantiated within Scop
Append_Elmt (Inner, Inner_Instances (Scop));
end if;
if Scop = Standard_Standard then
exit;
else
Scop := Scope (Scop);
end if;
end loop;
return False;
end Contains_Instance_Of;
-----------------------
-- Copy_Generic_Node --
-----------------------
function Copy_Generic_Node
(N : Node_Id;
Parent_Id : Node_Id;
Instantiating : Boolean) return Node_Id
is
Ent : Entity_Id;
New_N : Node_Id;
function Copy_Generic_Descendant (D : Union_Id) return Union_Id;
-- Check the given value of one of the Fields referenced by the current
-- node to determine whether to copy it recursively. The field may hold
-- a Node_Id, a List_Id, or an Elist_Id, or a plain value (Sloc, Uint,
-- Char) in which case it need not be copied.
procedure Copy_Descendants;
-- Common utility for various nodes
function Copy_Generic_Elist (E : Elist_Id) return Elist_Id;
-- Make copy of element list
function Copy_Generic_List
(L : List_Id;
Parent_Id : Node_Id) return List_Id;
-- Apply Copy_Node recursively to the members of a node list
function In_Defining_Unit_Name (Nam : Node_Id) return Boolean;
-- True if an identifier is part of the defining program unit name of
-- a child unit. The entity of such an identifier must be kept (for
-- ASIS use) even though as the name of an enclosing generic it would
-- otherwise not be preserved in the generic tree.
----------------------
-- Copy_Descendants --
----------------------
procedure Copy_Descendants is
use Atree.Unchecked_Access;
-- This code section is part of the implementation of an untyped
-- tree traversal, so it needs direct access to node fields.
begin
Set_Field1 (New_N, Copy_Generic_Descendant (Field1 (N)));
Set_Field2 (New_N, Copy_Generic_Descendant (Field2 (N)));
Set_Field3 (New_N, Copy_Generic_Descendant (Field3 (N)));
Set_Field4 (New_N, Copy_Generic_Descendant (Field4 (N)));
Set_Field5 (New_N, Copy_Generic_Descendant (Field5 (N)));
end Copy_Descendants;
-----------------------------
-- Copy_Generic_Descendant --
-----------------------------
function Copy_Generic_Descendant (D : Union_Id) return Union_Id is
begin
if D = Union_Id (Empty) then
return D;
elsif D in Node_Range then
return Union_Id
(Copy_Generic_Node (Node_Id (D), New_N, Instantiating));
elsif D in List_Range then
return Union_Id (Copy_Generic_List (List_Id (D), New_N));
elsif D in Elist_Range then
return Union_Id (Copy_Generic_Elist (Elist_Id (D)));
-- Nothing else is copyable (e.g. Uint values), return as is
else
return D;
end if;
end Copy_Generic_Descendant;
------------------------
-- Copy_Generic_Elist --
------------------------
function Copy_Generic_Elist (E : Elist_Id) return Elist_Id is
M : Elmt_Id;
L : Elist_Id;
begin
if Present (E) then
L := New_Elmt_List;
M := First_Elmt (E);
while Present (M) loop
Append_Elmt
(Copy_Generic_Node (Node (M), Empty, Instantiating), L);
Next_Elmt (M);
end loop;
return L;
else
return No_Elist;
end if;
end Copy_Generic_Elist;
-----------------------
-- Copy_Generic_List --
-----------------------
function Copy_Generic_List
(L : List_Id;
Parent_Id : Node_Id) return List_Id
is
N : Node_Id;
New_L : List_Id;
begin
if Present (L) then
New_L := New_List;
Set_Parent (New_L, Parent_Id);
N := First (L);
while Present (N) loop
Append (Copy_Generic_Node (N, Empty, Instantiating), New_L);
Next (N);
end loop;
return New_L;
else
return No_List;
end if;
end Copy_Generic_List;
---------------------------
-- In_Defining_Unit_Name --
---------------------------
function In_Defining_Unit_Name (Nam : Node_Id) return Boolean is
begin
return Present (Parent (Nam))
and then (Nkind (Parent (Nam)) = N_Defining_Program_Unit_Name
or else
(Nkind (Parent (Nam)) = N_Expanded_Name
and then In_Defining_Unit_Name (Parent (Nam))));
end In_Defining_Unit_Name;
-- Start of processing for Copy_Generic_Node
begin
if N = Empty then
return N;
end if;
New_N := New_Copy (N);
-- Copy aspects if present
if Has_Aspects (N) then
Set_Has_Aspects (New_N, False);
Set_Aspect_Specifications
(New_N, Copy_Generic_List (Aspect_Specifications (N), Parent_Id));
end if;
if Instantiating then
Adjust_Instantiation_Sloc (New_N, S_Adjustment);
end if;
if not Is_List_Member (N) then
Set_Parent (New_N, Parent_Id);
end if;
-- If defining identifier, then all fields have been copied already
if Nkind (New_N) in N_Entity then
null;
-- Special casing for identifiers and other entity names and operators
elsif Nkind_In (New_N, N_Identifier,
N_Character_Literal,
N_Expanded_Name,
N_Operator_Symbol)
or else Nkind (New_N) in N_Op
then
if not Instantiating then
-- Link both nodes in order to assign subsequently the entity of
-- the copy to the original node, in case this is a global
-- reference.
Set_Associated_Node (N, New_N);
-- If we are within an instantiation, this is a nested generic
-- that has already been analyzed at the point of definition.
-- We must preserve references that were global to the enclosing
-- parent at that point. Other occurrences, whether global or
-- local to the current generic, must be resolved anew, so we
-- reset the entity in the generic copy. A global reference has a
-- smaller depth than the parent, or else the same depth in case
-- both are distinct compilation units.
-- A child unit is implicitly declared within the enclosing parent
-- but is in fact global to it, and must be preserved.
-- It is also possible for Current_Instantiated_Parent to be
-- defined, and for this not to be a nested generic, namely if
-- the unit is loaded through Rtsfind. In that case, the entity of
-- New_N is only a link to the associated node, and not a defining
-- occurrence.
-- The entities for parent units in the defining_program_unit of a
-- generic child unit are established when the context of the unit
-- is first analyzed, before the generic copy is made. They are
-- preserved in the copy for use in ASIS queries.
Ent := Entity (New_N);
if No (Current_Instantiated_Parent.Gen_Id) then
if No (Ent)
or else Nkind (Ent) /= N_Defining_Identifier
or else not In_Defining_Unit_Name (N)
then
Set_Associated_Node (New_N, Empty);
end if;
elsif No (Ent)
or else
not Nkind_In (Ent, N_Defining_Identifier,
N_Defining_Character_Literal,
N_Defining_Operator_Symbol)
or else No (Scope (Ent))
or else
(Scope (Ent) = Current_Instantiated_Parent.Gen_Id
and then not Is_Child_Unit (Ent))
or else
(Scope_Depth (Scope (Ent)) >
Scope_Depth (Current_Instantiated_Parent.Gen_Id)
and then
Get_Source_Unit (Ent) =
Get_Source_Unit (Current_Instantiated_Parent.Gen_Id))
then
Set_Associated_Node (New_N, Empty);
end if;
-- Case of instantiating identifier or some other name or operator
else
-- If the associated node is still defined, the entity in it
-- is global, and must be copied to the instance. If this copy
-- is being made for a body to inline, it is applied to an
-- instantiated tree, and the entity is already present and
-- must be also preserved.
declare
Assoc : constant Node_Id := Get_Associated_Node (N);
begin
if Present (Assoc) then
if Nkind (Assoc) = Nkind (N) then
Set_Entity (New_N, Entity (Assoc));
Check_Private_View (N);
-- The name in the call may be a selected component if the
-- call has not been analyzed yet, as may be the case for
-- pre/post conditions in a generic unit.
elsif Nkind (Assoc) = N_Function_Call
and then Is_Entity_Name (Name (Assoc))
then
Set_Entity (New_N, Entity (Name (Assoc)));
elsif Nkind_In (Assoc, N_Defining_Identifier,
N_Defining_Character_Literal,
N_Defining_Operator_Symbol)
and then Expander_Active
then
-- Inlining case: we are copying a tree that contains
-- global entities, which are preserved in the copy to be
-- used for subsequent inlining.
null;
else
Set_Entity (New_N, Empty);
end if;
end if;
end;
end if;
-- For expanded name, we must copy the Prefix and Selector_Name
if Nkind (N) = N_Expanded_Name then
Set_Prefix
(New_N, Copy_Generic_Node (Prefix (N), New_N, Instantiating));
Set_Selector_Name (New_N,
Copy_Generic_Node (Selector_Name (N), New_N, Instantiating));
-- For operators, we must copy the right operand
elsif Nkind (N) in N_Op then
Set_Right_Opnd (New_N,
Copy_Generic_Node (Right_Opnd (N), New_N, Instantiating));
-- And for binary operators, the left operand as well
if Nkind (N) in N_Binary_Op then
Set_Left_Opnd (New_N,
Copy_Generic_Node (Left_Opnd (N), New_N, Instantiating));
end if;
end if;
-- Special casing for stubs
elsif Nkind (N) in N_Body_Stub then
-- In any case, we must copy the specification or defining
-- identifier as appropriate.
if Nkind (N) = N_Subprogram_Body_Stub then
Set_Specification (New_N,
Copy_Generic_Node (Specification (N), New_N, Instantiating));
else
Set_Defining_Identifier (New_N,
Copy_Generic_Node
(Defining_Identifier (N), New_N, Instantiating));
end if;
-- If we are not instantiating, then this is where we load and
-- analyze subunits, i.e. at the point where the stub occurs. A
-- more permissive system might defer this analysis to the point
-- of instantiation, but this seems too complicated for now.
if not Instantiating then
declare
Subunit_Name : constant Unit_Name_Type := Get_Unit_Name (N);
Subunit : Node_Id;
Unum : Unit_Number_Type;
New_Body : Node_Id;
begin
-- Make sure that, if it is a subunit of the main unit that is
-- preprocessed and if -gnateG is specified, the preprocessed
-- file will be written.
Lib.Analysing_Subunit_Of_Main :=
Lib.In_Extended_Main_Source_Unit (N);
Unum :=
Load_Unit
(Load_Name => Subunit_Name,
Required => False,
Subunit => True,
Error_Node => N);
Lib.Analysing_Subunit_Of_Main := False;
-- If the proper body is not found, a warning message will be
-- emitted when analyzing the stub, or later at the point of
-- instantiation. Here we just leave the stub as is.
if Unum = No_Unit then
Subunits_Missing := True;
goto Subunit_Not_Found;
end if;
Subunit := Cunit (Unum);
if Nkind (Unit (Subunit)) /= N_Subunit then
Error_Msg_N
("found child unit instead of expected SEPARATE subunit",
Subunit);
Error_Msg_Sloc := Sloc (N);
Error_Msg_N ("\to complete stub #", Subunit);
goto Subunit_Not_Found;
end if;
-- We must create a generic copy of the subunit, in order to
-- perform semantic analysis on it, and we must replace the
-- stub in the original generic unit with the subunit, in order
-- to preserve non-local references within.
-- Only the proper body needs to be copied. Library_Unit and
-- context clause are simply inherited by the generic copy.
-- Note that the copy (which may be recursive if there are
-- nested subunits) must be done first, before attaching it to
-- the enclosing generic.
New_Body :=
Copy_Generic_Node
(Proper_Body (Unit (Subunit)),
Empty, Instantiating => False);
-- Now place the original proper body in the original generic
-- unit. This is a body, not a compilation unit.
Rewrite (N, Proper_Body (Unit (Subunit)));
Set_Is_Compilation_Unit (Defining_Entity (N), False);
Set_Was_Originally_Stub (N);
-- Finally replace the body of the subunit with its copy, and
-- make this new subunit into the library unit of the generic
-- copy, which does not have stubs any longer.
Set_Proper_Body (Unit (Subunit), New_Body);
Set_Library_Unit (New_N, Subunit);
Inherit_Context (Unit (Subunit), N);
end;
-- If we are instantiating, this must be an error case, since
-- otherwise we would have replaced the stub node by the proper body
-- that corresponds. So just ignore it in the copy (i.e. we have
-- copied it, and that is good enough).
else
null;
end if;
<<Subunit_Not_Found>> null;
-- If the node is a compilation unit, it is the subunit of a stub, which
-- has been loaded already (see code below). In this case, the library
-- unit field of N points to the parent unit (which is a compilation
-- unit) and need not (and cannot) be copied.
-- When the proper body of the stub is analyzed, the library_unit link
-- is used to establish the proper context (see sem_ch10).
-- The other fields of a compilation unit are copied as usual
elsif Nkind (N) = N_Compilation_Unit then
-- This code can only be executed when not instantiating, because in
-- the copy made for an instantiation, the compilation unit node has
-- disappeared at the point that a stub is replaced by its proper
-- body.
pragma Assert (not Instantiating);
Set_Context_Items (New_N,
Copy_Generic_List (Context_Items (N), New_N));
Set_Unit (New_N,
Copy_Generic_Node (Unit (N), New_N, False));
Set_First_Inlined_Subprogram (New_N,
Copy_Generic_Node
(First_Inlined_Subprogram (N), New_N, False));
Set_Aux_Decls_Node (New_N,
Copy_Generic_Node (Aux_Decls_Node (N), New_N, False));
-- For an assignment node, the assignment is known to be semantically
-- legal if we are instantiating the template. This avoids incorrect
-- diagnostics in generated code.
elsif Nkind (N) = N_Assignment_Statement then
-- Copy name and expression fields in usual manner
Set_Name (New_N,
Copy_Generic_Node (Name (N), New_N, Instantiating));
Set_Expression (New_N,
Copy_Generic_Node (Expression (N), New_N, Instantiating));
if Instantiating then
Set_Assignment_OK (Name (New_N), True);
end if;
elsif Nkind_In (N, N_Aggregate, N_Extension_Aggregate) then
if not Instantiating then
Set_Associated_Node (N, New_N);
else
if Present (Get_Associated_Node (N))
and then Nkind (Get_Associated_Node (N)) = Nkind (N)
then
-- In the generic the aggregate has some composite type. If at
-- the point of instantiation the type has a private view,
-- install the full view (and that of its ancestors, if any).
declare
T : Entity_Id := (Etype (Get_Associated_Node (New_N)));
Rt : Entity_Id;
begin
if Present (T)
and then Is_Private_Type (T)
then
Switch_View (T);
end if;
if Present (T)
and then Is_Tagged_Type (T)
and then Is_Derived_Type (T)
then
Rt := Root_Type (T);
loop
T := Etype (T);
if Is_Private_Type (T) then
Switch_View (T);
end if;
exit when T = Rt;
end loop;
end if;
end;
end if;
end if;
-- Do not copy the associated node, which points to the generic copy
-- of the aggregate.
declare
use Atree.Unchecked_Access;
-- This code section is part of the implementation of an untyped
-- tree traversal, so it needs direct access to node fields.
begin
Set_Field1 (New_N, Copy_Generic_Descendant (Field1 (N)));
Set_Field2 (New_N, Copy_Generic_Descendant (Field2 (N)));
Set_Field3 (New_N, Copy_Generic_Descendant (Field3 (N)));
Set_Field5 (New_N, Copy_Generic_Descendant (Field5 (N)));
end;
-- Allocators do not have an identifier denoting the access type, so we
-- must locate it through the expression to check whether the views are
-- consistent.
elsif Nkind (N) = N_Allocator
and then Nkind (Expression (N)) = N_Qualified_Expression
and then Is_Entity_Name (Subtype_Mark (Expression (N)))
and then Instantiating
then
declare
T : constant Node_Id :=
Get_Associated_Node (Subtype_Mark (Expression (N)));
Acc_T : Entity_Id;
begin
if Present (T) then
-- Retrieve the allocator node in the generic copy
Acc_T := Etype (Parent (Parent (T)));
if Present (Acc_T)
and then Is_Private_Type (Acc_T)
then
Switch_View (Acc_T);
end if;
end if;
Copy_Descendants;
end;
-- For a proper body, we must catch the case of a proper body that
-- replaces a stub. This represents the point at which a separate
-- compilation unit, and hence template file, may be referenced, so we
-- must make a new source instantiation entry for the template of the
-- subunit, and ensure that all nodes in the subunit are adjusted using
-- this new source instantiation entry.
elsif Nkind (N) in N_Proper_Body then
declare
Save_Adjustment : constant Sloc_Adjustment := S_Adjustment;
begin
if Instantiating and then Was_Originally_Stub (N) then
Create_Instantiation_Source
(Instantiation_Node,
Defining_Entity (N),
False,
S_Adjustment);
end if;
-- Now copy the fields of the proper body, using the new
-- adjustment factor if one was needed as per test above.
Copy_Descendants;
-- Restore the original adjustment factor in case changed
S_Adjustment := Save_Adjustment;
end;
-- Don't copy Ident or Comment pragmas, since the comment belongs to the
-- generic unit, not to the instantiating unit.
elsif Nkind (N) = N_Pragma and then Instantiating then
declare
Prag_Id : constant Pragma_Id := Get_Pragma_Id (N);
begin
if Prag_Id = Pragma_Ident or else Prag_Id = Pragma_Comment then
New_N := Make_Null_Statement (Sloc (N));
else
Copy_Descendants;
end if;
end;
elsif Nkind_In (N, N_Integer_Literal, N_Real_Literal) then
-- No descendant fields need traversing
null;
elsif Nkind (N) = N_String_Literal
and then Present (Etype (N))
and then Instantiating
then
-- If the string is declared in an outer scope, the string_literal
-- subtype created for it may have the wrong scope. We force the
-- reanalysis of the constant to generate a new itype in the proper
-- context.
Set_Etype (New_N, Empty);
Set_Analyzed (New_N, False);
-- For the remaining nodes, copy their descendants recursively
else
Copy_Descendants;
if Instantiating and then Nkind (N) = N_Subprogram_Body then
Set_Generic_Parent (Specification (New_N), N);
-- Should preserve Corresponding_Spec??? (12.3(14))
end if;
end if;
return New_N;
end Copy_Generic_Node;
----------------------------
-- Denotes_Formal_Package --
----------------------------
function Denotes_Formal_Package
(Pack : Entity_Id;
On_Exit : Boolean := False;
Instance : Entity_Id := Empty) return Boolean
is
Par : Entity_Id;
Scop : constant Entity_Id := Scope (Pack);
E : Entity_Id;
function Is_Actual_Of_Previous_Formal (P : Entity_Id) return Boolean;
-- The package in question may be an actual for a previous formal
-- package P of the current instance, so examine its actuals as well.
-- This must be recursive over other formal packages.
----------------------------------
-- Is_Actual_Of_Previous_Formal --
----------------------------------
function Is_Actual_Of_Previous_Formal (P : Entity_Id) return Boolean is
E1 : Entity_Id;
begin
E1 := First_Entity (P);
while Present (E1) and then E1 /= Instance loop
if Ekind (E1) = E_Package
and then Nkind (Parent (E1)) = N_Package_Renaming_Declaration
then
if Renamed_Object (E1) = Pack then
return True;
elsif E1 = P or else Renamed_Object (E1) = P then
return False;
elsif Is_Actual_Of_Previous_Formal (E1) then
return True;
end if;
end if;
Next_Entity (E1);
end loop;
return False;
end Is_Actual_Of_Previous_Formal;
-- Start of processing for Denotes_Formal_Package
begin
if On_Exit then
Par :=
Instance_Envs.Table
(Instance_Envs.Last).Instantiated_Parent.Act_Id;
else
Par := Current_Instantiated_Parent.Act_Id;
end if;
if Ekind (Scop) = E_Generic_Package
or else Nkind (Unit_Declaration_Node (Scop)) =
N_Generic_Subprogram_Declaration
then
return True;
elsif Nkind (Original_Node (Unit_Declaration_Node (Pack))) =
N_Formal_Package_Declaration
then
return True;
elsif No (Par) then
return False;
else
-- Check whether this package is associated with a formal package of
-- the enclosing instantiation. Iterate over the list of renamings.
E := First_Entity (Par);
while Present (E) loop
if Ekind (E) /= E_Package
or else Nkind (Parent (E)) /= N_Package_Renaming_Declaration
then
null;
elsif Renamed_Object (E) = Par then
return False;
elsif Renamed_Object (E) = Pack then
return True;
elsif Is_Actual_Of_Previous_Formal (E) then
return True;
end if;
Next_Entity (E);
end loop;
return False;
end if;
end Denotes_Formal_Package;
-----------------
-- End_Generic --
-----------------
procedure End_Generic is
begin
-- ??? More things could be factored out in this routine. Should
-- probably be done at a later stage.
Inside_A_Generic := Generic_Flags.Table (Generic_Flags.Last);
Generic_Flags.Decrement_Last;
Expander_Mode_Restore;
end End_Generic;
-------------
-- Earlier --
-------------
function Earlier (N1, N2 : Node_Id) return Boolean is
procedure Find_Depth (P : in out Node_Id; D : in out Integer);
-- Find distance from given node to enclosing compilation unit
----------------
-- Find_Depth --
----------------
procedure Find_Depth (P : in out Node_Id; D : in out Integer) is
begin
while Present (P)
and then Nkind (P) /= N_Compilation_Unit
loop
P := True_Parent (P);
D := D + 1;
end loop;
end Find_Depth;
-- Local declarations
D1 : Integer := 0;
D2 : Integer := 0;
P1 : Node_Id := N1;
P2 : Node_Id := N2;
T1 : Source_Ptr;
T2 : Source_Ptr;
-- Start of processing for Earlier
begin
Find_Depth (P1, D1);
Find_Depth (P2, D2);
if P1 /= P2 then
return False;
else
P1 := N1;
P2 := N2;
end if;
while D1 > D2 loop
P1 := True_Parent (P1);
D1 := D1 - 1;
end loop;
while D2 > D1 loop
P2 := True_Parent (P2);
D2 := D2 - 1;
end loop;
-- At this point P1 and P2 are at the same distance from the root.
-- We examine their parents until we find a common declarative list.
-- If we reach the root, N1 and N2 do not descend from the same
-- declarative list (e.g. one is nested in the declarative part and
-- the other is in a block in the statement part) and the earlier
-- one is already frozen.
while not Is_List_Member (P1)
or else not Is_List_Member (P2)
or else List_Containing (P1) /= List_Containing (P2)
loop
P1 := True_Parent (P1);
P2 := True_Parent (P2);
if Nkind (Parent (P1)) = N_Subunit then
P1 := Corresponding_Stub (Parent (P1));
end if;
if Nkind (Parent (P2)) = N_Subunit then
P2 := Corresponding_Stub (Parent (P2));
end if;
if P1 = P2 then
return False;
end if;
end loop;
-- Expanded code usually shares the source location of the original
-- construct it was generated for. This however may not necessarely
-- reflect the true location of the code within the tree.
-- Before comparing the slocs of the two nodes, make sure that we are
-- working with correct source locations. Assume that P1 is to the left
-- of P2. If either one does not come from source, traverse the common
-- list heading towards the other node and locate the first source
-- statement.
-- P1 P2
-- ----+===+===+--------------+===+===+----
-- expanded code expanded code
if not Comes_From_Source (P1) then
while Present (P1) loop
-- Neither P2 nor a source statement were located during the
-- search. If we reach the end of the list, then P1 does not
-- occur earlier than P2.
-- ---->
-- start --- P2 ----- P1 --- end
if No (Next (P1)) then
return False;
-- We encounter P2 while going to the right of the list. This
-- means that P1 does indeed appear earlier.
-- ---->
-- start --- P1 ===== P2 --- end
-- expanded code in between
elsif P1 = P2 then
return True;
-- No need to look any further since we have located a source
-- statement.
elsif Comes_From_Source (P1) then
exit;
end if;
-- Keep going right
Next (P1);
end loop;
end if;
if not Comes_From_Source (P2) then
while Present (P2) loop
-- Neither P1 nor a source statement were located during the
-- search. If we reach the start of the list, then P1 does not
-- occur earlier than P2.
-- <----
-- start --- P2 --- P1 --- end
if No (Prev (P2)) then
return False;
-- We encounter P1 while going to the left of the list. This
-- means that P1 does indeed appear earlier.
-- <----
-- start --- P1 ===== P2 --- end
-- expanded code in between
elsif P2 = P1 then
return True;
-- No need to look any further since we have located a source
-- statement.
elsif Comes_From_Source (P2) then
exit;
end if;
-- Keep going left
Prev (P2);
end loop;
end if;
-- At this point either both nodes came from source or we approximated
-- their source locations through neighbouring source statements.
T1 := Top_Level_Location (Sloc (P1));
T2 := Top_Level_Location (Sloc (P2));
-- When two nodes come from the same instance, they have identical top
-- level locations. To determine proper relation within the tree, check
-- their locations within the template.
if T1 = T2 then
return Sloc (P1) < Sloc (P2);
-- The two nodes either come from unrelated instances or do not come
-- from instantiated code at all.
else
return T1 < T2;
end if;
end Earlier;
----------------------
-- Find_Actual_Type --
----------------------
function Find_Actual_Type
(Typ : Entity_Id;
Gen_Type : Entity_Id) return Entity_Id
is
Gen_Scope : constant Entity_Id := Scope (Gen_Type);
T : Entity_Id;
begin
-- Special processing only applies to child units
if not Is_Child_Unit (Gen_Scope) then
return Get_Instance_Of (Typ);
-- If designated or component type is itself a formal of the child unit,
-- its instance is available.
elsif Scope (Typ) = Gen_Scope then
return Get_Instance_Of (Typ);
-- If the array or access type is not declared in the parent unit,
-- no special processing needed.
elsif not Is_Generic_Type (Typ)
and then Scope (Gen_Scope) /= Scope (Typ)
then
return Get_Instance_Of (Typ);
-- Otherwise, retrieve designated or component type by visibility
else
T := Current_Entity (Typ);
while Present (T) loop
if In_Open_Scopes (Scope (T)) then
return T;
elsif Is_Generic_Actual_Type (T) then
return T;
end if;
T := Homonym (T);
end loop;
return Typ;
end if;
end Find_Actual_Type;
----------------------------
-- Freeze_Subprogram_Body --
----------------------------
procedure Freeze_Subprogram_Body
(Inst_Node : Node_Id;
Gen_Body : Node_Id;
Pack_Id : Entity_Id)
is
Gen_Unit : constant Entity_Id := Get_Generic_Entity (Inst_Node);
Par : constant Entity_Id := Scope (Gen_Unit);
E_G_Id : Entity_Id;
Enc_G : Entity_Id;
Enc_I : Node_Id;
F_Node : Node_Id;
function Enclosing_Package_Body (N : Node_Id) return Node_Id;
-- Find innermost package body that encloses the given node, and which
-- is not a compilation unit. Freeze nodes for the instance, or for its
-- enclosing body, may be inserted after the enclosing_body of the
-- generic unit. Used to determine proper placement of freeze node for
-- both package and subprogram instances.
function Package_Freeze_Node (B : Node_Id) return Node_Id;
-- Find entity for given package body, and locate or create a freeze
-- node for it.
----------------------------
-- Enclosing_Package_Body --
----------------------------
function Enclosing_Package_Body (N : Node_Id) return Node_Id is
P : Node_Id;
begin
P := Parent (N);
while Present (P)
and then Nkind (Parent (P)) /= N_Compilation_Unit
loop
if Nkind (P) = N_Package_Body then
if Nkind (Parent (P)) = N_Subunit then
return Corresponding_Stub (Parent (P));
else
return P;
end if;
end if;
P := True_Parent (P);
end loop;
return Empty;
end Enclosing_Package_Body;
-------------------------
-- Package_Freeze_Node --
-------------------------
function Package_Freeze_Node (B : Node_Id) return Node_Id is
Id : Entity_Id;
begin
if Nkind (B) = N_Package_Body then
Id := Corresponding_Spec (B);
else pragma Assert (Nkind (B) = N_Package_Body_Stub);
Id := Corresponding_Spec (Proper_Body (Unit (Library_Unit (B))));
end if;
Ensure_Freeze_Node (Id);
return Freeze_Node (Id);
end Package_Freeze_Node;
-- Start of processing of Freeze_Subprogram_Body
begin
-- If the instance and the generic body appear within the same unit, and
-- the instance precedes the generic, the freeze node for the instance
-- must appear after that of the generic. If the generic is nested
-- within another instance I2, then current instance must be frozen
-- after I2. In both cases, the freeze nodes are those of enclosing
-- packages. Otherwise, the freeze node is placed at the end of the
-- current declarative part.
Enc_G := Enclosing_Package_Body (Gen_Body);
Enc_I := Enclosing_Package_Body (Inst_Node);
Ensure_Freeze_Node (Pack_Id);
F_Node := Freeze_Node (Pack_Id);
if Is_Generic_Instance (Par)
and then Present (Freeze_Node (Par))
and then In_Same_Declarative_Part (Freeze_Node (Par), Inst_Node)
then
-- The parent was a premature instantiation. Insert freeze node at
-- the end the current declarative part.
if ABE_Is_Certain (Get_Package_Instantiation_Node (Par)) then
Insert_Freeze_Node_For_Instance (Inst_Node, F_Node);
-- Handle the following case:
--
-- package Parent_Inst is new ...
-- Parent_Inst []
--
-- procedure P ... -- this body freezes Parent_Inst
--
-- package Inst is new ...
--
-- In this particular scenario, the freeze node for Inst must be
-- inserted in the same manner as that of Parent_Inst - before the
-- next source body or at the end of the declarative list (body not
-- available). If body P did not exist and Parent_Inst was frozen
-- after Inst, either by a body following Inst or at the end of the
-- declarative region, the freeze node for Inst must be inserted
-- after that of Parent_Inst. This relation is established by
-- comparing the Slocs of Parent_Inst freeze node and Inst.
elsif List_Containing (Get_Package_Instantiation_Node (Par)) =
List_Containing (Inst_Node)
and then Sloc (Freeze_Node (Par)) < Sloc (Inst_Node)
then
Insert_Freeze_Node_For_Instance (Inst_Node, F_Node);
else
Insert_After (Freeze_Node (Par), F_Node);
end if;
-- The body enclosing the instance should be frozen after the body that
-- includes the generic, because the body of the instance may make
-- references to entities therein. If the two are not in the same
-- declarative part, or if the one enclosing the instance is frozen
-- already, freeze the instance at the end of the current declarative
-- part.
elsif Is_Generic_Instance (Par)
and then Present (Freeze_Node (Par))
and then Present (Enc_I)
then
if In_Same_Declarative_Part (Freeze_Node (Par), Enc_I)
or else
(Nkind (Enc_I) = N_Package_Body
and then
In_Same_Declarative_Part (Freeze_Node (Par), Parent (Enc_I)))
then
-- The enclosing package may contain several instances. Rather
-- than computing the earliest point at which to insert its freeze
-- node, we place it at the end of the declarative part of the
-- parent of the generic.
Insert_Freeze_Node_For_Instance
(Freeze_Node (Par), Package_Freeze_Node (Enc_I));
end if;
Insert_Freeze_Node_For_Instance (Inst_Node, F_Node);
elsif Present (Enc_G)
and then Present (Enc_I)
and then Enc_G /= Enc_I
and then Earlier (Inst_Node, Gen_Body)
then
if Nkind (Enc_G) = N_Package_Body then
E_G_Id := Corresponding_Spec (Enc_G);
else pragma Assert (Nkind (Enc_G) = N_Package_Body_Stub);
E_G_Id :=
Corresponding_Spec (Proper_Body (Unit (Library_Unit (Enc_G))));
end if;
-- Freeze package that encloses instance, and place node after the
-- package that encloses generic. If enclosing package is already
-- frozen we have to assume it is at the proper place. This may be a
-- potential ABE that requires dynamic checking. Do not add a freeze
-- node if the package that encloses the generic is inside the body
-- that encloses the instance, because the freeze node would be in
-- the wrong scope. Additional contortions needed if the bodies are
-- within a subunit.
declare
Enclosing_Body : Node_Id;
begin
if Nkind (Enc_I) = N_Package_Body_Stub then
Enclosing_Body := Proper_Body (Unit (Library_Unit (Enc_I)));
else
Enclosing_Body := Enc_I;
end if;
if Parent (List_Containing (Enc_G)) /= Enclosing_Body then
Insert_Freeze_Node_For_Instance
(Enc_G, Package_Freeze_Node (Enc_I));
end if;
end;
-- Freeze enclosing subunit before instance
Ensure_Freeze_Node (E_G_Id);
if not Is_List_Member (Freeze_Node (E_G_Id)) then
Insert_After (Enc_G, Freeze_Node (E_G_Id));
end if;
Insert_Freeze_Node_For_Instance (Inst_Node, F_Node);
else
-- If none of the above, insert freeze node at the end of the current
-- declarative part.
Insert_Freeze_Node_For_Instance (Inst_Node, F_Node);
end if;
end Freeze_Subprogram_Body;
----------------
-- Get_Gen_Id --
----------------
function Get_Gen_Id (E : Assoc_Ptr) return Entity_Id is
begin
return Generic_Renamings.Table (E).Gen_Id;
end Get_Gen_Id;
---------------------
-- Get_Instance_Of --
---------------------
function Get_Instance_Of (A : Entity_Id) return Entity_Id is
Res : constant Assoc_Ptr := Generic_Renamings_HTable.Get (A);
begin
if Res /= Assoc_Null then
return Generic_Renamings.Table (Res).Act_Id;
else
-- On exit, entity is not instantiated: not a generic parameter, or
-- else parameter of an inner generic unit.
return A;
end if;
end Get_Instance_Of;
------------------------------------
-- Get_Package_Instantiation_Node --
------------------------------------
function Get_Package_Instantiation_Node (A : Entity_Id) return Node_Id is
Decl : Node_Id := Unit_Declaration_Node (A);
Inst : Node_Id;
begin
-- If the Package_Instantiation attribute has been set on the package
-- entity, then use it directly when it (or its Original_Node) refers
-- to an N_Package_Instantiation node. In principle it should be
-- possible to have this field set in all cases, which should be
-- investigated, and would allow this function to be significantly
-- simplified. ???
Inst := Package_Instantiation (A);
if Present (Inst) then
if Nkind (Inst) = N_Package_Instantiation then
return Inst;
elsif Nkind (Original_Node (Inst)) = N_Package_Instantiation then
return Original_Node (Inst);
end if;
end if;
-- If the instantiation is a compilation unit that does not need body
-- then the instantiation node has been rewritten as a package
-- declaration for the instance, and we return the original node.
-- If it is a compilation unit and the instance node has not been
-- rewritten, then it is still the unit of the compilation. Finally, if
-- a body is present, this is a parent of the main unit whose body has
-- been compiled for inlining purposes, and the instantiation node has
-- been rewritten with the instance body.
-- Otherwise the instantiation node appears after the declaration. If
-- the entity is a formal package, the declaration may have been
-- rewritten as a generic declaration (in the case of a formal with box)
-- or left as a formal package declaration if it has actuals, and is
-- found with a forward search.
if Nkind (Parent (Decl)) = N_Compilation_Unit then
if Nkind (Decl) = N_Package_Declaration
and then Present (Corresponding_Body (Decl))
then
Decl := Unit_Declaration_Node (Corresponding_Body (Decl));
end if;
if Nkind (Original_Node (Decl)) = N_Package_Instantiation then
return Original_Node (Decl);
else
return Unit (Parent (Decl));
end if;
elsif Nkind (Decl) = N_Package_Declaration
and then Nkind (Original_Node (Decl)) = N_Formal_Package_Declaration
then
return Original_Node (Decl);
else
Inst := Next (Decl);
while not Nkind_In (Inst, N_Package_Instantiation,
N_Formal_Package_Declaration)
loop
Next (Inst);
end loop;
return Inst;
end if;
end Get_Package_Instantiation_Node;
------------------------
-- Has_Been_Exchanged --
------------------------
function Has_Been_Exchanged (E : Entity_Id) return Boolean is
Next : Elmt_Id;
begin
Next := First_Elmt (Exchanged_Views);
while Present (Next) loop
if Full_View (Node (Next)) = E then
return True;
end if;
Next_Elmt (Next);
end loop;
return False;
end Has_Been_Exchanged;
----------
-- Hash --
----------
function Hash (F : Entity_Id) return HTable_Range is
begin
return HTable_Range (F mod HTable_Size);
end Hash;
------------------------
-- Hide_Current_Scope --
------------------------
procedure Hide_Current_Scope is
C : constant Entity_Id := Current_Scope;
E : Entity_Id;
begin
Set_Is_Hidden_Open_Scope (C);
E := First_Entity (C);
while Present (E) loop
if Is_Immediately_Visible (E) then
Set_Is_Immediately_Visible (E, False);
Append_Elmt (E, Hidden_Entities);
end if;
Next_Entity (E);
end loop;
-- Make the scope name invisible as well. This is necessary, but might
-- conflict with calls to Rtsfind later on, in case the scope is a
-- predefined one. There is no clean solution to this problem, so for
-- now we depend on the user not redefining Standard itself in one of
-- the parent units.
if Is_Immediately_Visible (C) and then C /= Standard_Standard then
Set_Is_Immediately_Visible (C, False);
Append_Elmt (C, Hidden_Entities);
end if;
end Hide_Current_Scope;
--------------
-- Init_Env --
--------------
procedure Init_Env is
Saved : Instance_Env;
begin
Saved.Instantiated_Parent := Current_Instantiated_Parent;
Saved.Exchanged_Views := Exchanged_Views;
Saved.Hidden_Entities := Hidden_Entities;
Saved.Current_Sem_Unit := Current_Sem_Unit;
Saved.Parent_Unit_Visible := Parent_Unit_Visible;
Saved.Instance_Parent_Unit := Instance_Parent_Unit;
-- Save configuration switches. These may be reset if the unit is a
-- predefined unit, and the current mode is not Ada 2005.
Save_Opt_Config_Switches (Saved.Switches);
Instance_Envs.Append (Saved);
Exchanged_Views := New_Elmt_List;
Hidden_Entities := New_Elmt_List;
-- Make dummy entry for Instantiated parent. If generic unit is legal,
-- this is set properly in Set_Instance_Env.
Current_Instantiated_Parent :=
(Current_Scope, Current_Scope, Assoc_Null);
end Init_Env;
------------------------------
-- In_Same_Declarative_Part --
------------------------------
function In_Same_Declarative_Part
(F_Node : Node_Id;
Inst : Node_Id) return Boolean
is
Decls : constant Node_Id := Parent (F_Node);
Nod : Node_Id := Parent (Inst);
begin
while Present (Nod) loop
if Nod = Decls then
return True;
elsif Nkind_In (Nod, N_Subprogram_Body,
N_Package_Body,
N_Package_Declaration,
N_Task_Body,
N_Protected_Body,
N_Block_Statement)
then
return False;
elsif Nkind (Nod) = N_Subunit then
Nod := Corresponding_Stub (Nod);
elsif Nkind (Nod) = N_Compilation_Unit then
return False;
else
Nod := Parent (Nod);
end if;
end loop;
return False;
end In_Same_Declarative_Part;
---------------------
-- In_Main_Context --
---------------------
function In_Main_Context (E : Entity_Id) return Boolean is
Context : List_Id;
Clause : Node_Id;
Nam : Node_Id;
begin
if not Is_Compilation_Unit (E)
or else Ekind (E) /= E_Package
or else In_Private_Part (E)
then
return False;
end if;
Context := Context_Items (Cunit (Main_Unit));
Clause := First (Context);
while Present (Clause) loop
if Nkind (Clause) = N_With_Clause then
Nam := Name (Clause);
-- If the current scope is part of the context of the main unit,
-- analysis of the corresponding with_clause is not complete, and
-- the entity is not set. We use the Chars field directly, which
-- might produce false positives in rare cases, but guarantees
-- that we produce all the instance bodies we will need.
if (Is_Entity_Name (Nam) and then Chars (Nam) = Chars (E))
or else (Nkind (Nam) = N_Selected_Component
and then Chars (Selector_Name (Nam)) = Chars (E))
then
return True;
end if;
end if;
Next (Clause);
end loop;
return False;
end In_Main_Context;
---------------------
-- Inherit_Context --
---------------------
procedure Inherit_Context (Gen_Decl : Node_Id; Inst : Node_Id) is
Current_Context : List_Id;
Current_Unit : Node_Id;
Item : Node_Id;
New_I : Node_Id;
Clause : Node_Id;
OK : Boolean;
Lib_Unit : Node_Id;
begin
if Nkind (Parent (Gen_Decl)) = N_Compilation_Unit then
-- The inherited context is attached to the enclosing compilation
-- unit. This is either the main unit, or the declaration for the
-- main unit (in case the instantiation appears within the package
-- declaration and the main unit is its body).
Current_Unit := Parent (Inst);
while Present (Current_Unit)
and then Nkind (Current_Unit) /= N_Compilation_Unit
loop
Current_Unit := Parent (Current_Unit);
end loop;
Current_Context := Context_Items (Current_Unit);
Item := First (Context_Items (Parent (Gen_Decl)));
while Present (Item) loop
if Nkind (Item) = N_With_Clause then
Lib_Unit := Library_Unit (Item);
-- Take care to prevent direct cyclic with's
if Lib_Unit /= Current_Unit then
-- Do not add a unit if it is already in the context
Clause := First (Current_Context);
OK := True;
while Present (Clause) loop
if Nkind (Clause) = N_With_Clause and then
Library_Unit (Clause) = Lib_Unit
then
OK := False;
exit;
end if;
Next (Clause);
end loop;
if OK then
New_I := New_Copy (Item);
Set_Implicit_With (New_I, True);
Set_Implicit_With_From_Instantiation (New_I, True);
Append (New_I, Current_Context);
end if;
end if;
end if;
Next (Item);
end loop;
end if;
end Inherit_Context;
----------------
-- Initialize --
----------------
procedure Initialize is
begin
Generic_Renamings.Init;
Instance_Envs.Init;
Generic_Flags.Init;
Generic_Renamings_HTable.Reset;
Circularity_Detected := False;
Exchanged_Views := No_Elist;
Hidden_Entities := No_Elist;
end Initialize;
-------------------------------------
-- Insert_Freeze_Node_For_Instance --
-------------------------------------
procedure Insert_Freeze_Node_For_Instance
(N : Node_Id;
F_Node : Node_Id)
is
Decl : Node_Id;
Decls : List_Id;
Inst : Entity_Id;
Par_N : Node_Id;
function Enclosing_Body (N : Node_Id) return Node_Id;
-- Find enclosing package or subprogram body, if any. Freeze node may
-- be placed at end of current declarative list if previous instance
-- and current one have different enclosing bodies.
function Previous_Instance (Gen : Entity_Id) return Entity_Id;
-- Find the local instance, if any, that declares the generic that is
-- being instantiated. If present, the freeze node for this instance
-- must follow the freeze node for the previous instance.
--------------------
-- Enclosing_Body --
--------------------
function Enclosing_Body (N : Node_Id) return Node_Id is
P : Node_Id;
begin
P := Parent (N);
while Present (P)
and then Nkind (Parent (P)) /= N_Compilation_Unit
loop
if Nkind_In (P, N_Package_Body, N_Subprogram_Body) then
if Nkind (Parent (P)) = N_Subunit then
return Corresponding_Stub (Parent (P));
else
return P;
end if;
end if;
P := True_Parent (P);
end loop;
return Empty;
end Enclosing_Body;
-----------------------
-- Previous_Instance --
-----------------------
function Previous_Instance (Gen : Entity_Id) return Entity_Id is
S : Entity_Id;
begin
S := Scope (Gen);
while Present (S)
and then S /= Standard_Standard
loop
if Is_Generic_Instance (S)
and then In_Same_Source_Unit (S, N)
then
return S;
end if;
S := Scope (S);
end loop;
return Empty;
end Previous_Instance;
-- Start of processing for Insert_Freeze_Node_For_Instance
begin
if not Is_List_Member (F_Node) then
Decl := N;
Decls := List_Containing (N);
Inst := Entity (F_Node);
Par_N := Parent (Decls);
-- When processing a subprogram instantiation, utilize the actual
-- subprogram instantiation rather than its package wrapper as it
-- carries all the context information.
if Is_Wrapper_Package (Inst) then
Inst := Related_Instance (Inst);
end if;
-- If this is a package instance, check whether the generic is
-- declared in a previous instance and the current instance is
-- not within the previous one.
if Present (Generic_Parent (Parent (Inst)))
and then Is_In_Main_Unit (N)
then
declare
Enclosing_N : constant Node_Id := Enclosing_Body (N);
Par_I : constant Entity_Id :=
Previous_Instance
(Generic_Parent (Parent (Inst)));
Scop : Entity_Id;
begin
if Present (Par_I)
and then Earlier (N, Freeze_Node (Par_I))
then
Scop := Scope (Inst);
-- If the current instance is within the one that contains
-- the generic, the freeze node for the current one must
-- appear in the current declarative part. Ditto, if the
-- current instance is within another package instance or
-- within a body that does not enclose the current instance.
-- In these three cases the freeze node of the previous
-- instance is not relevant.
while Present (Scop)
and then Scop /= Standard_Standard
loop
exit when Scop = Par_I
or else
(Is_Generic_Instance (Scop)
and then Scope_Depth (Scop) > Scope_Depth (Par_I));
Scop := Scope (Scop);
end loop;
-- Previous instance encloses current instance
if Scop = Par_I then
null;
-- If the next node is a source body we must freeze in
-- the current scope as well.
elsif Present (Next (N))
and then Nkind_In (Next (N),
N_Subprogram_Body, N_Package_Body)
and then Comes_From_Source (Next (N))
then
null;
-- Current instance is within an unrelated instance
elsif Is_Generic_Instance (Scop) then
null;
-- Current instance is within an unrelated body
elsif Present (Enclosing_N)
and then Enclosing_N /= Enclosing_Body (Par_I)
then
null;
else
Insert_After (Freeze_Node (Par_I), F_Node);
return;
end if;
end if;
end;
end if;
-- When the instantiation occurs in a package declaration, append the
-- freeze node to the private declarations (if any).
if Nkind (Par_N) = N_Package_Specification
and then Decls = Visible_Declarations (Par_N)
and then Present (Private_Declarations (Par_N))
and then not Is_Empty_List (Private_Declarations (Par_N))
then
Decls := Private_Declarations (Par_N);
Decl := First (Decls);
end if;
-- Determine the proper freeze point of a package instantiation. We
-- adhere to the general rule of a package or subprogram body causing
-- freezing of anything before it in the same declarative region. In
-- this case, the proper freeze point of a package instantiation is
-- before the first source body which follows, or before a stub. This
-- ensures that entities coming from the instance are already frozen
-- and usable in source bodies.
if Nkind (Par_N) /= N_Package_Declaration
and then Ekind (Inst) = E_Package
and then Is_Generic_Instance (Inst)
and then
not In_Same_Source_Unit (Generic_Parent (Parent (Inst)), Inst)
then
while Present (Decl) loop
if (Nkind (Decl) in N_Unit_Body
or else
Nkind (Decl) in N_Body_Stub)
and then Comes_From_Source (Decl)
then
Insert_Before (Decl, F_Node);
return;
end if;
Next (Decl);
end loop;
end if;
-- In a package declaration, or if no previous body, insert at end
-- of list.
Set_Sloc (F_Node, Sloc (Last (Decls)));
Insert_After (Last (Decls), F_Node);
end if;
end Insert_Freeze_Node_For_Instance;
------------------
-- Install_Body --
------------------
procedure Install_Body
(Act_Body : Node_Id;
N : Node_Id;
Gen_Body : Node_Id;
Gen_Decl : Node_Id)
is
Act_Id : constant Entity_Id := Corresponding_Spec (Act_Body);
Act_Unit : constant Node_Id := Unit (Cunit (Get_Source_Unit (N)));
Gen_Id : constant Entity_Id := Corresponding_Spec (Gen_Body);
Par : constant Entity_Id := Scope (Gen_Id);
Gen_Unit : constant Node_Id :=
Unit (Cunit (Get_Source_Unit (Gen_Decl)));
Orig_Body : Node_Id := Gen_Body;
F_Node : Node_Id;
Body_Unit : Node_Id;
Must_Delay : Boolean;
function In_Same_Enclosing_Subp return Boolean;
-- Check whether instance and generic body are within same subprogram.
function True_Sloc (N : Node_Id) return Source_Ptr;
-- If the instance is nested inside a generic unit, the Sloc of the
-- instance indicates the place of the original definition, not the
-- point of the current enclosing instance. Pending a better usage of
-- Slocs to indicate instantiation places, we determine the place of
-- origin of a node by finding the maximum sloc of any ancestor node.
-- Why is this not equivalent to Top_Level_Location ???
----------------------------
-- In_Same_Enclosing_Subp --
----------------------------
function In_Same_Enclosing_Subp return Boolean is
Scop : Entity_Id;
Subp : Entity_Id;
begin
Scop := Scope (Act_Id);
while Scop /= Standard_Standard
and then not Is_Overloadable (Scop)
loop
Scop := Scope (Scop);
end loop;
if Scop = Standard_Standard then
return False;
else
Subp := Scop;
end if;
Scop := Scope (Gen_Id);
while Scop /= Standard_Standard loop
if Scop = Subp then
return True;
else
Scop := Scope (Scop);
end if;
end loop;
return False;
end In_Same_Enclosing_Subp;
---------------
-- True_Sloc --
---------------
function True_Sloc (N : Node_Id) return Source_Ptr is
Res : Source_Ptr;
N1 : Node_Id;
begin
Res := Sloc (N);
N1 := N;
while Present (N1) and then N1 /= Act_Unit loop
if Sloc (N1) > Res then
Res := Sloc (N1);
end if;
N1 := Parent (N1);
end loop;
return Res;
end True_Sloc;
-- Start of processing for Install_Body
begin
-- If the body is a subunit, the freeze point is the corresponding stub
-- in the current compilation, not the subunit itself.
if Nkind (Parent (Gen_Body)) = N_Subunit then
Orig_Body := Corresponding_Stub (Parent (Gen_Body));
else
Orig_Body := Gen_Body;
end if;
Body_Unit := Unit (Cunit (Get_Source_Unit (Orig_Body)));
-- If the instantiation and the generic definition appear in the same
-- package declaration, this is an early instantiation. If they appear
-- in the same declarative part, it is an early instantiation only if
-- the generic body appears textually later, and the generic body is
-- also in the main unit.
-- If instance is nested within a subprogram, and the generic body
-- is not, the instance is delayed because the enclosing body is. If
-- instance and body are within the same scope, or the same subprogram
-- body, indicate explicitly that the instance is delayed.
Must_Delay :=
(Gen_Unit = Act_Unit
and then (Nkind_In (Gen_Unit, N_Package_Declaration,
N_Generic_Package_Declaration)
or else (Gen_Unit = Body_Unit
and then True_Sloc (N) < Sloc (Orig_Body)))
and then Is_In_Main_Unit (Gen_Unit)
and then (Scope (Act_Id) = Scope (Gen_Id)
or else In_Same_Enclosing_Subp));
-- If this is an early instantiation, the freeze node is placed after
-- the generic body. Otherwise, if the generic appears in an instance,
-- we cannot freeze the current instance until the outer one is frozen.
-- This is only relevant if the current instance is nested within some
-- inner scope not itself within the outer instance. If this scope is
-- a package body in the same declarative part as the outer instance,
-- then that body needs to be frozen after the outer instance. Finally,
-- if no delay is needed, we place the freeze node at the end of the
-- current declarative part.
if Expander_Active then
Ensure_Freeze_Node (Act_Id);
F_Node := Freeze_Node (Act_Id);
if Must_Delay then
Insert_After (Orig_Body, F_Node);
elsif Is_Generic_Instance (Par)
and then Present (Freeze_Node (Par))
and then Scope (Act_Id) /= Par
then
-- Freeze instance of inner generic after instance of enclosing
-- generic.
if In_Same_Declarative_Part (Freeze_Node (Par), N) then
-- Handle the following case:
-- package Parent_Inst is new ...
-- Parent_Inst []
-- procedure P ... -- this body freezes Parent_Inst
-- package Inst is new ...
-- In this particular scenario, the freeze node for Inst must
-- be inserted in the same manner as that of Parent_Inst,
-- before the next source body or at the end of the declarative
-- list (body not available). If body P did not exist and
-- Parent_Inst was frozen after Inst, either by a body
-- following Inst or at the end of the declarative region,
-- the freeze node for Inst must be inserted after that of
-- Parent_Inst. This relation is established by comparing
-- the Slocs of Parent_Inst freeze node and Inst.
if List_Containing (Get_Package_Instantiation_Node (Par)) =
List_Containing (N)
and then Sloc (Freeze_Node (Par)) < Sloc (N)
then
Insert_Freeze_Node_For_Instance (N, F_Node);
else
Insert_After (Freeze_Node (Par), F_Node);
end if;
-- Freeze package enclosing instance of inner generic after
-- instance of enclosing generic.
elsif Nkind_In (Parent (N), N_Package_Body, N_Subprogram_Body)
and then In_Same_Declarative_Part (Freeze_Node (Par), Parent (N))
then
declare
Enclosing : Entity_Id;
begin
Enclosing := Corresponding_Spec (Parent (N));
if No (Enclosing) then
Enclosing := Defining_Entity (Parent (N));
end if;
Insert_Freeze_Node_For_Instance (N, F_Node);
Ensure_Freeze_Node (Enclosing);
if not Is_List_Member (Freeze_Node (Enclosing)) then
-- The enclosing context is a subunit, insert the freeze
-- node after the stub.
if Nkind (Parent (Parent (N))) = N_Subunit then
Insert_Freeze_Node_For_Instance
(Corresponding_Stub (Parent (Parent (N))),
Freeze_Node (Enclosing));
-- The enclosing context is a package with a stub body
-- which has already been replaced by the real body.
-- Insert the freeze node after the actual body.
elsif Ekind (Enclosing) = E_Package
and then Present (Body_Entity (Enclosing))
and then Was_Originally_Stub
(Parent (Body_Entity (Enclosing)))
then
Insert_Freeze_Node_For_Instance
(Parent (Body_Entity (Enclosing)),
Freeze_Node (Enclosing));
-- The parent instance has been frozen before the body of
-- the enclosing package, insert the freeze node after
-- the body.
elsif List_Containing (Freeze_Node (Par)) =
List_Containing (Parent (N))
and then Sloc (Freeze_Node (Par)) < Sloc (Parent (N))
then
Insert_Freeze_Node_For_Instance
(Parent (N), Freeze_Node (Enclosing));
else
Insert_After
(Freeze_Node (Par), Freeze_Node (Enclosing));
end if;
end if;
end;
else
Insert_Freeze_Node_For_Instance (N, F_Node);
end if;
else
Insert_Freeze_Node_For_Instance (N, F_Node);
end if;
end if;
Set_Is_Frozen (Act_Id);
Insert_Before (N, Act_Body);
Mark_Rewrite_Insertion (Act_Body);
end Install_Body;
-----------------------------
-- Install_Formal_Packages --
-----------------------------
procedure Install_Formal_Packages (Par : Entity_Id) is
E : Entity_Id;
Gen : Entity_Id;
Gen_E : Entity_Id := Empty;
begin
E := First_Entity (Par);
-- If we are installing an instance parent, locate the formal packages
-- of its generic parent.
if Is_Generic_Instance (Par) then
Gen := Generic_Parent (Package_Specification (Par));
Gen_E := First_Entity (Gen);
end if;
while Present (E) loop
if Ekind (E) = E_Package
and then Nkind (Parent (E)) = N_Package_Renaming_Declaration
then
-- If this is the renaming for the parent instance, done
if Renamed_Object (E) = Par then
exit;
-- The visibility of a formal of an enclosing generic is already
-- correct.
elsif Denotes_Formal_Package (E) then
null;
elsif Present (Associated_Formal_Package (E)) then
Check_Generic_Actuals (Renamed_Object (E), True);
Set_Is_Hidden (E, False);
-- Find formal package in generic unit that corresponds to
-- (instance of) formal package in instance.
while Present (Gen_E) and then Chars (Gen_E) /= Chars (E) loop
Next_Entity (Gen_E);
end loop;
if Present (Gen_E) then
Map_Formal_Package_Entities (Gen_E, E);
end if;
end if;
end if;
Next_Entity (E);
if Present (Gen_E) then
Next_Entity (Gen_E);
end if;
end loop;
end Install_Formal_Packages;
--------------------
-- Install_Parent --
--------------------
procedure Install_Parent (P : Entity_Id; In_Body : Boolean := False) is
Ancestors : constant Elist_Id := New_Elmt_List;
S : constant Entity_Id := Current_Scope;
Inst_Par : Entity_Id;
First_Par : Entity_Id;
Inst_Node : Node_Id;
Gen_Par : Entity_Id;
First_Gen : Entity_Id;
Elmt : Elmt_Id;
procedure Install_Noninstance_Specs (Par : Entity_Id);
-- Install the scopes of noninstance parent units ending with Par
procedure Install_Spec (Par : Entity_Id);
-- The child unit is within the declarative part of the parent, so the
-- declarations within the parent are immediately visible.
-------------------------------
-- Install_Noninstance_Specs --
-------------------------------
procedure Install_Noninstance_Specs (Par : Entity_Id) is
begin
if Present (Par)
and then Par /= Standard_Standard
and then not In_Open_Scopes (Par)
then
Install_Noninstance_Specs (Scope (Par));
Install_Spec (Par);
end if;
end Install_Noninstance_Specs;
------------------
-- Install_Spec --
------------------
procedure Install_Spec (Par : Entity_Id) is
Spec : constant Node_Id := Package_Specification (Par);
begin
-- If this parent of the child instance is a top-level unit,
-- then record the unit and its visibility for later resetting in
-- Remove_Parent. We exclude units that are generic instances, as we
-- only want to record this information for the ultimate top-level
-- noninstance parent (is that always correct???).
if Scope (Par) = Standard_Standard
and then not Is_Generic_Instance (Par)
then
Parent_Unit_Visible := Is_Immediately_Visible (Par);
Instance_Parent_Unit := Par;
end if;
-- Open the parent scope and make it and its declarations visible.
-- If this point is not within a body, then only the visible
-- declarations should be made visible, and installation of the
-- private declarations is deferred until the appropriate point
-- within analysis of the spec being instantiated (see the handling
-- of parent visibility in Analyze_Package_Specification). This is
-- relaxed in the case where the parent unit is Ada.Tags, to avoid
-- private view problems that occur when compiling instantiations of
-- a generic child of that package (Generic_Dispatching_Constructor).
-- If the instance freezes a tagged type, inlinings of operations
-- from Ada.Tags may need the full view of type Tag. If inlining took
-- proper account of establishing visibility of inlined subprograms'
-- parents then it should be possible to remove this
-- special check. ???
Push_Scope (Par);
Set_Is_Immediately_Visible (Par);
Install_Visible_Declarations (Par);
Set_Use (Visible_Declarations (Spec));
if In_Body or else Is_RTU (Par, Ada_Tags) then
Install_Private_Declarations (Par);
Set_Use (Private_Declarations (Spec));
end if;
end Install_Spec;
-- Start of processing for Install_Parent
begin
-- We need to install the parent instance to compile the instantiation
-- of the child, but the child instance must appear in the current
-- scope. Given that we cannot place the parent above the current scope
-- in the scope stack, we duplicate the current scope and unstack both
-- after the instantiation is complete.
-- If the parent is itself the instantiation of a child unit, we must
-- also stack the instantiation of its parent, and so on. Each such
-- ancestor is the prefix of the name in a prior instantiation.
-- If this is a nested instance, the parent unit itself resolves to
-- a renaming of the parent instance, whose declaration we need.
-- Finally, the parent may be a generic (not an instance) when the
-- child unit appears as a formal package.
Inst_Par := P;
if Present (Renamed_Entity (Inst_Par)) then
Inst_Par := Renamed_Entity (Inst_Par);
end if;
First_Par := Inst_Par;
Gen_Par := Generic_Parent (Package_Specification (Inst_Par));
First_Gen := Gen_Par;
while Present (Gen_Par)
and then Is_Child_Unit (Gen_Par)
loop
-- Load grandparent instance as well
Inst_Node := Get_Package_Instantiation_Node (Inst_Par);
if Nkind (Name (Inst_Node)) = N_Expanded_Name then
Inst_Par := Entity (Prefix (Name (Inst_Node)));
if Present (Renamed_Entity (Inst_Par)) then
Inst_Par := Renamed_Entity (Inst_Par);
end if;
Gen_Par := Generic_Parent (Package_Specification (Inst_Par));
if Present (Gen_Par) then
Prepend_Elmt (Inst_Par, Ancestors);
else
-- Parent is not the name of an instantiation
Install_Noninstance_Specs (Inst_Par);
exit;
end if;
else
-- Previous error
exit;
end if;
end loop;
if Present (First_Gen) then
Append_Elmt (First_Par, Ancestors);
else
Install_Noninstance_Specs (First_Par);
end if;
if not Is_Empty_Elmt_List (Ancestors) then
Elmt := First_Elmt (Ancestors);
while Present (Elmt) loop
Install_Spec (Node (Elmt));
Install_Formal_Packages (Node (Elmt));
Next_Elmt (Elmt);
end loop;
end if;
if not In_Body then
Push_Scope (S);
end if;
end Install_Parent;
-------------------------------
-- Install_Hidden_Primitives --
-------------------------------
procedure Install_Hidden_Primitives
(Prims_List : in out Elist_Id;
Gen_T : Entity_Id;
Act_T : Entity_Id)
is
Elmt : Elmt_Id;
List : Elist_Id := No_Elist;
Prim_G_Elmt : Elmt_Id;
Prim_A_Elmt : Elmt_Id;
Prim_G : Node_Id;
Prim_A : Node_Id;
begin
-- No action needed in case of serious errors because we cannot trust
-- in the order of primitives
if Serious_Errors_Detected > 0 then
return;
-- No action possible if we don't have available the list of primitive
-- operations
elsif No (Gen_T)
or else not Is_Record_Type (Gen_T)
or else not Is_Tagged_Type (Gen_T)
or else not Is_Record_Type (Act_T)
or else not Is_Tagged_Type (Act_T)
then
return;
-- There is no need to handle interface types since their primitives
-- cannot be hidden
elsif Is_Interface (Gen_T) then
return;
end if;
Prim_G_Elmt := First_Elmt (Primitive_Operations (Gen_T));
if not Is_Class_Wide_Type (Act_T) then
Prim_A_Elmt := First_Elmt (Primitive_Operations (Act_T));
else
Prim_A_Elmt := First_Elmt (Primitive_Operations (Root_Type (Act_T)));
end if;
loop
-- Skip predefined primitives in the generic formal
while Present (Prim_G_Elmt)
and then Is_Predefined_Dispatching_Operation (Node (Prim_G_Elmt))
loop
Next_Elmt (Prim_G_Elmt);
end loop;
-- Skip predefined primitives in the generic actual
while Present (Prim_A_Elmt)
and then Is_Predefined_Dispatching_Operation (Node (Prim_A_Elmt))
loop
Next_Elmt (Prim_A_Elmt);
end loop;
exit when No (Prim_G_Elmt) or else No (Prim_A_Elmt);
Prim_G := Node (Prim_G_Elmt);
Prim_A := Node (Prim_A_Elmt);
-- There is no need to handle interface primitives because their
-- primitives are not hidden
exit when Present (Interface_Alias (Prim_G));
-- Here we install one hidden primitive
if Chars (Prim_G) /= Chars (Prim_A)
and then Has_Suffix (Prim_A, 'P')
and then Remove_Suffix (Prim_A, 'P') = Chars (Prim_G)
then
Set_Chars (Prim_A, Chars (Prim_G));
Append_New_Elmt (Prim_A, To => List);
end if;
Next_Elmt (Prim_A_Elmt);
Next_Elmt (Prim_G_Elmt);
end loop;
-- Append the elements to the list of temporarily visible primitives
-- avoiding duplicates.
if Present (List) then
if No (Prims_List) then
Prims_List := New_Elmt_List;
end if;
Elmt := First_Elmt (List);
while Present (Elmt) loop
Append_Unique_Elmt (Node (Elmt), Prims_List);
Next_Elmt (Elmt);
end loop;
end if;
end Install_Hidden_Primitives;
-------------------------------
-- Restore_Hidden_Primitives --
-------------------------------
procedure Restore_Hidden_Primitives (Prims_List : in out Elist_Id) is
Prim_Elmt : Elmt_Id;
Prim : Node_Id;
begin
if Prims_List /= No_Elist then
Prim_Elmt := First_Elmt (Prims_List);
while Present (Prim_Elmt) loop
Prim := Node (Prim_Elmt);
Set_Chars (Prim, Add_Suffix (Prim, 'P'));
Next_Elmt (Prim_Elmt);
end loop;
Prims_List := No_Elist;
end if;
end Restore_Hidden_Primitives;
--------------------------------
-- Instantiate_Formal_Package --
--------------------------------
function Instantiate_Formal_Package
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return List_Id
is
Loc : constant Source_Ptr := Sloc (Actual);
Actual_Pack : Entity_Id;
Formal_Pack : Entity_Id;
Gen_Parent : Entity_Id;
Decls : List_Id;
Nod : Node_Id;
Parent_Spec : Node_Id;
procedure Find_Matching_Actual
(F : Node_Id;
Act : in out Entity_Id);
-- We need to associate each formal entity in the formal package with
-- the corresponding entity in the actual package. The actual package
-- has been analyzed and possibly expanded, and as a result there is
-- no one-to-one correspondence between the two lists (for example,
-- the actual may include subtypes, itypes, and inherited primitive
-- operations, interspersed among the renaming declarations for the
-- actuals) . We retrieve the corresponding actual by name because each
-- actual has the same name as the formal, and they do appear in the
-- same order.
function Get_Formal_Entity (N : Node_Id) return Entity_Id;
-- Retrieve entity of defining entity of generic formal parameter.
-- Only the declarations of formals need to be considered when
-- linking them to actuals, but the declarative list may include
-- internal entities generated during analysis, and those are ignored.
procedure Match_Formal_Entity
(Formal_Node : Node_Id;
Formal_Ent : Entity_Id;
Actual_Ent : Entity_Id);
-- Associates the formal entity with the actual. In the case where
-- Formal_Ent is a formal package, this procedure iterates through all
-- of its formals and enters associations between the actuals occurring
-- in the formal package's corresponding actual package (given by
-- Actual_Ent) and the formal package's formal parameters. This
-- procedure recurses if any of the parameters is itself a package.
function Is_Instance_Of
(Act_Spec : Entity_Id;
Gen_Anc : Entity_Id) return Boolean;
-- The actual can be an instantiation of a generic within another
-- instance, in which case there is no direct link from it to the
-- original generic ancestor. In that case, we recognize that the
-- ultimate ancestor is the same by examining names and scopes.
procedure Process_Nested_Formal (Formal : Entity_Id);
-- If the current formal is declared with a box, its own formals are
-- visible in the instance, as they were in the generic, and their
-- Hidden flag must be reset. If some of these formals are themselves
-- packages declared with a box, the processing must be recursive.
--------------------------
-- Find_Matching_Actual --
--------------------------
procedure Find_Matching_Actual
(F : Node_Id;
Act : in out Entity_Id)
is
Formal_Ent : Entity_Id;
begin
case Nkind (Original_Node (F)) is
when N_Formal_Object_Declaration |
N_Formal_Type_Declaration =>
Formal_Ent := Defining_Identifier (F);
while Chars (Act) /= Chars (Formal_Ent) loop
Next_Entity (Act);
end loop;
when N_Formal_Subprogram_Declaration |
N_Formal_Package_Declaration |
N_Package_Declaration |
N_Generic_Package_Declaration =>
Formal_Ent := Defining_Entity (F);
while Chars (Act) /= Chars (Formal_Ent) loop
Next_Entity (Act);
end loop;
when others =>
raise Program_Error;
end case;
end Find_Matching_Actual;
-------------------------
-- Match_Formal_Entity --
-------------------------
procedure Match_Formal_Entity
(Formal_Node : Node_Id;
Formal_Ent : Entity_Id;
Actual_Ent : Entity_Id)
is
Act_Pkg : Entity_Id;
begin
Set_Instance_Of (Formal_Ent, Actual_Ent);
if Ekind (Actual_Ent) = E_Package then
-- Record associations for each parameter
Act_Pkg := Actual_Ent;
declare
A_Ent : Entity_Id := First_Entity (Act_Pkg);
F_Ent : Entity_Id;
F_Node : Node_Id;
Gen_Decl : Node_Id;
Formals : List_Id;
Actual : Entity_Id;
begin
-- Retrieve the actual given in the formal package declaration
Actual := Entity (Name (Original_Node (Formal_Node)));
-- The actual in the formal package declaration may be a
-- renamed generic package, in which case we want to retrieve
-- the original generic in order to traverse its formal part.
if Present (Renamed_Entity (Actual)) then
Gen_Decl := Unit_Declaration_Node (Renamed_Entity (Actual));
else
Gen_Decl := Unit_Declaration_Node (Actual);
end if;
Formals := Generic_Formal_Declarations (Gen_Decl);
if Present (Formals) then
F_Node := First_Non_Pragma (Formals);
else
F_Node := Empty;
end if;
while Present (A_Ent)
and then Present (F_Node)
and then A_Ent /= First_Private_Entity (Act_Pkg)
loop
F_Ent := Get_Formal_Entity (F_Node);
if Present (F_Ent) then
-- This is a formal of the original package. Record
-- association and recurse.
Find_Matching_Actual (F_Node, A_Ent);
Match_Formal_Entity (F_Node, F_Ent, A_Ent);
Next_Entity (A_Ent);
end if;
Next_Non_Pragma (F_Node);
end loop;
end;
end if;
end Match_Formal_Entity;
-----------------------
-- Get_Formal_Entity --
-----------------------
function Get_Formal_Entity (N : Node_Id) return Entity_Id is
Kind : constant Node_Kind := Nkind (Original_Node (N));
begin
case Kind is
when N_Formal_Object_Declaration =>
return Defining_Identifier (N);
when N_Formal_Type_Declaration =>
return Defining_Identifier (N);
when N_Formal_Subprogram_Declaration =>
return Defining_Unit_Name (Specification (N));
when N_Formal_Package_Declaration =>
return Defining_Identifier (Original_Node (N));
when N_Generic_Package_Declaration =>
return Defining_Identifier (Original_Node (N));
-- All other declarations are introduced by semantic analysis and
-- have no match in the actual.
when others =>
return Empty;
end case;
end Get_Formal_Entity;
--------------------
-- Is_Instance_Of --
--------------------
function Is_Instance_Of
(Act_Spec : Entity_Id;
Gen_Anc : Entity_Id) return Boolean
is
Gen_Par : constant Entity_Id := Generic_Parent (Act_Spec);
begin
if No (Gen_Par) then
return False;
-- Simplest case: the generic parent of the actual is the formal
elsif Gen_Par = Gen_Anc then
return True;
elsif Chars (Gen_Par) /= Chars (Gen_Anc) then
return False;
-- The actual may be obtained through several instantiations. Its
-- scope must itself be an instance of a generic declared in the
-- same scope as the formal. Any other case is detected above.
elsif not Is_Generic_Instance (Scope (Gen_Par)) then
return False;
else
return Generic_Parent (Parent (Scope (Gen_Par))) = Scope (Gen_Anc);
end if;
end Is_Instance_Of;
---------------------------
-- Process_Nested_Formal --
---------------------------
procedure Process_Nested_Formal (Formal : Entity_Id) is
Ent : Entity_Id;
begin
if Present (Associated_Formal_Package (Formal))
and then Box_Present (Parent (Associated_Formal_Package (Formal)))
then
Ent := First_Entity (Formal);
while Present (Ent) loop
Set_Is_Hidden (Ent, False);
Set_Is_Visible_Formal (Ent);
Set_Is_Potentially_Use_Visible
(Ent, Is_Potentially_Use_Visible (Formal));
if Ekind (Ent) = E_Package then
exit when Renamed_Entity (Ent) = Renamed_Entity (Formal);
Process_Nested_Formal (Ent);
end if;
Next_Entity (Ent);
end loop;
end if;
end Process_Nested_Formal;
-- Start of processing for Instantiate_Formal_Package
begin
Analyze (Actual);
if not Is_Entity_Name (Actual)
or else Ekind (Entity (Actual)) /= E_Package
then
Error_Msg_N
("expect package instance to instantiate formal", Actual);
Abandon_Instantiation (Actual);
raise Program_Error;
else
Actual_Pack := Entity (Actual);
Set_Is_Instantiated (Actual_Pack);
-- The actual may be a renamed package, or an outer generic formal
-- package whose instantiation is converted into a renaming.
if Present (Renamed_Object (Actual_Pack)) then
Actual_Pack := Renamed_Object (Actual_Pack);
end if;
if Nkind (Analyzed_Formal) = N_Formal_Package_Declaration then
Gen_Parent := Get_Instance_Of (Entity (Name (Analyzed_Formal)));
Formal_Pack := Defining_Identifier (Analyzed_Formal);
else
Gen_Parent :=
Generic_Parent (Specification (Analyzed_Formal));
Formal_Pack :=
Defining_Unit_Name (Specification (Analyzed_Formal));
end if;
if Nkind (Parent (Actual_Pack)) = N_Defining_Program_Unit_Name then
Parent_Spec := Package_Specification (Actual_Pack);
else
Parent_Spec := Parent (Actual_Pack);
end if;
if Gen_Parent = Any_Id then
Error_Msg_N
("previous error in declaration of formal package", Actual);
Abandon_Instantiation (Actual);
elsif
Is_Instance_Of (Parent_Spec, Get_Instance_Of (Gen_Parent))
then
null;
else
Error_Msg_NE
("actual parameter must be instance of&", Actual, Gen_Parent);
Abandon_Instantiation (Actual);
end if;
Set_Instance_Of (Defining_Identifier (Formal), Actual_Pack);
Map_Formal_Package_Entities (Formal_Pack, Actual_Pack);
Nod :=
Make_Package_Renaming_Declaration (Loc,
Defining_Unit_Name => New_Copy (Defining_Identifier (Formal)),
Name => New_Occurrence_Of (Actual_Pack, Loc));
Set_Associated_Formal_Package (Defining_Unit_Name (Nod),
Defining_Identifier (Formal));
Decls := New_List (Nod);
-- If the formal F has a box, then the generic declarations are
-- visible in the generic G. In an instance of G, the corresponding
-- entities in the actual for F (which are the actuals for the
-- instantiation of the generic that F denotes) must also be made
-- visible for analysis of the current instance. On exit from the
-- current instance, those entities are made private again. If the
-- actual is currently in use, these entities are also use-visible.
-- The loop through the actual entities also steps through the formal
-- entities and enters associations from formals to actuals into the
-- renaming map. This is necessary to properly handle checking of
-- actual parameter associations for later formals that depend on
-- actuals declared in the formal package.
-- In Ada 2005, partial parameterization requires that we make
-- visible the actuals corresponding to formals that were defaulted
-- in the formal package. There formals are identified because they
-- remain formal generics within the formal package, rather than
-- being renamings of the actuals supplied.
declare
Gen_Decl : constant Node_Id :=
Unit_Declaration_Node (Gen_Parent);
Formals : constant List_Id :=
Generic_Formal_Declarations (Gen_Decl);
Actual_Ent : Entity_Id;
Actual_Of_Formal : Node_Id;
Formal_Node : Node_Id;
Formal_Ent : Entity_Id;
begin
if Present (Formals) then
Formal_Node := First_Non_Pragma (Formals);
else
Formal_Node := Empty;
end if;
Actual_Ent := First_Entity (Actual_Pack);
Actual_Of_Formal :=
First (Visible_Declarations (Specification (Analyzed_Formal)));
while Present (Actual_Ent)
and then Actual_Ent /= First_Private_Entity (Actual_Pack)
loop
if Present (Formal_Node) then
Formal_Ent := Get_Formal_Entity (Formal_Node);
if Present (Formal_Ent) then
Find_Matching_Actual (Formal_Node, Actual_Ent);
Match_Formal_Entity
(Formal_Node, Formal_Ent, Actual_Ent);
-- We iterate at the same time over the actuals of the
-- local package created for the formal, to determine
-- which one of the formals of the original generic were
-- defaulted in the formal. The corresponding actual
-- entities are visible in the enclosing instance.
if Box_Present (Formal)
or else
(Present (Actual_Of_Formal)
and then
Is_Generic_Formal
(Get_Formal_Entity (Actual_Of_Formal)))
then
Set_Is_Hidden (Actual_Ent, False);
Set_Is_Visible_Formal (Actual_Ent);
Set_Is_Potentially_Use_Visible
(Actual_Ent, In_Use (Actual_Pack));
if Ekind (Actual_Ent) = E_Package then
Process_Nested_Formal (Actual_Ent);
end if;
else
Set_Is_Hidden (Actual_Ent);
Set_Is_Potentially_Use_Visible (Actual_Ent, False);
end if;
end if;
Next_Non_Pragma (Formal_Node);
Next (Actual_Of_Formal);
else
-- No further formals to match, but the generic part may
-- contain inherited operation that are not hidden in the
-- enclosing instance.
Next_Entity (Actual_Ent);
end if;
end loop;
-- Inherited subprograms generated by formal derived types are
-- also visible if the types are.
Actual_Ent := First_Entity (Actual_Pack);
while Present (Actual_Ent)
and then Actual_Ent /= First_Private_Entity (Actual_Pack)
loop
if Is_Overloadable (Actual_Ent)
and then
Nkind (Parent (Actual_Ent)) = N_Subtype_Declaration
and then
not Is_Hidden (Defining_Identifier (Parent (Actual_Ent)))
then
Set_Is_Hidden (Actual_Ent, False);
Set_Is_Potentially_Use_Visible
(Actual_Ent, In_Use (Actual_Pack));
end if;
Next_Entity (Actual_Ent);
end loop;
end;
-- If the formal is not declared with a box, reanalyze it as an
-- abbreviated instantiation, to verify the matching rules of 12.7.
-- The actual checks are performed after the generic associations
-- have been analyzed, to guarantee the same visibility for this
-- instantiation and for the actuals.
-- In Ada 2005, the generic associations for the formal can include
-- defaulted parameters. These are ignored during check. This
-- internal instantiation is removed from the tree after conformance
-- checking, because it contains formal declarations for those
-- defaulted parameters, and those should not reach the back-end.
if not Box_Present (Formal) then
declare
I_Pack : constant Entity_Id :=
Make_Temporary (Sloc (Actual), 'P');
begin
Set_Is_Internal (I_Pack);
Append_To (Decls,
Make_Package_Instantiation (Sloc (Actual),
Defining_Unit_Name => I_Pack,
Name =>
New_Occurrence_Of
(Get_Instance_Of (Gen_Parent), Sloc (Actual)),
Generic_Associations =>
Generic_Associations (Formal)));
end;
end if;
return Decls;
end if;
end Instantiate_Formal_Package;
-----------------------------------
-- Instantiate_Formal_Subprogram --
-----------------------------------
function Instantiate_Formal_Subprogram
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return Node_Id
is
Loc : Source_Ptr;
Formal_Sub : constant Entity_Id :=
Defining_Unit_Name (Specification (Formal));
Analyzed_S : constant Entity_Id :=
Defining_Unit_Name (Specification (Analyzed_Formal));
Decl_Node : Node_Id;
Nam : Node_Id;
New_Spec : Node_Id;
function From_Parent_Scope (Subp : Entity_Id) return Boolean;
-- If the generic is a child unit, the parent has been installed on the
-- scope stack, but a default subprogram cannot resolve to something
-- on the parent because that parent is not really part of the visible
-- context (it is there to resolve explicit local entities). If the
-- default has resolved in this way, we remove the entity from immediate
-- visibility and analyze the node again to emit an error message or
-- find another visible candidate.
procedure Valid_Actual_Subprogram (Act : Node_Id);
-- Perform legality check and raise exception on failure
-----------------------
-- From_Parent_Scope --
-----------------------
function From_Parent_Scope (Subp : Entity_Id) return Boolean is
Gen_Scope : Node_Id;
begin
Gen_Scope := Scope (Analyzed_S);
while Present (Gen_Scope) and then Is_Child_Unit (Gen_Scope) loop
if Scope (Subp) = Scope (Gen_Scope) then
return True;
end if;
Gen_Scope := Scope (Gen_Scope);
end loop;
return False;
end From_Parent_Scope;
-----------------------------
-- Valid_Actual_Subprogram --
-----------------------------
procedure Valid_Actual_Subprogram (Act : Node_Id) is
Act_E : Entity_Id;
begin
if Is_Entity_Name (Act) then
Act_E := Entity (Act);
elsif Nkind (Act) = N_Selected_Component
and then Is_Entity_Name (Selector_Name (Act))
then
Act_E := Entity (Selector_Name (Act));
else
Act_E := Empty;
end if;
if (Present (Act_E) and then Is_Overloadable (Act_E))
or else Nkind_In (Act, N_Attribute_Reference,
N_Indexed_Component,
N_Character_Literal,
N_Explicit_Dereference)
then
return;
end if;
Error_Msg_NE
("expect subprogram or entry name in instantiation of&",
Instantiation_Node, Formal_Sub);
Abandon_Instantiation (Instantiation_Node);
end Valid_Actual_Subprogram;
-- Start of processing for Instantiate_Formal_Subprogram
begin
New_Spec := New_Copy_Tree (Specification (Formal));
-- The tree copy has created the proper instantiation sloc for the
-- new specification. Use this location for all other constructed
-- declarations.
Loc := Sloc (Defining_Unit_Name (New_Spec));
-- Create new entity for the actual (New_Copy_Tree does not)
Set_Defining_Unit_Name
(New_Spec, Make_Defining_Identifier (Loc, Chars (Formal_Sub)));
-- Create new entities for the each of the formals in the
-- specification of the renaming declaration built for the actual.
if Present (Parameter_Specifications (New_Spec)) then
declare
F : Node_Id;
begin
F := First (Parameter_Specifications (New_Spec));
while Present (F) loop
Set_Defining_Identifier (F,
Make_Defining_Identifier (Sloc (F),
Chars => Chars (Defining_Identifier (F))));
Next (F);
end loop;
end;
end if;
-- Find entity of actual. If the actual is an attribute reference, it
-- cannot be resolved here (its formal is missing) but is handled
-- instead in Attribute_Renaming. If the actual is overloaded, it is
-- fully resolved subsequently, when the renaming declaration for the
-- formal is analyzed. If it is an explicit dereference, resolve the
-- prefix but not the actual itself, to prevent interpretation as call.
if Present (Actual) then
Loc := Sloc (Actual);
Set_Sloc (New_Spec, Loc);
if Nkind (Actual) = N_Operator_Symbol then
Find_Direct_Name (Actual);
elsif Nkind (Actual) = N_Explicit_Dereference then
Analyze (Prefix (Actual));
elsif Nkind (Actual) /= N_Attribute_Reference then
Analyze (Actual);
end if;
Valid_Actual_Subprogram (Actual);
Nam := Actual;
elsif Present (Default_Name (Formal)) then
if not Nkind_In (Default_Name (Formal), N_Attribute_Reference,
N_Selected_Component,
N_Indexed_Component,
N_Character_Literal)
and then Present (Entity (Default_Name (Formal)))
then
Nam := New_Occurrence_Of (Entity (Default_Name (Formal)), Loc);
else
Nam := New_Copy (Default_Name (Formal));
Set_Sloc (Nam, Loc);
end if;
elsif Box_Present (Formal) then
-- Actual is resolved at the point of instantiation. Create an
-- identifier or operator with the same name as the formal.
if Nkind (Formal_Sub) = N_Defining_Operator_Symbol then
Nam := Make_Operator_Symbol (Loc,
Chars => Chars (Formal_Sub),
Strval => No_String);
else
Nam := Make_Identifier (Loc, Chars (Formal_Sub));
end if;
elsif Nkind (Specification (Formal)) = N_Procedure_Specification
and then Null_Present (Specification (Formal))
then
-- Generate null body for procedure, for use in the instance
Decl_Node :=
Make_Subprogram_Body (Loc,
Specification => New_Spec,
Declarations => New_List,
Handled_Statement_Sequence =>
Make_Handled_Sequence_Of_Statements (Loc,
Statements => New_List (Make_Null_Statement (Loc))));
Set_Is_Intrinsic_Subprogram (Defining_Unit_Name (New_Spec));
return Decl_Node;
else
Error_Msg_Sloc := Sloc (Scope (Analyzed_S));
Error_Msg_NE
("missing actual&", Instantiation_Node, Formal_Sub);
Error_Msg_NE
("\in instantiation of & declared#",
Instantiation_Node, Scope (Analyzed_S));
Abandon_Instantiation (Instantiation_Node);
end if;
Decl_Node :=
Make_Subprogram_Renaming_Declaration (Loc,
Specification => New_Spec,
Name => Nam);
-- If we do not have an actual and the formal specified <> then set to
-- get proper default.
if No (Actual) and then Box_Present (Formal) then
Set_From_Default (Decl_Node);
end if;
-- Gather possible interpretations for the actual before analyzing the
-- instance. If overloaded, it will be resolved when analyzing the
-- renaming declaration.
if Box_Present (Formal)
and then No (Actual)
then
Analyze (Nam);
if Is_Child_Unit (Scope (Analyzed_S))
and then Present (Entity (Nam))
then
if not Is_Overloaded (Nam) then
if From_Parent_Scope (Entity (Nam)) then
Set_Is_Immediately_Visible (Entity (Nam), False);
Set_Entity (Nam, Empty);
Set_Etype (Nam, Empty);
Analyze (Nam);
Set_Is_Immediately_Visible (Entity (Nam));
end if;
else
declare
I : Interp_Index;
It : Interp;
begin
Get_First_Interp (Nam, I, It);
while Present (It.Nam) loop
if From_Parent_Scope (It.Nam) then
Remove_Interp (I);
end if;
Get_Next_Interp (I, It);
end loop;
end;
end if;
end if;
end if;
-- The generic instantiation freezes the actual. This can only be done
-- once the actual is resolved, in the analysis of the renaming
-- declaration. To make the formal subprogram entity available, we set
-- Corresponding_Formal_Spec to point to the formal subprogram entity.
-- This is also needed in Analyze_Subprogram_Renaming for the processing
-- of formal abstract subprograms.
Set_Corresponding_Formal_Spec (Decl_Node, Analyzed_S);
-- We cannot analyze the renaming declaration, and thus find the actual,
-- until all the actuals are assembled in the instance. For subsequent
-- checks of other actuals, indicate the node that will hold the
-- instance of this formal.
Set_Instance_Of (Analyzed_S, Nam);
if Nkind (Actual) = N_Selected_Component
and then Is_Task_Type (Etype (Prefix (Actual)))
and then not Is_Frozen (Etype (Prefix (Actual)))
then
-- The renaming declaration will create a body, which must appear
-- outside of the instantiation, We move the renaming declaration
-- out of the instance, and create an additional renaming inside,
-- to prevent freezing anomalies.
declare
Anon_Id : constant Entity_Id := Make_Temporary (Loc, 'E');
begin
Set_Defining_Unit_Name (New_Spec, Anon_Id);
Insert_Before (Instantiation_Node, Decl_Node);
Analyze (Decl_Node);
-- Now create renaming within the instance
Decl_Node :=
Make_Subprogram_Renaming_Declaration (Loc,
Specification => New_Copy_Tree (New_Spec),
Name => New_Occurrence_Of (Anon_Id, Loc));
Set_Defining_Unit_Name (Specification (Decl_Node),
Make_Defining_Identifier (Loc, Chars (Formal_Sub)));
end;
end if;
return Decl_Node;
end Instantiate_Formal_Subprogram;
------------------------
-- Instantiate_Object --
------------------------
function Instantiate_Object
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id) return List_Id
is
Gen_Obj : constant Entity_Id := Defining_Identifier (Formal);
A_Gen_Obj : constant Entity_Id :=
Defining_Identifier (Analyzed_Formal);
Acc_Def : Node_Id := Empty;
Act_Assoc : constant Node_Id := Parent (Actual);
Actual_Decl : Node_Id := Empty;
Decl_Node : Node_Id;
Def : Node_Id;
Ftyp : Entity_Id;
List : constant List_Id := New_List;
Loc : constant Source_Ptr := Sloc (Actual);
Orig_Ftyp : constant Entity_Id := Etype (A_Gen_Obj);
Subt_Decl : Node_Id := Empty;
Subt_Mark : Node_Id := Empty;
begin
if Present (Subtype_Mark (Formal)) then
Subt_Mark := Subtype_Mark (Formal);
else
Check_Access_Definition (Formal);
Acc_Def := Access_Definition (Formal);
end if;
-- Sloc for error message on missing actual
Error_Msg_Sloc := Sloc (Scope (A_Gen_Obj));
if Get_Instance_Of (Gen_Obj) /= Gen_Obj then
Error_Msg_N ("duplicate instantiation of generic parameter", Actual);
end if;
Set_Parent (List, Parent (Actual));
-- OUT present
if Out_Present (Formal) then
-- An IN OUT generic actual must be a name. The instantiation is a
-- renaming declaration. The actual is the name being renamed. We
-- use the actual directly, rather than a copy, because it is not
-- used further in the list of actuals, and because a copy or a use
-- of relocate_node is incorrect if the instance is nested within a
-- generic. In order to simplify ASIS searches, the Generic_Parent
-- field links the declaration to the generic association.
if No (Actual) then
Error_Msg_NE
("missing actual&",
Instantiation_Node, Gen_Obj);
Error_Msg_NE
("\in instantiation of & declared#",
Instantiation_Node, Scope (A_Gen_Obj));
Abandon_Instantiation (Instantiation_Node);
end if;
if Present (Subt_Mark) then
Decl_Node :=
Make_Object_Renaming_Declaration (Loc,
Defining_Identifier => New_Copy (Gen_Obj),
Subtype_Mark => New_Copy_Tree (Subt_Mark),
Name => Actual);
else pragma Assert (Present (Acc_Def));
Decl_Node :=
Make_Object_Renaming_Declaration (Loc,
Defining_Identifier => New_Copy (Gen_Obj),
Access_Definition => New_Copy_Tree (Acc_Def),
Name => Actual);
end if;
Set_Corresponding_Generic_Association (Decl_Node, Act_Assoc);
-- The analysis of the actual may produce Insert_Action nodes, so
-- the declaration must have a context in which to attach them.
Append (Decl_Node, List);
Analyze (Actual);
-- Return if the analysis of the actual reported some error
if Etype (Actual) = Any_Type then
return List;
end if;
-- This check is performed here because Analyze_Object_Renaming will
-- not check it when Comes_From_Source is False. Note though that the
-- check for the actual being the name of an object will be performed
-- in Analyze_Object_Renaming.
if Is_Object_Reference (Actual)
and then Is_Dependent_Component_Of_Mutable_Object (Actual)
then
Error_Msg_N
("illegal discriminant-dependent component for in out parameter",
Actual);
end if;
-- The actual has to be resolved in order to check that it is a
-- variable (due to cases such as F (1), where F returns access to
-- an array, and for overloaded prefixes).
Ftyp := Get_Instance_Of (Etype (A_Gen_Obj));
-- If the type of the formal is not itself a formal, and the current
-- unit is a child unit, the formal type must be declared in a
-- parent, and must be retrieved by visibility.
if Ftyp = Orig_Ftyp
and then Is_Generic_Unit (Scope (Ftyp))
and then Is_Child_Unit (Scope (A_Gen_Obj))
then
declare
Temp : constant Node_Id :=
New_Copy_Tree (Subtype_Mark (Analyzed_Formal));
begin
Set_Entity (Temp, Empty);
Find_Type (Temp);
Ftyp := Entity (Temp);
end;
end if;
if Is_Private_Type (Ftyp)
and then not Is_Private_Type (Etype (Actual))
and then (Base_Type (Full_View (Ftyp)) = Base_Type (Etype (Actual))
or else Base_Type (Etype (Actual)) = Ftyp)
then
-- If the actual has the type of the full view of the formal, or
-- else a non-private subtype of the formal, then the visibility
-- of the formal type has changed. Add to the actuals a subtype
-- declaration that will force the exchange of views in the body
-- of the instance as well.
Subt_Decl :=
Make_Subtype_Declaration (Loc,
Defining_Identifier => Make_Temporary (Loc, 'P'),
Subtype_Indication => New_Occurrence_Of (Ftyp, Loc));
Prepend (Subt_Decl, List);
Prepend_Elmt (Full_View (Ftyp), Exchanged_Views);
Exchange_Declarations (Ftyp);
end if;
Resolve (Actual, Ftyp);
if not Denotes_Variable (Actual) then
Error_Msg_NE
("actual for& must be a variable", Actual, Gen_Obj);
elsif Base_Type (Ftyp) /= Base_Type (Etype (Actual)) then
-- Ada 2005 (AI-423): For a generic formal object of mode in out,
-- the type of the actual shall resolve to a specific anonymous
-- access type.
if Ada_Version < Ada_2005
or else
Ekind (Base_Type (Ftyp)) /=
E_Anonymous_Access_Type
or else
Ekind (Base_Type (Etype (Actual))) /=
E_Anonymous_Access_Type
then
Error_Msg_NE ("type of actual does not match type of&",
Actual, Gen_Obj);
end if;
end if;
Note_Possible_Modification (Actual, Sure => True);
-- Check for instantiation of atomic/volatile actual for
-- non-atomic/volatile formal (RM C.6 (12)).
if Is_Atomic_Object (Actual)
and then not Is_Atomic (Orig_Ftyp)
then
Error_Msg_N
("cannot instantiate non-atomic formal object " &
"with atomic actual", Actual);
elsif Is_Volatile_Object (Actual)
and then not Is_Volatile (Orig_Ftyp)
then
Error_Msg_N
("cannot instantiate non-volatile formal object " &
"with volatile actual", Actual);
end if;
-- Formal in-parameter
else
-- The instantiation of a generic formal in-parameter is constant
-- declaration. The actual is the expression for that declaration.
if Present (Actual) then
if Present (Subt_Mark) then
Def := Subt_Mark;
else pragma Assert (Present (Acc_Def));
Def := Acc_Def;
end if;
Decl_Node :=
Make_Object_Declaration (Loc,
Defining_Identifier => New_Copy (Gen_Obj),
Constant_Present => True,
Null_Exclusion_Present => Null_Exclusion_Present (Formal),
Object_Definition => New_Copy_Tree (Def),
Expression => Actual);
Set_Corresponding_Generic_Association (Decl_Node, Act_Assoc);
-- A generic formal object of a tagged type is defined to be
-- aliased so the new constant must also be treated as aliased.
if Is_Tagged_Type (Etype (A_Gen_Obj)) then
Set_Aliased_Present (Decl_Node);
end if;
Append (Decl_Node, List);
-- No need to repeat (pre-)analysis of some expression nodes
-- already handled in Preanalyze_Actuals.
if Nkind (Actual) /= N_Allocator then
Analyze (Actual);
-- Return if the analysis of the actual reported some error
if Etype (Actual) = Any_Type then
return List;
end if;
end if;
declare
Formal_Type : constant Entity_Id := Etype (A_Gen_Obj);
Typ : Entity_Id;
begin
Typ := Get_Instance_Of (Formal_Type);
Freeze_Before (Instantiation_Node, Typ);
-- If the actual is an aggregate, perform name resolution on
-- its components (the analysis of an aggregate does not do it)
-- to capture local names that may be hidden if the generic is
-- a child unit.
if Nkind (Actual) = N_Aggregate then
Preanalyze_And_Resolve (Actual, Typ);
end if;
if Is_Limited_Type (Typ)
and then not OK_For_Limited_Init (Typ, Actual)
then
Error_Msg_N
("initialization not allowed for limited types", Actual);
Explain_Limited_Type (Typ, Actual);
end if;
end;
elsif Present (Default_Expression (Formal)) then
-- Use default to construct declaration
if Present (Subt_Mark) then
Def := Subt_Mark;
else pragma Assert (Present (Acc_Def));
Def := Acc_Def;
end if;
Decl_Node :=
Make_Object_Declaration (Sloc (Formal),
Defining_Identifier => New_Copy (Gen_Obj),
Constant_Present => True,
Null_Exclusion_Present => Null_Exclusion_Present (Formal),
Object_Definition => New_Copy (Def),
Expression => New_Copy_Tree
(Default_Expression (Formal)));
Append (Decl_Node, List);
Set_Analyzed (Expression (Decl_Node), False);
else
Error_Msg_NE
("missing actual&",
Instantiation_Node, Gen_Obj);
Error_Msg_NE ("\in instantiation of & declared#",
Instantiation_Node, Scope (A_Gen_Obj));
if Is_Scalar_Type (Etype (A_Gen_Obj)) then
-- Create dummy constant declaration so that instance can be
-- analyzed, to minimize cascaded visibility errors.
if Present (Subt_Mark) then
Def := Subt_Mark;
else pragma Assert (Present (Acc_Def));
Def := Acc_Def;
end if;
Decl_Node :=
Make_Object_Declaration (Loc,
Defining_Identifier => New_Copy (Gen_Obj),
Constant_Present => True,
Null_Exclusion_Present => Null_Exclusion_Present (Formal),
Object_Definition => New_Copy (Def),
Expression =>
Make_Attribute_Reference (Sloc (Gen_Obj),
Attribute_Name => Name_First,
Prefix => New_Copy (Def)));
Append (Decl_Node, List);
else
Abandon_Instantiation (Instantiation_Node);
end if;
end if;
end if;
if Nkind (Actual) in N_Has_Entity then
Actual_Decl := Parent (Entity (Actual));
end if;
-- Ada 2005 (AI-423): For a formal object declaration with a null
-- exclusion or an access definition that has a null exclusion: If the
-- actual matching the formal object declaration denotes a generic
-- formal object of another generic unit G, and the instantiation
-- containing the actual 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.
-- Otherwise, the subtype of the actual matching the formal object
-- declaration shall exclude null.
if Ada_Version >= Ada_2005
and then Present (Actual_Decl)
and then
Nkind_In (Actual_Decl, N_Formal_Object_Declaration,
N_Object_Declaration)
and then Nkind (Analyzed_Formal) = N_Formal_Object_Declaration
and then not Has_Null_Exclusion (Actual_Decl)
and then Has_Null_Exclusion (Analyzed_Formal)
then
Error_Msg_Sloc := Sloc (Analyzed_Formal);
Error_Msg_N
("actual must exclude null to match generic formal#", Actual);
end if;
-- An effectively volatile object cannot be used as an actual in
-- a generic instance. The following check is only relevant when
-- SPARK_Mode is on as it is not a standard Ada legality rule.
if SPARK_Mode = On
and then Present (Actual)
and then Is_Effectively_Volatile_Object (Actual)
then
Error_Msg_N
("volatile object cannot act as actual in generic instantiation "
& "(SPARK RM 7.1.3(8))", Actual);
end if;
return List;
end Instantiate_Object;
------------------------------
-- Instantiate_Package_Body --
------------------------------
procedure Instantiate_Package_Body
(Body_Info : Pending_Body_Info;
Inlined_Body : Boolean := False;
Body_Optional : Boolean := False)
is
Act_Decl : constant Node_Id := Body_Info.Act_Decl;
Inst_Node : constant Node_Id := Body_Info.Inst_Node;
Loc : constant Source_Ptr := Sloc (Inst_Node);
Gen_Id : constant Node_Id := Name (Inst_Node);
Gen_Unit : constant Entity_Id := Get_Generic_Entity (Inst_Node);
Gen_Decl : constant Node_Id := Unit_Declaration_Node (Gen_Unit);
Act_Spec : constant Node_Id := Specification (Act_Decl);
Act_Decl_Id : constant Entity_Id := Defining_Entity (Act_Spec);
Act_Body_Name : Node_Id;
Gen_Body : Node_Id;
Gen_Body_Id : Node_Id;
Act_Body : Node_Id;
Act_Body_Id : Entity_Id;
Parent_Installed : Boolean := False;
Save_Style_Check : constant Boolean := Style_Check;
Par_Ent : Entity_Id := Empty;
Par_Vis : Boolean := False;
Vis_Prims_List : Elist_Id := No_Elist;
-- List of primitives made temporarily visible in the instantiation
-- to match the visibility of the formal type
procedure Check_Initialized_Types;
-- In a generic package body, an entity of a generic private type may
-- appear uninitialized. This is suspicious, unless the actual is a
-- fully initialized type.
-----------------------------
-- Check_Initialized_Types --
-----------------------------
procedure Check_Initialized_Types is
Decl : Node_Id;
Formal : Entity_Id;
Actual : Entity_Id;
Uninit_Var : Entity_Id;
begin
Decl := First (Generic_Formal_Declarations (Gen_Decl));
while Present (Decl) loop
Uninit_Var := Empty;
if Nkind (Decl) = N_Private_Extension_Declaration then
Uninit_Var := Uninitialized_Variable (Decl);
elsif Nkind (Decl) = N_Formal_Type_Declaration
and then Nkind (Formal_Type_Definition (Decl)) =
N_Formal_Private_Type_Definition
then
Uninit_Var :=
Uninitialized_Variable (Formal_Type_Definition (Decl));
end if;
if Present (Uninit_Var) then
Formal := Defining_Identifier (Decl);
Actual := First_Entity (Act_Decl_Id);
-- For each formal there is a subtype declaration that renames
-- the actual and has the same name as the formal. Locate the
-- formal for warning message about uninitialized variables
-- in the generic, for which the actual type should be a fully
-- initialized type.
while Present (Actual) loop
exit when Ekind (Actual) = E_Package
and then Present (Renamed_Object (Actual));
if Chars (Actual) = Chars (Formal)
and then not Is_Scalar_Type (Actual)
and then not Is_Fully_Initialized_Type (Actual)
and then Warn_On_No_Value_Assigned
then
Error_Msg_Node_2 := Formal;
Error_Msg_NE
("generic unit has uninitialized variable& of "
& "formal private type &?v?", Actual, Uninit_Var);
Error_Msg_NE
("actual type for& should be fully initialized type?v?",
Actual, Formal);
exit;
end if;
Next_Entity (Actual);
end loop;
end if;
Next (Decl);
end loop;
end Check_Initialized_Types;
-- Start of processing for Instantiate_Package_Body
begin
Gen_Body_Id := Corresponding_Body (Gen_Decl);
-- The instance body may already have been processed, as the parent of
-- another instance that is inlined (Load_Parent_Of_Generic).
if Present (Corresponding_Body (Instance_Spec (Inst_Node))) then
return;
end if;
Expander_Mode_Save_And_Set (Body_Info.Expander_Status);
-- Re-establish the state of information on which checks are suppressed.
-- This information was set in Body_Info at the point of instantiation,
-- and now we restore it so that the instance is compiled using the
-- check status at the instantiation (RM 11.5 (7.2/2), AI95-00224-01).
Local_Suppress_Stack_Top := Body_Info.Local_Suppress_Stack_Top;
Scope_Suppress := Body_Info.Scope_Suppress;
Opt.Ada_Version := Body_Info.Version;
Opt.Ada_Version_Pragma := Body_Info.Version_Pragma;
Restore_Warnings (Body_Info.Warnings);
Opt.SPARK_Mode := Body_Info.SPARK_Mode;
Opt.SPARK_Mode_Pragma := Body_Info.SPARK_Mode_Pragma;
if No (Gen_Body_Id) then
-- Do not look for parent of generic body if none is required.
-- This may happen when the routine is called as part of the
-- Pending_Instantiations processing, when nested instances
-- may precede the one generated from the main unit.
if not Unit_Requires_Body (Defining_Entity (Gen_Decl))
and then Body_Optional
then
return;
else
Load_Parent_Of_Generic
(Inst_Node, Specification (Gen_Decl), Body_Optional);
Gen_Body_Id := Corresponding_Body (Gen_Decl);
end if;
end if;
-- Establish global variable for sloc adjustment and for error recovery
Instantiation_Node := Inst_Node;
if Present (Gen_Body_Id) then
Save_Env (Gen_Unit, Act_Decl_Id);
Style_Check := False;
Current_Sem_Unit := Body_Info.Current_Sem_Unit;
Gen_Body := Unit_Declaration_Node (Gen_Body_Id);
Create_Instantiation_Source
(Inst_Node, Gen_Body_Id, False, S_Adjustment);
Act_Body :=
Copy_Generic_Node
(Original_Node (Gen_Body), Empty, Instantiating => True);
-- Build new name (possibly qualified) for body declaration
Act_Body_Id := New_Copy (Act_Decl_Id);
-- Some attributes of spec entity are not inherited by body entity
Set_Handler_Records (Act_Body_Id, No_List);
if Nkind (Defining_Unit_Name (Act_Spec)) =
N_Defining_Program_Unit_Name
then
Act_Body_Name :=
Make_Defining_Program_Unit_Name (Loc,
Name => New_Copy_Tree (Name (Defining_Unit_Name (Act_Spec))),
Defining_Identifier => Act_Body_Id);
else
Act_Body_Name := Act_Body_Id;
end if;
Set_Defining_Unit_Name (Act_Body, Act_Body_Name);
Set_Corresponding_Spec (Act_Body, Act_Decl_Id);
Check_Generic_Actuals (Act_Decl_Id, False);
Check_Initialized_Types;
-- Install primitives hidden at the point of the instantiation but
-- visible when processing the generic formals
declare
E : Entity_Id;
begin
E := First_Entity (Act_Decl_Id);
while Present (E) loop
if Is_Type (E)
and then Is_Generic_Actual_Type (E)
and then Is_Tagged_Type (E)
then
Install_Hidden_Primitives
(Prims_List => Vis_Prims_List,
Gen_T => Generic_Parent_Type (Parent (E)),
Act_T => E);
end if;
Next_Entity (E);
end loop;
end;
-- If it is a child unit, make the parent instance (which is an
-- instance of the parent of the generic) visible. The parent
-- instance is the prefix of the name of the generic unit.
if Ekind (Scope (Gen_Unit)) = E_Generic_Package
and then Nkind (Gen_Id) = N_Expanded_Name
then
Par_Ent := Entity (Prefix (Gen_Id));
Par_Vis := Is_Immediately_Visible (Par_Ent);
Install_Parent (Par_Ent, In_Body => True);
Parent_Installed := True;
elsif Is_Child_Unit (Gen_Unit) then
Par_Ent := Scope (Gen_Unit);
Par_Vis := Is_Immediately_Visible (Par_Ent);
Install_Parent (Par_Ent, In_Body => True);
Parent_Installed := True;
end if;
-- If the instantiation is a library unit, and this is the main unit,
-- then build the resulting compilation unit nodes for the instance.
-- If this is a compilation unit but it is not the main unit, then it
-- is the body of a unit in the context, that is being compiled
-- because it is encloses some inlined unit or another generic unit
-- being instantiated. In that case, this body is not part of the
-- current compilation, and is not attached to the tree, but its
-- parent must be set for analysis.
if Nkind (Parent (Inst_Node)) = N_Compilation_Unit then
-- Replace instance node with body of instance, and create new
-- node for corresponding instance declaration.
Build_Instance_Compilation_Unit_Nodes
(Inst_Node, Act_Body, Act_Decl);
Analyze (Inst_Node);
if Parent (Inst_Node) = Cunit (Main_Unit) then
-- If the instance is a child unit itself, then set the scope
-- of the expanded body to be the parent of the instantiation
-- (ensuring that the fully qualified name will be generated
-- for the elaboration subprogram).
if Nkind (Defining_Unit_Name (Act_Spec)) =
N_Defining_Program_Unit_Name
then
Set_Scope
(Defining_Entity (Inst_Node), Scope (Act_Decl_Id));
end if;
end if;
-- Case where instantiation is not a library unit
else
-- If this is an early instantiation, i.e. appears textually
-- before the corresponding body and must be elaborated first,
-- indicate that the body instance is to be delayed.
Install_Body (Act_Body, Inst_Node, Gen_Body, Gen_Decl);
-- Now analyze the body. We turn off all checks if this is an
-- internal unit, since there is no reason to have checks on for
-- any predefined run-time library code. All such code is designed
-- to be compiled with checks off.
-- Note that we do NOT apply this criterion to children of GNAT
-- The latter units must suppress checks explicitly if needed.
if Is_Predefined_File_Name
(Unit_File_Name (Get_Source_Unit (Gen_Decl)))
then
Analyze (Act_Body, Suppress => All_Checks);
else
Analyze (Act_Body);
end if;
end if;
Inherit_Context (Gen_Body, Inst_Node);
-- Remove the parent instances if they have been placed on the scope
-- stack to compile the body.
if Parent_Installed then
Remove_Parent (In_Body => True);
-- Restore the previous visibility of the parent
Set_Is_Immediately_Visible (Par_Ent, Par_Vis);
end if;
Restore_Hidden_Primitives (Vis_Prims_List);
Restore_Private_Views (Act_Decl_Id);
-- Remove the current unit from visibility if this is an instance
-- that is not elaborated on the fly for inlining purposes.
if not Inlined_Body then
Set_Is_Immediately_Visible (Act_Decl_Id, False);
end if;
Restore_Env;
Style_Check := Save_Style_Check;
-- If we have no body, and the unit requires a body, then complain. This
-- complaint is suppressed if we have detected other errors (since a
-- common reason for missing the body is that it had errors).
-- In CodePeer mode, a warning has been emitted already, no need for
-- further messages.
elsif Unit_Requires_Body (Gen_Unit)
and then not Body_Optional
then
if CodePeer_Mode then
null;
elsif Serious_Errors_Detected = 0 then
Error_Msg_NE
("cannot find body of generic package &", Inst_Node, Gen_Unit);
-- Don't attempt to perform any cleanup actions if some other error
-- was already detected, since this can cause blowups.
else
return;
end if;
-- Case of package that does not need a body
else
-- If the instantiation of the declaration is a library unit, rewrite
-- the original package instantiation as a package declaration in the
-- compilation unit node.
if Nkind (Parent (Inst_Node)) = N_Compilation_Unit then
Set_Parent_Spec (Act_Decl, Parent_Spec (Inst_Node));
Rewrite (Inst_Node, Act_Decl);
-- Generate elaboration entity, in case spec has elaboration code.
-- This cannot be done when the instance is analyzed, because it
-- is not known yet whether the body exists.
Set_Elaboration_Entity_Required (Act_Decl_Id, False);
Build_Elaboration_Entity (Parent (Inst_Node), Act_Decl_Id);
-- If the instantiation is not a library unit, then append the
-- declaration to the list of implicitly generated entities, unless
-- it is already a list member which means that it was already
-- processed
elsif not Is_List_Member (Act_Decl) then
Mark_Rewrite_Insertion (Act_Decl);
Insert_Before (Inst_Node, Act_Decl);
end if;
end if;
Expander_Mode_Restore;
end Instantiate_Package_Body;
---------------------------------
-- Instantiate_Subprogram_Body --
---------------------------------
procedure Instantiate_Subprogram_Body
(Body_Info : Pending_Body_Info;
Body_Optional : Boolean := False)
is
Act_Decl : constant Node_Id := Body_Info.Act_Decl;
Inst_Node : constant Node_Id := Body_Info.Inst_Node;
Loc : constant Source_Ptr := Sloc (Inst_Node);
Gen_Id : constant Node_Id := Name (Inst_Node);
Gen_Unit : constant Entity_Id := Get_Generic_Entity (Inst_Node);
Gen_Decl : constant Node_Id := Unit_Declaration_Node (Gen_Unit);
Anon_Id : constant Entity_Id :=
Defining_Unit_Name (Specification (Act_Decl));
Pack_Id : constant Entity_Id :=
Defining_Unit_Name (Parent (Act_Decl));
Decls : List_Id;
Gen_Body : Node_Id;
Gen_Body_Id : Node_Id;
Act_Body : Node_Id;
Pack_Body : Node_Id;
Prev_Formal : Entity_Id;
Ret_Expr : Node_Id;
Unit_Renaming : Node_Id;
Parent_Installed : Boolean := False;
Saved_Style_Check : constant Boolean := Style_Check;
Saved_Warnings : constant Warning_Record := Save_Warnings;
Par_Ent : Entity_Id := Empty;
Par_Vis : Boolean := False;
begin
Gen_Body_Id := Corresponding_Body (Gen_Decl);
-- Subprogram body may have been created already because of an inline
-- pragma, or because of multiple elaborations of the enclosing package
-- when several instances of the subprogram appear in the main unit.
if Present (Corresponding_Body (Act_Decl)) then
return;
end if;
Expander_Mode_Save_And_Set (Body_Info.Expander_Status);
-- Re-establish the state of information on which checks are suppressed.
-- This information was set in Body_Info at the point of instantiation,
-- and now we restore it so that the instance is compiled using the
-- check status at the instantiation (RM 11.5 (7.2/2), AI95-00224-01).
Local_Suppress_Stack_Top := Body_Info.Local_Suppress_Stack_Top;
Scope_Suppress := Body_Info.Scope_Suppress;
Opt.Ada_Version := Body_Info.Version;
Opt.Ada_Version_Pragma := Body_Info.Version_Pragma;
Restore_Warnings (Body_Info.Warnings);
Opt.SPARK_Mode := Body_Info.SPARK_Mode;
Opt.SPARK_Mode_Pragma := Body_Info.SPARK_Mode_Pragma;
if No (Gen_Body_Id) then
-- For imported generic subprogram, no body to compile, complete
-- the spec entity appropriately.
if Is_Imported (Gen_Unit) then
Set_Is_Imported (Anon_Id);
Set_First_Rep_Item (Anon_Id, First_Rep_Item (Gen_Unit));
Set_Interface_Name (Anon_Id, Interface_Name (Gen_Unit));
Set_Convention (Anon_Id, Convention (Gen_Unit));
Set_Has_Completion (Anon_Id);
return;
-- For other cases, compile the body
else
Load_Parent_Of_Generic
(Inst_Node, Specification (Gen_Decl), Body_Optional);
Gen_Body_Id := Corresponding_Body (Gen_Decl);
end if;
end if;
Instantiation_Node := Inst_Node;
if Present (Gen_Body_Id) then
Gen_Body := Unit_Declaration_Node (Gen_Body_Id);
if Nkind (Gen_Body) = N_Subprogram_Body_Stub then
-- Either body is not present, or context is non-expanding, as
-- when compiling a subunit. Mark the instance as completed, and
-- diagnose a missing body when needed.
if Expander_Active
and then Operating_Mode = Generate_Code
then
Error_Msg_N
("missing proper body for instantiation", Gen_Body);
end if;
Set_Has_Completion (Anon_Id);
return;
end if;
Save_Env (Gen_Unit, Anon_Id);
Style_Check := False;
Current_Sem_Unit := Body_Info.Current_Sem_Unit;
Create_Instantiation_Source
(Inst_Node,
Gen_Body_Id,
False,
S_Adjustment);
Act_Body :=
Copy_Generic_Node
(Original_Node (Gen_Body), Empty, Instantiating => True);
-- Create proper defining name for the body, to correspond to
-- the one in the spec.
Set_Defining_Unit_Name (Specification (Act_Body),
Make_Defining_Identifier
(Sloc (Defining_Entity (Inst_Node)), Chars (Anon_Id)));
Set_Corresponding_Spec (Act_Body, Anon_Id);
Set_Has_Completion (Anon_Id);
Check_Generic_Actuals (Pack_Id, False);
-- Generate a reference to link the visible subprogram instance to
-- the generic body, which for navigation purposes is the only
-- available source for the instance.
Generate_Reference
(Related_Instance (Pack_Id),
Gen_Body_Id, 'b', Set_Ref => False, Force => True);
-- If it is a child unit, make the parent instance (which is an
-- instance of the parent of the generic) visible. The parent
-- instance is the prefix of the name of the generic unit.
if Ekind (Scope (Gen_Unit)) = E_Generic_Package
and then Nkind (Gen_Id) = N_Expanded_Name
then
Par_Ent := Entity (Prefix (Gen_Id));
Par_Vis := Is_Immediately_Visible (Par_Ent);
Install_Parent (Par_Ent, In_Body => True);
Parent_Installed := True;
elsif Is_Child_Unit (Gen_Unit) then
Par_Ent := Scope (Gen_Unit);
Par_Vis := Is_Immediately_Visible (Par_Ent);
Install_Parent (Par_Ent, In_Body => True);
Parent_Installed := True;
end if;
-- Inside its body, a reference to the generic unit is a reference
-- to the instance. The corresponding renaming is the first
-- declaration in the body.
Unit_Renaming :=
Make_Subprogram_Renaming_Declaration (Loc,
Specification =>
Copy_Generic_Node (
Specification (Original_Node (Gen_Body)),
Empty,
Instantiating => True),
Name => New_Occurrence_Of (Anon_Id, Loc));
-- If there is a formal subprogram with the same name as the unit
-- itself, do not add this renaming declaration. This is a temporary
-- fix for one ACVC test. ???
Prev_Formal := First_Entity (Pack_Id);
while Present (Prev_Formal) loop
if Chars (Prev_Formal) = Chars (Gen_Unit)
and then Is_Overloadable (Prev_Formal)
then
exit;
end if;
Next_Entity (Prev_Formal);
end loop;
if Present (Prev_Formal) then
Decls := New_List (Act_Body);
else
Decls := New_List (Unit_Renaming, Act_Body);
end if;
-- The subprogram body is placed in the body of a dummy package body,
-- whose spec contains the subprogram declaration as well as the
-- renaming declarations for the generic parameters.
Pack_Body := Make_Package_Body (Loc,
Defining_Unit_Name => New_Copy (Pack_Id),
Declarations => Decls);
Set_Corresponding_Spec (Pack_Body, Pack_Id);
-- If the instantiation is a library unit, then build resulting
-- compilation unit nodes for the instance. The declaration of
-- the enclosing package is the grandparent of the subprogram
-- declaration. First replace the instantiation node as the unit
-- of the corresponding compilation.
if Nkind (Parent (Inst_Node)) = N_Compilation_Unit then
if Parent (Inst_Node) = Cunit (Main_Unit) then
Set_Unit (Parent (Inst_Node), Inst_Node);
Build_Instance_Compilation_Unit_Nodes
(Inst_Node, Pack_Body, Parent (Parent (Act_Decl)));
Analyze (Inst_Node);
else
Set_Parent (Pack_Body, Parent (Inst_Node));
Analyze (Pack_Body);
end if;
else
Insert_Before (Inst_Node, Pack_Body);
Mark_Rewrite_Insertion (Pack_Body);
Analyze (Pack_Body);
if Expander_Active then
Freeze_Subprogram_Body (Inst_Node, Gen_Body, Pack_Id);
end if;
end if;
Inherit_Context (Gen_Body, Inst_Node);
Restore_Private_Views (Pack_Id, False);
if Parent_Installed then
Remove_Parent (In_Body => True);
-- Restore the previous visibility of the parent
Set_Is_Immediately_Visible (Par_Ent, Par_Vis);
end if;
Restore_Env;
Style_Check := Saved_Style_Check;
Restore_Warnings (Saved_Warnings);
-- Body not found. Error was emitted already. If there were no previous
-- errors, this may be an instance whose scope is a premature instance.
-- In that case we must insure that the (legal) program does raise
-- program error if executed. We generate a subprogram body for this
-- purpose. See DEC ac30vso.
-- Should not reference proprietary DEC tests in comments ???
elsif Serious_Errors_Detected = 0
and then Nkind (Parent (Inst_Node)) /= N_Compilation_Unit
then
if Body_Optional then
return;
elsif Ekind (Anon_Id) = E_Procedure then
Act_Body :=
Make_Subprogram_Body (Loc,
Specification =>
Make_Procedure_Specification (Loc,
Defining_Unit_Name =>
Make_Defining_Identifier (Loc, Chars (Anon_Id)),
Parameter_Specifications =>
New_Copy_List
(Parameter_Specifications (Parent (Anon_Id)))),
Declarations => Empty_List,
Handled_Statement_Sequence =>
Make_Handled_Sequence_Of_Statements (Loc,
Statements =>
New_List (
Make_Raise_Program_Error (Loc,
Reason =>
PE_Access_Before_Elaboration))));
else
Ret_Expr :=
Make_Raise_Program_Error (Loc,
Reason => PE_Access_Before_Elaboration);
Set_Etype (Ret_Expr, (Etype (Anon_Id)));
Set_Analyzed (Ret_Expr);
Act_Body :=
Make_Subprogram_Body (Loc,
Specification =>
Make_Function_Specification (Loc,
Defining_Unit_Name =>
Make_Defining_Identifier (Loc, Chars (Anon_Id)),
Parameter_Specifications =>
New_Copy_List
(Parameter_Specifications (Parent (Anon_Id))),
Result_Definition =>
New_Occurrence_Of (Etype (Anon_Id), Loc)),
Declarations => Empty_List,
Handled_Statement_Sequence =>
Make_Handled_Sequence_Of_Statements (Loc,
Statements =>
New_List
(Make_Simple_Return_Statement (Loc, Ret_Expr))));
end if;
Pack_Body := Make_Package_Body (Loc,
Defining_Unit_Name => New_Copy (Pack_Id),
Declarations => New_List (Act_Body));
Insert_After (Inst_Node, Pack_Body);
Set_Corresponding_Spec (Pack_Body, Pack_Id);
Analyze (Pack_Body);
end if;
Expander_Mode_Restore;
end Instantiate_Subprogram_Body;
----------------------
-- Instantiate_Type --
----------------------
function Instantiate_Type
(Formal : Node_Id;
Actual : Node_Id;
Analyzed_Formal : Node_Id;
Actual_Decls : List_Id) return List_Id
is
Gen_T : constant Entity_Id := Defining_Identifier (Formal);
A_Gen_T : constant Entity_Id :=
Defining_Identifier (Analyzed_Formal);
Ancestor : Entity_Id := Empty;
Def : constant Node_Id := Formal_Type_Definition (Formal);
Act_T : Entity_Id;
Decl_Node : Node_Id;
Decl_Nodes : List_Id;
Loc : Source_Ptr;
Subt : Entity_Id;
procedure Diagnose_Predicated_Actual;
-- There are a number of constructs in which a discrete type with
-- predicates is illegal, e.g. as an index in an array type declaration.
-- If a generic type is used is such a construct in a generic package
-- declaration, it carries the flag No_Predicate_On_Actual. it is part
-- of the generic contract that the actual cannot have predicates.
procedure Validate_Array_Type_Instance;
procedure Validate_Access_Subprogram_Instance;
procedure Validate_Access_Type_Instance;
procedure Validate_Derived_Type_Instance;
procedure Validate_Derived_Interface_Type_Instance;
procedure Validate_Discriminated_Formal_Type;
procedure Validate_Interface_Type_Instance;
procedure Validate_Private_Type_Instance;
procedure Validate_Incomplete_Type_Instance;
-- These procedures perform validation tests for the named case.
-- Validate_Discriminated_Formal_Type is shared by formal private
-- types and Ada 2012 formal incomplete types.
function Subtypes_Match (Gen_T, Act_T : Entity_Id) return Boolean;
-- Check that base types are the same and that the subtypes match
-- statically. Used in several of the above.
---------------------------------
-- Diagnose_Predicated_Actual --
---------------------------------
procedure Diagnose_Predicated_Actual is
begin
if No_Predicate_On_Actual (A_Gen_T)
and then Has_Predicates (Act_T)
then
Error_Msg_NE
("actual for& cannot be a type with predicate",
Instantiation_Node, A_Gen_T);
elsif No_Dynamic_Predicate_On_Actual (A_Gen_T)
and then Has_Predicates (Act_T)
and then not Has_Static_Predicate_Aspect (Act_T)
then
Error_Msg_NE
("actual for& cannot be a type with a dynamic predicate",
Instantiation_Node, A_Gen_T);
end if;
end Diagnose_Predicated_Actual;
--------------------
-- Subtypes_Match --
--------------------
function Subtypes_Match (Gen_T, Act_T : Entity_Id) return Boolean is
T : constant Entity_Id := Get_Instance_Of (Gen_T);
begin
-- Some detailed comments would be useful here ???
return ((Base_Type (T) = Act_T
or else Base_Type (T) = Base_Type (Act_T))
and then Subtypes_Statically_Match (T, Act_T))
or else (Is_Class_Wide_Type (Gen_T)
and then Is_Class_Wide_Type (Act_T)
and then Subtypes_Match
(Get_Instance_Of (Root_Type (Gen_T)),
Root_Type (Act_T)))
or else
(Ekind_In (Gen_T, E_Anonymous_Access_Subprogram_Type,
E_Anonymous_Access_Type)
and then Ekind (Act_T) = Ekind (Gen_T)
and then Subtypes_Statically_Match
(Designated_Type (Gen_T), Designated_Type (Act_T)));
end Subtypes_Match;
-----------------------------------------
-- Validate_Access_Subprogram_Instance --
-----------------------------------------
procedure Validate_Access_Subprogram_Instance is
begin
if not Is_Access_Type (Act_T)
or else Ekind (Designated_Type (Act_T)) /= E_Subprogram_Type
then
Error_Msg_NE
("expect access type in instantiation of &", Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
-- According to AI05-288, actuals for access_to_subprograms must be
-- subtype conformant with the generic formal. Previous to AI05-288
-- only mode conformance was required.
-- This is a binding interpretation that applies to previous versions
-- of the language, no need to maintain previous weaker checks.
Check_Subtype_Conformant
(Designated_Type (Act_T),
Designated_Type (A_Gen_T),
Actual,
Get_Inst => True);
if Ekind (Base_Type (Act_T)) = E_Access_Protected_Subprogram_Type then
if Ekind (A_Gen_T) = E_Access_Subprogram_Type then
Error_Msg_NE
("protected access type not allowed for formal &",
Actual, Gen_T);
end if;
elsif Ekind (A_Gen_T) = E_Access_Protected_Subprogram_Type then
Error_Msg_NE
("expect protected access type for formal &",
Actual, Gen_T);
end if;
end Validate_Access_Subprogram_Instance;
-----------------------------------
-- Validate_Access_Type_Instance --
-----------------------------------
procedure Validate_Access_Type_Instance is
Desig_Type : constant Entity_Id :=
Find_Actual_Type (Designated_Type (A_Gen_T), A_Gen_T);
Desig_Act : Entity_Id;
begin
if not Is_Access_Type (Act_T) then
Error_Msg_NE
("expect access type in instantiation of &", Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
if Is_Access_Constant (A_Gen_T) then
if not Is_Access_Constant (Act_T) then
Error_Msg_N
("actual type must be access-to-constant type", Actual);
Abandon_Instantiation (Actual);
end if;
else
if Is_Access_Constant (Act_T) then
Error_Msg_N
("actual type must be access-to-variable type", Actual);
Abandon_Instantiation (Actual);
elsif Ekind (A_Gen_T) = E_General_Access_Type
and then Ekind (Base_Type (Act_T)) /= E_General_Access_Type
then
Error_Msg_N -- CODEFIX
("actual must be general access type!", Actual);
Error_Msg_NE -- CODEFIX
("add ALL to }!", Actual, Act_T);
Abandon_Instantiation (Actual);
end if;
end if;
-- The designated subtypes, that is to say the subtypes introduced
-- by an access type declaration (and not by a subtype declaration)
-- must match.
Desig_Act := Designated_Type (Base_Type (Act_T));
-- The designated type may have been introduced through a limited_
-- with clause, in which case retrieve the non-limited view. This
-- applies to incomplete types as well as to class-wide types.
if From_Limited_With (Desig_Act) then
Desig_Act := Available_View (Desig_Act);
end if;
if not Subtypes_Match (Desig_Type, Desig_Act) then
Error_Msg_NE
("designated type of actual does not match that of formal &",
Actual, Gen_T);
if not Predicates_Match (Desig_Type, Desig_Act) then
Error_Msg_N ("\predicates do not match", Actual);
end if;
Abandon_Instantiation (Actual);
elsif Is_Access_Type (Designated_Type (Act_T))
and then Is_Constrained (Designated_Type (Designated_Type (Act_T)))
/=
Is_Constrained (Designated_Type (Desig_Type))
then
Error_Msg_NE
("designated type of actual does not match that of formal &",
Actual, Gen_T);
if not Predicates_Match (Desig_Type, Desig_Act) then
Error_Msg_N ("\predicates do not match", Actual);
end if;
Abandon_Instantiation (Actual);
end if;
-- Ada 2005: null-exclusion indicators of the two types must agree
if Can_Never_Be_Null (A_Gen_T) /= Can_Never_Be_Null (Act_T) then
Error_Msg_NE
("non null exclusion of actual and formal & do not match",
Actual, Gen_T);
end if;
end Validate_Access_Type_Instance;
----------------------------------
-- Validate_Array_Type_Instance --
----------------------------------
procedure Validate_Array_Type_Instance is
I1 : Node_Id;
I2 : Node_Id;
T2 : Entity_Id;
function Formal_Dimensions return Int;
-- Count number of dimensions in array type formal
-----------------------
-- Formal_Dimensions --
-----------------------
function Formal_Dimensions return Int is
Num : Int := 0;
Index : Node_Id;
begin
if Nkind (Def) = N_Constrained_Array_Definition then
Index := First (Discrete_Subtype_Definitions (Def));
else
Index := First (Subtype_Marks (Def));
end if;
while Present (Index) loop
Num := Num + 1;
Next_Index (Index);
end loop;
return Num;
end Formal_Dimensions;
-- Start of processing for Validate_Array_Type_Instance
begin
if not Is_Array_Type (Act_T) then
Error_Msg_NE
("expect array type in instantiation of &", Actual, Gen_T);
Abandon_Instantiation (Actual);
elsif Nkind (Def) = N_Constrained_Array_Definition then
if not (Is_Constrained (Act_T)) then
Error_Msg_NE
("expect constrained array in instantiation of &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
else
if Is_Constrained (Act_T) then
Error_Msg_NE
("expect unconstrained array in instantiation of &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
end if;
if Formal_Dimensions /= Number_Dimensions (Act_T) then
Error_Msg_NE
("dimensions of actual do not match formal &", Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
I1 := First_Index (A_Gen_T);
I2 := First_Index (Act_T);
for J in 1 .. Formal_Dimensions loop
-- If the indexes of the actual were given by a subtype_mark,
-- the index was transformed into a range attribute. Retrieve
-- the original type mark for checking.
if Is_Entity_Name (Original_Node (I2)) then
T2 := Entity (Original_Node (I2));
else
T2 := Etype (I2);
end if;
if not Subtypes_Match
(Find_Actual_Type (Etype (I1), A_Gen_T), T2)
then
Error_Msg_NE
("index types of actual do not match those of formal &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Next_Index (I1);
Next_Index (I2);
end loop;
-- Check matching subtypes. Note that there are complex visibility
-- issues when the generic is a child unit and some aspect of the
-- generic type is declared in a parent unit of the generic. We do
-- the test to handle this special case only after a direct check
-- for static matching has failed. The case where both the component
-- type and the array type are separate formals, and the component
-- type is a private view may also require special checking in
-- Subtypes_Match.
if Subtypes_Match
(Component_Type (A_Gen_T), Component_Type (Act_T))
or else Subtypes_Match
(Find_Actual_Type (Component_Type (A_Gen_T), A_Gen_T),
Component_Type (Act_T))
then
null;
else
Error_Msg_NE
("component subtype of actual does not match that of formal &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
if Has_Aliased_Components (A_Gen_T)
and then not Has_Aliased_Components (Act_T)
then
Error_Msg_NE
("actual must have aliased components to match formal type &",
Actual, Gen_T);
end if;
end Validate_Array_Type_Instance;
-----------------------------------------------
-- Validate_Derived_Interface_Type_Instance --
-----------------------------------------------
procedure Validate_Derived_Interface_Type_Instance is
Par : constant Entity_Id := Entity (Subtype_Indication (Def));
Elmt : Elmt_Id;
begin
-- First apply interface instance checks
Validate_Interface_Type_Instance;
-- Verify that immediate parent interface is an ancestor of
-- the actual.
if Present (Par)
and then not Interface_Present_In_Ancestor (Act_T, Par)
then
Error_Msg_NE
("interface actual must include progenitor&", Actual, Par);
end if;
-- Now verify that the actual includes all other ancestors of
-- the formal.
Elmt := First_Elmt (Interfaces (A_Gen_T));
while Present (Elmt) loop
if not Interface_Present_In_Ancestor
(Act_T, Get_Instance_Of (Node (Elmt)))
then
Error_Msg_NE
("interface actual must include progenitor&",
Actual, Node (Elmt));
end if;
Next_Elmt (Elmt);
end loop;
end Validate_Derived_Interface_Type_Instance;
------------------------------------
-- Validate_Derived_Type_Instance --
------------------------------------
procedure Validate_Derived_Type_Instance is
Actual_Discr : Entity_Id;
Ancestor_Discr : Entity_Id;
begin
-- If the parent type in the generic declaration is itself a previous
-- formal type, then it is local to the generic and absent from the
-- analyzed generic definition. In that case the ancestor is the
-- instance of the formal (which must have been instantiated
-- previously), unless the ancestor is itself a formal derived type.
-- In this latter case (which is the subject of Corrigendum 8652/0038
-- (AI-202) the ancestor of the formals is the ancestor of its
-- parent. Otherwise, the analyzed generic carries the parent type.
-- If the parent type is defined in a previous formal package, then
-- the scope of that formal package is that of the generic type
-- itself, and it has already been mapped into the corresponding type
-- in the actual package.
-- Common case: parent type defined outside of the generic
if Is_Entity_Name (Subtype_Mark (Def))
and then Present (Entity (Subtype_Mark (Def)))
then
Ancestor := Get_Instance_Of (Entity (Subtype_Mark (Def)));
-- Check whether parent is defined in a previous formal package
elsif
Scope (Scope (Base_Type (Etype (A_Gen_T)))) = Scope (A_Gen_T)
then
Ancestor :=
Get_Instance_Of (Base_Type (Etype (A_Gen_T)));
-- The type may be a local derivation, or a type extension of a
-- previous formal, or of a formal of a parent package.
elsif Is_Derived_Type (Get_Instance_Of (A_Gen_T))
or else
Ekind (Get_Instance_Of (A_Gen_T)) = E_Record_Type_With_Private
then
-- Check whether the parent is another derived formal type in the
-- same generic unit.
if Etype (A_Gen_T) /= A_Gen_T
and then Is_Generic_Type (Etype (A_Gen_T))
and then Scope (Etype (A_Gen_T)) = Scope (A_Gen_T)
and then Etype (Etype (A_Gen_T)) /= Etype (A_Gen_T)
then
-- Locate ancestor of parent from the subtype declaration
-- created for the actual.
declare
Decl : Node_Id;
begin
Decl := First (Actual_Decls);
while Present (Decl) loop
if Nkind (Decl) = N_Subtype_Declaration
and then Chars (Defining_Identifier (Decl)) =
Chars (Etype (A_Gen_T))
then
Ancestor := Generic_Parent_Type (Decl);
exit;
else
Next (Decl);
end if;
end loop;
end;
pragma Assert (Present (Ancestor));
-- The ancestor itself may be a previous formal that has been
-- instantiated.
Ancestor := Get_Instance_Of (Ancestor);
else
Ancestor :=
Get_Instance_Of (Base_Type (Get_Instance_Of (A_Gen_T)));
end if;
-- An unusual case: the actual is a type declared in a parent unit,
-- but is not a formal type so there is no instance_of for it.
-- Retrieve it by analyzing the record extension.
elsif Is_Child_Unit (Scope (A_Gen_T))
and then In_Open_Scopes (Scope (Act_T))
and then Is_Generic_Instance (Scope (Act_T))
then
Analyze (Subtype_Mark (Def));
Ancestor := Entity (Subtype_Mark (Def));
else
Ancestor := Get_Instance_Of (Etype (Base_Type (A_Gen_T)));
end if;
-- If the formal derived type has pragma Preelaborable_Initialization
-- then the actual type must have preelaborable initialization.
if Known_To_Have_Preelab_Init (A_Gen_T)
and then not Has_Preelaborable_Initialization (Act_T)
then
Error_Msg_NE
("actual for & must have preelaborable initialization",
Actual, Gen_T);
end if;
-- Ada 2005 (AI-251)
if Ada_Version >= Ada_2005 and then Is_Interface (Ancestor) then
if not Interface_Present_In_Ancestor (Act_T, Ancestor) then
Error_Msg_NE
("(Ada 2005) expected type implementing & in instantiation",
Actual, Ancestor);
end if;
elsif not Is_Ancestor (Base_Type (Ancestor), Act_T) then
Error_Msg_NE
("expect type derived from & in instantiation",
Actual, First_Subtype (Ancestor));
Abandon_Instantiation (Actual);
end if;
-- Ada 2005 (AI-443): Synchronized formal derived type checks. Note
-- that the formal type declaration has been rewritten as a private
-- extension.
if Ada_Version >= Ada_2005
and then Nkind (Parent (A_Gen_T)) = N_Private_Extension_Declaration
and then Synchronized_Present (Parent (A_Gen_T))
then
-- The actual must be a synchronized tagged type
if not Is_Tagged_Type (Act_T) then
Error_Msg_N
("actual of synchronized type must be tagged", Actual);
Abandon_Instantiation (Actual);
elsif Nkind (Parent (Act_T)) = N_Full_Type_Declaration
and then Nkind (Type_Definition (Parent (Act_T))) =
N_Derived_Type_Definition
and then not Synchronized_Present (Type_Definition
(Parent (Act_T)))
then
Error_Msg_N
("actual of synchronized type must be synchronized", Actual);
Abandon_Instantiation (Actual);
end if;
end if;
-- Perform atomic/volatile checks (RM C.6(12)). Note that AI05-0218-1
-- removes the second instance of the phrase "or allow pass by copy".
if Is_Atomic (Act_T) and then not Is_Atomic (Ancestor) then
Error_Msg_N
("cannot have atomic actual type for non-atomic formal type",
Actual);
elsif Is_Volatile (Act_T) and then not Is_Volatile (Ancestor) then
Error_Msg_N
("cannot have volatile actual type for non-volatile formal type",
Actual);
end if;
-- It should not be necessary to check for unknown discriminants on
-- Formal, but for some reason Has_Unknown_Discriminants is false for
-- A_Gen_T, so Is_Indefinite_Subtype incorrectly returns False. This
-- needs fixing. ???
if not Is_Indefinite_Subtype (A_Gen_T)
and then not Unknown_Discriminants_Present (Formal)
and then Is_Indefinite_Subtype (Act_T)
then
Error_Msg_N
("actual subtype must be constrained", Actual);
Abandon_Instantiation (Actual);
end if;
if not Unknown_Discriminants_Present (Formal) then
if Is_Constrained (Ancestor) then
if not Is_Constrained (Act_T) then
Error_Msg_N
("actual subtype must be constrained", Actual);
Abandon_Instantiation (Actual);
end if;
-- Ancestor is unconstrained, Check if generic formal and actual
-- agree on constrainedness. The check only applies to array types
-- and discriminated types.
elsif Is_Constrained (Act_T) then
if Ekind (Ancestor) = E_Access_Type
or else
(not Is_Constrained (A_Gen_T)
and then Is_Composite_Type (A_Gen_T))
then
Error_Msg_N
("actual subtype must be unconstrained", Actual);
Abandon_Instantiation (Actual);
end if;
-- A class-wide type is only allowed if the formal has unknown
-- discriminants.
elsif Is_Class_Wide_Type (Act_T)
and then not Has_Unknown_Discriminants (Ancestor)
then
Error_Msg_NE
("actual for & cannot be a class-wide type", Actual, Gen_T);
Abandon_Instantiation (Actual);
-- Otherwise, the formal and actual must have the same number
-- of discriminants and each discriminant of the actual must
-- correspond to a discriminant of the formal.
elsif Has_Discriminants (Act_T)
and then not Has_Unknown_Discriminants (Act_T)
and then Has_Discriminants (Ancestor)
then
Actual_Discr := First_Discriminant (Act_T);
Ancestor_Discr := First_Discriminant (Ancestor);
while Present (Actual_Discr)
and then Present (Ancestor_Discr)
loop
if Base_Type (Act_T) /= Base_Type (Ancestor) and then
No (Corresponding_Discriminant (Actual_Discr))
then
Error_Msg_NE
("discriminant & does not correspond " &
"to ancestor discriminant", Actual, Actual_Discr);
Abandon_Instantiation (Actual);
end if;
Next_Discriminant (Actual_Discr);
Next_Discriminant (Ancestor_Discr);
end loop;
if Present (Actual_Discr) or else Present (Ancestor_Discr) then
Error_Msg_NE
("actual for & must have same number of discriminants",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
-- This case should be caught by the earlier check for
-- constrainedness, but the check here is added for completeness.
elsif Has_Discriminants (Act_T)
and then not Has_Unknown_Discriminants (Act_T)
then
Error_Msg_NE
("actual for & must not have discriminants", Actual, Gen_T);
Abandon_Instantiation (Actual);
elsif Has_Discriminants (Ancestor) then
Error_Msg_NE
("actual for & must have known discriminants", Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
if not Subtypes_Statically_Compatible
(Act_T, Ancestor, Formal_Derived_Matching => True)
then
Error_Msg_N
("constraint on actual is incompatible with formal", Actual);
Abandon_Instantiation (Actual);
end if;
end if;
-- If the formal and actual types are abstract, check that there
-- are no abstract primitives of the actual type that correspond to
-- nonabstract primitives of the formal type (second sentence of
-- RM95-3.9.3(9)).
if Is_Abstract_Type (A_Gen_T) and then Is_Abstract_Type (Act_T) then
Check_Abstract_Primitives : declare
Gen_Prims : constant Elist_Id :=
Primitive_Operations (A_Gen_T);
Gen_Elmt : Elmt_Id;
Gen_Subp : Entity_Id;
Anc_Subp : Entity_Id;
Anc_Formal : Entity_Id;
Anc_F_Type : Entity_Id;
Act_Prims : constant Elist_Id := Primitive_Operations (Act_T);
Act_Elmt : Elmt_Id;
Act_Subp : Entity_Id;
Act_Formal : Entity_Id;
Act_F_Type : Entity_Id;
Subprograms_Correspond : Boolean;
function Is_Tagged_Ancestor (T1, T2 : Entity_Id) return Boolean;
-- Returns true if T2 is derived directly or indirectly from
-- T1, including derivations from interfaces. T1 and T2 are
-- required to be specific tagged base types.
------------------------
-- Is_Tagged_Ancestor --
------------------------
function Is_Tagged_Ancestor (T1, T2 : Entity_Id) return Boolean
is
Intfc_Elmt : Elmt_Id;
begin
-- The predicate is satisfied if the types are the same
if T1 = T2 then
return True;
-- If we've reached the top of the derivation chain then
-- we know that T1 is not an ancestor of T2.
elsif Etype (T2) = T2 then
return False;
-- Proceed to check T2's immediate parent
elsif Is_Ancestor (T1, Base_Type (Etype (T2))) then
return True;
-- Finally, check to see if T1 is an ancestor of any of T2's
-- progenitors.
else
Intfc_Elmt := First_Elmt (Interfaces (T2));
while Present (Intfc_Elmt) loop
if Is_Ancestor (T1, Node (Intfc_Elmt)) then
return True;
end if;
Next_Elmt (Intfc_Elmt);
end loop;
end if;
return False;
end Is_Tagged_Ancestor;
-- Start of processing for Check_Abstract_Primitives
begin
-- Loop over all of the formal derived type's primitives
Gen_Elmt := First_Elmt (Gen_Prims);
while Present (Gen_Elmt) loop
Gen_Subp := Node (Gen_Elmt);
-- If the primitive of the formal is not abstract, then
-- determine whether there is a corresponding primitive of
-- the actual type that's abstract.
if not Is_Abstract_Subprogram (Gen_Subp) then
Act_Elmt := First_Elmt (Act_Prims);
while Present (Act_Elmt) loop
Act_Subp := Node (Act_Elmt);
-- If we find an abstract primitive of the actual,
-- then we need to test whether it corresponds to the
-- subprogram from which the generic formal primitive
-- is inherited.
if Is_Abstract_Subprogram (Act_Subp) then
Anc_Subp := Alias (Gen_Subp);
-- Test whether we have a corresponding primitive
-- by comparing names, kinds, formal types, and
-- result types.
if Chars (Anc_Subp) = Chars (Act_Subp)
and then Ekind (Anc_Subp) = Ekind (Act_Subp)
then
Anc_Formal := First_Formal (Anc_Subp);
Act_Formal := First_Formal (Act_Subp);
while Present (Anc_Formal)
and then Present (Act_Formal)
loop
Anc_F_Type := Etype (Anc_Formal);
Act_F_Type := Etype (Act_Formal);
if Ekind (Anc_F_Type)
= E_Anonymous_Access_Type
then
Anc_F_Type := Designated_Type (Anc_F_Type);
if Ekind (Act_F_Type)
= E_Anonymous_Access_Type
then
Act_F_Type :=
Designated_Type (Act_F_Type);
else
exit;
end if;
elsif
Ekind (Act_F_Type) = E_Anonymous_Access_Type
then
exit;
end if;
Anc_F_Type := Base_Type (Anc_F_Type);
Act_F_Type := Base_Type (Act_F_Type);
-- If the formal is controlling, then the
-- the type of the actual primitive's formal
-- must be derived directly or indirectly
-- from the type of the ancestor primitive's
-- formal.
if Is_Controlling_Formal (Anc_Formal) then
if not Is_Tagged_Ancestor
(Anc_F_Type, Act_F_Type)
then
exit;
end if;
-- Otherwise the types of the formals must
-- be the same.
elsif Anc_F_Type /= Act_F_Type then
exit;
end if;
Next_Entity (Anc_Formal);
Next_Entity (Act_Formal);
end loop;
-- If we traversed through all of the formals
-- then so far the subprograms correspond, so
-- now check that any result types correspond.
if No (Anc_Formal) and then No (Act_Formal) then
Subprograms_Correspond := True;
if Ekind (Act_Subp) = E_Function then
Anc_F_Type := Etype (Anc_Subp);
Act_F_Type := Etype (Act_Subp);
if Ekind (Anc_F_Type)
= E_Anonymous_Access_Type
then
Anc_F_Type :=
Designated_Type (Anc_F_Type);
if Ekind (Act_F_Type)
= E_Anonymous_Access_Type
then
Act_F_Type :=
Designated_Type (Act_F_Type);
else
Subprograms_Correspond := False;
end if;
elsif
Ekind (Act_F_Type)
= E_Anonymous_Access_Type
then
Subprograms_Correspond := False;
end if;
Anc_F_Type := Base_Type (Anc_F_Type);
Act_F_Type := Base_Type (Act_F_Type);
-- Now either the result types must be
-- the same or, if the result type is
-- controlling, the result type of the
-- actual primitive must descend from the
-- result type of the ancestor primitive.
if Subprograms_Correspond
and then Anc_F_Type /= Act_F_Type
and then
Has_Controlling_Result (Anc_Subp)
and then
not Is_Tagged_Ancestor
(Anc_F_Type, Act_F_Type)
then
Subprograms_Correspond := False;
end if;
end if;
-- Found a matching subprogram belonging to
-- formal ancestor type, so actual subprogram
-- corresponds and this violates 3.9.3(9).
if Subprograms_Correspond then
Error_Msg_NE
("abstract subprogram & overrides " &
"nonabstract subprogram of ancestor",
Actual,
Act_Subp);
end if;
end if;
end if;
end if;
Next_Elmt (Act_Elmt);
end loop;
end if;
Next_Elmt (Gen_Elmt);
end loop;
end Check_Abstract_Primitives;
end if;
-- Verify that limitedness matches. If parent is a limited
-- interface then the generic formal is not unless declared
-- explicitly so. If not declared limited, the actual cannot be
-- limited (see AI05-0087).
-- Even though this AI is a binding interpretation, we enable the
-- check only in Ada 2012 mode, because this improper construct
-- shows up in user code and in existing B-tests.
if Is_Limited_Type (Act_T)
and then not Is_Limited_Type (A_Gen_T)
and then Ada_Version >= Ada_2012
then
if In_Instance then
null;
else
Error_Msg_NE
("actual for non-limited & cannot be a limited type", Actual,
Gen_T);
Explain_Limited_Type (Act_T, Actual);
Abandon_Instantiation (Actual);
end if;
end if;
end Validate_Derived_Type_Instance;
----------------------------------------
-- Validate_Discriminated_Formal_Type --
----------------------------------------
procedure Validate_Discriminated_Formal_Type is
Formal_Discr : Entity_Id;
Actual_Discr : Entity_Id;
Formal_Subt : Entity_Id;
begin
if Has_Discriminants (A_Gen_T) then
if not Has_Discriminants (Act_T) then
Error_Msg_NE
("actual for & must have discriminants", Actual, Gen_T);
Abandon_Instantiation (Actual);
elsif Is_Constrained (Act_T) then
Error_Msg_NE
("actual for & must be unconstrained", Actual, Gen_T);
Abandon_Instantiation (Actual);
else
Formal_Discr := First_Discriminant (A_Gen_T);
Actual_Discr := First_Discriminant (Act_T);
while Formal_Discr /= Empty loop
if Actual_Discr = Empty then
Error_Msg_NE
("discriminants on actual do not match formal",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Formal_Subt := Get_Instance_Of (Etype (Formal_Discr));
-- Access discriminants match if designated types do
if Ekind (Base_Type (Formal_Subt)) = E_Anonymous_Access_Type
and then (Ekind (Base_Type (Etype (Actual_Discr)))) =
E_Anonymous_Access_Type
and then
Get_Instance_Of
(Designated_Type (Base_Type (Formal_Subt))) =
Designated_Type (Base_Type (Etype (Actual_Discr)))
then
null;
elsif Base_Type (Formal_Subt) /=
Base_Type (Etype (Actual_Discr))
then
Error_Msg_NE
("types of actual discriminants must match formal",
Actual, Gen_T);
Abandon_Instantiation (Actual);
elsif not Subtypes_Statically_Match
(Formal_Subt, Etype (Actual_Discr))
and then Ada_Version >= Ada_95
then
Error_Msg_NE
("subtypes of actual discriminants must match formal",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Next_Discriminant (Formal_Discr);
Next_Discriminant (Actual_Discr);
end loop;
if Actual_Discr /= Empty then
Error_Msg_NE
("discriminants on actual do not match formal",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
end if;
end if;
end Validate_Discriminated_Formal_Type;
---------------------------------------
-- Validate_Incomplete_Type_Instance --
---------------------------------------
procedure Validate_Incomplete_Type_Instance is
begin
if not Is_Tagged_Type (Act_T)
and then Is_Tagged_Type (A_Gen_T)
then
Error_Msg_NE
("actual for & must be a tagged type", Actual, Gen_T);
end if;
Validate_Discriminated_Formal_Type;
end Validate_Incomplete_Type_Instance;
--------------------------------------
-- Validate_Interface_Type_Instance --
--------------------------------------
procedure Validate_Interface_Type_Instance is
begin
if not Is_Interface (Act_T) then
Error_Msg_NE
("actual for formal interface type must be an interface",
Actual, Gen_T);
elsif Is_Limited_Type (Act_T) /= Is_Limited_Type (A_Gen_T)
or else
Is_Task_Interface (A_Gen_T) /= Is_Task_Interface (Act_T)
or else
Is_Protected_Interface (A_Gen_T) /=
Is_Protected_Interface (Act_T)
or else
Is_Synchronized_Interface (A_Gen_T) /=
Is_Synchronized_Interface (Act_T)
then
Error_Msg_NE
("actual for interface& does not match (RM 12.5.5(4))",
Actual, Gen_T);
end if;
end Validate_Interface_Type_Instance;
------------------------------------
-- Validate_Private_Type_Instance --
------------------------------------
procedure Validate_Private_Type_Instance is
begin
if Is_Limited_Type (Act_T)
and then not Is_Limited_Type (A_Gen_T)
then
if In_Instance then
null;
else
Error_Msg_NE
("actual for non-limited & cannot be a limited type", Actual,
Gen_T);
Explain_Limited_Type (Act_T, Actual);
Abandon_Instantiation (Actual);
end if;
elsif Known_To_Have_Preelab_Init (A_Gen_T)
and then not Has_Preelaborable_Initialization (Act_T)
then
Error_Msg_NE
("actual for & must have preelaborable initialization", Actual,
Gen_T);
elsif Is_Indefinite_Subtype (Act_T)
and then not Is_Indefinite_Subtype (A_Gen_T)
and then Ada_Version >= Ada_95
then
Error_Msg_NE
("actual for & must be a definite subtype", Actual, Gen_T);
elsif not Is_Tagged_Type (Act_T)
and then Is_Tagged_Type (A_Gen_T)
then
Error_Msg_NE
("actual for & must be a tagged type", Actual, Gen_T);
end if;
Validate_Discriminated_Formal_Type;
Ancestor := Gen_T;
end Validate_Private_Type_Instance;
-- Start of processing for Instantiate_Type
begin
if Get_Instance_Of (A_Gen_T) /= A_Gen_T then
Error_Msg_N ("duplicate instantiation of generic type", Actual);
return New_List (Error);
elsif not Is_Entity_Name (Actual)
or else not Is_Type (Entity (Actual))
then
Error_Msg_NE
("expect valid subtype mark to instantiate &", Actual, Gen_T);
Abandon_Instantiation (Actual);
else
Act_T := Entity (Actual);
-- Ada 2005 (AI-216): An Unchecked_Union subtype shall only be passed
-- as a generic actual parameter if the corresponding formal type
-- does not have a known_discriminant_part, or is a formal derived
-- type that is an Unchecked_Union type.
if Is_Unchecked_Union (Base_Type (Act_T)) then
if not Has_Discriminants (A_Gen_T)
or else
(Is_Derived_Type (A_Gen_T)
and then
Is_Unchecked_Union (A_Gen_T))
then
null;
else
Error_Msg_N ("unchecked union cannot be the actual for a" &
" discriminated formal type", Act_T);
end if;
end if;
-- Deal with fixed/floating restrictions
if Is_Floating_Point_Type (Act_T) then
Check_Restriction (No_Floating_Point, Actual);
elsif Is_Fixed_Point_Type (Act_T) then
Check_Restriction (No_Fixed_Point, Actual);
end if;
-- Deal with error of using incomplete type as generic actual.
-- This includes limited views of a type, even if the non-limited
-- view may be available.
if Ekind (Act_T) = E_Incomplete_Type
or else (Is_Class_Wide_Type (Act_T)
and then
Ekind (Root_Type (Act_T)) = E_Incomplete_Type)
then
-- If the formal is an incomplete type, the actual can be
-- incomplete as well.
if Ekind (A_Gen_T) = E_Incomplete_Type then
null;
elsif Is_Class_Wide_Type (Act_T)
or else No (Full_View (Act_T))
then
Error_Msg_N ("premature use of incomplete type", Actual);
Abandon_Instantiation (Actual);
else
Act_T := Full_View (Act_T);
Set_Entity (Actual, Act_T);
if Has_Private_Component (Act_T) then
Error_Msg_N
("premature use of type with private component", Actual);
end if;
end if;
-- Deal with error of premature use of private type as generic actual
elsif Is_Private_Type (Act_T)
and then Is_Private_Type (Base_Type (Act_T))
and then not Is_Generic_Type (Act_T)
and then not Is_Derived_Type (Act_T)
and then No (Full_View (Root_Type (Act_T)))
then
-- If the formal is an incomplete type, the actual can be
-- private or incomplete as well.
if Ekind (A_Gen_T) = E_Incomplete_Type then
null;
else
Error_Msg_N ("premature use of private type", Actual);
end if;
elsif Has_Private_Component (Act_T) then
Error_Msg_N
("premature use of type with private component", Actual);
end if;
Set_Instance_Of (A_Gen_T, Act_T);
-- If the type is generic, the class-wide type may also be used
if Is_Tagged_Type (A_Gen_T)
and then Is_Tagged_Type (Act_T)
and then not Is_Class_Wide_Type (A_Gen_T)
then
Set_Instance_Of (Class_Wide_Type (A_Gen_T),
Class_Wide_Type (Act_T));
end if;
if not Is_Abstract_Type (A_Gen_T)
and then Is_Abstract_Type (Act_T)
then
Error_Msg_N
("actual of non-abstract formal cannot be abstract", Actual);
end if;
-- A generic scalar type is a first subtype for which we generate
-- an anonymous base type. Indicate that the instance of this base
-- is the base type of the actual.
if Is_Scalar_Type (A_Gen_T) then
Set_Instance_Of (Etype (A_Gen_T), Etype (Act_T));
end if;
end if;
if Error_Posted (Act_T) then
null;
else
case Nkind (Def) is
when N_Formal_Private_Type_Definition =>
Validate_Private_Type_Instance;
when N_Formal_Incomplete_Type_Definition =>
Validate_Incomplete_Type_Instance;
when N_Formal_Derived_Type_Definition =>
Validate_Derived_Type_Instance;
when N_Formal_Discrete_Type_Definition =>
if not Is_Discrete_Type (Act_T) then
Error_Msg_NE
("expect discrete type in instantiation of&",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Diagnose_Predicated_Actual;
when N_Formal_Signed_Integer_Type_Definition =>
if not Is_Signed_Integer_Type (Act_T) then
Error_Msg_NE
("expect signed integer type in instantiation of&",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Diagnose_Predicated_Actual;
when N_Formal_Modular_Type_Definition =>
if not Is_Modular_Integer_Type (Act_T) then
Error_Msg_NE
("expect modular type in instantiation of &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
Diagnose_Predicated_Actual;
when N_Formal_Floating_Point_Definition =>
if not Is_Floating_Point_Type (Act_T) then
Error_Msg_NE
("expect float type in instantiation of &", Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
when N_Formal_Ordinary_Fixed_Point_Definition =>
if not Is_Ordinary_Fixed_Point_Type (Act_T) then
Error_Msg_NE
("expect ordinary fixed point type in instantiation of &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
when N_Formal_Decimal_Fixed_Point_Definition =>
if not Is_Decimal_Fixed_Point_Type (Act_T) then
Error_Msg_NE
("expect decimal type in instantiation of &",
Actual, Gen_T);
Abandon_Instantiation (Actual);
end if;
when N_Array_Type_Definition =>
Validate_Array_Type_Instance;
when N_Access_To_Object_Definition =>
Validate_Access_Type_Instance;
when N_Access_Function_Definition |
N_Access_Procedure_Definition =>
Validate_Access_Subprogram_Instance;
when N_Record_Definition =>
Validate_Interface_Type_Instance;
when N_Derived_Type_Definition =>
Validate_Derived_Interface_Type_Instance;
when others =>
raise Program_Error;
end case;
end if;
Subt := New_Copy (Gen_T);
-- Use adjusted sloc of subtype name as the location for other nodes in
-- the subtype declaration.
Loc := Sloc (Subt);
Decl_Node :=
Make_Subtype_Declaration (Loc,
Defining_Identifier => Subt,
Subtype_Indication => New_Occurrence_Of (Act_T, Loc));
if Is_Private_Type (Act_T) then
Set_Has_Private_View (Subtype_Indication (Decl_Node));
elsif Is_Access_Type (Act_T)
and then Is_Private_Type (Designated_Type (Act_T))
then
Set_Has_Private_View (Subtype_Indication (Decl_Node));
end if;
Decl_Nodes := New_List (Decl_Node);
-- Flag actual derived types so their elaboration produces the
-- appropriate renamings for the primitive operations of the ancestor.
-- Flag actual for formal private types as well, to determine whether
-- operations in the private part may override inherited operations.
-- If the formal has an interface list, the ancestor is not the
-- parent, but the analyzed formal that includes the interface
-- operations of all its progenitors.
-- Same treatment for formal private types, so we can check whether the
-- type is tagged limited when validating derivations in the private
-- part. (See AI05-096).
if Nkind (Def) = N_Formal_Derived_Type_Definition then
if Present (Interface_List (Def)) then
Set_Generic_Parent_Type (Decl_Node, A_Gen_T);
else
Set_Generic_Parent_Type (Decl_Node, Ancestor);
end if;
elsif Nkind_In (Def,
N_Formal_Private_Type_Definition,
N_Formal_Incomplete_Type_Definition)
then
Set_Generic_Parent_Type (Decl_Node, A_Gen_T);
end if;
-- If the actual is a synchronized type that implements an interface,
-- the primitive operations are attached to the corresponding record,
-- and we have to treat it as an additional generic actual, so that its
-- primitive operations become visible in the instance. The task or
-- protected type itself does not carry primitive operations.
if Is_Concurrent_Type (Act_T)
and then Is_Tagged_Type (Act_T)
and then Present (Corresponding_Record_Type (Act_T))
and then Present (Ancestor)
and then Is_Interface (Ancestor)
then
declare
Corr_Rec : constant Entity_Id :=
Corresponding_Record_Type (Act_T);
New_Corr : Entity_Id;
Corr_Decl : Node_Id;
begin
New_Corr := Make_Temporary (Loc, 'S');
Corr_Decl :=
Make_Subtype_Declaration (Loc,
Defining_Identifier => New_Corr,
Subtype_Indication =>
New_Occurrence_Of (Corr_Rec, Loc));
Append_To (Decl_Nodes, Corr_Decl);
if Ekind (Act_T) = E_Task_Type then
Set_Ekind (Subt, E_Task_Subtype);
else
Set_Ekind (Subt, E_Protected_Subtype);
end if;
Set_Corresponding_Record_Type (Subt, Corr_Rec);
Set_Generic_Parent_Type (Corr_Decl, Ancestor);
Set_Generic_Parent_Type (Decl_Node, Empty);
end;
end if;
return Decl_Nodes;
end Instantiate_Type;
---------------------
-- Is_In_Main_Unit --
---------------------
function Is_In_Main_Unit (N : Node_Id) return Boolean is
Unum : constant Unit_Number_Type := Get_Source_Unit (N);
Current_Unit : Node_Id;
begin
if Unum = Main_Unit then
return True;
-- If the current unit is a subunit then it is either the main unit or
-- is being compiled as part of the main unit.
elsif Nkind (N) = N_Compilation_Unit then
return Nkind (Unit (N)) = N_Subunit;
end if;
Current_Unit := Parent (N);
while Present (Current_Unit)
and then Nkind (Current_Unit) /= N_Compilation_Unit
loop
Current_Unit := Parent (Current_Unit);
end loop;
-- The instantiation node is in the main unit, or else the current node
-- (perhaps as the result of nested instantiations) is in the main unit,
-- or in the declaration of the main unit, which in this last case must
-- be a body.
return Unum = Main_Unit
or else Current_Unit = Cunit (Main_Unit)
or else Current_Unit = Library_Unit (Cunit (Main_Unit))
or else (Present (Library_Unit (Current_Unit))
and then Is_In_Main_Unit (Library_Unit (Current_Unit)));
end Is_In_Main_Unit;
----------------------------
-- Load_Parent_Of_Generic --
----------------------------
procedure Load_Parent_Of_Generic
(N : Node_Id;
Spec : Node_Id;
Body_Optional : Boolean := False)
is
Comp_Unit : constant Node_Id := Cunit (Get_Source_Unit (Spec));
Saved_Style_Check : constant Boolean := Style_Check;
Saved_Warnings : constant Warning_Record := Save_Warnings;
True_Parent : Node_Id;
Inst_Node : Node_Id;
OK : Boolean;
Previous_Instances : constant Elist_Id := New_Elmt_List;
procedure Collect_Previous_Instances (Decls : List_Id);
-- Collect all instantiations in the given list of declarations, that
-- precede the generic that we need to load. If the bodies of these
-- instantiations are available, we must analyze them, to ensure that
-- the public symbols generated are the same when the unit is compiled
-- to generate code, and when it is compiled in the context of a unit
-- that needs a particular nested instance. This process is applied to
-- both package and subprogram instances.
--------------------------------
-- Collect_Previous_Instances --
--------------------------------
procedure Collect_Previous_Instances (Decls : List_Id) is
Decl : Node_Id;
begin
Decl := First (Decls);
while Present (Decl) loop
if Sloc (Decl) >= Sloc (Inst_Node) then
return;
-- If Decl is an instantiation, then record it as requiring
-- instantiation of the corresponding body, except if it is an
-- abbreviated instantiation generated internally for conformance
-- checking purposes only for the case of a formal package
-- declared without a box (see Instantiate_Formal_Package). Such
-- an instantiation does not generate any code (the actual code
-- comes from actual) and thus does not need to be analyzed here.
-- If the instantiation appears with a generic package body it is
-- not analyzed here either.
elsif Nkind (Decl) = N_Package_Instantiation
and then not Is_Internal (Defining_Entity (Decl))
then
Append_Elmt (Decl, Previous_Instances);
-- For a subprogram instantiation, omit instantiations intrinsic
-- operations (Unchecked_Conversions, etc.) that have no bodies.
elsif Nkind_In (Decl, N_Function_Instantiation,
N_Procedure_Instantiation)
and then not Is_Intrinsic_Subprogram (Entity (Name (Decl)))
then
Append_Elmt (Decl, Previous_Instances);
elsif Nkind (Decl) = N_Package_Declaration then
Collect_Previous_Instances
(Visible_Declarations (Specification (Decl)));
Collect_Previous_Instances
(Private_Declarations (Specification (Decl)));
-- Previous non-generic bodies may contain instances as well
elsif Nkind (Decl) = N_Package_Body
and then Ekind (Corresponding_Spec (Decl)) /= E_Generic_Package
then
Collect_Previous_Instances (Declarations (Decl));
elsif Nkind (Decl) = N_Subprogram_Body
and then not Acts_As_Spec (Decl)
and then not Is_Generic_Subprogram (Corresponding_Spec (Decl))
then
Collect_Previous_Instances (Declarations (Decl));
end if;
Next (Decl);
end loop;
end Collect_Previous_Instances;
-- Start of processing for Load_Parent_Of_Generic
begin
if not In_Same_Source_Unit (N, Spec)
or else Nkind (Unit (Comp_Unit)) = N_Package_Declaration
or else (Nkind (Unit (Comp_Unit)) = N_Package_Body
and then not Is_In_Main_Unit (Spec))
then
-- Find body of parent of spec, and analyze it. A special case arises
-- when the parent is an instantiation, that is to say when we are
-- currently instantiating a nested generic. In that case, there is
-- no separate file for the body of the enclosing instance. Instead,
-- the enclosing body must be instantiated as if it were a pending
-- instantiation, in order to produce the body for the nested generic
-- we require now. Note that in that case the generic may be defined
-- in a package body, the instance defined in the same package body,
-- and the original enclosing body may not be in the main unit.
Inst_Node := Empty;
True_Parent := Parent (Spec);
while Present (True_Parent)
and then Nkind (True_Parent) /= N_Compilation_Unit
loop
if Nkind (True_Parent) = N_Package_Declaration
and then
Nkind (Original_Node (True_Parent)) = N_Package_Instantiation
then
-- Parent is a compilation unit that is an instantiation.
-- Instantiation node has been replaced with package decl.
Inst_Node := Original_Node (True_Parent);
exit;
elsif Nkind (True_Parent) = N_Package_Declaration
and then Present (Generic_Parent (Specification (True_Parent)))
and then Nkind (Parent (True_Parent)) /= N_Compilation_Unit
then
-- Parent is an instantiation within another specification.
-- Declaration for instance has been inserted before original
-- instantiation node. A direct link would be preferable?
Inst_Node := Next (True_Parent);
while Present (Inst_Node)
and then Nkind (Inst_Node) /= N_Package_Instantiation
loop
Next (Inst_Node);
end loop;
-- If the instance appears within a generic, and the generic
-- unit is defined within a formal package of the enclosing
-- generic, there is no generic body available, and none
-- needed. A more precise test should be used ???
if No (Inst_Node) then
return;
end if;
exit;
else
True_Parent := Parent (True_Parent);
end if;
end loop;
-- Case where we are currently instantiating a nested generic
if Present (Inst_Node) then
if Nkind (Parent (True_Parent)) = N_Compilation_Unit then
-- Instantiation node and declaration of instantiated package
-- were exchanged when only the declaration was needed.
-- Restore instantiation node before proceeding with body.
Set_Unit (Parent (True_Parent), Inst_Node);
end if;
-- Now complete instantiation of enclosing body, if it appears in
-- some other unit. If it appears in the current unit, the body
-- will have been instantiated already.
if No (Corresponding_Body (Instance_Spec (Inst_Node))) then
-- We need to determine the expander mode to instantiate the
-- enclosing body. Because the generic body we need may use
-- global entities declared in the enclosing package (including
-- aggregates) it is in general necessary to compile this body
-- with expansion enabled, except if we are within a generic
-- package, in which case the usual generic rule applies.
declare
Exp_Status : Boolean := True;
Scop : Entity_Id;
begin
-- Loop through scopes looking for generic package
Scop := Scope (Defining_Entity (Instance_Spec (Inst_Node)));
while Present (Scop)
and then Scop /= Standard_Standard
loop
if Ekind (Scop) = E_Generic_Package then
Exp_Status := False;
exit;
end if;
Scop := Scope (Scop);
end loop;
-- Collect previous instantiations in the unit that contains
-- the desired generic.
if Nkind (Parent (True_Parent)) /= N_Compilation_Unit
and then not Body_Optional
then
declare
Decl : Elmt_Id;
Info : Pending_Body_Info;
Par : Node_Id;
begin
Par := Parent (Inst_Node);
while Present (Par) loop
exit when Nkind (Parent (Par)) = N_Compilation_Unit;
Par := Parent (Par);
end loop;
pragma Assert (Present (Par));
if Nkind (Par) = N_Package_Body then
Collect_Previous_Instances (Declarations (Par));
elsif Nkind (Par) = N_Package_Declaration then
Collect_Previous_Instances
(Visible_Declarations (Specification (Par)));
Collect_Previous_Instances
(Private_Declarations (Specification (Par)));
else
-- Enclosing unit is a subprogram body. In this
-- case all instance bodies are processed in order
-- and there is no need to collect them separately.
null;
end if;
Decl := First_Elmt (Previous_Instances);
while Present (Decl) loop
Info :=
(Inst_Node => Node (Decl),
Act_Decl =>
Instance_Spec (Node (Decl)),
Expander_Status => Exp_Status,
Current_Sem_Unit =>
Get_Code_Unit (Sloc (Node (Decl))),
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top =>
Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma);
-- Package instance
if
Nkind (Node (Decl)) = N_Package_Instantiation
then
Instantiate_Package_Body
(Info, Body_Optional => True);
-- Subprogram instance
else
-- The instance_spec is the wrapper package,
-- and the subprogram declaration is the last
-- declaration in the wrapper.
Info.Act_Decl :=
Last
(Visible_Declarations
(Specification (Info.Act_Decl)));
Instantiate_Subprogram_Body
(Info, Body_Optional => True);
end if;
Next_Elmt (Decl);
end loop;
end;
end if;
Instantiate_Package_Body
(Body_Info =>
((Inst_Node => Inst_Node,
Act_Decl => True_Parent,
Expander_Status => Exp_Status,
Current_Sem_Unit => Get_Code_Unit
(Sloc (Inst_Node)),
Scope_Suppress => Scope_Suppress,
Local_Suppress_Stack_Top => Local_Suppress_Stack_Top,
Version => Ada_Version,
Version_Pragma => Ada_Version_Pragma,
Warnings => Save_Warnings,
SPARK_Mode => SPARK_Mode,
SPARK_Mode_Pragma => SPARK_Mode_Pragma)),
Body_Optional => Body_Optional);
end;
end if;
-- Case where we are not instantiating a nested generic
else
Opt.Style_Check := False;
Expander_Mode_Save_And_Set (True);
Load_Needed_Body (Comp_Unit, OK);
Opt.Style_Check := Saved_Style_Check;
Restore_Warnings (Saved_Warnings);
Expander_Mode_Restore;
if not OK
and then Unit_Requires_Body (Defining_Entity (Spec))
and then not Body_Optional
then
declare
Bname : constant Unit_Name_Type :=
Get_Body_Name (Get_Unit_Name (Unit (Comp_Unit)));
begin
-- In CodePeer mode, the missing body may make the analysis
-- incomplete, but we do not treat it as fatal.
if CodePeer_Mode then
return;
else
Error_Msg_Unit_1 := Bname;
Error_Msg_N ("this instantiation requires$!", N);
Error_Msg_File_1 :=
Get_File_Name (Bname, Subunit => False);
Error_Msg_N ("\but file{ was not found!", N);
raise Unrecoverable_Error;
end if;
end;
end if;
end if;
end if;
-- If loading parent of the generic caused an instantiation circularity,
-- we abandon compilation at this point, because otherwise in some cases
-- we get into trouble with infinite recursions after this point.
if Circularity_Detected then
raise Unrecoverable_Error;
end if;
end Load_Parent_Of_Generic;
---------------------------------
-- Map_Formal_Package_Entities --
---------------------------------
procedure Map_Formal_Package_Entities (Form : Entity_Id; Act : Entity_Id) is
E1 : Entity_Id;
E2 : Entity_Id;
begin
Set_Instance_Of (Form, Act);
-- Traverse formal and actual package to map the corresponding entities.
-- We skip over internal entities that may be generated during semantic
-- analysis, and find the matching entities by name, given that they
-- must appear in the same order.
E1 := First_Entity (Form);
E2 := First_Entity (Act);
while Present (E1) and then E1 /= First_Private_Entity (Form) loop
-- Could this test be a single condition??? Seems like it could, and
-- isn't FPE (Form) a constant anyway???
if not Is_Internal (E1)
and then Present (Parent (E1))
and then not Is_Class_Wide_Type (E1)
and then not Is_Internal_Name (Chars (E1))
then
while Present (E2) and then Chars (E2) /= Chars (E1) loop
Next_Entity (E2);
end loop;
if No (E2) then
exit;
else
Set_Instance_Of (E1, E2);
if Is_Type (E1) and then Is_Tagged_Type (E2) then
Set_Instance_Of (Class_Wide_Type (E1), Class_Wide_Type (E2));
end if;
if Is_Constrained (E1) then
Set_Instance_Of (Base_Type (E1), Base_Type (E2));
end if;
if Ekind (E1) = E_Package and then No (Renamed_Object (E1)) then
Map_Formal_Package_Entities (E1, E2);
end if;
end if;
end if;
Next_Entity (E1);
end loop;
end Map_Formal_Package_Entities;
-----------------------
-- Move_Freeze_Nodes --
-----------------------
procedure Move_Freeze_Nodes
(Out_Of : Entity_Id;
After : Node_Id;
L : List_Id)
is
Decl : Node_Id;
Next_Decl : Node_Id;
Next_Node : Node_Id := After;
Spec : Node_Id;
function Is_Outer_Type (T : Entity_Id) return Boolean;
-- Check whether entity is declared in a scope external to that of the
-- generic unit.
-------------------
-- Is_Outer_Type --
-------------------
function Is_Outer_Type (T : Entity_Id) return Boolean is
Scop : Entity_Id := Scope (T);
begin
if Scope_Depth (Scop) < Scope_Depth (Out_Of) then
return True;
else
while Scop /= Standard_Standard loop
if Scop = Out_Of then
return False;
else
Scop := Scope (Scop);
end if;
end loop;
return True;
end if;
end Is_Outer_Type;
-- Start of processing for Move_Freeze_Nodes
begin
if No (L) then
return;
end if;
-- First remove the freeze nodes that may appear before all other
-- declarations.
Decl := First (L);
while Present (Decl)
and then Nkind (Decl) = N_Freeze_Entity
and then Is_Outer_Type (Entity (Decl))
loop
Decl := Remove_Head (L);
Insert_After (Next_Node, Decl);
Set_Analyzed (Decl, False);
Next_Node := Decl;
Decl := First (L);
end loop;
-- Next scan the list of declarations and remove each freeze node that
-- appears ahead of the current node.
while Present (Decl) loop
while Present (Next (Decl))
and then Nkind (Next (Decl)) = N_Freeze_Entity
and then Is_Outer_Type (Entity (Next (Decl)))
loop
Next_Decl := Remove_Next (Decl);
Insert_After (Next_Node, Next_Decl);
Set_Analyzed (Next_Decl, False);
Next_Node := Next_Decl;
end loop;
-- If the declaration is a nested package or concurrent type, then
-- recurse. Nested generic packages will have been processed from the
-- inside out.
case Nkind (Decl) is
when N_Package_Declaration =>
Spec := Specification (Decl);
when N_Task_Type_Declaration =>
Spec := Task_Definition (Decl);
when N_Protected_Type_Declaration =>
Spec := Protected_Definition (Decl);
when others =>
Spec := Empty;
end case;
if Present (Spec) then
Move_Freeze_Nodes (Out_Of, Next_Node, Visible_Declarations (Spec));
Move_Freeze_Nodes (Out_Of, Next_Node, Private_Declarations (Spec));
end if;
Next (Decl);
end loop;
end Move_Freeze_Nodes;
----------------
-- Next_Assoc --
----------------
function Next_Assoc (E : Assoc_Ptr) return Assoc_Ptr is
begin
return Generic_Renamings.Table (E).Next_In_HTable;
end Next_Assoc;
------------------------
-- Preanalyze_Actuals --
------------------------
procedure Preanalyze_Actuals (N : Node_Id) is
Assoc : Node_Id;
Act : Node_Id;
Errs : constant Int := Serious_Errors_Detected;
Cur : Entity_Id := Empty;
-- Current homograph of the instance name
Vis : Boolean;
-- Saved visibility status of the current homograph
begin
Assoc := First (Generic_Associations (N));
-- If the instance is a child unit, its name may hide an outer homonym,
-- so make it invisible to perform name resolution on the actuals.
if Nkind (Defining_Unit_Name (N)) = N_Defining_Program_Unit_Name
and then Present
(Current_Entity (Defining_Identifier (Defining_Unit_Name (N))))
then
Cur := Current_Entity (Defining_Identifier (Defining_Unit_Name (N)));
if Is_Compilation_Unit (Cur) then
Vis := Is_Immediately_Visible (Cur);
Set_Is_Immediately_Visible (Cur, False);
else
Cur := Empty;
end if;
end if;
while Present (Assoc) loop
if Nkind (Assoc) /= N_Others_Choice then
Act := Explicit_Generic_Actual_Parameter (Assoc);
-- Within a nested instantiation, a defaulted actual is an empty
-- association, so nothing to analyze. If the subprogram actual
-- is an attribute, analyze prefix only, because actual is not a
-- complete attribute reference.
-- If actual is an allocator, analyze expression only. The full
-- analysis can generate code, and if instance is a compilation
-- unit we have to wait until the package instance is installed
-- to have a proper place to insert this code.
-- String literals may be operators, but at this point we do not
-- know whether the actual is a formal subprogram or a string.
if No (Act) then
null;
elsif Nkind (Act) = N_Attribute_Reference then
Analyze (Prefix (Act));
elsif Nkind (Act) = N_Explicit_Dereference then
Analyze (Prefix (Act));
elsif Nkind (Act) = N_Allocator then
declare
Expr : constant Node_Id := Expression (Act);
begin
if Nkind (Expr) = N_Subtype_Indication then
Analyze (Subtype_Mark (Expr));
-- Analyze separately each discriminant constraint, when
-- given with a named association.
declare
Constr : Node_Id;
begin
Constr := First (Constraints (Constraint (Expr)));
while Present (Constr) loop
if Nkind (Constr) = N_Discriminant_Association then
Analyze (Expression (Constr));
else
Analyze (Constr);
end if;
Next (Constr);
end loop;
end;
else
Analyze (Expr);
end if;
end;
elsif Nkind (Act) /= N_Operator_Symbol then
Analyze (Act);
end if;
-- Ensure that a ghost subprogram does not act as generic actual
if Is_Entity_Name (Act)
and then Is_Ghost_Subprogram (Entity (Act))
then
Error_Msg_N
("ghost subprogram & cannot act as generic actual", Act);
Abandon_Instantiation (Act);
elsif Errs /= Serious_Errors_Detected then
-- Do a minimal analysis of the generic, to prevent spurious
-- warnings complaining about the generic being unreferenced,
-- before abandoning the instantiation.
Analyze (Name (N));
if Is_Entity_Name (Name (N))
and then Etype (Name (N)) /= Any_Type
then
Generate_Reference (Entity (Name (N)), Name (N));
Set_Is_Instantiated (Entity (Name (N)));
end if;
if Present (Cur) then
-- For the case of a child instance hiding an outer homonym,
-- provide additional warning which might explain the error.
Set_Is_Immediately_Visible (Cur, Vis);
Error_Msg_NE ("& hides outer unit with the same name??",
N, Defining_Unit_Name (N));
end if;
Abandon_Instantiation (Act);
end if;
end if;
Next (Assoc);
end loop;
if Present (Cur) then
Set_Is_Immediately_Visible (Cur, Vis);
end if;
end Preanalyze_Actuals;
-------------------
-- Remove_Parent --
-------------------
procedure Remove_Parent (In_Body : Boolean := False) is
S : Entity_Id := Current_Scope;
-- S is the scope containing the instantiation just completed. The scope
-- stack contains the parent instances of the instantiation, followed by
-- the original S.
Cur_P : Entity_Id;
E : Entity_Id;
P : Entity_Id;
Hidden : Elmt_Id;
begin
-- After child instantiation is complete, remove from scope stack the
-- extra copy of the current scope, and then remove parent instances.
if not In_Body then
Pop_Scope;
while Current_Scope /= S loop
P := Current_Scope;
End_Package_Scope (Current_Scope);
if In_Open_Scopes (P) then
E := First_Entity (P);
while Present (E) loop
Set_Is_Immediately_Visible (E, True);
Next_Entity (E);
end loop;
-- If instantiation is declared in a block, it is the enclosing
-- scope that might be a parent instance. Note that only one
-- block can be involved, because the parent instances have
-- been installed within it.
if Ekind (P) = E_Block then
Cur_P := Scope (P);
else
Cur_P := P;
end if;
if Is_Generic_Instance (Cur_P) and then P /= Current_Scope then
-- We are within an instance of some sibling. Retain
-- visibility of parent, for proper subsequent cleanup, and
-- reinstall private declarations as well.
Set_In_Private_Part (P);
Install_Private_Declarations (P);
end if;
-- If the ultimate parent is a top-level unit recorded in
-- Instance_Parent_Unit, then reset its visibility to what it was
-- before instantiation. (It's not clear what the purpose is of
-- testing whether Scope (P) is In_Open_Scopes, but that test was
-- present before the ultimate parent test was added.???)
elsif not In_Open_Scopes (Scope (P))
or else (P = Instance_Parent_Unit
and then not Parent_Unit_Visible)
then
Set_Is_Immediately_Visible (P, False);
-- If the current scope is itself an instantiation of a generic
-- nested within P, and we are in the private part of body of this
-- instantiation, restore the full views of P, that were removed
-- in End_Package_Scope above. This obscure case can occur when a
-- subunit of a generic contains an instance of a child unit of
-- its generic parent unit.
elsif S = Current_Scope and then Is_Generic_Instance (S) then
declare
Par : constant Entity_Id :=
Generic_Parent (Package_Specification (S));
begin
if Present (Par)
and then P = Scope (Par)
and then (In_Package_Body (S) or else In_Private_Part (S))
then
Set_In_Private_Part (P);
Install_Private_Declarations (P);
end if;
end;
end if;
end loop;
-- Reset visibility of entities in the enclosing scope
Set_Is_Hidden_Open_Scope (Current_Scope, False);
Hidden := First_Elmt (Hidden_Entities);
while Present (Hidden) loop
Set_Is_Immediately_Visible (Node (Hidden), True);
Next_Elmt (Hidden);
end loop;
else
-- Each body is analyzed separately, and there is no context that
-- needs preserving from one body instance to the next, so remove all
-- parent scopes that have been installed.
while Present (S) loop
End_Package_Scope (S);
Set_Is_Immediately_Visible (S, False);
S := Current_Scope;
exit when S = Standard_Standard;
end loop;
end if;
end Remove_Parent;
-----------------
-- Restore_Env --
-----------------
procedure Restore_Env is
Saved : Instance_Env renames Instance_Envs.Table (Instance_Envs.Last);
begin
if No (Current_Instantiated_Parent.Act_Id) then
-- Restore environment after subprogram inlining
Restore_Private_Views (Empty);
end if;
Current_Instantiated_Parent := Saved.Instantiated_Parent;
Exchanged_Views := Saved.Exchanged_Views;
Hidden_Entities := Saved.Hidden_Entities;
Current_Sem_Unit := Saved.Current_Sem_Unit;
Parent_Unit_Visible := Saved.Parent_Unit_Visible;
Instance_Parent_Unit := Saved.Instance_Parent_Unit;
Restore_Opt_Config_Switches (Saved.Switches);
Instance_Envs.Decrement_Last;
end Restore_Env;
---------------------------
-- Restore_Private_Views --
---------------------------
procedure Restore_Private_Views
(Pack_Id : Entity_Id;
Is_Package : Boolean := True)
is
M : Elmt_Id;
E : Entity_Id;
Typ : Entity_Id;
Dep_Elmt : Elmt_Id;
Dep_Typ : Node_Id;
procedure Restore_Nested_Formal (Formal : Entity_Id);
-- Hide the generic formals of formal packages declared with box which
-- were reachable in the current instantiation.
---------------------------
-- Restore_Nested_Formal --
---------------------------
procedure Restore_Nested_Formal (Formal : Entity_Id) is
Ent : Entity_Id;
begin
if Present (Renamed_Object (Formal))
and then Denotes_Formal_Package (Renamed_Object (Formal), True)
then
return;
elsif Present (Associated_Formal_Package (Formal)) then
Ent := First_Entity (Formal);
while Present (Ent) loop
exit when Ekind (Ent) = E_Package
and then Renamed_Entity (Ent) = Renamed_Entity (Formal);
Set_Is_Hidden (Ent);
Set_Is_Potentially_Use_Visible (Ent, False);
-- If package, then recurse
if Ekind (Ent) = E_Package then
Restore_Nested_Formal (Ent);
end if;
Next_Entity (Ent);
end loop;
end if;
end Restore_Nested_Formal;
-- Start of processing for Restore_Private_Views
begin
M := First_Elmt (Exchanged_Views);
while Present (M) loop
Typ := Node (M);
-- Subtypes of types whose views have been exchanged, and that are
-- defined within the instance, were not on the Private_Dependents
-- list on entry to the instance, so they have to be exchanged
-- explicitly now, in order to remain consistent with the view of the
-- parent type.
if Ekind_In (Typ, E_Private_Type,
E_Limited_Private_Type,
E_Record_Type_With_Private)
then
Dep_Elmt := First_Elmt (Private_Dependents (Typ));
while Present (Dep_Elmt) loop
Dep_Typ := Node (Dep_Elmt);
if Scope (Dep_Typ) = Pack_Id
and then Present (Full_View (Dep_Typ))
then
Replace_Elmt (Dep_Elmt, Full_View (Dep_Typ));
Exchange_Declarations (Dep_Typ);
end if;
Next_Elmt (Dep_Elmt);
end loop;
end if;
Exchange_Declarations (Node (M));
Next_Elmt (M);
end loop;
if No (Pack_Id) then
return;
end if;
-- Make the generic formal parameters private, and make the formal types
-- into subtypes of the actuals again.
E := First_Entity (Pack_Id);
while Present (E) loop
Set_Is_Hidden (E, True);
if Is_Type (E)
and then Nkind (Parent (E)) = N_Subtype_Declaration
then
-- If the actual for E is itself a generic actual type from
-- an enclosing instance, E is still a generic actual type
-- outside of the current instance. This matter when resolving
-- an overloaded call that may be ambiguous in the enclosing
-- instance, when two of its actuals coincide.
if Is_Entity_Name (Subtype_Indication (Parent (E)))
and then Is_Generic_Actual_Type
(Entity (Subtype_Indication (Parent (E))))
then
null;
else
Set_Is_Generic_Actual_Type (E, False);
end if;
-- An unusual case of aliasing: the actual may also be directly
-- visible in the generic, and be private there, while it is fully
-- visible in the context of the instance. The internal subtype
-- is private in the instance but has full visibility like its
-- parent in the enclosing scope. This enforces the invariant that
-- the privacy status of all private dependents of a type coincide
-- with that of the parent type. This can only happen when a
-- generic child unit is instantiated within a sibling.
if Is_Private_Type (E)
and then not Is_Private_Type (Etype (E))
then
Exchange_Declarations (E);
end if;
elsif Ekind (E) = E_Package then
-- The end of the renaming list is the renaming of the generic
-- package itself. If the instance is a subprogram, all entities
-- in the corresponding package are renamings. If this entity is
-- a formal package, make its own formals private as well. The
-- actual in this case is itself the renaming of an instantiation.
-- If the entity is not a package renaming, it is the entity
-- created to validate formal package actuals: ignore it.
-- If the actual is itself a formal package for the enclosing
-- generic, or the actual for such a formal package, it remains
-- visible on exit from the instance, and therefore nothing needs
-- to be done either, except to keep it accessible.
if Is_Package and then Renamed_Object (E) = Pack_Id then
exit;
elsif Nkind (Parent (E)) /= N_Package_Renaming_Declaration then
null;
elsif
Denotes_Formal_Package (Renamed_Object (E), True, Pack_Id)
then
Set_Is_Hidden (E, False);
else
declare
Act_P : constant Entity_Id := Renamed_Object (E);
Id : Entity_Id;
begin
Id := First_Entity (Act_P);
while Present (Id)
and then Id /= First_Private_Entity (Act_P)
loop
exit when Ekind (Id) = E_Package
and then Renamed_Object (Id) = Act_P;
Set_Is_Hidden (Id, True);
Set_Is_Potentially_Use_Visible (Id, In_Use (Act_P));
if Ekind (Id) = E_Package then
Restore_Nested_Formal (Id);
end if;
Next_Entity (Id);
end loop;
end;
end if;
end if;
Next_Entity (E);
end loop;
end Restore_Private_Views;
--------------
-- Save_Env --
--------------
procedure Save_Env
(Gen_Unit : Entity_Id;
Act_Unit : Entity_Id)
is
begin
Init_Env;
Set_Instance_Env (Gen_Unit, Act_Unit);
end Save_Env;
----------------------------
-- Save_Global_References --
----------------------------
procedure Save_Global_References (N : Node_Id) is
Gen_Scope : Entity_Id;
E : Entity_Id;
N2 : Node_Id;
function Is_Global (E : Entity_Id) return Boolean;
-- Check whether entity is defined outside of generic unit. Examine the
-- scope of an entity, and the scope of the scope, etc, until we find
-- either Standard, in which case the entity is global, or the generic
-- unit itself, which indicates that the entity is local. If the entity
-- is the generic unit itself, as in the case of a recursive call, or
-- the enclosing generic unit, if different from the current scope, then
-- it is local as well, because it will be replaced at the point of
-- instantiation. On the other hand, if it is a reference to a child
-- unit of a common ancestor, which appears in an instantiation, it is
-- global because it is used to denote a specific compilation unit at
-- the time the instantiations will be analyzed.
procedure Reset_Entity (N : Node_Id);
-- Save semantic information on global entity so that it is not resolved
-- again at instantiation time.
procedure Save_Entity_Descendants (N : Node_Id);
-- Apply Save_Global_References to the two syntactic descendants of
-- non-terminal nodes that carry an Associated_Node and are processed
-- through Reset_Entity. Once the global entity (if any) has been
-- captured together with its type, only two syntactic descendants need
-- to be traversed to complete the processing of the tree rooted at N.
-- This applies to Selected_Components, Expanded_Names, and to Operator
-- nodes. N can also be a character literal, identifier, or operator
-- symbol node, but the call has no effect in these cases.
procedure Save_Global_Defaults (N1, N2 : Node_Id);
-- Default actuals in nested instances must be handled specially
-- because there is no link to them from the original tree. When an
-- actual subprogram is given by a default, we add an explicit generic
-- association for it in the instantiation node. When we save the
-- global references on the name of the instance, we recover the list
-- of generic associations, and add an explicit one to the original
-- generic tree, through which a global actual can be preserved.
-- Similarly, if a child unit is instantiated within a sibling, in the
-- context of the parent, we must preserve the identifier of the parent
-- so that it can be properly resolved in a subsequent instantiation.
procedure Save_Global_Descendant (D : Union_Id);
-- Apply Save_Global_References recursively to the descendents of the
-- current node.
procedure Save_References (N : Node_Id);
-- This is the recursive procedure that does the work, once the
-- enclosing generic scope has been established.
---------------
-- Is_Global --
---------------
function Is_Global (E : Entity_Id) return Boolean is
Se : Entity_Id;
function Is_Instance_Node (Decl : Node_Id) return Boolean;
-- Determine whether the parent node of a reference to a child unit
-- denotes an instantiation or a formal package, in which case the
-- reference to the child unit is global, even if it appears within
-- the current scope (e.g. when the instance appears within the body
-- of an ancestor).
----------------------
-- Is_Instance_Node --
----------------------
function Is_Instance_Node (Decl : Node_Id) return Boolean is
begin
return Nkind (Decl) in N_Generic_Instantiation
or else
Nkind (Original_Node (Decl)) = N_Formal_Package_Declaration;
end Is_Instance_Node;
-- Start of processing for Is_Global
begin
if E = Gen_Scope then
return False;
elsif E = Standard_Standard then
return True;
elsif Is_Child_Unit (E)
and then (Is_Instance_Node (Parent (N2))
or else (Nkind (Parent (N2)) = N_Expanded_Name
and then N2 = Selector_Name (Parent (N2))
and then
Is_Instance_Node (Parent (Parent (N2)))))
then
return True;
else
Se := Scope (E);
while Se /= Gen_Scope loop
if Se = Standard_Standard then
return True;
else
Se := Scope (Se);
end if;
end loop;
return False;
end if;
end Is_Global;
------------------
-- Reset_Entity --
------------------
procedure Reset_Entity (N : Node_Id) is
procedure Set_Global_Type (N : Node_Id; N2 : Node_Id);
-- If the type of N2 is global to the generic unit, save the type in
-- the generic node. Just as we perform name capture for explicit
-- references within the generic, we must capture the global types
-- of local entities because they may participate in resolution in
-- the instance.
function Top_Ancestor (E : Entity_Id) return Entity_Id;
-- Find the ultimate ancestor of the current unit. If it is not a
-- generic unit, then the name of the current unit in the prefix of
-- an expanded name must be replaced with its generic homonym to
-- ensure that it will be properly resolved in an instance.
---------------------
-- Set_Global_Type --
---------------------
procedure Set_Global_Type (N : Node_Id; N2 : Node_Id) is
Typ : constant Entity_Id := Etype (N2);
begin
Set_Etype (N, Typ);
if Entity (N) /= N2
and then Has_Private_View (Entity (N))
then
-- If the entity of N is not the associated node, this is a
-- nested generic and it has an associated node as well, whose
-- type is already the full view (see below). Indicate that the
-- original node has a private view.
Set_Has_Private_View (N);
end if;
-- If not a private type, nothing else to do
if not Is_Private_Type (Typ) then
if Is_Array_Type (Typ)
and then Is_Private_Type (Component_Type (Typ))
then
Set_Has_Private_View (N);
end if;
-- If it is a derivation of a private type in a context where no
-- full view is needed, nothing to do either.
elsif No (Full_View (Typ)) and then Typ /= Etype (Typ) then
null;
-- Otherwise mark the type for flipping and use the full view when
-- available.
else
Set_Has_Private_View (N);
if Present (Full_View (Typ)) then
Set_Etype (N2, Full_View (Typ));
end if;
end if;
end Set_Global_Type;
------------------
-- Top_Ancestor --
------------------
function Top_Ancestor (E : Entity_Id) return Entity_Id is
Par : Entity_Id;
begin
Par := E;
while Is_Child_Unit (Par) loop
Par := Scope (Par);
end loop;
return Par;
end Top_Ancestor;
-- Start of processing for Reset_Entity
begin
N2 := Get_Associated_Node (N);
E := Entity (N2);
if Present (E) then
-- If the node is an entry call to an entry in an enclosing task,
-- it is rewritten as a selected component. No global entity to
-- preserve in this case, since the expansion will be redone in
-- the instance.
if not Nkind_In (E, N_Defining_Identifier,
N_Defining_Character_Literal,
N_Defining_Operator_Symbol)
then
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
return;
end if;
-- If the entity is an itype created as a subtype of an access
-- type with a null exclusion restore source entity for proper
-- visibility. The itype will be created anew in the instance.
if Is_Itype (E)
and then Ekind (E) = E_Access_Subtype
and then Is_Entity_Name (N)
and then Chars (Etype (E)) = Chars (N)
then
E := Etype (E);
Set_Entity (N2, E);
Set_Etype (N2, E);
end if;
if Is_Global (E) then
-- If the entity is a package renaming that is the prefix of
-- an expanded name, it has been rewritten as the renamed
-- package, which is necessary semantically but complicates
-- ASIS tree traversal, so we recover the original entity to
-- expose the renaming. Take into account that the context may
-- be a nested generic, that the original node may itself have
-- an associated node that had better be an entity, and that
-- the current node is still a selected component.
if Ekind (E) = E_Package
and then Nkind (N) = N_Selected_Component
and then Nkind (Parent (N)) = N_Expanded_Name
and then Present (Original_Node (N2))
and then Is_Entity_Name (Original_Node (N2))
and then Present (Entity (Original_Node (N2)))
then
if Is_Global (Entity (Original_Node (N2))) then
N2 := Original_Node (N2);
Set_Associated_Node (N, N2);
Set_Global_Type (N, N2);
else
-- Renaming is local, and will be resolved in instance
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
else
Set_Global_Type (N, N2);
end if;
elsif Nkind (N) = N_Op_Concat
and then Is_Generic_Type (Etype (N2))
and then (Base_Type (Etype (Right_Opnd (N2))) = Etype (N2)
or else
Base_Type (Etype (Left_Opnd (N2))) = Etype (N2))
and then Is_Intrinsic_Subprogram (E)
then
null;
else
-- Entity is local. Mark generic node as unresolved.
-- Note that now it does not have an entity.
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
if Nkind (Parent (N)) in N_Generic_Instantiation
and then N = Name (Parent (N))
then
Save_Global_Defaults (Parent (N), Parent (N2));
end if;
elsif Nkind (Parent (N)) = N_Selected_Component
and then Nkind (Parent (N2)) = N_Expanded_Name
then
if Is_Global (Entity (Parent (N2))) then
Change_Selected_Component_To_Expanded_Name (Parent (N));
Set_Associated_Node (Parent (N), Parent (N2));
Set_Global_Type (Parent (N), Parent (N2));
Save_Entity_Descendants (N);
-- If this is a reference to the current generic entity, replace
-- by the name of the generic homonym of the current package. This
-- is because in an instantiation Par.P.Q will not resolve to the
-- name of the instance, whose enclosing scope is not necessarily
-- Par. We use the generic homonym rather that the name of the
-- generic itself because it may be hidden by a local declaration.
elsif In_Open_Scopes (Entity (Parent (N2)))
and then not
Is_Generic_Unit (Top_Ancestor (Entity (Prefix (Parent (N2)))))
then
if Ekind (Entity (Parent (N2))) = E_Generic_Package then
Rewrite (Parent (N),
Make_Identifier (Sloc (N),
Chars =>
Chars (Generic_Homonym (Entity (Parent (N2))))));
else
Rewrite (Parent (N),
Make_Identifier (Sloc (N),
Chars => Chars (Selector_Name (Parent (N2)))));
end if;
end if;
if Nkind (Parent (Parent (N))) in N_Generic_Instantiation
and then Parent (N) = Name (Parent (Parent (N)))
then
Save_Global_Defaults
(Parent (Parent (N)), Parent (Parent ((N2))));
end if;
-- A selected component may denote a static constant that has been
-- folded. If the static constant is global to the generic, capture
-- its value. Otherwise the folding will happen in any instantiation.
elsif Nkind (Parent (N)) = N_Selected_Component
and then Nkind_In (Parent (N2), N_Integer_Literal, N_Real_Literal)
then
if Present (Entity (Original_Node (Parent (N2))))
and then Is_Global (Entity (Original_Node (Parent (N2))))
then
Rewrite (Parent (N), New_Copy (Parent (N2)));
Set_Analyzed (Parent (N), False);
else
null;
end if;
-- A selected component may be transformed into a parameterless
-- function call. If the called entity is global, rewrite the node
-- appropriately, i.e. as an extended name for the global entity.
elsif Nkind (Parent (N)) = N_Selected_Component
and then Nkind (Parent (N2)) = N_Function_Call
and then N = Selector_Name (Parent (N))
then
if No (Parameter_Associations (Parent (N2))) then
if Is_Global (Entity (Name (Parent (N2)))) then
Change_Selected_Component_To_Expanded_Name (Parent (N));
Set_Associated_Node (Parent (N), Name (Parent (N2)));
Set_Global_Type (Parent (N), Name (Parent (N2)));
Save_Entity_Descendants (N);
else
Set_Is_Prefixed_Call (Parent (N));
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
-- In Ada 2005, X.F may be a call to a primitive operation,
-- rewritten as F (X). This rewriting will be done again in an
-- instance, so keep the original node. Global entities will be
-- captured as for other constructs. Indicate that this must
-- resolve as a call, to prevent accidental overloading in the
-- instance, if both a component and a primitive operation appear
-- as candidates.
else
Set_Is_Prefixed_Call (Parent (N));
end if;
-- Entity is local. Reset in generic unit, so that node is resolved
-- anew at the point of instantiation.
else
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
end Reset_Entity;
-----------------------------
-- Save_Entity_Descendants --
-----------------------------
procedure Save_Entity_Descendants (N : Node_Id) is
begin
case Nkind (N) is
when N_Binary_Op =>
Save_Global_Descendant (Union_Id (Left_Opnd (N)));
Save_Global_Descendant (Union_Id (Right_Opnd (N)));
when N_Unary_Op =>
Save_Global_Descendant (Union_Id (Right_Opnd (N)));
when N_Expanded_Name | N_Selected_Component =>
Save_Global_Descendant (Union_Id (Prefix (N)));
Save_Global_Descendant (Union_Id (Selector_Name (N)));
when N_Identifier | N_Character_Literal | N_Operator_Symbol =>
null;
when others =>
raise Program_Error;
end case;
end Save_Entity_Descendants;
--------------------------
-- Save_Global_Defaults --
--------------------------
procedure Save_Global_Defaults (N1, N2 : Node_Id) is
Loc : constant Source_Ptr := Sloc (N1);
Assoc2 : constant List_Id := Generic_Associations (N2);
Gen_Id : constant Entity_Id := Get_Generic_Entity (N2);
Assoc1 : List_Id;
Act1 : Node_Id;
Act2 : Node_Id;
Def : Node_Id;
Ndec : Node_Id;
Subp : Entity_Id;
Actual : Entity_Id;
begin
Assoc1 := Generic_Associations (N1);
if Present (Assoc1) then
Act1 := First (Assoc1);
else
Act1 := Empty;
Set_Generic_Associations (N1, New_List);
Assoc1 := Generic_Associations (N1);
end if;
if Present (Assoc2) then
Act2 := First (Assoc2);
else
return;
end if;
while Present (Act1) and then Present (Act2) loop
Next (Act1);
Next (Act2);
end loop;
-- Find the associations added for default subprograms
if Present (Act2) then
while Nkind (Act2) /= N_Generic_Association
or else No (Entity (Selector_Name (Act2)))
or else not Is_Overloadable (Entity (Selector_Name (Act2)))
loop
Next (Act2);
end loop;
-- Add a similar association if the default is global. The
-- renaming declaration for the actual has been analyzed, and
-- its alias is the program it renames. Link the actual in the
-- original generic tree with the node in the analyzed tree.
while Present (Act2) loop
Subp := Entity (Selector_Name (Act2));
Def := Explicit_Generic_Actual_Parameter (Act2);
-- Following test is defence against rubbish errors
if No (Alias (Subp)) then
return;
end if;
-- Retrieve the resolved actual from the renaming declaration
-- created for the instantiated formal.
Actual := Entity (Name (Parent (Parent (Subp))));
Set_Entity (Def, Actual);
Set_Etype (Def, Etype (Actual));
if Is_Global (Actual) then
Ndec :=
Make_Generic_Association (Loc,
Selector_Name => New_Occurrence_Of (Subp, Loc),
Explicit_Generic_Actual_Parameter =>
New_Occurrence_Of (Actual, Loc));
Set_Associated_Node
(Explicit_Generic_Actual_Parameter (Ndec), Def);
Append (Ndec, Assoc1);
-- If there are other defaults, add a dummy association in case
-- there are other defaulted formals with the same name.
elsif Present (Next (Act2)) then
Ndec :=
Make_Generic_Association (Loc,
Selector_Name => New_Occurrence_Of (Subp, Loc),
Explicit_Generic_Actual_Parameter => Empty);
Append (Ndec, Assoc1);
end if;
Next (Act2);
end loop;
end if;
if Nkind (Name (N1)) = N_Identifier
and then Is_Child_Unit (Gen_Id)
and then Is_Global (Gen_Id)
and then Is_Generic_Unit (Scope (Gen_Id))
and then In_Open_Scopes (Scope (Gen_Id))
then
-- This is an instantiation of a child unit within a sibling, so
-- that the generic parent is in scope. An eventual instance must
-- occur within the scope of an instance of the parent. Make name
-- in instance into an expanded name, to preserve the identifier
-- of the parent, so it can be resolved subsequently.
Rewrite (Name (N2),
Make_Expanded_Name (Loc,
Chars => Chars (Gen_Id),
Prefix => New_Occurrence_Of (Scope (Gen_Id), Loc),
Selector_Name => New_Occurrence_Of (Gen_Id, Loc)));
Set_Entity (Name (N2), Gen_Id);
Rewrite (Name (N1),
Make_Expanded_Name (Loc,
Chars => Chars (Gen_Id),
Prefix => New_Occurrence_Of (Scope (Gen_Id), Loc),
Selector_Name => New_Occurrence_Of (Gen_Id, Loc)));
Set_Associated_Node (Name (N1), Name (N2));
Set_Associated_Node (Prefix (Name (N1)), Empty);
Set_Associated_Node
(Selector_Name (Name (N1)), Selector_Name (Name (N2)));
Set_Etype (Name (N1), Etype (Gen_Id));
end if;
end Save_Global_Defaults;
----------------------------
-- Save_Global_Descendant --
----------------------------
procedure Save_Global_Descendant (D : Union_Id) is
N1 : Node_Id;
begin
if D in Node_Range then
if D = Union_Id (Empty) then
null;
elsif Nkind (Node_Id (D)) /= N_Compilation_Unit then
Save_References (Node_Id (D));
end if;
elsif D in List_Range then
if D = Union_Id (No_List)
or else Is_Empty_List (List_Id (D))
then
null;
else
N1 := First (List_Id (D));
while Present (N1) loop
Save_References (N1);
Next (N1);
end loop;
end if;
-- Element list or other non-node field, nothing to do
else
null;
end if;
end Save_Global_Descendant;
---------------------
-- Save_References --
---------------------
-- This is the recursive procedure that does the work once the enclosing
-- generic scope has been established. We have to treat specially a
-- number of node rewritings that are required by semantic processing
-- and which change the kind of nodes in the generic copy: typically
-- constant-folding, replacing an operator node by a string literal, or
-- a selected component by an expanded name. In each of those cases, the
-- transformation is propagated to the generic unit.
procedure Save_References (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
begin
if N = Empty then
null;
elsif Nkind_In (N, N_Character_Literal, N_Operator_Symbol) then
if Nkind (N) = Nkind (Get_Associated_Node (N)) then
Reset_Entity (N);
elsif Nkind (N) = N_Operator_Symbol
and then Nkind (Get_Associated_Node (N)) = N_String_Literal
then
Change_Operator_Symbol_To_String_Literal (N);
end if;
elsif Nkind (N) in N_Op then
if Nkind (N) = Nkind (Get_Associated_Node (N)) then
if Nkind (N) = N_Op_Concat then
Set_Is_Component_Left_Opnd (N,
Is_Component_Left_Opnd (Get_Associated_Node (N)));
Set_Is_Component_Right_Opnd (N,
Is_Component_Right_Opnd (Get_Associated_Node (N)));
end if;
Reset_Entity (N);
else
-- Node may be transformed into call to a user-defined operator
N2 := Get_Associated_Node (N);
if Nkind (N2) = N_Function_Call then
E := Entity (Name (N2));
if Present (E)
and then Is_Global (E)
then
Set_Etype (N, Etype (N2));
else
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
elsif Nkind_In (N2, N_Integer_Literal,
N_Real_Literal,
N_String_Literal)
then
if Present (Original_Node (N2))
and then Nkind (Original_Node (N2)) = Nkind (N)
then
-- Operation was constant-folded. Whenever possible,
-- recover semantic information from unfolded node,
-- for ASIS use.
Set_Associated_Node (N, Original_Node (N2));
if Nkind (N) = N_Op_Concat then
Set_Is_Component_Left_Opnd (N,
Is_Component_Left_Opnd (Get_Associated_Node (N)));
Set_Is_Component_Right_Opnd (N,
Is_Component_Right_Opnd (Get_Associated_Node (N)));
end if;
Reset_Entity (N);
else
-- If original node is already modified, propagate
-- constant-folding to template.
Rewrite (N, New_Copy (N2));
Set_Analyzed (N, False);
end if;
elsif Nkind (N2) = N_Identifier
and then Ekind (Entity (N2)) = E_Enumeration_Literal
then
-- Same if call was folded into a literal, but in this case
-- retain the entity to avoid spurious ambiguities if it is
-- overloaded at the point of instantiation or inlining.
Rewrite (N, New_Copy (N2));
Set_Analyzed (N, False);
end if;
end if;
-- Complete operands check if node has not been constant-folded
if Nkind (N) in N_Op then
Save_Entity_Descendants (N);
end if;
elsif Nkind (N) = N_Identifier then
if Nkind (N) = Nkind (Get_Associated_Node (N)) then
-- If this is a discriminant reference, always save it. It is
-- used in the instance to find the corresponding discriminant
-- positionally rather than by name.
Set_Original_Discriminant
(N, Original_Discriminant (Get_Associated_Node (N)));
Reset_Entity (N);
else
N2 := Get_Associated_Node (N);
if Nkind (N2) = N_Function_Call then
E := Entity (Name (N2));
-- Name resolves to a call to parameterless function. If
-- original entity is global, mark node as resolved.
if Present (E)
and then Is_Global (E)
then
Set_Etype (N, Etype (N2));
else
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
elsif Nkind_In (N2, N_Integer_Literal, N_Real_Literal)
and then Is_Entity_Name (Original_Node (N2))
then
-- Name resolves to named number that is constant-folded,
-- We must preserve the original name for ASIS use, and
-- undo the constant-folding, which will be repeated in
-- each instance.
Set_Associated_Node (N, Original_Node (N2));
Reset_Entity (N);
elsif Nkind (N2) = N_String_Literal then
-- Name resolves to string literal. Perform the same
-- replacement in generic.
Rewrite (N, New_Copy (N2));
elsif Nkind (N2) = N_Explicit_Dereference then
-- An identifier is rewritten as a dereference if it is the
-- prefix in an implicit dereference (call or attribute).
-- The analysis of an instantiation will expand the node
-- again, so we preserve the original tree but link it to
-- the resolved entity in case it is global.
if Is_Entity_Name (Prefix (N2))
and then Present (Entity (Prefix (N2)))
and then Is_Global (Entity (Prefix (N2)))
then
Set_Associated_Node (N, Prefix (N2));
elsif Nkind (Prefix (N2)) = N_Function_Call
and then Is_Global (Entity (Name (Prefix (N2))))
then
Rewrite (N,
Make_Explicit_Dereference (Loc,
Prefix => Make_Function_Call (Loc,
Name =>
New_Occurrence_Of (Entity (Name (Prefix (N2))),
Loc))));
else
Set_Associated_Node (N, Empty);
Set_Etype (N, Empty);
end if;
-- The subtype mark of a nominally unconstrained object is
-- rewritten as a subtype indication using the bounds of the
-- expression. Recover the original subtype mark.
elsif Nkind (N2) = N_Subtype_Indication
and then Is_Entity_Name (Original_Node (N2))
then
Set_Associated_Node (N, Original_Node (N2));
Reset_Entity (N);
else
null;
end if;
end if;
elsif Nkind (N) in N_Entity then
null;
else
declare
Qual : Node_Id := Empty;
Typ : Entity_Id := Empty;
Nam : Node_Id;
use Atree.Unchecked_Access;
-- This code section is part of implementing an untyped tree
-- traversal, so it needs direct access to node fields.
begin
if Nkind_In (N, N_Aggregate, N_Extension_Aggregate) then
N2 := Get_Associated_Node (N);
if No (N2) then
Typ := Empty;
else
Typ := Etype (N2);
-- In an instance within a generic, use the name of the
-- actual and not the original generic parameter. If the
-- actual is global in the current generic it must be
-- preserved for its instantiation.
if Nkind (Parent (Typ)) = N_Subtype_Declaration
and then
Present (Generic_Parent_Type (Parent (Typ)))
then
Typ := Base_Type (Typ);
Set_Etype (N2, Typ);
end if;
end if;
if No (N2)
or else No (Typ)
or else not Is_Global (Typ)
then
Set_Associated_Node (N, Empty);
-- If the aggregate is an actual in a call, it has been
-- resolved in the current context, to some local type.
-- The enclosing call may have been disambiguated by the
-- aggregate, and this disambiguation might fail at
-- instantiation time because the type to which the
-- aggregate did resolve is not preserved. In order to
-- preserve some of this information, we wrap the
-- aggregate in a qualified expression, using the id of
-- its type. For further disambiguation we qualify the
-- type name with its scope (if visible) because both
-- id's will have corresponding entities in an instance.
-- This resolves most of the problems with missing type
-- information on aggregates in instances.
if Nkind (N2) = Nkind (N)
and then Nkind (Parent (N2)) in N_Subprogram_Call
and then Comes_From_Source (Typ)
then
if Is_Immediately_Visible (Scope (Typ)) then
Nam := Make_Selected_Component (Loc,
Prefix =>
Make_Identifier (Loc, Chars (Scope (Typ))),
Selector_Name =>
Make_Identifier (Loc, Chars (Typ)));
else
Nam := Make_Identifier (Loc, Chars (Typ));
end if;
Qual :=
Make_Qualified_Expression (Loc,
Subtype_Mark => Nam,
Expression => Relocate_Node (N));
end if;
end if;
Save_Global_Descendant (Field1 (N));
Save_Global_Descendant (Field2 (N));
Save_Global_Descendant (Field3 (N));
Save_Global_Descendant (Field5 (N));
if Present (Qual) then
Rewrite (N, Qual);
end if;
-- All other cases than aggregates
else
Save_Global_Descendant (Field1 (N));
Save_Global_Descendant (Field2 (N));
Save_Global_Descendant (Field3 (N));
Save_Global_Descendant (Field4 (N));
Save_Global_Descendant (Field5 (N));
end if;
end;
end if;
-- If a node has aspects, references within their expressions must
-- be saved separately, given they are not directly in the tree.
if Has_Aspects (N) then
declare
Aspect : Node_Id;
begin
Aspect := First (Aspect_Specifications (N));
while Present (Aspect) loop
if Present (Expression (Aspect)) then
Save_Global_References (Expression (Aspect));
end if;
Next (Aspect);
end loop;
end;
end if;
end Save_References;
-- Start of processing for Save_Global_References
begin
Gen_Scope := Current_Scope;
-- If the generic unit is a child unit, references to entities in the
-- parent are treated as local, because they will be resolved anew in
-- the context of the instance of the parent.
while Is_Child_Unit (Gen_Scope)
and then Ekind (Scope (Gen_Scope)) = E_Generic_Package
loop
Gen_Scope := Scope (Gen_Scope);
end loop;
Save_References (N);
end Save_Global_References;
--------------------------------------
-- Set_Copied_Sloc_For_Inlined_Body --
--------------------------------------
procedure Set_Copied_Sloc_For_Inlined_Body (N : Node_Id; E : Entity_Id) is
begin
Create_Instantiation_Source (N, E, True, S_Adjustment);
end Set_Copied_Sloc_For_Inlined_Body;
---------------------
-- Set_Instance_Of --
---------------------
procedure Set_Instance_Of (A : Entity_Id; B : Entity_Id) is
begin
Generic_Renamings.Table (Generic_Renamings.Last) := (A, B, Assoc_Null);
Generic_Renamings_HTable.Set (Generic_Renamings.Last);
Generic_Renamings.Increment_Last;
end Set_Instance_Of;
--------------------
-- Set_Next_Assoc --
--------------------
procedure Set_Next_Assoc (E : Assoc_Ptr; Next : Assoc_Ptr) is
begin
Generic_Renamings.Table (E).Next_In_HTable := Next;
end Set_Next_Assoc;
-------------------
-- Start_Generic --
-------------------
procedure Start_Generic is
begin
-- ??? More things could be factored out in this routine.
-- Should probably be done at a later stage.
Generic_Flags.Append (Inside_A_Generic);
Inside_A_Generic := True;
Expander_Mode_Save_And_Set (False);
end Start_Generic;
----------------------
-- Set_Instance_Env --
----------------------
procedure Set_Instance_Env
(Gen_Unit : Entity_Id;
Act_Unit : Entity_Id)
is
Assertion_Status : constant Boolean := Assertions_Enabled;
Save_SPARK_Mode : constant SPARK_Mode_Type := SPARK_Mode;
Save_SPARK_Mode_Pragma : constant Node_Id := SPARK_Mode_Pragma;
begin
-- Regardless of the current mode, predefined units are analyzed in the
-- most current Ada mode, and earlier version Ada checks do not apply
-- to predefined units. Nothing needs to be done for non-internal units.
-- These are always analyzed in the current mode.
if Is_Internal_File_Name
(Fname => Unit_File_Name (Get_Source_Unit (Gen_Unit)),
Renamings_Included => True)
then
Set_Opt_Config_Switches (True, Current_Sem_Unit = Main_Unit);
-- In Ada2012 we may want to enable assertions in an instance of a
-- predefined unit, in which case we need to preserve the current
-- setting for the Assertions_Enabled flag. This will become more
-- critical when pre/postconditions are added to predefined units,
-- as is already the case for some numeric libraries.
if Ada_Version >= Ada_2012 then
Assertions_Enabled := Assertion_Status;
end if;
-- SPARK_Mode for an instance is the one applicable at the point of
-- instantiation.
SPARK_Mode := Save_SPARK_Mode;
SPARK_Mode_Pragma := Save_SPARK_Mode_Pragma;
end if;
Current_Instantiated_Parent :=
(Gen_Id => Gen_Unit,
Act_Id => Act_Unit,
Next_In_HTable => Assoc_Null);
end Set_Instance_Env;
-----------------
-- Switch_View --
-----------------
procedure Switch_View (T : Entity_Id) is
BT : constant Entity_Id := Base_Type (T);
Priv_Elmt : Elmt_Id := No_Elmt;
Priv_Sub : Entity_Id;
begin
-- T may be private but its base type may have been exchanged through
-- some other occurrence, in which case there is nothing to switch
-- besides T itself. Note that a private dependent subtype of a private
-- type might not have been switched even if the base type has been,
-- because of the last branch of Check_Private_View (see comment there).
if not Is_Private_Type (BT) then
Prepend_Elmt (Full_View (T), Exchanged_Views);
Exchange_Declarations (T);
return;
end if;
Priv_Elmt := First_Elmt (Private_Dependents (BT));
if Present (Full_View (BT)) then
Prepend_Elmt (Full_View (BT), Exchanged_Views);
Exchange_Declarations (BT);
end if;
while Present (Priv_Elmt) loop
Priv_Sub := (Node (Priv_Elmt));
-- We avoid flipping the subtype if the Etype of its full view is
-- private because this would result in a malformed subtype. This
-- occurs when the Etype of the subtype full view is the full view of
-- the base type (and since the base types were just switched, the
-- subtype is pointing to the wrong view). This is currently the case
-- for tagged record types, access types (maybe more?) and needs to
-- be resolved. ???
if Present (Full_View (Priv_Sub))
and then not Is_Private_Type (Etype (Full_View (Priv_Sub)))
then
Prepend_Elmt (Full_View (Priv_Sub), Exchanged_Views);
Exchange_Declarations (Priv_Sub);
end if;
Next_Elmt (Priv_Elmt);
end loop;
end Switch_View;
-----------------
-- True_Parent --
-----------------
function True_Parent (N : Node_Id) return Node_Id is
begin
if Nkind (Parent (N)) = N_Subunit then
return Parent (Corresponding_Stub (Parent (N)));
else
return Parent (N);
end if;
end True_Parent;
-----------------------------
-- Valid_Default_Attribute --
-----------------------------
procedure Valid_Default_Attribute (Nam : Entity_Id; Def : Node_Id) is
Attr_Id : constant Attribute_Id :=
Get_Attribute_Id (Attribute_Name (Def));
T : constant Entity_Id := Entity (Prefix (Def));
Is_Fun : constant Boolean := (Ekind (Nam) = E_Function);
F : Entity_Id;
Num_F : Int;
OK : Boolean;
begin
if No (T)
or else T = Any_Id
then
return;
end if;
Num_F := 0;
F := First_Formal (Nam);
while Present (F) loop
Num_F := Num_F + 1;
Next_Formal (F);
end loop;
case Attr_Id is
when Attribute_Adjacent | Attribute_Ceiling | Attribute_Copy_Sign |
Attribute_Floor | Attribute_Fraction | Attribute_Machine |
Attribute_Model | Attribute_Remainder | Attribute_Rounding |
Attribute_Unbiased_Rounding =>
OK := Is_Fun
and then Num_F = 1
and then Is_Floating_Point_Type (T);
when Attribute_Image | Attribute_Pred | Attribute_Succ |
Attribute_Value | Attribute_Wide_Image |
Attribute_Wide_Value =>
OK := (Is_Fun and then Num_F = 1 and then Is_Scalar_Type (T));
when Attribute_Max | Attribute_Min =>
OK := (Is_Fun and then Num_F = 2 and then Is_Scalar_Type (T));
when Attribute_Input =>
OK := (Is_Fun and then Num_F = 1);
when Attribute_Output | Attribute_Read | Attribute_Write =>
OK := (not Is_Fun and then Num_F = 2);
when others =>
OK := False;
end case;
if not OK then
Error_Msg_N ("attribute reference has wrong profile for subprogram",
Def);
end if;
end Valid_Default_Attribute;
end Sem_Ch12;
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