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|
------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- S E M _ C H 1 3 --
-- --
-- B o d y --
-- --
-- Copyright (C) 1992-2010, 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 Checks; use Checks;
with Einfo; use Einfo;
with Elists; use Elists;
with Errout; use Errout;
with Exp_Disp; use Exp_Disp;
with Exp_Tss; use Exp_Tss;
with Exp_Util; use Exp_Util;
with Lib; use Lib;
with Lib.Xref; use Lib.Xref;
with Namet; use Namet;
with Nlists; use Nlists;
with Nmake; use Nmake;
with Opt; use Opt;
with Restrict; use Restrict;
with Rident; use Rident;
with Rtsfind; use Rtsfind;
with Sem; use Sem;
with Sem_Aux; use Sem_Aux;
with Sem_Ch3; use Sem_Ch3;
with Sem_Ch6; use Sem_Ch6;
with Sem_Ch8; use Sem_Ch8;
with Sem_Eval; use Sem_Eval;
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 Sinput; use Sinput;
with Snames; use Snames;
with Stand; use Stand;
with Sinfo; use Sinfo;
with Stringt; use Stringt;
with Targparm; use Targparm;
with Ttypes; use Ttypes;
with Tbuild; use Tbuild;
with Urealp; use Urealp;
with GNAT.Heap_Sort_G;
package body Sem_Ch13 is
SSU : constant Pos := System_Storage_Unit;
-- Convenient short hand for commonly used constant
-----------------------
-- Local Subprograms --
-----------------------
procedure Alignment_Check_For_Esize_Change (Typ : Entity_Id);
-- This routine is called after setting the Esize of type entity Typ.
-- The purpose is to deal with the situation where an alignment has been
-- inherited from a derived type that is no longer appropriate for the
-- new Esize value. In this case, we reset the Alignment to unknown.
procedure Build_Predicate_Function (Typ : Entity_Id; N : Node_Id);
-- If Typ has predicates (indicated by Has_Predicates being set for Typ,
-- then either there are pragma Invariant entries on the rep chain for the
-- type (note that Predicate aspects are converted to pragma Predicate), or
-- there are inherited aspects from a parent type, or ancestor subtypes.
-- This procedure builds the spec and body for the Predicate function that
-- tests these predicates. N is the freeze node for the type. The spec of
-- the function is inserted before the freeze node, and the body of the
-- function is inserted after the freeze node.
procedure Build_Static_Predicate
(Typ : Entity_Id;
Expr : Node_Id;
Nam : Name_Id);
-- Given a predicated type Typ, where Typ is a discrete static subtype,
-- whose predicate expression is Expr, tests if Expr is a static predicate,
-- and if so, builds the predicate range list. Nam is the name of the one
-- argument to the predicate function. Occurrences of the type name in the
-- predicate expression have been replaced by identifier references to this
-- name, which is unique, so any identifier with Chars matching Nam must be
-- a reference to the type. If the predicate is non-static, this procedure
-- returns doing nothing. If the predicate is static, then the predicate
-- list is stored in Static_Predicate (Typ), and the Expr is rewritten as
-- a canonicalized membership operation.
function Get_Alignment_Value (Expr : Node_Id) return Uint;
-- Given the expression for an alignment value, returns the corresponding
-- Uint value. If the value is inappropriate, then error messages are
-- posted as required, and a value of No_Uint is returned.
function Is_Operational_Item (N : Node_Id) return Boolean;
-- A specification for a stream attribute is allowed before the full type
-- is declared, as explained in AI-00137 and the corrigendum. Attributes
-- that do not specify a representation characteristic are operational
-- attributes.
procedure New_Stream_Subprogram
(N : Node_Id;
Ent : Entity_Id;
Subp : Entity_Id;
Nam : TSS_Name_Type);
-- Create a subprogram renaming of a given stream attribute to the
-- designated subprogram and then in the tagged case, provide this as a
-- primitive operation, or in the non-tagged case make an appropriate TSS
-- entry. This is more properly an expansion activity than just semantics,
-- but the presence of user-defined stream functions for limited types is a
-- legality check, which is why this takes place here rather than in
-- exp_ch13, where it was previously. Nam indicates the name of the TSS
-- function to be generated.
--
-- To avoid elaboration anomalies with freeze nodes, for untagged types
-- we generate both a subprogram declaration and a subprogram renaming
-- declaration, so that the attribute specification is handled as a
-- renaming_as_body. For tagged types, the specification is one of the
-- primitive specs.
generic
with procedure Replace_Type_Reference (N : Node_Id);
procedure Replace_Type_References_Generic (N : Node_Id; TName : Name_Id);
-- This is used to scan an expression for a predicate or invariant aspect
-- replacing occurrences of the name TName (the name of the subtype to
-- which the aspect applies) with appropriate references to the parameter
-- of the predicate function or invariant procedure. The procedure passed
-- as a generic parameter does the actual replacement of node N, which is
-- either a simple direct reference to TName, or a selected component that
-- represents an appropriately qualified occurrence of TName.
procedure Set_Biased
(E : Entity_Id;
N : Node_Id;
Msg : String;
Biased : Boolean := True);
-- If Biased is True, sets Has_Biased_Representation flag for E, and
-- outputs a warning message at node N if Warn_On_Biased_Representation is
-- is True. This warning inserts the string Msg to describe the construct
-- causing biasing.
----------------------------------------------
-- Table for Validate_Unchecked_Conversions --
----------------------------------------------
-- The following table collects unchecked conversions for validation.
-- Entries are made by Validate_Unchecked_Conversion and then the
-- call to Validate_Unchecked_Conversions does the actual error
-- checking and posting of warnings. The reason for this delayed
-- processing is to take advantage of back-annotations of size and
-- alignment values performed by the back end.
-- Note: the reason we store a Source_Ptr value instead of a Node_Id
-- is that by the time Validate_Unchecked_Conversions is called, Sprint
-- will already have modified all Sloc values if the -gnatD option is set.
type UC_Entry is record
Eloc : Source_Ptr; -- node used for posting warnings
Source : Entity_Id; -- source type for unchecked conversion
Target : Entity_Id; -- target type for unchecked conversion
end record;
package Unchecked_Conversions is new Table.Table (
Table_Component_Type => UC_Entry,
Table_Index_Type => Int,
Table_Low_Bound => 1,
Table_Initial => 50,
Table_Increment => 200,
Table_Name => "Unchecked_Conversions");
----------------------------------------
-- Table for Validate_Address_Clauses --
----------------------------------------
-- If an address clause has the form
-- for X'Address use Expr
-- where Expr is of the form Y'Address or recursively is a reference
-- to a constant of either of these forms, and X and Y are entities of
-- objects, then if Y has a smaller alignment than X, that merits a
-- warning about possible bad alignment. The following table collects
-- address clauses of this kind. We put these in a table so that they
-- can be checked after the back end has completed annotation of the
-- alignments of objects, since we can catch more cases that way.
type Address_Clause_Check_Record is record
N : Node_Id;
-- The address clause
X : Entity_Id;
-- The entity of the object overlaying Y
Y : Entity_Id;
-- The entity of the object being overlaid
Off : Boolean;
-- Whether the address is offset within Y
end record;
package Address_Clause_Checks is new Table.Table (
Table_Component_Type => Address_Clause_Check_Record,
Table_Index_Type => Int,
Table_Low_Bound => 1,
Table_Initial => 20,
Table_Increment => 200,
Table_Name => "Address_Clause_Checks");
-----------------------------------------
-- Adjust_Record_For_Reverse_Bit_Order --
-----------------------------------------
procedure Adjust_Record_For_Reverse_Bit_Order (R : Entity_Id) is
Comp : Node_Id;
CC : Node_Id;
begin
-- Processing depends on version of Ada
-- For Ada 95, we just renumber bits within a storage unit. We do the
-- same for Ada 83 mode, since we recognize pragma Bit_Order in Ada 83,
-- and are free to add this extension.
if Ada_Version < Ada_2005 then
Comp := First_Component_Or_Discriminant (R);
while Present (Comp) loop
CC := Component_Clause (Comp);
-- If component clause is present, then deal with the non-default
-- bit order case for Ada 95 mode.
-- We only do this processing for the base type, and in fact that
-- is important, since otherwise if there are record subtypes, we
-- could reverse the bits once for each subtype, which is wrong.
if Present (CC)
and then Ekind (R) = E_Record_Type
then
declare
CFB : constant Uint := Component_Bit_Offset (Comp);
CSZ : constant Uint := Esize (Comp);
CLC : constant Node_Id := Component_Clause (Comp);
Pos : constant Node_Id := Position (CLC);
FB : constant Node_Id := First_Bit (CLC);
Storage_Unit_Offset : constant Uint :=
CFB / System_Storage_Unit;
Start_Bit : constant Uint :=
CFB mod System_Storage_Unit;
begin
-- Cases where field goes over storage unit boundary
if Start_Bit + CSZ > System_Storage_Unit then
-- Allow multi-byte field but generate warning
if Start_Bit mod System_Storage_Unit = 0
and then CSZ mod System_Storage_Unit = 0
then
Error_Msg_N
("multi-byte field specified with non-standard"
& " Bit_Order?", CLC);
if Bytes_Big_Endian then
Error_Msg_N
("bytes are not reversed "
& "(component is big-endian)?", CLC);
else
Error_Msg_N
("bytes are not reversed "
& "(component is little-endian)?", CLC);
end if;
-- Do not allow non-contiguous field
else
Error_Msg_N
("attempt to specify non-contiguous field "
& "not permitted", CLC);
Error_Msg_N
("\caused by non-standard Bit_Order "
& "specified", CLC);
Error_Msg_N
("\consider possibility of using "
& "Ada 2005 mode here", CLC);
end if;
-- Case where field fits in one storage unit
else
-- Give warning if suspicious component clause
if Intval (FB) >= System_Storage_Unit
and then Warn_On_Reverse_Bit_Order
then
Error_Msg_N
("?Bit_Order clause does not affect " &
"byte ordering", Pos);
Error_Msg_Uint_1 :=
Intval (Pos) + Intval (FB) /
System_Storage_Unit;
Error_Msg_N
("?position normalized to ^ before bit " &
"order interpreted", Pos);
end if;
-- Here is where we fix up the Component_Bit_Offset value
-- to account for the reverse bit order. Some examples of
-- what needs to be done are:
-- First_Bit .. Last_Bit Component_Bit_Offset
-- old new old new
-- 0 .. 0 7 .. 7 0 7
-- 0 .. 1 6 .. 7 0 6
-- 0 .. 2 5 .. 7 0 5
-- 0 .. 7 0 .. 7 0 4
-- 1 .. 1 6 .. 6 1 6
-- 1 .. 4 3 .. 6 1 3
-- 4 .. 7 0 .. 3 4 0
-- The rule is that the first bit is is obtained by
-- subtracting the old ending bit from storage_unit - 1.
Set_Component_Bit_Offset
(Comp,
(Storage_Unit_Offset * System_Storage_Unit) +
(System_Storage_Unit - 1) -
(Start_Bit + CSZ - 1));
Set_Normalized_First_Bit
(Comp,
Component_Bit_Offset (Comp) mod
System_Storage_Unit);
end if;
end;
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
-- For Ada 2005, we do machine scalar processing, as fully described In
-- AI-133. This involves gathering all components which start at the
-- same byte offset and processing them together. Same approach is still
-- valid in later versions including Ada 2012.
else
declare
Max_Machine_Scalar_Size : constant Uint :=
UI_From_Int
(Standard_Long_Long_Integer_Size);
-- We use this as the maximum machine scalar size
Num_CC : Natural;
SSU : constant Uint := UI_From_Int (System_Storage_Unit);
begin
-- This first loop through components does two things. First it
-- deals with the case of components with component clauses whose
-- length is greater than the maximum machine scalar size (either
-- accepting them or rejecting as needed). Second, it counts the
-- number of components with component clauses whose length does
-- not exceed this maximum for later processing.
Num_CC := 0;
Comp := First_Component_Or_Discriminant (R);
while Present (Comp) loop
CC := Component_Clause (Comp);
if Present (CC) then
declare
Fbit : constant Uint :=
Static_Integer (First_Bit (CC));
Lbit : constant Uint :=
Static_Integer (Last_Bit (CC));
begin
-- Case of component with last bit >= max machine scalar
if Lbit >= Max_Machine_Scalar_Size then
-- This is allowed only if first bit is zero, and
-- last bit + 1 is a multiple of storage unit size.
if Fbit = 0 and then (Lbit + 1) mod SSU = 0 then
-- This is the case to give a warning if enabled
if Warn_On_Reverse_Bit_Order then
Error_Msg_N
("multi-byte field specified with "
& " non-standard Bit_Order?", CC);
if Bytes_Big_Endian then
Error_Msg_N
("\bytes are not reversed "
& "(component is big-endian)?", CC);
else
Error_Msg_N
("\bytes are not reversed "
& "(component is little-endian)?", CC);
end if;
end if;
-- Give error message for RM 13.4.1(10) violation
else
Error_Msg_FE
("machine scalar rules not followed for&",
First_Bit (CC), Comp);
Error_Msg_Uint_1 := Lbit;
Error_Msg_Uint_2 := Max_Machine_Scalar_Size;
Error_Msg_F
("\last bit (^) exceeds maximum machine "
& "scalar size (^)",
First_Bit (CC));
if (Lbit + 1) mod SSU /= 0 then
Error_Msg_Uint_1 := SSU;
Error_Msg_F
("\and is not a multiple of Storage_Unit (^) "
& "('R'M 13.4.1(10))",
First_Bit (CC));
else
Error_Msg_Uint_1 := Fbit;
Error_Msg_F
("\and first bit (^) is non-zero "
& "('R'M 13.4.1(10))",
First_Bit (CC));
end if;
end if;
-- OK case of machine scalar related component clause,
-- For now, just count them.
else
Num_CC := Num_CC + 1;
end if;
end;
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
-- We need to sort the component clauses on the basis of the
-- Position values in the clause, so we can group clauses with
-- the same Position. together to determine the relevant machine
-- scalar size.
Sort_CC : declare
Comps : array (0 .. Num_CC) of Entity_Id;
-- Array to collect component and discriminant entities. The
-- data starts at index 1, the 0'th entry is for the sort
-- routine.
function CP_Lt (Op1, Op2 : Natural) return Boolean;
-- Compare routine for Sort
procedure CP_Move (From : Natural; To : Natural);
-- Move routine for Sort
package Sorting is new GNAT.Heap_Sort_G (CP_Move, CP_Lt);
Start : Natural;
Stop : Natural;
-- Start and stop positions in the component list of the set of
-- components with the same starting position (that constitute
-- components in a single machine scalar).
MaxL : Uint;
-- Maximum last bit value of any component in this set
MSS : Uint;
-- Corresponding machine scalar size
-----------
-- CP_Lt --
-----------
function CP_Lt (Op1, Op2 : Natural) return Boolean is
begin
return Position (Component_Clause (Comps (Op1))) <
Position (Component_Clause (Comps (Op2)));
end CP_Lt;
-------------
-- CP_Move --
-------------
procedure CP_Move (From : Natural; To : Natural) is
begin
Comps (To) := Comps (From);
end CP_Move;
-- Start of processing for Sort_CC
begin
-- Collect the machine scalar relevant component clauses
Num_CC := 0;
Comp := First_Component_Or_Discriminant (R);
while Present (Comp) loop
declare
CC : constant Node_Id := Component_Clause (Comp);
begin
-- Collect only component clauses whose last bit is less
-- than machine scalar size. Any component clause whose
-- last bit exceeds this value does not take part in
-- machine scalar layout considerations. The test for
-- Error_Posted makes sure we exclude component clauses
-- for which we already posted an error.
if Present (CC)
and then not Error_Posted (Last_Bit (CC))
and then Static_Integer (Last_Bit (CC)) <
Max_Machine_Scalar_Size
then
Num_CC := Num_CC + 1;
Comps (Num_CC) := Comp;
end if;
end;
Next_Component_Or_Discriminant (Comp);
end loop;
-- Sort by ascending position number
Sorting.Sort (Num_CC);
-- We now have all the components whose size does not exceed
-- the max machine scalar value, sorted by starting position.
-- In this loop we gather groups of clauses starting at the
-- same position, to process them in accordance with AI-133.
Stop := 0;
while Stop < Num_CC loop
Start := Stop + 1;
Stop := Start;
MaxL :=
Static_Integer
(Last_Bit (Component_Clause (Comps (Start))));
while Stop < Num_CC loop
if Static_Integer
(Position (Component_Clause (Comps (Stop + 1)))) =
Static_Integer
(Position (Component_Clause (Comps (Stop))))
then
Stop := Stop + 1;
MaxL :=
UI_Max
(MaxL,
Static_Integer
(Last_Bit
(Component_Clause (Comps (Stop)))));
else
exit;
end if;
end loop;
-- Now we have a group of component clauses from Start to
-- Stop whose positions are identical, and MaxL is the
-- maximum last bit value of any of these components.
-- We need to determine the corresponding machine scalar
-- size. This loop assumes that machine scalar sizes are
-- even, and that each possible machine scalar has twice
-- as many bits as the next smaller one.
MSS := Max_Machine_Scalar_Size;
while MSS mod 2 = 0
and then (MSS / 2) >= SSU
and then (MSS / 2) > MaxL
loop
MSS := MSS / 2;
end loop;
-- Here is where we fix up the Component_Bit_Offset value
-- to account for the reverse bit order. Some examples of
-- what needs to be done for the case of a machine scalar
-- size of 8 are:
-- First_Bit .. Last_Bit Component_Bit_Offset
-- old new old new
-- 0 .. 0 7 .. 7 0 7
-- 0 .. 1 6 .. 7 0 6
-- 0 .. 2 5 .. 7 0 5
-- 0 .. 7 0 .. 7 0 4
-- 1 .. 1 6 .. 6 1 6
-- 1 .. 4 3 .. 6 1 3
-- 4 .. 7 0 .. 3 4 0
-- The rule is that the first bit is obtained by subtracting
-- the old ending bit from machine scalar size - 1.
for C in Start .. Stop loop
declare
Comp : constant Entity_Id := Comps (C);
CC : constant Node_Id :=
Component_Clause (Comp);
LB : constant Uint :=
Static_Integer (Last_Bit (CC));
NFB : constant Uint := MSS - Uint_1 - LB;
NLB : constant Uint := NFB + Esize (Comp) - 1;
Pos : constant Uint :=
Static_Integer (Position (CC));
begin
if Warn_On_Reverse_Bit_Order then
Error_Msg_Uint_1 := MSS;
Error_Msg_N
("info: reverse bit order in machine " &
"scalar of length^?", First_Bit (CC));
Error_Msg_Uint_1 := NFB;
Error_Msg_Uint_2 := NLB;
if Bytes_Big_Endian then
Error_Msg_NE
("?\info: big-endian range for "
& "component & is ^ .. ^",
First_Bit (CC), Comp);
else
Error_Msg_NE
("?\info: little-endian range "
& "for component & is ^ .. ^",
First_Bit (CC), Comp);
end if;
end if;
Set_Component_Bit_Offset (Comp, Pos * SSU + NFB);
Set_Normalized_First_Bit (Comp, NFB mod SSU);
end;
end loop;
end loop;
end Sort_CC;
end;
end if;
end Adjust_Record_For_Reverse_Bit_Order;
--------------------------------------
-- Alignment_Check_For_Esize_Change --
--------------------------------------
procedure Alignment_Check_For_Esize_Change (Typ : Entity_Id) is
begin
-- If the alignment is known, and not set by a rep clause, and is
-- inconsistent with the size being set, then reset it to unknown,
-- we assume in this case that the size overrides the inherited
-- alignment, and that the alignment must be recomputed.
if Known_Alignment (Typ)
and then not Has_Alignment_Clause (Typ)
and then Esize (Typ) mod (Alignment (Typ) * SSU) /= 0
then
Init_Alignment (Typ);
end if;
end Alignment_Check_For_Esize_Change;
-----------------------------------
-- Analyze_Aspect_Specifications --
-----------------------------------
procedure Analyze_Aspect_Specifications
(N : Node_Id;
E : Entity_Id;
L : List_Id)
is
Aspect : Node_Id;
Aitem : Node_Id;
Ent : Node_Id;
Ins_Node : Node_Id := N;
-- Insert pragmas (except Pre/Post/Invariant/Predicate) after this node
-- The general processing involves building an attribute definition
-- clause or a pragma node that corresponds to the access type. Then
-- one of two things happens:
-- If we are required to delay the evaluation of this aspect to the
-- freeze point, we preanalyze the relevant argument, and then attach
-- the corresponding pragma/attribute definition clause to the aspect
-- specification node, which is then placed in the Rep Item chain.
-- In this case we mark the entity with the Has_Delayed_Aspects flag,
-- and we evaluate the rep item at the freeze point.
-- If no delay is required, we just insert the pragma or attribute
-- after the declaration, and it will get processed by the normal
-- circuit. The From_Aspect_Specification flag is set on the pragma
-- or attribute definition node in either case to activate special
-- processing (e.g. not traversing the list of homonyms for inline).
Delay_Required : Boolean;
-- Set True if delay is required
begin
-- Return if no aspects
if L = No_List then
return;
end if;
-- Return if already analyzed (avoids duplicate calls in some cases
-- where type declarations get rewritten and processed twice).
if Analyzed (N) then
return;
end if;
-- Loop through aspects
Aspect := First (L);
while Present (Aspect) loop
declare
Loc : constant Source_Ptr := Sloc (Aspect);
Id : constant Node_Id := Identifier (Aspect);
Expr : constant Node_Id := Expression (Aspect);
Nam : constant Name_Id := Chars (Id);
A_Id : constant Aspect_Id := Get_Aspect_Id (Nam);
Anod : Node_Id;
T : Entity_Id;
Eloc : Source_Ptr := Sloc (Expr);
-- Source location of expression, modified when we split PPC's
begin
Set_Entity (Aspect, E);
Ent := New_Occurrence_Of (E, Sloc (Id));
-- Check for duplicate aspect. Note that the Comes_From_Source
-- test allows duplicate Pre/Post's that we generate internally
-- to escape being flagged here.
Anod := First (L);
while Anod /= Aspect loop
if Nam = Chars (Identifier (Anod))
and then Comes_From_Source (Aspect)
then
Error_Msg_Name_1 := Nam;
Error_Msg_Sloc := Sloc (Anod);
-- Case of same aspect specified twice
if Class_Present (Anod) = Class_Present (Aspect) then
if not Class_Present (Anod) then
Error_Msg_NE
("aspect% for & previously given#",
Id, E);
else
Error_Msg_NE
("aspect `%''Class` for & previously given#",
Id, E);
end if;
-- Case of Pre and Pre'Class both specified
elsif Nam = Name_Pre then
if Class_Present (Aspect) then
Error_Msg_NE
("aspect `Pre''Class` for & is not allowed here",
Id, E);
Error_Msg_NE
("\since aspect `Pre` previously given#",
Id, E);
else
Error_Msg_NE
("aspect `Pre` for & is not allowed here",
Id, E);
Error_Msg_NE
("\since aspect `Pre''Class` previously given#",
Id, E);
end if;
end if;
goto Continue;
end if;
Next (Anod);
end loop;
-- Processing based on specific aspect
case A_Id is
-- No_Aspect should be impossible
when No_Aspect =>
raise Program_Error;
-- Aspects taking an optional boolean argument. For all of
-- these we just create a matching pragma and insert it,
-- setting flag Cancel_Aspect if the expression is False.
when Aspect_Ada_2005 |
Aspect_Ada_2012 |
Aspect_Atomic |
Aspect_Atomic_Components |
Aspect_Discard_Names |
Aspect_Favor_Top_Level |
Aspect_Inline |
Aspect_Inline_Always |
Aspect_No_Return |
Aspect_Pack |
Aspect_Persistent_BSS |
Aspect_Preelaborable_Initialization |
Aspect_Pure_Function |
Aspect_Shared |
Aspect_Suppress_Debug_Info |
Aspect_Unchecked_Union |
Aspect_Universal_Aliasing |
Aspect_Unmodified |
Aspect_Unreferenced |
Aspect_Unreferenced_Objects |
Aspect_Volatile |
Aspect_Volatile_Components =>
-- Build corresponding pragma node
Aitem :=
Make_Pragma (Loc,
Pragma_Argument_Associations => New_List (Ent),
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Chars (Id)));
-- Deal with missing expression case, delay never needed
if No (Expr) then
Delay_Required := False;
-- Expression is present
else
Preanalyze_Spec_Expression (Expr, Standard_Boolean);
-- If preanalysis gives a static expression, we don't
-- need to delay (this will happen often in practice).
if Is_OK_Static_Expression (Expr) then
Delay_Required := False;
if Is_False (Expr_Value (Expr)) then
Set_Aspect_Cancel (Aitem);
end if;
-- If we don't get a static expression, then delay, the
-- expression may turn out static by freeze time.
else
Delay_Required := True;
end if;
end if;
-- Aspects corresponding to attribute definition clauses
when Aspect_Address |
Aspect_Alignment |
Aspect_Bit_Order |
Aspect_Component_Size |
Aspect_External_Tag |
Aspect_Machine_Radix |
Aspect_Object_Size |
Aspect_Size |
Aspect_Storage_Pool |
Aspect_Storage_Size |
Aspect_Stream_Size |
Aspect_Value_Size =>
-- Preanalyze the expression with the appropriate type
case A_Id is
when Aspect_Address =>
T := RTE (RE_Address);
when Aspect_Bit_Order =>
T := RTE (RE_Bit_Order);
when Aspect_External_Tag =>
T := Standard_String;
when Aspect_Storage_Pool =>
T := Class_Wide_Type (RTE (RE_Root_Storage_Pool));
when others =>
T := Any_Integer;
end case;
Preanalyze_Spec_Expression (Expr, T);
-- Construct the attribute definition clause
Aitem :=
Make_Attribute_Definition_Clause (Loc,
Name => Ent,
Chars => Chars (Id),
Expression => Relocate_Node (Expr));
-- We do not need a delay if we have a static expression
if Is_OK_Static_Expression (Expression (Aitem)) then
Delay_Required := False;
-- Here a delay is required
else
Delay_Required := True;
end if;
-- Aspects corresponding to pragmas with two arguments, where
-- the first argument is a local name referring to the entity,
-- and the second argument is the aspect definition expression.
when Aspect_Suppress |
Aspect_Unsuppress =>
-- Construct the pragma
Aitem :=
Make_Pragma (Loc,
Pragma_Argument_Associations => New_List (
New_Occurrence_Of (E, Eloc),
Relocate_Node (Expr)),
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Chars (Id)));
-- We don't have to play the delay game here, since the only
-- values are check names which don't get analyzed anyway.
Delay_Required := False;
-- Aspects corresponding to stream routines
when Aspect_Input |
Aspect_Output |
Aspect_Read |
Aspect_Write =>
-- Construct the attribute definition clause
Aitem :=
Make_Attribute_Definition_Clause (Loc,
Name => Ent,
Chars => Chars (Id),
Expression => Relocate_Node (Expr));
-- These are always delayed (typically the subprogram that
-- is referenced cannot have been declared yet, since it has
-- a reference to the type for which this aspect is defined.
Delay_Required := True;
-- Aspects corresponding to pragmas with two arguments, where
-- the second argument is a local name referring to the entity,
-- and the first argument is the aspect definition expression.
when Aspect_Warnings =>
-- Construct the pragma
Aitem :=
Make_Pragma (Loc,
Pragma_Argument_Associations => New_List (
Relocate_Node (Expr),
New_Occurrence_Of (E, Eloc)),
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Chars (Id)),
Class_Present => Class_Present (Aspect));
-- We don't have to play the delay game here, since the only
-- values are check names which don't get analyzed anyway.
Delay_Required := False;
-- Aspects Pre/Post generate Precondition/Postcondition pragmas
-- with a first argument that is the expression, and a second
-- argument that is an informative message if the test fails.
-- This is inserted right after the declaration, to get the
-- required pragma placement. The processing for the pragmas
-- takes care of the required delay.
when Aspect_Pre | Aspect_Post => declare
Pname : Name_Id;
begin
if A_Id = Aspect_Pre then
Pname := Name_Precondition;
else
Pname := Name_Postcondition;
end if;
-- If the expressions is of the form A and then B, then
-- we generate separate Pre/Post aspects for the separate
-- clauses. Since we allow multiple pragmas, there is no
-- problem in allowing multiple Pre/Post aspects internally.
-- We do not do this for Pre'Class, since we have to put
-- these conditions together in a complex OR expression
if Pname = Name_Postcondition
or else not Class_Present (Aspect)
then
while Nkind (Expr) = N_And_Then loop
Insert_After (Aspect,
Make_Aspect_Specification (Sloc (Right_Opnd (Expr)),
Identifier => Identifier (Aspect),
Expression => Relocate_Node (Right_Opnd (Expr)),
Class_Present => Class_Present (Aspect),
Split_PPC => True));
Rewrite (Expr, Relocate_Node (Left_Opnd (Expr)));
Eloc := Sloc (Expr);
end loop;
end if;
-- Build the precondition/postcondition pragma
Aitem :=
Make_Pragma (Loc,
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Pname),
Class_Present => Class_Present (Aspect),
Split_PPC => Split_PPC (Aspect),
Pragma_Argument_Associations => New_List (
Make_Pragma_Argument_Association (Eloc,
Chars => Name_Check,
Expression => Relocate_Node (Expr))));
-- Add message unless exception messages are suppressed
if not Opt.Exception_Locations_Suppressed then
Append_To (Pragma_Argument_Associations (Aitem),
Make_Pragma_Argument_Association (Eloc,
Chars => Name_Message,
Expression =>
Make_String_Literal (Eloc,
Strval => "failed "
& Get_Name_String (Pname)
& " from "
& Build_Location_String (Eloc))));
end if;
Set_From_Aspect_Specification (Aitem, True);
-- For Pre/Post cases, insert immediately after the entity
-- declaration, since that is the required pragma placement.
-- Note that for these aspects, we do not have to worry
-- about delay issues, since the pragmas themselves deal
-- with delay of visibility for the expression analysis.
-- If the entity is a library-level subprogram, the pre/
-- postconditions must be treated as late pragmas.
if Nkind (Parent (N)) = N_Compilation_Unit then
Add_Global_Declaration (Aitem);
else
Insert_After (N, Aitem);
end if;
goto Continue;
end;
-- Invariant aspects generate a corresponding pragma with a
-- first argument that is the entity, a second argument that is
-- the expression and a third argument that is an appropriate
-- message. This is inserted right after the declaration, to
-- get the required pragma placement. The pragma processing
-- takes care of the required delay.
when Aspect_Invariant =>
-- Construct the pragma
Aitem :=
Make_Pragma (Loc,
Pragma_Argument_Associations =>
New_List (Ent, Relocate_Node (Expr)),
Class_Present => Class_Present (Aspect),
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Name_Invariant));
-- Add message unless exception messages are suppressed
if not Opt.Exception_Locations_Suppressed then
Append_To (Pragma_Argument_Associations (Aitem),
Make_Pragma_Argument_Association (Eloc,
Chars => Name_Message,
Expression =>
Make_String_Literal (Eloc,
Strval => "failed invariant from "
& Build_Location_String (Eloc))));
end if;
Set_From_Aspect_Specification (Aitem, True);
-- For Invariant case, insert immediately after the entity
-- declaration. We do not have to worry about delay issues
-- since the pragma processing takes care of this.
Insert_After (N, Aitem);
goto Continue;
-- Predicate aspects generate a corresponding pragma with a
-- first argument that is the entity, and the second argument
-- is the expression. This is inserted immediately after the
-- declaration, to get the required pragma placement. The
-- pragma processing takes care of the required delay.
when Aspect_Predicate =>
-- Construct the pragma
Aitem :=
Make_Pragma (Loc,
Pragma_Argument_Associations =>
New_List (Ent, Relocate_Node (Expr)),
Class_Present => Class_Present (Aspect),
Pragma_Identifier =>
Make_Identifier (Sloc (Id), Name_Predicate));
Set_From_Aspect_Specification (Aitem, True);
-- Make sure we have a freeze node (it might otherwise be
-- missing in cases like subtype X is Y, and we would not
-- have a place to build the predicate function).
Ensure_Freeze_Node (E);
-- For Predicate case, insert immediately after the entity
-- declaration. We do not have to worry about delay issues
-- since the pragma processing takes care of this.
Insert_After (N, Aitem);
goto Continue;
end case;
Set_From_Aspect_Specification (Aitem, True);
-- If a delay is required, we delay the freeze (not much point in
-- delaying the aspect if we don't delay the freeze!). The pragma
-- or clause is then attached to the aspect specification which
-- is placed in the rep item list.
if Delay_Required then
Ensure_Freeze_Node (E);
Set_Is_Delayed_Aspect (Aitem);
Set_Has_Delayed_Aspects (E);
Set_Aspect_Rep_Item (Aspect, Aitem);
Record_Rep_Item (E, Aspect);
-- If no delay required, insert the pragma/clause in the tree
else
-- For Pre/Post cases, insert immediately after the entity
-- declaration, since that is the required pragma placement.
if A_Id = Aspect_Pre or else A_Id = Aspect_Post then
Insert_After (N, Aitem);
-- For all other cases, insert in sequence
else
Insert_After (Ins_Node, Aitem);
Ins_Node := Aitem;
end if;
end if;
end;
<<Continue>>
Next (Aspect);
end loop;
end Analyze_Aspect_Specifications;
-----------------------
-- Analyze_At_Clause --
-----------------------
-- An at clause is replaced by the corresponding Address attribute
-- definition clause that is the preferred approach in Ada 95.
procedure Analyze_At_Clause (N : Node_Id) is
CS : constant Boolean := Comes_From_Source (N);
begin
-- This is an obsolescent feature
Check_Restriction (No_Obsolescent_Features, N);
if Warn_On_Obsolescent_Feature then
Error_Msg_N
("at clause is an obsolescent feature (RM J.7(2))?", N);
Error_Msg_N
("\use address attribute definition clause instead?", N);
end if;
-- Rewrite as address clause
Rewrite (N,
Make_Attribute_Definition_Clause (Sloc (N),
Name => Identifier (N),
Chars => Name_Address,
Expression => Expression (N)));
-- We preserve Comes_From_Source, since logically the clause still
-- comes from the source program even though it is changed in form.
Set_Comes_From_Source (N, CS);
-- Analyze rewritten clause
Analyze_Attribute_Definition_Clause (N);
end Analyze_At_Clause;
-----------------------------------------
-- Analyze_Attribute_Definition_Clause --
-----------------------------------------
procedure Analyze_Attribute_Definition_Clause (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
Nam : constant Node_Id := Name (N);
Attr : constant Name_Id := Chars (N);
Expr : constant Node_Id := Expression (N);
Id : constant Attribute_Id := Get_Attribute_Id (Attr);
Ent : Entity_Id;
U_Ent : Entity_Id;
FOnly : Boolean := False;
-- Reset to True for subtype specific attribute (Alignment, Size)
-- and for stream attributes, i.e. those cases where in the call
-- to Rep_Item_Too_Late, FOnly is set True so that only the freezing
-- rules are checked. Note that the case of stream attributes is not
-- clear from the RM, but see AI95-00137. Also, the RM seems to
-- disallow Storage_Size for derived task types, but that is also
-- clearly unintentional.
procedure Analyze_Stream_TSS_Definition (TSS_Nam : TSS_Name_Type);
-- Common processing for 'Read, 'Write, 'Input and 'Output attribute
-- definition clauses.
function Duplicate_Clause return Boolean;
-- This routine checks if the aspect for U_Ent being given by attribute
-- definition clause N is for an aspect that has already been specified,
-- and if so gives an error message. If there is a duplicate, True is
-- returned, otherwise if there is no error, False is returned.
-----------------------------------
-- Analyze_Stream_TSS_Definition --
-----------------------------------
procedure Analyze_Stream_TSS_Definition (TSS_Nam : TSS_Name_Type) is
Subp : Entity_Id := Empty;
I : Interp_Index;
It : Interp;
Pnam : Entity_Id;
Is_Read : constant Boolean := (TSS_Nam = TSS_Stream_Read);
function Has_Good_Profile (Subp : Entity_Id) return Boolean;
-- Return true if the entity is a subprogram with an appropriate
-- profile for the attribute being defined.
----------------------
-- Has_Good_Profile --
----------------------
function Has_Good_Profile (Subp : Entity_Id) return Boolean is
F : Entity_Id;
Is_Function : constant Boolean := (TSS_Nam = TSS_Stream_Input);
Expected_Ekind : constant array (Boolean) of Entity_Kind :=
(False => E_Procedure, True => E_Function);
Typ : Entity_Id;
begin
if Ekind (Subp) /= Expected_Ekind (Is_Function) then
return False;
end if;
F := First_Formal (Subp);
if No (F)
or else Ekind (Etype (F)) /= E_Anonymous_Access_Type
or else Designated_Type (Etype (F)) /=
Class_Wide_Type (RTE (RE_Root_Stream_Type))
then
return False;
end if;
if not Is_Function then
Next_Formal (F);
declare
Expected_Mode : constant array (Boolean) of Entity_Kind :=
(False => E_In_Parameter,
True => E_Out_Parameter);
begin
if Parameter_Mode (F) /= Expected_Mode (Is_Read) then
return False;
end if;
end;
Typ := Etype (F);
else
Typ := Etype (Subp);
end if;
return Base_Type (Typ) = Base_Type (Ent)
and then No (Next_Formal (F));
end Has_Good_Profile;
-- Start of processing for Analyze_Stream_TSS_Definition
begin
FOnly := True;
if not Is_Type (U_Ent) then
Error_Msg_N ("local name must be a subtype", Nam);
return;
end if;
Pnam := TSS (Base_Type (U_Ent), TSS_Nam);
-- If Pnam is present, it can be either inherited from an ancestor
-- type (in which case it is legal to redefine it for this type), or
-- be a previous definition of the attribute for the same type (in
-- which case it is illegal).
-- In the first case, it will have been analyzed already, and we
-- can check that its profile does not match the expected profile
-- for a stream attribute of U_Ent. In the second case, either Pnam
-- has been analyzed (and has the expected profile), or it has not
-- been analyzed yet (case of a type that has not been frozen yet
-- and for which the stream attribute has been set using Set_TSS).
if Present (Pnam)
and then (No (First_Entity (Pnam)) or else Has_Good_Profile (Pnam))
then
Error_Msg_Sloc := Sloc (Pnam);
Error_Msg_Name_1 := Attr;
Error_Msg_N ("% attribute already defined #", Nam);
return;
end if;
Analyze (Expr);
if Is_Entity_Name (Expr) then
if not Is_Overloaded (Expr) then
if Has_Good_Profile (Entity (Expr)) then
Subp := Entity (Expr);
end if;
else
Get_First_Interp (Expr, I, It);
while Present (It.Nam) loop
if Has_Good_Profile (It.Nam) then
Subp := It.Nam;
exit;
end if;
Get_Next_Interp (I, It);
end loop;
end if;
end if;
if Present (Subp) then
if Is_Abstract_Subprogram (Subp) then
Error_Msg_N ("stream subprogram must not be abstract", Expr);
return;
end if;
Set_Entity (Expr, Subp);
Set_Etype (Expr, Etype (Subp));
New_Stream_Subprogram (N, U_Ent, Subp, TSS_Nam);
else
Error_Msg_Name_1 := Attr;
Error_Msg_N ("incorrect expression for% attribute", Expr);
end if;
end Analyze_Stream_TSS_Definition;
----------------------
-- Duplicate_Clause --
----------------------
function Duplicate_Clause return Boolean is
A : Node_Id;
begin
-- Nothing to do if this attribute definition clause comes from
-- an aspect specification, since we could not be duplicating an
-- explicit clause, and we dealt with the case of duplicated aspects
-- in Analyze_Aspect_Specifications.
if From_Aspect_Specification (N) then
return False;
end if;
-- Otherwise current clause may duplicate previous clause or a
-- previously given aspect specification for the same aspect.
A := Get_Rep_Item_For_Entity (U_Ent, Chars (N));
if Present (A) then
if Entity (A) = U_Ent then
Error_Msg_Name_1 := Chars (N);
Error_Msg_Sloc := Sloc (A);
Error_Msg_NE ("aspect% for & previously given#", N, U_Ent);
return True;
end if;
end if;
return False;
end Duplicate_Clause;
-- Start of processing for Analyze_Attribute_Definition_Clause
begin
-- Process Ignore_Rep_Clauses option
if Ignore_Rep_Clauses then
case Id is
-- The following should be ignored. They do not affect legality
-- and may be target dependent. The basic idea of -gnatI is to
-- ignore any rep clauses that may be target dependent but do not
-- affect legality (except possibly to be rejected because they
-- are incompatible with the compilation target).
when Attribute_Alignment |
Attribute_Bit_Order |
Attribute_Component_Size |
Attribute_Machine_Radix |
Attribute_Object_Size |
Attribute_Size |
Attribute_Small |
Attribute_Stream_Size |
Attribute_Value_Size =>
Rewrite (N, Make_Null_Statement (Sloc (N)));
return;
-- The following should not be ignored, because in the first place
-- they are reasonably portable, and should not cause problems in
-- compiling code from another target, and also they do affect
-- legality, e.g. failing to provide a stream attribute for a
-- type may make a program illegal.
when Attribute_External_Tag |
Attribute_Input |
Attribute_Output |
Attribute_Read |
Attribute_Storage_Pool |
Attribute_Storage_Size |
Attribute_Write =>
null;
-- Other cases are errors ("attribute& cannot be set with
-- definition clause"), which will be caught below.
when others =>
null;
end case;
end if;
Analyze (Nam);
Ent := Entity (Nam);
if Rep_Item_Too_Early (Ent, N) then
return;
end if;
-- Rep clause applies to full view of incomplete type or private type if
-- we have one (if not, this is a premature use of the type). However,
-- certain semantic checks need to be done on the specified entity (i.e.
-- the private view), so we save it in Ent.
if Is_Private_Type (Ent)
and then Is_Derived_Type (Ent)
and then not Is_Tagged_Type (Ent)
and then No (Full_View (Ent))
then
-- If this is a private type whose completion is a derivation from
-- another private type, there is no full view, and the attribute
-- belongs to the type itself, not its underlying parent.
U_Ent := Ent;
elsif Ekind (Ent) = E_Incomplete_Type then
-- The attribute applies to the full view, set the entity of the
-- attribute definition accordingly.
Ent := Underlying_Type (Ent);
U_Ent := Ent;
Set_Entity (Nam, Ent);
else
U_Ent := Underlying_Type (Ent);
end if;
-- Complete other routine error checks
if Etype (Nam) = Any_Type then
return;
elsif Scope (Ent) /= Current_Scope then
Error_Msg_N ("entity must be declared in this scope", Nam);
return;
elsif No (U_Ent) then
U_Ent := Ent;
elsif Is_Type (U_Ent)
and then not Is_First_Subtype (U_Ent)
and then Id /= Attribute_Object_Size
and then Id /= Attribute_Value_Size
and then not From_At_Mod (N)
then
Error_Msg_N ("cannot specify attribute for subtype", Nam);
return;
end if;
Set_Entity (N, U_Ent);
-- Switch on particular attribute
case Id is
-------------
-- Address --
-------------
-- Address attribute definition clause
when Attribute_Address => Address : begin
-- A little error check, catch for X'Address use X'Address;
if Nkind (Nam) = N_Identifier
and then Nkind (Expr) = N_Attribute_Reference
and then Attribute_Name (Expr) = Name_Address
and then Nkind (Prefix (Expr)) = N_Identifier
and then Chars (Nam) = Chars (Prefix (Expr))
then
Error_Msg_NE
("address for & is self-referencing", Prefix (Expr), Ent);
return;
end if;
-- Not that special case, carry on with analysis of expression
Analyze_And_Resolve (Expr, RTE (RE_Address));
-- Even when ignoring rep clauses we need to indicate that the
-- entity has an address clause and thus it is legal to declare
-- it imported.
if Ignore_Rep_Clauses then
if Ekind_In (U_Ent, E_Variable, E_Constant) then
Record_Rep_Item (U_Ent, N);
end if;
return;
end if;
if Duplicate_Clause then
null;
-- Case of address clause for subprogram
elsif Is_Subprogram (U_Ent) then
if Has_Homonym (U_Ent) then
Error_Msg_N
("address clause cannot be given " &
"for overloaded subprogram",
Nam);
return;
end if;
-- For subprograms, all address clauses are permitted, and we
-- mark the subprogram as having a deferred freeze so that Gigi
-- will not elaborate it too soon.
-- Above needs more comments, what is too soon about???
Set_Has_Delayed_Freeze (U_Ent);
-- Case of address clause for entry
elsif Ekind (U_Ent) = E_Entry then
if Nkind (Parent (N)) = N_Task_Body then
Error_Msg_N
("entry address must be specified in task spec", Nam);
return;
end if;
-- For entries, we require a constant address
Check_Constant_Address_Clause (Expr, U_Ent);
-- Special checks for task types
if Is_Task_Type (Scope (U_Ent))
and then Comes_From_Source (Scope (U_Ent))
then
Error_Msg_N
("?entry address declared for entry in task type", N);
Error_Msg_N
("\?only one task can be declared of this type", N);
end if;
-- Entry address clauses are obsolescent
Check_Restriction (No_Obsolescent_Features, N);
if Warn_On_Obsolescent_Feature then
Error_Msg_N
("attaching interrupt to task entry is an " &
"obsolescent feature (RM J.7.1)?", N);
Error_Msg_N
("\use interrupt procedure instead?", N);
end if;
-- Case of an address clause for a controlled object which we
-- consider to be erroneous.
elsif Is_Controlled (Etype (U_Ent))
or else Has_Controlled_Component (Etype (U_Ent))
then
Error_Msg_NE
("?controlled object& must not be overlaid", Nam, U_Ent);
Error_Msg_N
("\?Program_Error will be raised at run time", Nam);
Insert_Action (Declaration_Node (U_Ent),
Make_Raise_Program_Error (Loc,
Reason => PE_Overlaid_Controlled_Object));
return;
-- Case of address clause for a (non-controlled) object
elsif
Ekind (U_Ent) = E_Variable
or else
Ekind (U_Ent) = E_Constant
then
declare
Expr : constant Node_Id := Expression (N);
O_Ent : Entity_Id;
Off : Boolean;
begin
-- Exported variables cannot have an address clause, because
-- this cancels the effect of the pragma Export.
if Is_Exported (U_Ent) then
Error_Msg_N
("cannot export object with address clause", Nam);
return;
end if;
Find_Overlaid_Entity (N, O_Ent, Off);
-- Overlaying controlled objects is erroneous
if Present (O_Ent)
and then (Has_Controlled_Component (Etype (O_Ent))
or else Is_Controlled (Etype (O_Ent)))
then
Error_Msg_N
("?cannot overlay with controlled object", Expr);
Error_Msg_N
("\?Program_Error will be raised at run time", Expr);
Insert_Action (Declaration_Node (U_Ent),
Make_Raise_Program_Error (Loc,
Reason => PE_Overlaid_Controlled_Object));
return;
elsif Present (O_Ent)
and then Ekind (U_Ent) = E_Constant
and then not Is_Constant_Object (O_Ent)
then
Error_Msg_N ("constant overlays a variable?", Expr);
elsif Present (Renamed_Object (U_Ent)) then
Error_Msg_N
("address clause not allowed"
& " for a renaming declaration (RM 13.1(6))", Nam);
return;
-- Imported variables can have an address clause, but then
-- the import is pretty meaningless except to suppress
-- initializations, so we do not need such variables to
-- be statically allocated (and in fact it causes trouble
-- if the address clause is a local value).
elsif Is_Imported (U_Ent) then
Set_Is_Statically_Allocated (U_Ent, False);
end if;
-- We mark a possible modification of a variable with an
-- address clause, since it is likely aliasing is occurring.
Note_Possible_Modification (Nam, Sure => False);
-- Here we are checking for explicit overlap of one variable
-- by another, and if we find this then mark the overlapped
-- variable as also being volatile to prevent unwanted
-- optimizations. This is a significant pessimization so
-- avoid it when there is an offset, i.e. when the object
-- is composite; they cannot be optimized easily anyway.
if Present (O_Ent)
and then Is_Object (O_Ent)
and then not Off
then
Set_Treat_As_Volatile (O_Ent);
end if;
-- Legality checks on the address clause for initialized
-- objects is deferred until the freeze point, because
-- a subsequent pragma might indicate that the object is
-- imported and thus not initialized.
Set_Has_Delayed_Freeze (U_Ent);
-- If an initialization call has been generated for this
-- object, it needs to be deferred to after the freeze node
-- we have just now added, otherwise GIGI will see a
-- reference to the variable (as actual to the IP call)
-- before its definition.
declare
Init_Call : constant Node_Id := Find_Init_Call (U_Ent, N);
begin
if Present (Init_Call) then
Remove (Init_Call);
Append_Freeze_Action (U_Ent, Init_Call);
end if;
end;
if Is_Exported (U_Ent) then
Error_Msg_N
("& cannot be exported if an address clause is given",
Nam);
Error_Msg_N
("\define and export a variable " &
"that holds its address instead",
Nam);
end if;
-- Entity has delayed freeze, so we will generate an
-- alignment check at the freeze point unless suppressed.
if not Range_Checks_Suppressed (U_Ent)
and then not Alignment_Checks_Suppressed (U_Ent)
then
Set_Check_Address_Alignment (N);
end if;
-- Kill the size check code, since we are not allocating
-- the variable, it is somewhere else.
Kill_Size_Check_Code (U_Ent);
-- If the address clause is of the form:
-- for Y'Address use X'Address
-- or
-- Const : constant Address := X'Address;
-- ...
-- for Y'Address use Const;
-- then we make an entry in the table for checking the size
-- and alignment of the overlaying variable. We defer this
-- check till after code generation to take full advantage
-- of the annotation done by the back end. This entry is
-- only made if the address clause comes from source.
-- If the entity has a generic type, the check will be
-- performed in the instance if the actual type justifies
-- it, and we do not insert the clause in the table to
-- prevent spurious warnings.
if Address_Clause_Overlay_Warnings
and then Comes_From_Source (N)
and then Present (O_Ent)
and then Is_Object (O_Ent)
then
if not Is_Generic_Type (Etype (U_Ent)) then
Address_Clause_Checks.Append ((N, U_Ent, O_Ent, Off));
end if;
-- If variable overlays a constant view, and we are
-- warning on overlays, then mark the variable as
-- overlaying a constant (we will give warnings later
-- if this variable is assigned).
if Is_Constant_Object (O_Ent)
and then Ekind (U_Ent) = E_Variable
then
Set_Overlays_Constant (U_Ent);
end if;
end if;
end;
-- Not a valid entity for an address clause
else
Error_Msg_N ("address cannot be given for &", Nam);
end if;
end Address;
---------------
-- Alignment --
---------------
-- Alignment attribute definition clause
when Attribute_Alignment => Alignment : declare
Align : constant Uint := Get_Alignment_Value (Expr);
begin
FOnly := True;
if not Is_Type (U_Ent)
and then Ekind (U_Ent) /= E_Variable
and then Ekind (U_Ent) /= E_Constant
then
Error_Msg_N ("alignment cannot be given for &", Nam);
elsif Duplicate_Clause then
null;
elsif Align /= No_Uint then
Set_Has_Alignment_Clause (U_Ent);
Set_Alignment (U_Ent, Align);
-- For an array type, U_Ent is the first subtype. In that case,
-- also set the alignment of the anonymous base type so that
-- other subtypes (such as the itypes for aggregates of the
-- type) also receive the expected alignment.
if Is_Array_Type (U_Ent) then
Set_Alignment (Base_Type (U_Ent), Align);
end if;
end if;
end Alignment;
---------------
-- Bit_Order --
---------------
-- Bit_Order attribute definition clause
when Attribute_Bit_Order => Bit_Order : declare
begin
if not Is_Record_Type (U_Ent) then
Error_Msg_N
("Bit_Order can only be defined for record type", Nam);
elsif Duplicate_Clause then
null;
else
Analyze_And_Resolve (Expr, RTE (RE_Bit_Order));
if Etype (Expr) = Any_Type then
return;
elsif not Is_Static_Expression (Expr) then
Flag_Non_Static_Expr
("Bit_Order requires static expression!", Expr);
else
if (Expr_Value (Expr) = 0) /= Bytes_Big_Endian then
Set_Reverse_Bit_Order (U_Ent, True);
end if;
end if;
end if;
end Bit_Order;
--------------------
-- Component_Size --
--------------------
-- Component_Size attribute definition clause
when Attribute_Component_Size => Component_Size_Case : declare
Csize : constant Uint := Static_Integer (Expr);
Ctyp : Entity_Id;
Btype : Entity_Id;
Biased : Boolean;
New_Ctyp : Entity_Id;
Decl : Node_Id;
begin
if not Is_Array_Type (U_Ent) then
Error_Msg_N ("component size requires array type", Nam);
return;
end if;
Btype := Base_Type (U_Ent);
Ctyp := Component_Type (Btype);
if Duplicate_Clause then
null;
elsif Rep_Item_Too_Early (Btype, N) then
null;
elsif Csize /= No_Uint then
Check_Size (Expr, Ctyp, Csize, Biased);
-- For the biased case, build a declaration for a subtype that
-- will be used to represent the biased subtype that reflects
-- the biased representation of components. We need the subtype
-- to get proper conversions on referencing elements of the
-- array. Note: component size clauses are ignored in VM mode.
if VM_Target = No_VM then
if Biased then
New_Ctyp :=
Make_Defining_Identifier (Loc,
Chars =>
New_External_Name (Chars (U_Ent), 'C', 0, 'T'));
Decl :=
Make_Subtype_Declaration (Loc,
Defining_Identifier => New_Ctyp,
Subtype_Indication =>
New_Occurrence_Of (Component_Type (Btype), Loc));
Set_Parent (Decl, N);
Analyze (Decl, Suppress => All_Checks);
Set_Has_Delayed_Freeze (New_Ctyp, False);
Set_Esize (New_Ctyp, Csize);
Set_RM_Size (New_Ctyp, Csize);
Init_Alignment (New_Ctyp);
Set_Is_Itype (New_Ctyp, True);
Set_Associated_Node_For_Itype (New_Ctyp, U_Ent);
Set_Component_Type (Btype, New_Ctyp);
Set_Biased (New_Ctyp, N, "component size clause");
end if;
Set_Component_Size (Btype, Csize);
-- For VM case, we ignore component size clauses
else
-- Give a warning unless we are in GNAT mode, in which case
-- the warning is suppressed since it is not useful.
if not GNAT_Mode then
Error_Msg_N
("?component size ignored in this configuration", N);
end if;
end if;
-- Deal with warning on overridden size
if Warn_On_Overridden_Size
and then Has_Size_Clause (Ctyp)
and then RM_Size (Ctyp) /= Csize
then
Error_Msg_NE
("?component size overrides size clause for&",
N, Ctyp);
end if;
Set_Has_Component_Size_Clause (Btype, True);
Set_Has_Non_Standard_Rep (Btype, True);
end if;
end Component_Size_Case;
------------------
-- External_Tag --
------------------
when Attribute_External_Tag => External_Tag :
begin
if not Is_Tagged_Type (U_Ent) then
Error_Msg_N ("should be a tagged type", Nam);
end if;
if Duplicate_Clause then
null;
else
Analyze_And_Resolve (Expr, Standard_String);
if not Is_Static_Expression (Expr) then
Flag_Non_Static_Expr
("static string required for tag name!", Nam);
end if;
if VM_Target = No_VM then
Set_Has_External_Tag_Rep_Clause (U_Ent);
else
Error_Msg_Name_1 := Attr;
Error_Msg_N
("% attribute unsupported in this configuration", Nam);
end if;
if not Is_Library_Level_Entity (U_Ent) then
Error_Msg_NE
("?non-unique external tag supplied for &", N, U_Ent);
Error_Msg_N
("?\same external tag applies to all subprogram calls", N);
Error_Msg_N
("?\corresponding internal tag cannot be obtained", N);
end if;
end if;
end External_Tag;
-----------
-- Input --
-----------
when Attribute_Input =>
Analyze_Stream_TSS_Definition (TSS_Stream_Input);
Set_Has_Specified_Stream_Input (Ent);
-------------------
-- Machine_Radix --
-------------------
-- Machine radix attribute definition clause
when Attribute_Machine_Radix => Machine_Radix : declare
Radix : constant Uint := Static_Integer (Expr);
begin
if not Is_Decimal_Fixed_Point_Type (U_Ent) then
Error_Msg_N ("decimal fixed-point type expected for &", Nam);
elsif Duplicate_Clause then
null;
elsif Radix /= No_Uint then
Set_Has_Machine_Radix_Clause (U_Ent);
Set_Has_Non_Standard_Rep (Base_Type (U_Ent));
if Radix = 2 then
null;
elsif Radix = 10 then
Set_Machine_Radix_10 (U_Ent);
else
Error_Msg_N ("machine radix value must be 2 or 10", Expr);
end if;
end if;
end Machine_Radix;
-----------------
-- Object_Size --
-----------------
-- Object_Size attribute definition clause
when Attribute_Object_Size => Object_Size : declare
Size : constant Uint := Static_Integer (Expr);
Biased : Boolean;
pragma Warnings (Off, Biased);
begin
if not Is_Type (U_Ent) then
Error_Msg_N ("Object_Size cannot be given for &", Nam);
elsif Duplicate_Clause then
null;
else
Check_Size (Expr, U_Ent, Size, Biased);
if Size /= 8
and then
Size /= 16
and then
Size /= 32
and then
UI_Mod (Size, 64) /= 0
then
Error_Msg_N
("Object_Size must be 8, 16, 32, or multiple of 64",
Expr);
end if;
Set_Esize (U_Ent, Size);
Set_Has_Object_Size_Clause (U_Ent);
Alignment_Check_For_Esize_Change (U_Ent);
end if;
end Object_Size;
------------
-- Output --
------------
when Attribute_Output =>
Analyze_Stream_TSS_Definition (TSS_Stream_Output);
Set_Has_Specified_Stream_Output (Ent);
----------
-- Read --
----------
when Attribute_Read =>
Analyze_Stream_TSS_Definition (TSS_Stream_Read);
Set_Has_Specified_Stream_Read (Ent);
----------
-- Size --
----------
-- Size attribute definition clause
when Attribute_Size => Size : declare
Size : constant Uint := Static_Integer (Expr);
Etyp : Entity_Id;
Biased : Boolean;
begin
FOnly := True;
if Duplicate_Clause then
null;
elsif not Is_Type (U_Ent)
and then Ekind (U_Ent) /= E_Variable
and then Ekind (U_Ent) /= E_Constant
then
Error_Msg_N ("size cannot be given for &", Nam);
elsif Is_Array_Type (U_Ent)
and then not Is_Constrained (U_Ent)
then
Error_Msg_N
("size cannot be given for unconstrained array", Nam);
elsif Size /= No_Uint then
if VM_Target /= No_VM and then not GNAT_Mode then
-- Size clause is not handled properly on VM targets.
-- Display a warning unless we are in GNAT mode, in which
-- case this is useless.
Error_Msg_N
("?size clauses are ignored in this configuration", N);
end if;
if Is_Type (U_Ent) then
Etyp := U_Ent;
else
Etyp := Etype (U_Ent);
end if;
-- Check size, note that Gigi is in charge of checking that the
-- size of an array or record type is OK. Also we do not check
-- the size in the ordinary fixed-point case, since it is too
-- early to do so (there may be subsequent small clause that
-- affects the size). We can check the size if a small clause
-- has already been given.
if not Is_Ordinary_Fixed_Point_Type (U_Ent)
or else Has_Small_Clause (U_Ent)
then
Check_Size (Expr, Etyp, Size, Biased);
Set_Biased (U_Ent, N, "size clause", Biased);
end if;
-- For types set RM_Size and Esize if possible
if Is_Type (U_Ent) then
Set_RM_Size (U_Ent, Size);
-- For scalar types, increase Object_Size to power of 2, but
-- not less than a storage unit in any case (i.e., normally
-- this means it will be byte addressable).
if Is_Scalar_Type (U_Ent) then
if Size <= System_Storage_Unit then
Init_Esize (U_Ent, System_Storage_Unit);
elsif Size <= 16 then
Init_Esize (U_Ent, 16);
elsif Size <= 32 then
Init_Esize (U_Ent, 32);
else
Set_Esize (U_Ent, (Size + 63) / 64 * 64);
end if;
-- For all other types, object size = value size. The
-- backend will adjust as needed.
else
Set_Esize (U_Ent, Size);
end if;
Alignment_Check_For_Esize_Change (U_Ent);
-- For objects, set Esize only
else
if Is_Elementary_Type (Etyp) then
if Size /= System_Storage_Unit
and then
Size /= System_Storage_Unit * 2
and then
Size /= System_Storage_Unit * 4
and then
Size /= System_Storage_Unit * 8
then
Error_Msg_Uint_1 := UI_From_Int (System_Storage_Unit);
Error_Msg_Uint_2 := Error_Msg_Uint_1 * 8;
Error_Msg_N
("size for primitive object must be a power of 2"
& " in the range ^-^", N);
end if;
end if;
Set_Esize (U_Ent, Size);
end if;
Set_Has_Size_Clause (U_Ent);
end if;
end Size;
-----------
-- Small --
-----------
-- Small attribute definition clause
when Attribute_Small => Small : declare
Implicit_Base : constant Entity_Id := Base_Type (U_Ent);
Small : Ureal;
begin
Analyze_And_Resolve (Expr, Any_Real);
if Etype (Expr) = Any_Type then
return;
elsif not Is_Static_Expression (Expr) then
Flag_Non_Static_Expr
("small requires static expression!", Expr);
return;
else
Small := Expr_Value_R (Expr);
if Small <= Ureal_0 then
Error_Msg_N ("small value must be greater than zero", Expr);
return;
end if;
end if;
if not Is_Ordinary_Fixed_Point_Type (U_Ent) then
Error_Msg_N
("small requires an ordinary fixed point type", Nam);
elsif Has_Small_Clause (U_Ent) then
Error_Msg_N ("small already given for &", Nam);
elsif Small > Delta_Value (U_Ent) then
Error_Msg_N
("small value must not be greater then delta value", Nam);
else
Set_Small_Value (U_Ent, Small);
Set_Small_Value (Implicit_Base, Small);
Set_Has_Small_Clause (U_Ent);
Set_Has_Small_Clause (Implicit_Base);
Set_Has_Non_Standard_Rep (Implicit_Base);
end if;
end Small;
------------------
-- Storage_Pool --
------------------
-- Storage_Pool attribute definition clause
when Attribute_Storage_Pool => Storage_Pool : declare
Pool : Entity_Id;
T : Entity_Id;
begin
if Ekind (U_Ent) = E_Access_Subprogram_Type then
Error_Msg_N
("storage pool cannot be given for access-to-subprogram type",
Nam);
return;
elsif not
Ekind_In (U_Ent, E_Access_Type, E_General_Access_Type)
then
Error_Msg_N
("storage pool can only be given for access types", Nam);
return;
elsif Is_Derived_Type (U_Ent) then
Error_Msg_N
("storage pool cannot be given for a derived access type",
Nam);
elsif Duplicate_Clause then
return;
elsif Present (Associated_Storage_Pool (U_Ent)) then
Error_Msg_N ("storage pool already given for &", Nam);
return;
end if;
Analyze_And_Resolve
(Expr, Class_Wide_Type (RTE (RE_Root_Storage_Pool)));
if not Denotes_Variable (Expr) then
Error_Msg_N ("storage pool must be a variable", Expr);
return;
end if;
if Nkind (Expr) = N_Type_Conversion then
T := Etype (Expression (Expr));
else
T := Etype (Expr);
end if;
-- The Stack_Bounded_Pool is used internally for implementing
-- access types with a Storage_Size. Since it only work
-- properly when used on one specific type, we need to check
-- that it is not hijacked improperly:
-- type T is access Integer;
-- for T'Storage_Size use n;
-- type Q is access Float;
-- for Q'Storage_Size use T'Storage_Size; -- incorrect
if RTE_Available (RE_Stack_Bounded_Pool)
and then Base_Type (T) = RTE (RE_Stack_Bounded_Pool)
then
Error_Msg_N ("non-shareable internal Pool", Expr);
return;
end if;
-- If the argument is a name that is not an entity name, then
-- we construct a renaming operation to define an entity of
-- type storage pool.
if not Is_Entity_Name (Expr)
and then Is_Object_Reference (Expr)
then
Pool := Make_Temporary (Loc, 'P', Expr);
declare
Rnode : constant Node_Id :=
Make_Object_Renaming_Declaration (Loc,
Defining_Identifier => Pool,
Subtype_Mark =>
New_Occurrence_Of (Etype (Expr), Loc),
Name => Expr);
begin
Insert_Before (N, Rnode);
Analyze (Rnode);
Set_Associated_Storage_Pool (U_Ent, Pool);
end;
elsif Is_Entity_Name (Expr) then
Pool := Entity (Expr);
-- If pool is a renamed object, get original one. This can
-- happen with an explicit renaming, and within instances.
while Present (Renamed_Object (Pool))
and then Is_Entity_Name (Renamed_Object (Pool))
loop
Pool := Entity (Renamed_Object (Pool));
end loop;
if Present (Renamed_Object (Pool))
and then Nkind (Renamed_Object (Pool)) = N_Type_Conversion
and then Is_Entity_Name (Expression (Renamed_Object (Pool)))
then
Pool := Entity (Expression (Renamed_Object (Pool)));
end if;
Set_Associated_Storage_Pool (U_Ent, Pool);
elsif Nkind (Expr) = N_Type_Conversion
and then Is_Entity_Name (Expression (Expr))
and then Nkind (Original_Node (Expr)) = N_Attribute_Reference
then
Pool := Entity (Expression (Expr));
Set_Associated_Storage_Pool (U_Ent, Pool);
else
Error_Msg_N ("incorrect reference to a Storage Pool", Expr);
return;
end if;
end Storage_Pool;
------------------
-- Storage_Size --
------------------
-- Storage_Size attribute definition clause
when Attribute_Storage_Size => Storage_Size : declare
Btype : constant Entity_Id := Base_Type (U_Ent);
Sprag : Node_Id;
begin
if Is_Task_Type (U_Ent) then
Check_Restriction (No_Obsolescent_Features, N);
if Warn_On_Obsolescent_Feature then
Error_Msg_N
("storage size clause for task is an " &
"obsolescent feature (RM J.9)?", N);
Error_Msg_N ("\use Storage_Size pragma instead?", N);
end if;
FOnly := True;
end if;
if not Is_Access_Type (U_Ent)
and then Ekind (U_Ent) /= E_Task_Type
then
Error_Msg_N ("storage size cannot be given for &", Nam);
elsif Is_Access_Type (U_Ent) and Is_Derived_Type (U_Ent) then
Error_Msg_N
("storage size cannot be given for a derived access type",
Nam);
elsif Duplicate_Clause then
null;
else
Analyze_And_Resolve (Expr, Any_Integer);
if Is_Access_Type (U_Ent) then
if Present (Associated_Storage_Pool (U_Ent)) then
Error_Msg_N ("storage pool already given for &", Nam);
return;
end if;
if Is_OK_Static_Expression (Expr)
and then Expr_Value (Expr) = 0
then
Set_No_Pool_Assigned (Btype);
end if;
else -- Is_Task_Type (U_Ent)
Sprag := Get_Rep_Pragma (Btype, Name_Storage_Size);
if Present (Sprag) then
Error_Msg_Sloc := Sloc (Sprag);
Error_Msg_N
("Storage_Size already specified#", Nam);
return;
end if;
end if;
Set_Has_Storage_Size_Clause (Btype);
end if;
end Storage_Size;
-----------------
-- Stream_Size --
-----------------
when Attribute_Stream_Size => Stream_Size : declare
Size : constant Uint := Static_Integer (Expr);
begin
if Ada_Version <= Ada_95 then
Check_Restriction (No_Implementation_Attributes, N);
end if;
if Duplicate_Clause then
null;
elsif Is_Elementary_Type (U_Ent) then
if Size /= System_Storage_Unit
and then
Size /= System_Storage_Unit * 2
and then
Size /= System_Storage_Unit * 4
and then
Size /= System_Storage_Unit * 8
then
Error_Msg_Uint_1 := UI_From_Int (System_Storage_Unit);
Error_Msg_N
("stream size for elementary type must be a"
& " power of 2 and at least ^", N);
elsif RM_Size (U_Ent) > Size then
Error_Msg_Uint_1 := RM_Size (U_Ent);
Error_Msg_N
("stream size for elementary type must be a"
& " power of 2 and at least ^", N);
end if;
Set_Has_Stream_Size_Clause (U_Ent);
else
Error_Msg_N ("Stream_Size cannot be given for &", Nam);
end if;
end Stream_Size;
----------------
-- Value_Size --
----------------
-- Value_Size attribute definition clause
when Attribute_Value_Size => Value_Size : declare
Size : constant Uint := Static_Integer (Expr);
Biased : Boolean;
begin
if not Is_Type (U_Ent) then
Error_Msg_N ("Value_Size cannot be given for &", Nam);
elsif Duplicate_Clause then
null;
elsif Is_Array_Type (U_Ent)
and then not Is_Constrained (U_Ent)
then
Error_Msg_N
("Value_Size cannot be given for unconstrained array", Nam);
else
if Is_Elementary_Type (U_Ent) then
Check_Size (Expr, U_Ent, Size, Biased);
Set_Biased (U_Ent, N, "value size clause", Biased);
end if;
Set_RM_Size (U_Ent, Size);
end if;
end Value_Size;
-----------
-- Write --
-----------
when Attribute_Write =>
Analyze_Stream_TSS_Definition (TSS_Stream_Write);
Set_Has_Specified_Stream_Write (Ent);
-- All other attributes cannot be set
when others =>
Error_Msg_N
("attribute& cannot be set with definition clause", N);
end case;
-- The test for the type being frozen must be performed after
-- any expression the clause has been analyzed since the expression
-- itself might cause freezing that makes the clause illegal.
if Rep_Item_Too_Late (U_Ent, N, FOnly) then
return;
end if;
end Analyze_Attribute_Definition_Clause;
----------------------------
-- Analyze_Code_Statement --
----------------------------
procedure Analyze_Code_Statement (N : Node_Id) is
HSS : constant Node_Id := Parent (N);
SBody : constant Node_Id := Parent (HSS);
Subp : constant Entity_Id := Current_Scope;
Stmt : Node_Id;
Decl : Node_Id;
StmtO : Node_Id;
DeclO : Node_Id;
begin
-- Analyze and check we get right type, note that this implements the
-- requirement (RM 13.8(1)) that Machine_Code be with'ed, since that
-- is the only way that Asm_Insn could possibly be visible.
Analyze_And_Resolve (Expression (N));
if Etype (Expression (N)) = Any_Type then
return;
elsif Etype (Expression (N)) /= RTE (RE_Asm_Insn) then
Error_Msg_N ("incorrect type for code statement", N);
return;
end if;
Check_Code_Statement (N);
-- Make sure we appear in the handled statement sequence of a
-- subprogram (RM 13.8(3)).
if Nkind (HSS) /= N_Handled_Sequence_Of_Statements
or else Nkind (SBody) /= N_Subprogram_Body
then
Error_Msg_N
("code statement can only appear in body of subprogram", N);
return;
end if;
-- Do remaining checks (RM 13.8(3)) if not already done
if not Is_Machine_Code_Subprogram (Subp) then
Set_Is_Machine_Code_Subprogram (Subp);
-- No exception handlers allowed
if Present (Exception_Handlers (HSS)) then
Error_Msg_N
("exception handlers not permitted in machine code subprogram",
First (Exception_Handlers (HSS)));
end if;
-- No declarations other than use clauses and pragmas (we allow
-- certain internally generated declarations as well).
Decl := First (Declarations (SBody));
while Present (Decl) loop
DeclO := Original_Node (Decl);
if Comes_From_Source (DeclO)
and not Nkind_In (DeclO, N_Pragma,
N_Use_Package_Clause,
N_Use_Type_Clause,
N_Implicit_Label_Declaration)
then
Error_Msg_N
("this declaration not allowed in machine code subprogram",
DeclO);
end if;
Next (Decl);
end loop;
-- No statements other than code statements, pragmas, and labels.
-- Again we allow certain internally generated statements.
Stmt := First (Statements (HSS));
while Present (Stmt) loop
StmtO := Original_Node (Stmt);
if Comes_From_Source (StmtO)
and then not Nkind_In (StmtO, N_Pragma,
N_Label,
N_Code_Statement)
then
Error_Msg_N
("this statement is not allowed in machine code subprogram",
StmtO);
end if;
Next (Stmt);
end loop;
end if;
end Analyze_Code_Statement;
-----------------------------------------------
-- Analyze_Enumeration_Representation_Clause --
-----------------------------------------------
procedure Analyze_Enumeration_Representation_Clause (N : Node_Id) is
Ident : constant Node_Id := Identifier (N);
Aggr : constant Node_Id := Array_Aggregate (N);
Enumtype : Entity_Id;
Elit : Entity_Id;
Expr : Node_Id;
Assoc : Node_Id;
Choice : Node_Id;
Val : Uint;
Err : Boolean := False;
Lo : constant Uint := Expr_Value (Type_Low_Bound (Universal_Integer));
Hi : constant Uint := Expr_Value (Type_High_Bound (Universal_Integer));
-- Allowed range of universal integer (= allowed range of enum lit vals)
Min : Uint;
Max : Uint;
-- Minimum and maximum values of entries
Max_Node : Node_Id;
-- Pointer to node for literal providing max value
begin
if Ignore_Rep_Clauses then
return;
end if;
-- First some basic error checks
Find_Type (Ident);
Enumtype := Entity (Ident);
if Enumtype = Any_Type
or else Rep_Item_Too_Early (Enumtype, N)
then
return;
else
Enumtype := Underlying_Type (Enumtype);
end if;
if not Is_Enumeration_Type (Enumtype) then
Error_Msg_NE
("enumeration type required, found}",
Ident, First_Subtype (Enumtype));
return;
end if;
-- Ignore rep clause on generic actual type. This will already have
-- been flagged on the template as an error, and this is the safest
-- way to ensure we don't get a junk cascaded message in the instance.
if Is_Generic_Actual_Type (Enumtype) then
return;
-- Type must be in current scope
elsif Scope (Enumtype) /= Current_Scope then
Error_Msg_N ("type must be declared in this scope", Ident);
return;
-- Type must be a first subtype
elsif not Is_First_Subtype (Enumtype) then
Error_Msg_N ("cannot give enumeration rep clause for subtype", N);
return;
-- Ignore duplicate rep clause
elsif Has_Enumeration_Rep_Clause (Enumtype) then
Error_Msg_N ("duplicate enumeration rep clause ignored", N);
return;
-- Don't allow rep clause for standard [wide_[wide_]]character
elsif Is_Standard_Character_Type (Enumtype) then
Error_Msg_N ("enumeration rep clause not allowed for this type", N);
return;
-- Check that the expression is a proper aggregate (no parentheses)
elsif Paren_Count (Aggr) /= 0 then
Error_Msg
("extra parentheses surrounding aggregate not allowed",
First_Sloc (Aggr));
return;
-- All tests passed, so set rep clause in place
else
Set_Has_Enumeration_Rep_Clause (Enumtype);
Set_Has_Enumeration_Rep_Clause (Base_Type (Enumtype));
end if;
-- Now we process the aggregate. Note that we don't use the normal
-- aggregate code for this purpose, because we don't want any of the
-- normal expansion activities, and a number of special semantic
-- rules apply (including the component type being any integer type)
Elit := First_Literal (Enumtype);
-- First the positional entries if any
if Present (Expressions (Aggr)) then
Expr := First (Expressions (Aggr));
while Present (Expr) loop
if No (Elit) then
Error_Msg_N ("too many entries in aggregate", Expr);
return;
end if;
Val := Static_Integer (Expr);
-- Err signals that we found some incorrect entries processing
-- the list. The final checks for completeness and ordering are
-- skipped in this case.
if Val = No_Uint then
Err := True;
elsif Val < Lo or else Hi < Val then
Error_Msg_N ("value outside permitted range", Expr);
Err := True;
end if;
Set_Enumeration_Rep (Elit, Val);
Set_Enumeration_Rep_Expr (Elit, Expr);
Next (Expr);
Next (Elit);
end loop;
end if;
-- Now process the named entries if present
if Present (Component_Associations (Aggr)) then
Assoc := First (Component_Associations (Aggr));
while Present (Assoc) loop
Choice := First (Choices (Assoc));
if Present (Next (Choice)) then
Error_Msg_N
("multiple choice not allowed here", Next (Choice));
Err := True;
end if;
if Nkind (Choice) = N_Others_Choice then
Error_Msg_N ("others choice not allowed here", Choice);
Err := True;
elsif Nkind (Choice) = N_Range then
-- ??? should allow zero/one element range here
Error_Msg_N ("range not allowed here", Choice);
Err := True;
else
Analyze_And_Resolve (Choice, Enumtype);
if Is_Entity_Name (Choice)
and then Is_Type (Entity (Choice))
then
Error_Msg_N ("subtype name not allowed here", Choice);
Err := True;
-- ??? should allow static subtype with zero/one entry
elsif Etype (Choice) = Base_Type (Enumtype) then
if not Is_Static_Expression (Choice) then
Flag_Non_Static_Expr
("non-static expression used for choice!", Choice);
Err := True;
else
Elit := Expr_Value_E (Choice);
if Present (Enumeration_Rep_Expr (Elit)) then
Error_Msg_Sloc := Sloc (Enumeration_Rep_Expr (Elit));
Error_Msg_NE
("representation for& previously given#",
Choice, Elit);
Err := True;
end if;
Set_Enumeration_Rep_Expr (Elit, Expression (Assoc));
Expr := Expression (Assoc);
Val := Static_Integer (Expr);
if Val = No_Uint then
Err := True;
elsif Val < Lo or else Hi < Val then
Error_Msg_N ("value outside permitted range", Expr);
Err := True;
end if;
Set_Enumeration_Rep (Elit, Val);
end if;
end if;
end if;
Next (Assoc);
end loop;
end if;
-- Aggregate is fully processed. Now we check that a full set of
-- representations was given, and that they are in range and in order.
-- These checks are only done if no other errors occurred.
if not Err then
Min := No_Uint;
Max := No_Uint;
Elit := First_Literal (Enumtype);
while Present (Elit) loop
if No (Enumeration_Rep_Expr (Elit)) then
Error_Msg_NE ("missing representation for&!", N, Elit);
else
Val := Enumeration_Rep (Elit);
if Min = No_Uint then
Min := Val;
end if;
if Val /= No_Uint then
if Max /= No_Uint and then Val <= Max then
Error_Msg_NE
("enumeration value for& not ordered!",
Enumeration_Rep_Expr (Elit), Elit);
end if;
Max_Node := Enumeration_Rep_Expr (Elit);
Max := Val;
end if;
-- If there is at least one literal whose representation is not
-- equal to the Pos value, then note that this enumeration type
-- has a non-standard representation.
if Val /= Enumeration_Pos (Elit) then
Set_Has_Non_Standard_Rep (Base_Type (Enumtype));
end if;
end if;
Next (Elit);
end loop;
-- Now set proper size information
declare
Minsize : Uint := UI_From_Int (Minimum_Size (Enumtype));
begin
if Has_Size_Clause (Enumtype) then
-- All OK, if size is OK now
if RM_Size (Enumtype) >= Minsize then
null;
else
-- Try if we can get by with biasing
Minsize :=
UI_From_Int (Minimum_Size (Enumtype, Biased => True));
-- Error message if even biasing does not work
if RM_Size (Enumtype) < Minsize then
Error_Msg_Uint_1 := RM_Size (Enumtype);
Error_Msg_Uint_2 := Max;
Error_Msg_N
("previously given size (^) is too small "
& "for this value (^)", Max_Node);
-- If biasing worked, indicate that we now have biased rep
else
Set_Biased
(Enumtype, Size_Clause (Enumtype), "size clause");
end if;
end if;
else
Set_RM_Size (Enumtype, Minsize);
Set_Enum_Esize (Enumtype);
end if;
Set_RM_Size (Base_Type (Enumtype), RM_Size (Enumtype));
Set_Esize (Base_Type (Enumtype), Esize (Enumtype));
Set_Alignment (Base_Type (Enumtype), Alignment (Enumtype));
end;
end if;
-- We repeat the too late test in case it froze itself!
if Rep_Item_Too_Late (Enumtype, N) then
null;
end if;
end Analyze_Enumeration_Representation_Clause;
----------------------------
-- Analyze_Free_Statement --
----------------------------
procedure Analyze_Free_Statement (N : Node_Id) is
begin
Analyze (Expression (N));
end Analyze_Free_Statement;
---------------------------
-- Analyze_Freeze_Entity --
---------------------------
procedure Analyze_Freeze_Entity (N : Node_Id) is
E : constant Entity_Id := Entity (N);
begin
-- Remember that we are processing a freezing entity. Required to
-- ensure correct decoration of internal entities associated with
-- interfaces (see New_Overloaded_Entity).
Inside_Freezing_Actions := Inside_Freezing_Actions + 1;
-- For tagged types covering interfaces add internal entities that link
-- the primitives of the interfaces with the primitives that cover them.
-- Note: These entities were originally generated only when generating
-- code because their main purpose was to provide support to initialize
-- the secondary dispatch tables. They are now generated also when
-- compiling with no code generation to provide ASIS the relationship
-- between interface primitives and tagged type primitives. They are
-- also used to locate primitives covering interfaces when processing
-- generics (see Derive_Subprograms).
if Ada_Version >= Ada_2005
and then Ekind (E) = E_Record_Type
and then Is_Tagged_Type (E)
and then not Is_Interface (E)
and then Has_Interfaces (E)
then
-- This would be a good common place to call the routine that checks
-- overriding of interface primitives (and thus factorize calls to
-- Check_Abstract_Overriding located at different contexts in the
-- compiler). However, this is not possible because it causes
-- spurious errors in case of late overriding.
Add_Internal_Interface_Entities (E);
end if;
-- Check CPP types
if Ekind (E) = E_Record_Type
and then Is_CPP_Class (E)
and then Is_Tagged_Type (E)
and then Tagged_Type_Expansion
and then Expander_Active
then
if CPP_Num_Prims (E) = 0 then
-- If the CPP type has user defined components then it must import
-- primitives from C++. This is required because if the C++ class
-- has no primitives then the C++ compiler does not added the _tag
-- component to the type.
pragma Assert (Chars (First_Entity (E)) = Name_uTag);
if First_Entity (E) /= Last_Entity (E) then
Error_Msg_N
("?'C'P'P type must import at least one primitive from C++",
E);
end if;
end if;
-- Check that all its primitives are abstract or imported from C++.
-- Check also availability of the C++ constructor.
declare
Has_Constructors : constant Boolean := Has_CPP_Constructors (E);
Elmt : Elmt_Id;
Error_Reported : Boolean := False;
Prim : Node_Id;
begin
Elmt := First_Elmt (Primitive_Operations (E));
while Present (Elmt) loop
Prim := Node (Elmt);
if Comes_From_Source (Prim) then
if Is_Abstract_Subprogram (Prim) then
null;
elsif not Is_Imported (Prim)
or else Convention (Prim) /= Convention_CPP
then
Error_Msg_N
("?primitives of 'C'P'P types must be imported from C++"
& " or abstract", Prim);
elsif not Has_Constructors
and then not Error_Reported
then
Error_Msg_Name_1 := Chars (E);
Error_Msg_N
("?'C'P'P constructor required for type %", Prim);
Error_Reported := True;
end if;
end if;
Next_Elmt (Elmt);
end loop;
end;
end if;
Inside_Freezing_Actions := Inside_Freezing_Actions - 1;
-- If we have a type with predicates, build predicate function
if Is_Type (E) and then Has_Predicates (E) then
Build_Predicate_Function (E, N);
end if;
end Analyze_Freeze_Entity;
------------------------------------------
-- Analyze_Record_Representation_Clause --
------------------------------------------
-- Note: we check as much as we can here, but we can't do any checks
-- based on the position values (e.g. overlap checks) until freeze time
-- because especially in Ada 2005 (machine scalar mode), the processing
-- for non-standard bit order can substantially change the positions.
-- See procedure Check_Record_Representation_Clause (called from Freeze)
-- for the remainder of this processing.
procedure Analyze_Record_Representation_Clause (N : Node_Id) is
Ident : constant Node_Id := Identifier (N);
Biased : Boolean;
CC : Node_Id;
Comp : Entity_Id;
Fbit : Uint;
Hbit : Uint := Uint_0;
Lbit : Uint;
Ocomp : Entity_Id;
Posit : Uint;
Rectype : Entity_Id;
CR_Pragma : Node_Id := Empty;
-- Points to N_Pragma node if Complete_Representation pragma present
begin
if Ignore_Rep_Clauses then
return;
end if;
Find_Type (Ident);
Rectype := Entity (Ident);
if Rectype = Any_Type
or else Rep_Item_Too_Early (Rectype, N)
then
return;
else
Rectype := Underlying_Type (Rectype);
end if;
-- First some basic error checks
if not Is_Record_Type (Rectype) then
Error_Msg_NE
("record type required, found}", Ident, First_Subtype (Rectype));
return;
elsif Scope (Rectype) /= Current_Scope then
Error_Msg_N ("type must be declared in this scope", N);
return;
elsif not Is_First_Subtype (Rectype) then
Error_Msg_N ("cannot give record rep clause for subtype", N);
return;
elsif Has_Record_Rep_Clause (Rectype) then
Error_Msg_N ("duplicate record rep clause ignored", N);
return;
elsif Rep_Item_Too_Late (Rectype, N) then
return;
end if;
if Present (Mod_Clause (N)) then
declare
Loc : constant Source_Ptr := Sloc (N);
M : constant Node_Id := Mod_Clause (N);
P : constant List_Id := Pragmas_Before (M);
AtM_Nod : Node_Id;
Mod_Val : Uint;
pragma Warnings (Off, Mod_Val);
begin
Check_Restriction (No_Obsolescent_Features, Mod_Clause (N));
if Warn_On_Obsolescent_Feature then
Error_Msg_N
("mod clause is an obsolescent feature (RM J.8)?", N);
Error_Msg_N
("\use alignment attribute definition clause instead?", N);
end if;
if Present (P) then
Analyze_List (P);
end if;
-- In ASIS_Mode mode, expansion is disabled, but we must convert
-- the Mod clause into an alignment clause anyway, so that the
-- back-end can compute and back-annotate properly the size and
-- alignment of types that may include this record.
-- This seems dubious, this destroys the source tree in a manner
-- not detectable by ASIS ???
if Operating_Mode = Check_Semantics
and then ASIS_Mode
then
AtM_Nod :=
Make_Attribute_Definition_Clause (Loc,
Name => New_Reference_To (Base_Type (Rectype), Loc),
Chars => Name_Alignment,
Expression => Relocate_Node (Expression (M)));
Set_From_At_Mod (AtM_Nod);
Insert_After (N, AtM_Nod);
Mod_Val := Get_Alignment_Value (Expression (AtM_Nod));
Set_Mod_Clause (N, Empty);
else
-- Get the alignment value to perform error checking
Mod_Val := Get_Alignment_Value (Expression (M));
end if;
end;
end if;
-- For untagged types, clear any existing component clauses for the
-- type. If the type is derived, this is what allows us to override
-- a rep clause for the parent. For type extensions, the representation
-- of the inherited components is inherited, so we want to keep previous
-- component clauses for completeness.
if not Is_Tagged_Type (Rectype) then
Comp := First_Component_Or_Discriminant (Rectype);
while Present (Comp) loop
Set_Component_Clause (Comp, Empty);
Next_Component_Or_Discriminant (Comp);
end loop;
end if;
-- All done if no component clauses
CC := First (Component_Clauses (N));
if No (CC) then
return;
end if;
-- A representation like this applies to the base type
Set_Has_Record_Rep_Clause (Base_Type (Rectype));
Set_Has_Non_Standard_Rep (Base_Type (Rectype));
Set_Has_Specified_Layout (Base_Type (Rectype));
-- Process the component clauses
while Present (CC) loop
-- Pragma
if Nkind (CC) = N_Pragma then
Analyze (CC);
-- The only pragma of interest is Complete_Representation
if Pragma_Name (CC) = Name_Complete_Representation then
CR_Pragma := CC;
end if;
-- Processing for real component clause
else
Posit := Static_Integer (Position (CC));
Fbit := Static_Integer (First_Bit (CC));
Lbit := Static_Integer (Last_Bit (CC));
if Posit /= No_Uint
and then Fbit /= No_Uint
and then Lbit /= No_Uint
then
if Posit < 0 then
Error_Msg_N
("position cannot be negative", Position (CC));
elsif Fbit < 0 then
Error_Msg_N
("first bit cannot be negative", First_Bit (CC));
-- The Last_Bit specified in a component clause must not be
-- less than the First_Bit minus one (RM-13.5.1(10)).
elsif Lbit < Fbit - 1 then
Error_Msg_N
("last bit cannot be less than first bit minus one",
Last_Bit (CC));
-- Values look OK, so find the corresponding record component
-- Even though the syntax allows an attribute reference for
-- implementation-defined components, GNAT does not allow the
-- tag to get an explicit position.
elsif Nkind (Component_Name (CC)) = N_Attribute_Reference then
if Attribute_Name (Component_Name (CC)) = Name_Tag then
Error_Msg_N ("position of tag cannot be specified", CC);
else
Error_Msg_N ("illegal component name", CC);
end if;
else
Comp := First_Entity (Rectype);
while Present (Comp) loop
exit when Chars (Comp) = Chars (Component_Name (CC));
Next_Entity (Comp);
end loop;
if No (Comp) then
-- Maybe component of base type that is absent from
-- statically constrained first subtype.
Comp := First_Entity (Base_Type (Rectype));
while Present (Comp) loop
exit when Chars (Comp) = Chars (Component_Name (CC));
Next_Entity (Comp);
end loop;
end if;
if No (Comp) then
Error_Msg_N
("component clause is for non-existent field", CC);
-- Ada 2012 (AI05-0026): Any name that denotes a
-- discriminant of an object of an unchecked union type
-- shall not occur within a record_representation_clause.
-- The general restriction of using record rep clauses on
-- Unchecked_Union types has now been lifted. Since it is
-- possible to introduce a record rep clause which mentions
-- the discriminant of an Unchecked_Union in non-Ada 2012
-- code, this check is applied to all versions of the
-- language.
elsif Ekind (Comp) = E_Discriminant
and then Is_Unchecked_Union (Rectype)
then
Error_Msg_N
("cannot reference discriminant of Unchecked_Union",
Component_Name (CC));
elsif Present (Component_Clause (Comp)) then
-- Diagnose duplicate rep clause, or check consistency
-- if this is an inherited component. In a double fault,
-- there may be a duplicate inconsistent clause for an
-- inherited component.
if Scope (Original_Record_Component (Comp)) = Rectype
or else Parent (Component_Clause (Comp)) = N
then
Error_Msg_Sloc := Sloc (Component_Clause (Comp));
Error_Msg_N ("component clause previously given#", CC);
else
declare
Rep1 : constant Node_Id := Component_Clause (Comp);
begin
if Intval (Position (Rep1)) /=
Intval (Position (CC))
or else Intval (First_Bit (Rep1)) /=
Intval (First_Bit (CC))
or else Intval (Last_Bit (Rep1)) /=
Intval (Last_Bit (CC))
then
Error_Msg_N ("component clause inconsistent "
& "with representation of ancestor", CC);
elsif Warn_On_Redundant_Constructs then
Error_Msg_N ("?redundant component clause "
& "for inherited component!", CC);
end if;
end;
end if;
-- Normal case where this is the first component clause we
-- have seen for this entity, so set it up properly.
else
-- Make reference for field in record rep clause and set
-- appropriate entity field in the field identifier.
Generate_Reference
(Comp, Component_Name (CC), Set_Ref => False);
Set_Entity (Component_Name (CC), Comp);
-- Update Fbit and Lbit to the actual bit number
Fbit := Fbit + UI_From_Int (SSU) * Posit;
Lbit := Lbit + UI_From_Int (SSU) * Posit;
if Has_Size_Clause (Rectype)
and then Esize (Rectype) <= Lbit
then
Error_Msg_N
("bit number out of range of specified size",
Last_Bit (CC));
else
Set_Component_Clause (Comp, CC);
Set_Component_Bit_Offset (Comp, Fbit);
Set_Esize (Comp, 1 + (Lbit - Fbit));
Set_Normalized_First_Bit (Comp, Fbit mod SSU);
Set_Normalized_Position (Comp, Fbit / SSU);
if Warn_On_Overridden_Size
and then Has_Size_Clause (Etype (Comp))
and then RM_Size (Etype (Comp)) /= Esize (Comp)
then
Error_Msg_NE
("?component size overrides size clause for&",
Component_Name (CC), Etype (Comp));
end if;
-- This information is also set in the corresponding
-- component of the base type, found by accessing the
-- Original_Record_Component link if it is present.
Ocomp := Original_Record_Component (Comp);
if Hbit < Lbit then
Hbit := Lbit;
end if;
Check_Size
(Component_Name (CC),
Etype (Comp),
Esize (Comp),
Biased);
Set_Biased
(Comp, First_Node (CC), "component clause", Biased);
if Present (Ocomp) then
Set_Component_Clause (Ocomp, CC);
Set_Component_Bit_Offset (Ocomp, Fbit);
Set_Normalized_First_Bit (Ocomp, Fbit mod SSU);
Set_Normalized_Position (Ocomp, Fbit / SSU);
Set_Esize (Ocomp, 1 + (Lbit - Fbit));
Set_Normalized_Position_Max
(Ocomp, Normalized_Position (Ocomp));
-- Note: we don't use Set_Biased here, because we
-- already gave a warning above if needed, and we
-- would get a duplicate for the same name here.
Set_Has_Biased_Representation
(Ocomp, Has_Biased_Representation (Comp));
end if;
if Esize (Comp) < 0 then
Error_Msg_N ("component size is negative", CC);
end if;
end if;
end if;
end if;
end if;
end if;
Next (CC);
end loop;
-- Check missing components if Complete_Representation pragma appeared
if Present (CR_Pragma) then
Comp := First_Component_Or_Discriminant (Rectype);
while Present (Comp) loop
if No (Component_Clause (Comp)) then
Error_Msg_NE
("missing component clause for &", CR_Pragma, Comp);
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
-- If no Complete_Representation pragma, warn if missing components
elsif Warn_On_Unrepped_Components then
declare
Num_Repped_Components : Nat := 0;
Num_Unrepped_Components : Nat := 0;
begin
-- First count number of repped and unrepped components
Comp := First_Component_Or_Discriminant (Rectype);
while Present (Comp) loop
if Present (Component_Clause (Comp)) then
Num_Repped_Components := Num_Repped_Components + 1;
else
Num_Unrepped_Components := Num_Unrepped_Components + 1;
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
-- We are only interested in the case where there is at least one
-- unrepped component, and at least half the components have rep
-- clauses. We figure that if less than half have them, then the
-- partial rep clause is really intentional. If the component
-- type has no underlying type set at this point (as for a generic
-- formal type), we don't know enough to give a warning on the
-- component.
if Num_Unrepped_Components > 0
and then Num_Unrepped_Components < Num_Repped_Components
then
Comp := First_Component_Or_Discriminant (Rectype);
while Present (Comp) loop
if No (Component_Clause (Comp))
and then Comes_From_Source (Comp)
and then Present (Underlying_Type (Etype (Comp)))
and then (Is_Scalar_Type (Underlying_Type (Etype (Comp)))
or else Size_Known_At_Compile_Time
(Underlying_Type (Etype (Comp))))
and then not Has_Warnings_Off (Rectype)
then
Error_Msg_Sloc := Sloc (Comp);
Error_Msg_NE
("?no component clause given for & declared #",
N, Comp);
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
end if;
end;
end if;
end Analyze_Record_Representation_Clause;
-------------------------------
-- Build_Invariant_Procedure --
-------------------------------
-- The procedure that is constructed here has the form
-- procedure typInvariant (Ixxx : typ) is
-- begin
-- pragma Check (Invariant, exp, "failed invariant from xxx");
-- pragma Check (Invariant, exp, "failed invariant from xxx");
-- ...
-- pragma Check (Invariant, exp, "failed inherited invariant from xxx");
-- ...
-- end typInvariant;
procedure Build_Invariant_Procedure (Typ : Entity_Id; N : Node_Id) is
Loc : constant Source_Ptr := Sloc (Typ);
Stmts : List_Id;
Spec : Node_Id;
SId : Entity_Id;
PDecl : Node_Id;
PBody : Node_Id;
Visible_Decls : constant List_Id := Visible_Declarations (N);
Private_Decls : constant List_Id := Private_Declarations (N);
procedure Add_Invariants (T : Entity_Id; Inherit : Boolean);
-- Appends statements to Stmts for any invariants in the rep item chain
-- of the given type. If Inherit is False, then we only process entries
-- on the chain for the type Typ. If Inherit is True, then we ignore any
-- Invariant aspects, but we process all Invariant'Class aspects, adding
-- "inherited" to the exception message and generating an informational
-- message about the inheritance of an invariant.
Object_Name : constant Name_Id := New_Internal_Name ('I');
-- Name for argument of invariant procedure
Object_Entity : constant Node_Id :=
Make_Defining_Identifier (Loc, Object_Name);
-- The procedure declaration entity for the argument
--------------------
-- Add_Invariants --
--------------------
procedure Add_Invariants (T : Entity_Id; Inherit : Boolean) is
Ritem : Node_Id;
Arg1 : Node_Id;
Arg2 : Node_Id;
Arg3 : Node_Id;
Exp : Node_Id;
Loc : Source_Ptr;
Assoc : List_Id;
Str : String_Id;
procedure Replace_Type_Reference (N : Node_Id);
-- Replace a single occurrence N of the subtype name with a reference
-- to the formal of the predicate function. N can be an identifier
-- referencing the subtype, or a selected component, representing an
-- appropriately qualified occurrence of the subtype name.
procedure Replace_Type_References is
new Replace_Type_References_Generic (Replace_Type_Reference);
-- Traverse an expression replacing all occurrences of the subtype
-- name with appropriate references to the object that is the formal
-- parameter of the predicate function. Note that we must ensure
-- that the type and entity information is properly set in the
-- replacement node, since we will do a Preanalyze call of this
-- expression without proper visibility of the procedure argument.
----------------------------
-- Replace_Type_Reference --
----------------------------
procedure Replace_Type_Reference (N : Node_Id) is
begin
-- Invariant'Class, replace with T'Class (obj)
if Class_Present (Ritem) then
Rewrite (N,
Make_Type_Conversion (Loc,
Subtype_Mark =>
Make_Attribute_Reference (Loc,
Prefix => New_Occurrence_Of (T, Loc),
Attribute_Name => Name_Class),
Expression => Make_Identifier (Loc, Object_Name)));
Set_Entity (Expression (N), Object_Entity);
Set_Etype (Expression (N), Typ);
-- Invariant, replace with obj
else
Rewrite (N, Make_Identifier (Loc, Object_Name));
Set_Entity (N, Object_Entity);
Set_Etype (N, Typ);
end if;
end Replace_Type_Reference;
-- Start of processing for Add_Invariants
begin
Ritem := First_Rep_Item (T);
while Present (Ritem) loop
if Nkind (Ritem) = N_Pragma
and then Pragma_Name (Ritem) = Name_Invariant
then
Arg1 := First (Pragma_Argument_Associations (Ritem));
Arg2 := Next (Arg1);
Arg3 := Next (Arg2);
Arg1 := Get_Pragma_Arg (Arg1);
Arg2 := Get_Pragma_Arg (Arg2);
-- For Inherit case, ignore Invariant, process only Class case
if Inherit then
if not Class_Present (Ritem) then
goto Continue;
end if;
-- For Inherit false, process only item for right type
else
if Entity (Arg1) /= Typ then
goto Continue;
end if;
end if;
if No (Stmts) then
Stmts := Empty_List;
end if;
Exp := New_Copy_Tree (Arg2);
Loc := Sloc (Exp);
-- We need to replace any occurrences of the name of the type
-- with references to the object, converted to type'Class in
-- the case of Invariant'Class aspects.
Replace_Type_References (Exp, Chars (T));
-- Now we need to preanalyze the expression to properly capture
-- the visibility in the visible part. The expression will not
-- be analyzed for real until the body is analyzed, but that is
-- at the end of the private part and has the wrong visibility.
Set_Parent (Exp, N);
Preanalyze_Spec_Expression (Exp, Standard_Boolean);
-- Build first two arguments for Check pragma
Assoc := New_List (
Make_Pragma_Argument_Association (Loc,
Expression => Make_Identifier (Loc, Name_Invariant)),
Make_Pragma_Argument_Association (Loc, Expression => Exp));
-- Add message if present in Invariant pragma
if Present (Arg3) then
Str := Strval (Get_Pragma_Arg (Arg3));
-- If inherited case, and message starts "failed invariant",
-- change it to be "failed inherited invariant".
if Inherit then
String_To_Name_Buffer (Str);
if Name_Buffer (1 .. 16) = "failed invariant" then
Insert_Str_In_Name_Buffer ("inherited ", 8);
Str := String_From_Name_Buffer;
end if;
end if;
Append_To (Assoc,
Make_Pragma_Argument_Association (Loc,
Expression => Make_String_Literal (Loc, Str)));
end if;
-- Add Check pragma to list of statements
Append_To (Stmts,
Make_Pragma (Loc,
Pragma_Identifier =>
Make_Identifier (Loc, Name_Check),
Pragma_Argument_Associations => Assoc));
-- If Inherited case and option enabled, output info msg. Note
-- that we know this is a case of Invariant'Class.
if Inherit and Opt.List_Inherited_Aspects then
Error_Msg_Sloc := Sloc (Ritem);
Error_Msg_N
("?info: & inherits `Invariant''Class` aspect from #",
Typ);
end if;
end if;
<<Continue>>
Next_Rep_Item (Ritem);
end loop;
end Add_Invariants;
-- Start of processing for Build_Invariant_Procedure
begin
Stmts := No_List;
PDecl := Empty;
PBody := Empty;
Set_Etype (Object_Entity, Typ);
-- Add invariants for the current type
Add_Invariants (Typ, Inherit => False);
-- Add invariants for parent types
declare
Current_Typ : Entity_Id;
Parent_Typ : Entity_Id;
begin
Current_Typ := Typ;
loop
Parent_Typ := Etype (Current_Typ);
if Is_Private_Type (Parent_Typ)
and then Present (Full_View (Base_Type (Parent_Typ)))
then
Parent_Typ := Full_View (Base_Type (Parent_Typ));
end if;
exit when Parent_Typ = Current_Typ;
Current_Typ := Parent_Typ;
Add_Invariants (Current_Typ, Inherit => True);
end loop;
end;
-- Build the procedure if we generated at least one Check pragma
if Stmts /= No_List then
-- Build procedure declaration
SId :=
Make_Defining_Identifier (Loc,
Chars => New_External_Name (Chars (Typ), "Invariant"));
Set_Has_Invariants (SId);
Set_Invariant_Procedure (Typ, SId);
Spec :=
Make_Procedure_Specification (Loc,
Defining_Unit_Name => SId,
Parameter_Specifications => New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier => Object_Entity,
Parameter_Type => New_Occurrence_Of (Typ, Loc))));
PDecl := Make_Subprogram_Declaration (Loc, Specification => Spec);
-- Build procedure body
SId :=
Make_Defining_Identifier (Loc,
Chars => New_External_Name (Chars (Typ), "Invariant"));
Spec :=
Make_Procedure_Specification (Loc,
Defining_Unit_Name => SId,
Parameter_Specifications => New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier =>
Make_Defining_Identifier (Loc, Object_Name),
Parameter_Type => New_Occurrence_Of (Typ, Loc))));
PBody :=
Make_Subprogram_Body (Loc,
Specification => Spec,
Declarations => Empty_List,
Handled_Statement_Sequence =>
Make_Handled_Sequence_Of_Statements (Loc,
Statements => Stmts));
-- Insert procedure declaration and spec at the appropriate points.
-- Skip this if there are no private declarations (that's an error
-- that will be diagnosed elsewhere, and there is no point in having
-- an invariant procedure set if the full declaration is missing).
if Present (Private_Decls) then
-- The spec goes at the end of visible declarations, but they have
-- already been analyzed, so we need to explicitly do the analyze.
Append_To (Visible_Decls, PDecl);
Analyze (PDecl);
-- The body goes at the end of the private declarations, which we
-- have not analyzed yet, so we do not need to perform an explicit
-- analyze call. We skip this if there are no private declarations
-- (this is an error that will be caught elsewhere);
Append_To (Private_Decls, PBody);
end if;
end if;
end Build_Invariant_Procedure;
------------------------------
-- Build_Predicate_Function --
------------------------------
-- The procedure that is constructed here has the form
-- function typPredicate (Ixxx : typ) return Boolean is
-- begin
-- return
-- exp1 and then exp2 and then ...
-- and then typ1Predicate (typ1 (Ixxx))
-- and then typ2Predicate (typ2 (Ixxx))
-- and then ...;
-- end typPredicate;
-- Here exp1, and exp2 are expressions from Predicate pragmas. Note that
-- this is the point at which these expressions get analyzed, providing the
-- required delay, and typ1, typ2, are entities from which predicates are
-- inherited. Note that we do NOT generate Check pragmas, that's because we
-- use this function even if checks are off, e.g. for membership tests.
procedure Build_Predicate_Function (Typ : Entity_Id; N : Node_Id) is
Loc : constant Source_Ptr := Sloc (Typ);
Spec : Node_Id;
SId : Entity_Id;
FDecl : Node_Id;
FBody : Node_Id;
Expr : Node_Id;
-- This is the expression for the return statement in the function. It
-- is build by connecting the component predicates with AND THEN.
procedure Add_Call (T : Entity_Id);
-- Includes a call to the predicate function for type T in Expr if T
-- has predicates and Predicate_Function (T) is non-empty.
procedure Add_Predicates;
-- Appends expressions for any Predicate pragmas in the rep item chain
-- Typ to Expr. Note that we look only at items for this exact entity.
-- Inheritance of predicates for the parent type is done by calling the
-- Predicate_Function of the parent type, using Add_Call above.
Object_Name : constant Name_Id := New_Internal_Name ('I');
-- Name for argument of Predicate procedure
--------------
-- Add_Call --
--------------
procedure Add_Call (T : Entity_Id) is
Exp : Node_Id;
begin
if Present (T) and then Present (Predicate_Function (T)) then
Set_Has_Predicates (Typ);
-- Build the call to the predicate function of T
Exp :=
Make_Predicate_Call
(T, Convert_To (T, Make_Identifier (Loc, Object_Name)));
-- Add call to evolving expression, using AND THEN if needed
if No (Expr) then
Expr := Exp;
else
Expr :=
Make_And_Then (Loc,
Left_Opnd => Relocate_Node (Expr),
Right_Opnd => Exp);
end if;
-- Output info message on inheritance if required. Note we do not
-- give this information for generic actual types, since it is
-- unwelcome noise in that case in instantiations. We also
-- generally suppress the message in instantiations, and also
-- if it involves internal names.
if Opt.List_Inherited_Aspects
and then not Is_Generic_Actual_Type (Typ)
and then Instantiation_Depth (Sloc (Typ)) = 0
and then not Is_Internal_Name (Chars (T))
and then not Is_Internal_Name (Chars (Typ))
then
Error_Msg_Sloc := Sloc (Predicate_Function (T));
Error_Msg_Node_2 := T;
Error_Msg_N ("?info: & inherits predicate from & #", Typ);
end if;
end if;
end Add_Call;
--------------------
-- Add_Predicates --
--------------------
procedure Add_Predicates is
Ritem : Node_Id;
Arg1 : Node_Id;
Arg2 : Node_Id;
procedure Replace_Type_Reference (N : Node_Id);
-- Replace a single occurrence N of the subtype name with a reference
-- to the formal of the predicate function. N can be an identifier
-- referencing the subtype, or a selected component, representing an
-- appropriately qualified occurrence of the subtype name.
procedure Replace_Type_References is
new Replace_Type_References_Generic (Replace_Type_Reference);
-- Traverse an expression changing every occurrence of an identifier
-- whose name matches the name of the subtype with a reference to
-- the formal parameter of the predicate function.
----------------------------
-- Replace_Type_Reference --
----------------------------
procedure Replace_Type_Reference (N : Node_Id) is
begin
Rewrite (N, Make_Identifier (Loc, Object_Name));
end Replace_Type_Reference;
-- Start of processing for Add_Predicates
begin
Ritem := First_Rep_Item (Typ);
while Present (Ritem) loop
if Nkind (Ritem) = N_Pragma
and then Pragma_Name (Ritem) = Name_Predicate
then
Arg1 := First (Pragma_Argument_Associations (Ritem));
Arg2 := Next (Arg1);
Arg1 := Get_Pragma_Arg (Arg1);
Arg2 := Get_Pragma_Arg (Arg2);
-- See if this predicate pragma is for the current type
if Entity (Arg1) = Typ then
-- We have a match, this entry is for our subtype
-- First We need to replace any occurrences of the name of
-- the type with references to the object.
Replace_Type_References (Arg2, Chars (Typ));
-- OK, replacement complete, now we can add the expression
if No (Expr) then
Expr := Relocate_Node (Arg2);
-- There already was a predicate, so add to it
else
Expr :=
Make_And_Then (Loc,
Left_Opnd => Relocate_Node (Expr),
Right_Opnd => Relocate_Node (Arg2));
end if;
end if;
end if;
Next_Rep_Item (Ritem);
end loop;
end Add_Predicates;
-- Start of processing for Build_Predicate_Function
begin
-- Initialize for construction of statement list
Expr := Empty;
-- Return if already built or if type does not have predicates
if not Has_Predicates (Typ)
or else Present (Predicate_Function (Typ))
then
return;
end if;
-- Add Predicates for the current type
Add_Predicates;
-- Add predicates for ancestor if present
declare
Atyp : constant Entity_Id := Nearest_Ancestor (Typ);
begin
if Present (Atyp) then
Add_Call (Atyp);
end if;
end;
-- If we have predicates, build the function
if Present (Expr) then
-- Build function declaration
pragma Assert (Has_Predicates (Typ));
SId :=
Make_Defining_Identifier (Loc,
Chars => New_External_Name (Chars (Typ), "Predicate"));
Set_Has_Predicates (SId);
Set_Predicate_Function (Typ, SId);
Spec :=
Make_Function_Specification (Loc,
Defining_Unit_Name => SId,
Parameter_Specifications => New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier =>
Make_Defining_Identifier (Loc, Object_Name),
Parameter_Type => New_Occurrence_Of (Typ, Loc))),
Result_Definition =>
New_Occurrence_Of (Standard_Boolean, Loc));
FDecl := Make_Subprogram_Declaration (Loc, Specification => Spec);
-- Build function body
SId :=
Make_Defining_Identifier (Loc,
Chars => New_External_Name (Chars (Typ), "Predicate"));
Spec :=
Make_Function_Specification (Loc,
Defining_Unit_Name => SId,
Parameter_Specifications => New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier =>
Make_Defining_Identifier (Loc, Object_Name),
Parameter_Type =>
New_Occurrence_Of (Typ, Loc))),
Result_Definition =>
New_Occurrence_Of (Standard_Boolean, Loc));
FBody :=
Make_Subprogram_Body (Loc,
Specification => Spec,
Declarations => Empty_List,
Handled_Statement_Sequence =>
Make_Handled_Sequence_Of_Statements (Loc,
Statements => New_List (
Make_Simple_Return_Statement (Loc,
Expression => Expr))));
-- Insert declaration before freeze node and body after
Insert_Before_And_Analyze (N, FDecl);
Insert_After_And_Analyze (N, FBody);
-- Deal with static predicate case
if Ekind_In (Typ, E_Enumeration_Subtype,
E_Modular_Integer_Subtype,
E_Signed_Integer_Subtype)
and then Is_Static_Subtype (Typ)
then
Build_Static_Predicate (Typ, Expr, Object_Name);
end if;
end if;
end Build_Predicate_Function;
----------------------------
-- Build_Static_Predicate --
----------------------------
procedure Build_Static_Predicate
(Typ : Entity_Id;
Expr : Node_Id;
Nam : Name_Id)
is
Loc : constant Source_Ptr := Sloc (Expr);
Non_Static : exception;
-- Raised if something non-static is found
Btyp : constant Entity_Id := Base_Type (Typ);
BLo : constant Uint := Expr_Value (Type_Low_Bound (Btyp));
BHi : constant Uint := Expr_Value (Type_High_Bound (Btyp));
-- Low bound and high bound value of base type of Typ
TLo : constant Uint := Expr_Value (Type_Low_Bound (Typ));
THi : constant Uint := Expr_Value (Type_High_Bound (Typ));
-- Low bound and high bound values of static subtype Typ
type REnt is record
Lo, Hi : Uint;
end record;
-- One entry in a Rlist value, a single REnt (range entry) value
-- denotes one range from Lo to Hi. To represent a single value
-- range Lo = Hi = value.
type RList is array (Nat range <>) of REnt;
-- A list of ranges. The ranges are sorted in increasing order,
-- and are disjoint (there is a gap of at least one value between
-- each range in the table). A value is in the set of ranges in
-- Rlist if it lies within one of these ranges
False_Range : constant RList :=
RList'(1 .. 0 => REnt'(No_Uint, No_Uint));
-- An empty set of ranges represents a range list that can never be
-- satisfied, since there are no ranges in which the value could lie,
-- so it does not lie in any of them. False_Range is a canonical value
-- for this empty set, but general processing should test for an Rlist
-- with length zero (see Is_False predicate), since other null ranges
-- may appear which must be treated as False.
True_Range : constant RList := RList'(1 => REnt'(BLo, BHi));
-- Range representing True, value must be in the base range
function "and" (Left, Right : RList) return RList;
-- And's together two range lists, returning a range list. This is
-- a set intersection operation.
function "or" (Left, Right : RList) return RList;
-- Or's together two range lists, returning a range list. This is a
-- set union operation.
function "not" (Right : RList) return RList;
-- Returns complement of a given range list, i.e. a range list
-- representing all the values in TLo .. THi that are not in the
-- input operand Right.
function Build_Val (V : Uint) return Node_Id;
-- Return an analyzed N_Identifier node referencing this value, suitable
-- for use as an entry in the Static_Predicate list. This node is typed
-- with the base type.
function Build_Range (Lo, Hi : Uint) return Node_Id;
-- Return an analyzed N_Range node referencing this range, suitable
-- for use as an entry in the Static_Predicate list. This node is typed
-- with the base type.
function Get_RList (Exp : Node_Id) return RList;
-- This is a recursive routine that converts the given expression into
-- a list of ranges, suitable for use in building the static predicate.
function Is_False (R : RList) return Boolean;
pragma Inline (Is_False);
-- Returns True if the given range list is empty, and thus represents
-- a False list of ranges that can never be satisfied.
function Is_True (R : RList) return Boolean;
-- Returns True if R trivially represents the True predicate by having
-- a single range from BLo to BHi.
function Is_Type_Ref (N : Node_Id) return Boolean;
pragma Inline (Is_Type_Ref);
-- Returns if True if N is a reference to the type for the predicate in
-- the expression (i.e. if it is an identifier whose Chars field matches
-- the Nam given in the call).
function Lo_Val (N : Node_Id) return Uint;
-- Given static expression or static range from a Static_Predicate list,
-- gets expression value or low bound of range.
function Hi_Val (N : Node_Id) return Uint;
-- Given static expression or static range from a Static_Predicate list,
-- gets expression value of high bound of range.
function Membership_Entry (N : Node_Id) return RList;
-- Given a single membership entry (range, value, or subtype), returns
-- the corresponding range list. Raises Static_Error if not static.
function Membership_Entries (N : Node_Id) return RList;
-- Given an element on an alternatives list of a membership operation,
-- returns the range list corresponding to this entry and all following
-- entries (i.e. returns the "or" of this list of values).
function Stat_Pred (Typ : Entity_Id) return RList;
-- Given a type, if it has a static predicate, then return the predicate
-- as a range list, otherwise raise Non_Static.
-----------
-- "and" --
-----------
function "and" (Left, Right : RList) return RList is
FEnt : REnt;
-- First range of result
SLeft : Nat := Left'First;
-- Start of rest of left entries
SRight : Nat := Right'First;
-- Start of rest of right entries
begin
-- If either range is True, return the other
if Is_True (Left) then
return Right;
elsif Is_True (Right) then
return Left;
end if;
-- If either range is False, return False
if Is_False (Left) or else Is_False (Right) then
return False_Range;
end if;
-- Loop to remove entries at start that are disjoint, and thus
-- just get discarded from the result entirely.
loop
-- If no operands left in either operand, result is false
if SLeft > Left'Last or else SRight > Right'Last then
return False_Range;
-- Discard first left operand entry if disjoint with right
elsif Left (SLeft).Hi < Right (SRight).Lo then
SLeft := SLeft + 1;
-- Discard first right operand entry if disjoint with left
elsif Right (SRight).Hi < Left (SLeft).Lo then
SRight := SRight + 1;
-- Otherwise we have an overlapping entry
else
exit;
end if;
end loop;
-- Now we have two non-null operands, and first entries overlap.
-- The first entry in the result will be the overlapping part of
-- these two entries.
FEnt := REnt'(Lo => UI_Max (Left (SLeft).Lo, Right (SRight).Lo),
Hi => UI_Min (Left (SLeft).Hi, Right (SRight).Hi));
-- Now we can remove the entry that ended at a lower value, since
-- its contribution is entirely contained in Fent.
if Left (SLeft).Hi <= Right (SRight).Hi then
SLeft := SLeft + 1;
else
SRight := SRight + 1;
end if;
-- Compute result by concatenating this first entry with the "and"
-- of the remaining parts of the left and right operands. Note that
-- if either of these is empty, "and" will yield empty, so that we
-- will end up with just Fent, which is what we want in that case.
return
FEnt & (Left (SLeft .. Left'Last) and Right (SRight .. Right'Last));
end "and";
-----------
-- "not" --
-----------
function "not" (Right : RList) return RList is
begin
-- Return True if False range
if Is_False (Right) then
return True_Range;
end if;
-- Return False if True range
if Is_True (Right) then
return False_Range;
end if;
-- Here if not trivial case
declare
Result : RList (1 .. Right'Length + 1);
-- May need one more entry for gap at beginning and end
Count : Nat := 0;
-- Number of entries stored in Result
begin
-- Gap at start
if Right (Right'First).Lo > TLo then
Count := Count + 1;
Result (Count) := REnt'(TLo, Right (Right'First).Lo - 1);
end if;
-- Gaps between ranges
for J in Right'First .. Right'Last - 1 loop
Count := Count + 1;
Result (Count) :=
REnt'(Right (J).Hi + 1, Right (J + 1).Lo - 1);
end loop;
-- Gap at end
if Right (Right'Last).Hi < THi then
Count := Count + 1;
Result (Count) := REnt'(Right (Right'Last).Hi + 1, THi);
end if;
return Result (1 .. Count);
end;
end "not";
----------
-- "or" --
----------
function "or" (Left, Right : RList) return RList is
FEnt : REnt;
-- First range of result
SLeft : Nat := Left'First;
-- Start of rest of left entries
SRight : Nat := Right'First;
-- Start of rest of right entries
begin
-- If either range is True, return True
if Is_True (Left) or else Is_True (Right) then
return True_Range;
end if;
-- If either range is False (empty), return the other
if Is_False (Left) then
return Right;
elsif Is_False (Right) then
return Left;
end if;
-- Initialize result first entry from left or right operand
-- depending on which starts with the lower range.
if Left (SLeft).Lo < Right (SRight).Lo then
FEnt := Left (SLeft);
SLeft := SLeft + 1;
else
FEnt := Right (SRight);
SRight := SRight + 1;
end if;
-- This loop eats ranges from left and right operands that
-- are contiguous with the first range we are gathering.
loop
-- Eat first entry in left operand if contiguous or
-- overlapped by gathered first operand of result.
if SLeft <= Left'Last
and then Left (SLeft).Lo <= FEnt.Hi + 1
then
FEnt.Hi := UI_Max (FEnt.Hi, Left (SLeft).Hi);
SLeft := SLeft + 1;
-- Eat first entry in right operand if contiguous or
-- overlapped by gathered right operand of result.
elsif SRight <= Right'Last
and then Right (SRight).Lo <= FEnt.Hi + 1
then
FEnt.Hi := UI_Max (FEnt.Hi, Right (SRight).Hi);
SRight := SRight + 1;
-- All done if no more entries to eat!
else
exit;
end if;
end loop;
-- Obtain result as the first entry we just computed, concatenated
-- to the "or" of the remaining results (if one operand is empty,
-- this will just concatenate with the other
return
FEnt & (Left (SLeft .. Left'Last) or Right (SRight .. Right'Last));
end "or";
-----------------
-- Build_Range --
-----------------
function Build_Range (Lo, Hi : Uint) return Node_Id is
Result : Node_Id;
begin
if Lo = Hi then
return Build_Val (Hi);
else
Result :=
Make_Range (Loc,
Low_Bound => Build_Val (Lo),
High_Bound => Build_Val (Hi));
Set_Etype (Result, Btyp);
Set_Analyzed (Result);
return Result;
end if;
end Build_Range;
---------------
-- Build_Val --
---------------
function Build_Val (V : Uint) return Node_Id is
Result : Node_Id;
begin
if Is_Enumeration_Type (Typ) then
Result := Get_Enum_Lit_From_Pos (Typ, V, Loc);
else
Result := Make_Integer_Literal (Loc, V);
end if;
Set_Etype (Result, Btyp);
Set_Is_Static_Expression (Result);
Set_Analyzed (Result);
return Result;
end Build_Val;
---------------
-- Get_RList --
---------------
function Get_RList (Exp : Node_Id) return RList is
Op : Node_Kind;
Val : Uint;
begin
-- Static expression can only be true or false
if Is_OK_Static_Expression (Exp) then
-- For False
if Expr_Value (Exp) = 0 then
return False_Range;
else
return True_Range;
end if;
end if;
-- Otherwise test node type
Op := Nkind (Exp);
case Op is
-- And
when N_Op_And | N_And_Then =>
return Get_RList (Left_Opnd (Exp))
and
Get_RList (Right_Opnd (Exp));
-- Or
when N_Op_Or | N_Or_Else =>
return Get_RList (Left_Opnd (Exp))
or
Get_RList (Right_Opnd (Exp));
-- Not
when N_Op_Not =>
return not Get_RList (Right_Opnd (Exp));
-- Comparisons of type with static value
when N_Op_Compare =>
-- Type is left operand
if Is_Type_Ref (Left_Opnd (Exp))
and then Is_OK_Static_Expression (Right_Opnd (Exp))
then
Val := Expr_Value (Right_Opnd (Exp));
-- Typ is right operand
elsif Is_Type_Ref (Right_Opnd (Exp))
and then Is_OK_Static_Expression (Left_Opnd (Exp))
then
Val := Expr_Value (Left_Opnd (Exp));
-- Invert sense of comparison
case Op is
when N_Op_Gt => Op := N_Op_Lt;
when N_Op_Lt => Op := N_Op_Gt;
when N_Op_Ge => Op := N_Op_Le;
when N_Op_Le => Op := N_Op_Ge;
when others => null;
end case;
-- Other cases are non-static
else
raise Non_Static;
end if;
-- Construct range according to comparison operation
case Op is
when N_Op_Eq =>
return RList'(1 => REnt'(Val, Val));
when N_Op_Ge =>
return RList'(1 => REnt'(Val, BHi));
when N_Op_Gt =>
return RList'(1 => REnt'(Val + 1, BHi));
when N_Op_Le =>
return RList'(1 => REnt'(BLo, Val));
when N_Op_Lt =>
return RList'(1 => REnt'(BLo, Val - 1));
when N_Op_Ne =>
return RList'(REnt'(BLo, Val - 1),
REnt'(Val + 1, BHi));
when others =>
raise Program_Error;
end case;
-- Membership (IN)
when N_In =>
if not Is_Type_Ref (Left_Opnd (Exp)) then
raise Non_Static;
end if;
if Present (Right_Opnd (Exp)) then
return Membership_Entry (Right_Opnd (Exp));
else
return Membership_Entries (First (Alternatives (Exp)));
end if;
-- Negative membership (NOT IN)
when N_Not_In =>
if not Is_Type_Ref (Left_Opnd (Exp)) then
raise Non_Static;
end if;
if Present (Right_Opnd (Exp)) then
return not Membership_Entry (Right_Opnd (Exp));
else
return not Membership_Entries (First (Alternatives (Exp)));
end if;
-- Function call, may be call to static predicate
when N_Function_Call =>
if Is_Entity_Name (Name (Exp)) then
declare
Ent : constant Entity_Id := Entity (Name (Exp));
begin
if Has_Predicates (Ent) then
return Stat_Pred (Etype (First_Formal (Ent)));
end if;
end;
end if;
-- Other function call cases are non-static
raise Non_Static;
-- Qualified expression, dig out the expression
when N_Qualified_Expression =>
return Get_RList (Expression (Exp));
-- Xor operator
when N_Op_Xor =>
return (Get_RList (Left_Opnd (Exp))
and not Get_RList (Right_Opnd (Exp)))
or (Get_RList (Right_Opnd (Exp))
and not Get_RList (Left_Opnd (Exp)));
-- Any other node type is non-static
when others =>
raise Non_Static;
end case;
end Get_RList;
------------
-- Hi_Val --
------------
function Hi_Val (N : Node_Id) return Uint is
begin
if Is_Static_Expression (N) then
return Expr_Value (N);
else
pragma Assert (Nkind (N) = N_Range);
return Expr_Value (High_Bound (N));
end if;
end Hi_Val;
--------------
-- Is_False --
--------------
function Is_False (R : RList) return Boolean is
begin
return R'Length = 0;
end Is_False;
-------------
-- Is_True --
-------------
function Is_True (R : RList) return Boolean is
begin
return R'Length = 1
and then R (R'First).Lo = BLo
and then R (R'First).Hi = BHi;
end Is_True;
-----------------
-- Is_Type_Ref --
-----------------
function Is_Type_Ref (N : Node_Id) return Boolean is
begin
return Nkind (N) = N_Identifier and then Chars (N) = Nam;
end Is_Type_Ref;
------------
-- Lo_Val --
------------
function Lo_Val (N : Node_Id) return Uint is
begin
if Is_Static_Expression (N) then
return Expr_Value (N);
else
pragma Assert (Nkind (N) = N_Range);
return Expr_Value (Low_Bound (N));
end if;
end Lo_Val;
------------------------
-- Membership_Entries --
------------------------
function Membership_Entries (N : Node_Id) return RList is
begin
if No (Next (N)) then
return Membership_Entry (N);
else
return Membership_Entry (N) or Membership_Entries (Next (N));
end if;
end Membership_Entries;
----------------------
-- Membership_Entry --
----------------------
function Membership_Entry (N : Node_Id) return RList is
Val : Uint;
SLo : Uint;
SHi : Uint;
begin
-- Range case
if Nkind (N) = N_Range then
if not Is_Static_Expression (Low_Bound (N))
or else
not Is_Static_Expression (High_Bound (N))
then
raise Non_Static;
else
SLo := Expr_Value (Low_Bound (N));
SHi := Expr_Value (High_Bound (N));
return RList'(1 => REnt'(SLo, SHi));
end if;
-- Static expression case
elsif Is_Static_Expression (N) then
Val := Expr_Value (N);
return RList'(1 => REnt'(Val, Val));
-- Identifier (other than static expression) case
else pragma Assert (Nkind (N) = N_Identifier);
-- Type case
if Is_Type (Entity (N)) then
-- If type has predicates, process them
if Has_Predicates (Entity (N)) then
return Stat_Pred (Entity (N));
-- For static subtype without predicates, get range
elsif Is_Static_Subtype (Entity (N)) then
SLo := Expr_Value (Type_Low_Bound (Entity (N)));
SHi := Expr_Value (Type_High_Bound (Entity (N)));
return RList'(1 => REnt'(SLo, SHi));
-- Any other type makes us non-static
else
raise Non_Static;
end if;
-- Any other kind of identifier in predicate (e.g. a non-static
-- expression value) means this is not a static predicate.
else
raise Non_Static;
end if;
end if;
end Membership_Entry;
---------------
-- Stat_Pred --
---------------
function Stat_Pred (Typ : Entity_Id) return RList is
begin
-- Not static if type does not have static predicates
if not Has_Predicates (Typ)
or else No (Static_Predicate (Typ))
then
raise Non_Static;
end if;
-- Otherwise we convert the predicate list to a range list
declare
Result : RList (1 .. List_Length (Static_Predicate (Typ)));
P : Node_Id;
begin
P := First (Static_Predicate (Typ));
for J in Result'Range loop
Result (J) := REnt'(Lo_Val (P), Hi_Val (P));
Next (P);
end loop;
return Result;
end;
end Stat_Pred;
-- Start of processing for Build_Static_Predicate
begin
-- Now analyze the expression to see if it is a static predicate
declare
Ranges : constant RList := Get_RList (Expr);
-- Range list from expression if it is static
Plist : List_Id;
begin
-- Convert range list into a form for the static predicate. In the
-- Ranges array, we just have raw ranges, these must be converted
-- to properly typed and analyzed static expressions or range nodes.
-- Note: here we limit ranges to the ranges of the subtype, so that
-- a predicate is always false for values outside the subtype. That
-- seems fine, such values are invalid anyway, and considering them
-- to fail the predicate seems allowed and friendly, and furthermore
-- simplifies processing for case statements and loops.
Plist := New_List;
for J in Ranges'Range loop
declare
Lo : Uint := Ranges (J).Lo;
Hi : Uint := Ranges (J).Hi;
begin
-- Ignore completely out of range entry
if Hi < TLo or else Lo > THi then
null;
-- Otherwise process entry
else
-- Adjust out of range value to subtype range
if Lo < TLo then
Lo := TLo;
end if;
if Hi > THi then
Hi := THi;
end if;
-- Convert range into required form
if Lo = Hi then
Append_To (Plist, Build_Val (Lo));
else
Append_To (Plist, Build_Range (Lo, Hi));
end if;
end if;
end;
end loop;
-- Processing was successful and all entries were static, so now we
-- can store the result as the predicate list.
Set_Static_Predicate (Typ, Plist);
-- The processing for static predicates put the expression into
-- canonical form as a series of ranges. It also eliminated
-- duplicates and collapsed and combined ranges. We might as well
-- replace the alternatives list of the right operand of the
-- membership test with the static predicate list, which will
-- usually be more efficient.
declare
New_Alts : constant List_Id := New_List;
Old_Node : Node_Id;
New_Node : Node_Id;
begin
Old_Node := First (Plist);
while Present (Old_Node) loop
New_Node := New_Copy (Old_Node);
if Nkind (New_Node) = N_Range then
Set_Low_Bound (New_Node, New_Copy (Low_Bound (Old_Node)));
Set_High_Bound (New_Node, New_Copy (High_Bound (Old_Node)));
end if;
Append_To (New_Alts, New_Node);
Next (Old_Node);
end loop;
-- If empty list, replace by False
if Is_Empty_List (New_Alts) then
Rewrite (Expr, New_Occurrence_Of (Standard_False, Loc));
-- Else replace by set membership test
else
Rewrite (Expr,
Make_In (Loc,
Left_Opnd => Make_Identifier (Loc, Nam),
Right_Opnd => Empty,
Alternatives => New_Alts));
-- Resolve new expression in function context
Install_Formals (Predicate_Function (Typ));
Push_Scope (Predicate_Function (Typ));
Analyze_And_Resolve (Expr, Standard_Boolean);
Pop_Scope;
end if;
end;
end;
-- If non-static, return doing nothing
exception
when Non_Static =>
return;
end Build_Static_Predicate;
-----------------------------------
-- Check_Constant_Address_Clause --
-----------------------------------
procedure Check_Constant_Address_Clause
(Expr : Node_Id;
U_Ent : Entity_Id)
is
procedure Check_At_Constant_Address (Nod : Node_Id);
-- Checks that the given node N represents a name whose 'Address is
-- constant (in the same sense as OK_Constant_Address_Clause, i.e. the
-- address value is the same at the point of declaration of U_Ent and at
-- the time of elaboration of the address clause.
procedure Check_Expr_Constants (Nod : Node_Id);
-- Checks that Nod meets the requirements for a constant address clause
-- in the sense of the enclosing procedure.
procedure Check_List_Constants (Lst : List_Id);
-- Check that all elements of list Lst meet the requirements for a
-- constant address clause in the sense of the enclosing procedure.
-------------------------------
-- Check_At_Constant_Address --
-------------------------------
procedure Check_At_Constant_Address (Nod : Node_Id) is
begin
if Is_Entity_Name (Nod) then
if Present (Address_Clause (Entity ((Nod)))) then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_NE
("address for& cannot" &
" depend on another address clause! (RM 13.1(22))!",
Nod, U_Ent);
elsif In_Same_Source_Unit (Entity (Nod), U_Ent)
and then Sloc (U_Ent) < Sloc (Entity (Nod))
then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_Node_2 := U_Ent;
Error_Msg_NE
("\& must be defined before & (RM 13.1(22))!",
Nod, Entity (Nod));
end if;
elsif Nkind (Nod) = N_Selected_Component then
declare
T : constant Entity_Id := Etype (Prefix (Nod));
begin
if (Is_Record_Type (T)
and then Has_Discriminants (T))
or else
(Is_Access_Type (T)
and then Is_Record_Type (Designated_Type (T))
and then Has_Discriminants (Designated_Type (T)))
then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_N
("\address cannot depend on component" &
" of discriminated record (RM 13.1(22))!",
Nod);
else
Check_At_Constant_Address (Prefix (Nod));
end if;
end;
elsif Nkind (Nod) = N_Indexed_Component then
Check_At_Constant_Address (Prefix (Nod));
Check_List_Constants (Expressions (Nod));
else
Check_Expr_Constants (Nod);
end if;
end Check_At_Constant_Address;
--------------------------
-- Check_Expr_Constants --
--------------------------
procedure Check_Expr_Constants (Nod : Node_Id) is
Loc_U_Ent : constant Source_Ptr := Sloc (U_Ent);
Ent : Entity_Id := Empty;
begin
if Nkind (Nod) in N_Has_Etype
and then Etype (Nod) = Any_Type
then
return;
end if;
case Nkind (Nod) is
when N_Empty | N_Error =>
return;
when N_Identifier | N_Expanded_Name =>
Ent := Entity (Nod);
-- We need to look at the original node if it is different
-- from the node, since we may have rewritten things and
-- substituted an identifier representing the rewrite.
if Original_Node (Nod) /= Nod then
Check_Expr_Constants (Original_Node (Nod));
-- If the node is an object declaration without initial
-- value, some code has been expanded, and the expression
-- is not constant, even if the constituents might be
-- acceptable, as in A'Address + offset.
if Ekind (Ent) = E_Variable
and then
Nkind (Declaration_Node (Ent)) = N_Object_Declaration
and then
No (Expression (Declaration_Node (Ent)))
then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
-- If entity is constant, it may be the result of expanding
-- a check. We must verify that its declaration appears
-- before the object in question, else we also reject the
-- address clause.
elsif Ekind (Ent) = E_Constant
and then In_Same_Source_Unit (Ent, U_Ent)
and then Sloc (Ent) > Loc_U_Ent
then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
end if;
return;
end if;
-- Otherwise look at the identifier and see if it is OK
if Ekind_In (Ent, E_Named_Integer, E_Named_Real)
or else Is_Type (Ent)
then
return;
elsif
Ekind (Ent) = E_Constant
or else
Ekind (Ent) = E_In_Parameter
then
-- This is the case where we must have Ent defined before
-- U_Ent. Clearly if they are in different units this
-- requirement is met since the unit containing Ent is
-- already processed.
if not In_Same_Source_Unit (Ent, U_Ent) then
return;
-- Otherwise location of Ent must be before the location
-- of U_Ent, that's what prior defined means.
elsif Sloc (Ent) < Loc_U_Ent then
return;
else
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_Node_2 := U_Ent;
Error_Msg_NE
("\& must be defined before & (RM 13.1(22))!",
Nod, Ent);
end if;
elsif Nkind (Original_Node (Nod)) = N_Function_Call then
Check_Expr_Constants (Original_Node (Nod));
else
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
if Comes_From_Source (Ent) then
Error_Msg_NE
("\reference to variable& not allowed"
& " (RM 13.1(22))!", Nod, Ent);
else
Error_Msg_N
("non-static expression not allowed"
& " (RM 13.1(22))!", Nod);
end if;
end if;
when N_Integer_Literal =>
-- If this is a rewritten unchecked conversion, in a system
-- where Address is an integer type, always use the base type
-- for a literal value. This is user-friendly and prevents
-- order-of-elaboration issues with instances of unchecked
-- conversion.
if Nkind (Original_Node (Nod)) = N_Function_Call then
Set_Etype (Nod, Base_Type (Etype (Nod)));
end if;
when N_Real_Literal |
N_String_Literal |
N_Character_Literal =>
return;
when N_Range =>
Check_Expr_Constants (Low_Bound (Nod));
Check_Expr_Constants (High_Bound (Nod));
when N_Explicit_Dereference =>
Check_Expr_Constants (Prefix (Nod));
when N_Indexed_Component =>
Check_Expr_Constants (Prefix (Nod));
Check_List_Constants (Expressions (Nod));
when N_Slice =>
Check_Expr_Constants (Prefix (Nod));
Check_Expr_Constants (Discrete_Range (Nod));
when N_Selected_Component =>
Check_Expr_Constants (Prefix (Nod));
when N_Attribute_Reference =>
if Attribute_Name (Nod) = Name_Address
or else
Attribute_Name (Nod) = Name_Access
or else
Attribute_Name (Nod) = Name_Unchecked_Access
or else
Attribute_Name (Nod) = Name_Unrestricted_Access
then
Check_At_Constant_Address (Prefix (Nod));
else
Check_Expr_Constants (Prefix (Nod));
Check_List_Constants (Expressions (Nod));
end if;
when N_Aggregate =>
Check_List_Constants (Component_Associations (Nod));
Check_List_Constants (Expressions (Nod));
when N_Component_Association =>
Check_Expr_Constants (Expression (Nod));
when N_Extension_Aggregate =>
Check_Expr_Constants (Ancestor_Part (Nod));
Check_List_Constants (Component_Associations (Nod));
Check_List_Constants (Expressions (Nod));
when N_Null =>
return;
when N_Binary_Op | N_Short_Circuit | N_Membership_Test =>
Check_Expr_Constants (Left_Opnd (Nod));
Check_Expr_Constants (Right_Opnd (Nod));
when N_Unary_Op =>
Check_Expr_Constants (Right_Opnd (Nod));
when N_Type_Conversion |
N_Qualified_Expression |
N_Allocator =>
Check_Expr_Constants (Expression (Nod));
when N_Unchecked_Type_Conversion =>
Check_Expr_Constants (Expression (Nod));
-- If this is a rewritten unchecked conversion, subtypes in
-- this node are those created within the instance. To avoid
-- order of elaboration issues, replace them with their base
-- types. Note that address clauses can cause order of
-- elaboration problems because they are elaborated by the
-- back-end at the point of definition, and may mention
-- entities declared in between (as long as everything is
-- static). It is user-friendly to allow unchecked conversions
-- in this context.
if Nkind (Original_Node (Nod)) = N_Function_Call then
Set_Etype (Expression (Nod),
Base_Type (Etype (Expression (Nod))));
Set_Etype (Nod, Base_Type (Etype (Nod)));
end if;
when N_Function_Call =>
if not Is_Pure (Entity (Name (Nod))) then
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_NE
("\function & is not pure (RM 13.1(22))!",
Nod, Entity (Name (Nod)));
else
Check_List_Constants (Parameter_Associations (Nod));
end if;
when N_Parameter_Association =>
Check_Expr_Constants (Explicit_Actual_Parameter (Nod));
when others =>
Error_Msg_NE
("invalid address clause for initialized object &!",
Nod, U_Ent);
Error_Msg_NE
("\must be constant defined before& (RM 13.1(22))!",
Nod, U_Ent);
end case;
end Check_Expr_Constants;
--------------------------
-- Check_List_Constants --
--------------------------
procedure Check_List_Constants (Lst : List_Id) is
Nod1 : Node_Id;
begin
if Present (Lst) then
Nod1 := First (Lst);
while Present (Nod1) loop
Check_Expr_Constants (Nod1);
Next (Nod1);
end loop;
end if;
end Check_List_Constants;
-- Start of processing for Check_Constant_Address_Clause
begin
-- If rep_clauses are to be ignored, no need for legality checks. In
-- particular, no need to pester user about rep clauses that violate
-- the rule on constant addresses, given that these clauses will be
-- removed by Freeze before they reach the back end.
if not Ignore_Rep_Clauses then
Check_Expr_Constants (Expr);
end if;
end Check_Constant_Address_Clause;
----------------------------------------
-- Check_Record_Representation_Clause --
----------------------------------------
procedure Check_Record_Representation_Clause (N : Node_Id) is
Loc : constant Source_Ptr := Sloc (N);
Ident : constant Node_Id := Identifier (N);
Rectype : Entity_Id;
Fent : Entity_Id;
CC : Node_Id;
Fbit : Uint;
Lbit : Uint;
Hbit : Uint := Uint_0;
Comp : Entity_Id;
Pcomp : Entity_Id;
Max_Bit_So_Far : Uint;
-- Records the maximum bit position so far. If all field positions
-- are monotonically increasing, then we can skip the circuit for
-- checking for overlap, since no overlap is possible.
Tagged_Parent : Entity_Id := Empty;
-- This is set in the case of a derived tagged type for which we have
-- Is_Fully_Repped_Tagged_Type True (indicating that all components are
-- positioned by record representation clauses). In this case we must
-- check for overlap between components of this tagged type, and the
-- components of its parent. Tagged_Parent will point to this parent
-- type. For all other cases Tagged_Parent is left set to Empty.
Parent_Last_Bit : Uint;
-- Relevant only if Tagged_Parent is set, Parent_Last_Bit indicates the
-- last bit position for any field in the parent type. We only need to
-- check overlap for fields starting below this point.
Overlap_Check_Required : Boolean;
-- Used to keep track of whether or not an overlap check is required
Overlap_Detected : Boolean := False;
-- Set True if an overlap is detected
Ccount : Natural := 0;
-- Number of component clauses in record rep clause
procedure Check_Component_Overlap (C1_Ent, C2_Ent : Entity_Id);
-- Given two entities for record components or discriminants, checks
-- if they have overlapping component clauses and issues errors if so.
procedure Find_Component;
-- Finds component entity corresponding to current component clause (in
-- CC), and sets Comp to the entity, and Fbit/Lbit to the zero origin
-- start/stop bits for the field. If there is no matching component or
-- if the matching component does not have a component clause, then
-- that's an error and Comp is set to Empty, but no error message is
-- issued, since the message was already given. Comp is also set to
-- Empty if the current "component clause" is in fact a pragma.
-----------------------------
-- Check_Component_Overlap --
-----------------------------
procedure Check_Component_Overlap (C1_Ent, C2_Ent : Entity_Id) is
CC1 : constant Node_Id := Component_Clause (C1_Ent);
CC2 : constant Node_Id := Component_Clause (C2_Ent);
begin
if Present (CC1) and then Present (CC2) then
-- Exclude odd case where we have two tag fields in the same
-- record, both at location zero. This seems a bit strange, but
-- it seems to happen in some circumstances, perhaps on an error.
if Chars (C1_Ent) = Name_uTag
and then
Chars (C2_Ent) = Name_uTag
then
return;
end if;
-- Here we check if the two fields overlap
declare
S1 : constant Uint := Component_Bit_Offset (C1_Ent);
S2 : constant Uint := Component_Bit_Offset (C2_Ent);
E1 : constant Uint := S1 + Esize (C1_Ent);
E2 : constant Uint := S2 + Esize (C2_Ent);
begin
if E2 <= S1 or else E1 <= S2 then
null;
else
Error_Msg_Node_2 := Component_Name (CC2);
Error_Msg_Sloc := Sloc (Error_Msg_Node_2);
Error_Msg_Node_1 := Component_Name (CC1);
Error_Msg_N
("component& overlaps & #", Component_Name (CC1));
Overlap_Detected := True;
end if;
end;
end if;
end Check_Component_Overlap;
--------------------
-- Find_Component --
--------------------
procedure Find_Component is
procedure Search_Component (R : Entity_Id);
-- Search components of R for a match. If found, Comp is set.
----------------------
-- Search_Component --
----------------------
procedure Search_Component (R : Entity_Id) is
begin
Comp := First_Component_Or_Discriminant (R);
while Present (Comp) loop
-- Ignore error of attribute name for component name (we
-- already gave an error message for this, so no need to
-- complain here)
if Nkind (Component_Name (CC)) = N_Attribute_Reference then
null;
else
exit when Chars (Comp) = Chars (Component_Name (CC));
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
end Search_Component;
-- Start of processing for Find_Component
begin
-- Return with Comp set to Empty if we have a pragma
if Nkind (CC) = N_Pragma then
Comp := Empty;
return;
end if;
-- Search current record for matching component
Search_Component (Rectype);
-- If not found, maybe component of base type that is absent from
-- statically constrained first subtype.
if No (Comp) then
Search_Component (Base_Type (Rectype));
end if;
-- If no component, or the component does not reference the component
-- clause in question, then there was some previous error for which
-- we already gave a message, so just return with Comp Empty.
if No (Comp)
or else Component_Clause (Comp) /= CC
then
Comp := Empty;
-- Normal case where we have a component clause
else
Fbit := Component_Bit_Offset (Comp);
Lbit := Fbit + Esize (Comp) - 1;
end if;
end Find_Component;
-- Start of processing for Check_Record_Representation_Clause
begin
Find_Type (Ident);
Rectype := Entity (Ident);
if Rectype = Any_Type then
return;
else
Rectype := Underlying_Type (Rectype);
end if;
-- See if we have a fully repped derived tagged type
declare
PS : constant Entity_Id := Parent_Subtype (Rectype);
begin
if Present (PS) and then Is_Fully_Repped_Tagged_Type (PS) then
Tagged_Parent := PS;
-- Find maximum bit of any component of the parent type
Parent_Last_Bit := UI_From_Int (System_Address_Size - 1);
Pcomp := First_Entity (Tagged_Parent);
while Present (Pcomp) loop
if Ekind_In (Pcomp, E_Discriminant, E_Component) then
if Component_Bit_Offset (Pcomp) /= No_Uint
and then Known_Static_Esize (Pcomp)
then
Parent_Last_Bit :=
UI_Max
(Parent_Last_Bit,
Component_Bit_Offset (Pcomp) + Esize (Pcomp) - 1);
end if;
Next_Entity (Pcomp);
end if;
end loop;
end if;
end;
-- All done if no component clauses
CC := First (Component_Clauses (N));
if No (CC) then
return;
end if;
-- If a tag is present, then create a component clause that places it
-- at the start of the record (otherwise gigi may place it after other
-- fields that have rep clauses).
Fent := First_Entity (Rectype);
if Nkind (Fent) = N_Defining_Identifier
and then Chars (Fent) = Name_uTag
then
Set_Component_Bit_Offset (Fent, Uint_0);
Set_Normalized_Position (Fent, Uint_0);
Set_Normalized_First_Bit (Fent, Uint_0);
Set_Normalized_Position_Max (Fent, Uint_0);
Init_Esize (Fent, System_Address_Size);
Set_Component_Clause (Fent,
Make_Component_Clause (Loc,
Component_Name => Make_Identifier (Loc, Name_uTag),
Position => Make_Integer_Literal (Loc, Uint_0),
First_Bit => Make_Integer_Literal (Loc, Uint_0),
Last_Bit =>
Make_Integer_Literal (Loc,
UI_From_Int (System_Address_Size))));
Ccount := Ccount + 1;
end if;
Max_Bit_So_Far := Uint_Minus_1;
Overlap_Check_Required := False;
-- Process the component clauses
while Present (CC) loop
Find_Component;
if Present (Comp) then
Ccount := Ccount + 1;
-- We need a full overlap check if record positions non-monotonic
if Fbit <= Max_Bit_So_Far then
Overlap_Check_Required := True;
end if;
Max_Bit_So_Far := Lbit;
-- Check bit position out of range of specified size
if Has_Size_Clause (Rectype)
and then Esize (Rectype) <= Lbit
then
Error_Msg_N
("bit number out of range of specified size",
Last_Bit (CC));
-- Check for overlap with tag field
else
if Is_Tagged_Type (Rectype)
and then Fbit < System_Address_Size
then
Error_Msg_NE
("component overlaps tag field of&",
Component_Name (CC), Rectype);
Overlap_Detected := True;
end if;
if Hbit < Lbit then
Hbit := Lbit;
end if;
end if;
-- Check parent overlap if component might overlap parent field
if Present (Tagged_Parent)
and then Fbit <= Parent_Last_Bit
then
Pcomp := First_Component_Or_Discriminant (Tagged_Parent);
while Present (Pcomp) loop
if not Is_Tag (Pcomp)
and then Chars (Pcomp) /= Name_uParent
then
Check_Component_Overlap (Comp, Pcomp);
end if;
Next_Component_Or_Discriminant (Pcomp);
end loop;
end if;
end if;
Next (CC);
end loop;
-- Now that we have processed all the component clauses, check for
-- overlap. We have to leave this till last, since the components can
-- appear in any arbitrary order in the representation clause.
-- We do not need this check if all specified ranges were monotonic,
-- as recorded by Overlap_Check_Required being False at this stage.
-- This first section checks if there are any overlapping entries at
-- all. It does this by sorting all entries and then seeing if there are
-- any overlaps. If there are none, then that is decisive, but if there
-- are overlaps, they may still be OK (they may result from fields in
-- different variants).
if Overlap_Check_Required then
Overlap_Check1 : declare
OC_Fbit : array (0 .. Ccount) of Uint;
-- First-bit values for component clauses, the value is the offset
-- of the first bit of the field from start of record. The zero
-- entry is for use in sorting.
OC_Lbit : array (0 .. Ccount) of Uint;
-- Last-bit values for component clauses, the value is the offset
-- of the last bit of the field from start of record. The zero
-- entry is for use in sorting.
OC_Count : Natural := 0;
-- Count of entries in OC_Fbit and OC_Lbit
function OC_Lt (Op1, Op2 : Natural) return Boolean;
-- Compare routine for Sort
procedure OC_Move (From : Natural; To : Natural);
-- Move routine for Sort
package Sorting is new GNAT.Heap_Sort_G (OC_Move, OC_Lt);
-----------
-- OC_Lt --
-----------
function OC_Lt (Op1, Op2 : Natural) return Boolean is
begin
return OC_Fbit (Op1) < OC_Fbit (Op2);
end OC_Lt;
-------------
-- OC_Move --
-------------
procedure OC_Move (From : Natural; To : Natural) is
begin
OC_Fbit (To) := OC_Fbit (From);
OC_Lbit (To) := OC_Lbit (From);
end OC_Move;
-- Start of processing for Overlap_Check
begin
CC := First (Component_Clauses (N));
while Present (CC) loop
-- Exclude component clause already marked in error
if not Error_Posted (CC) then
Find_Component;
if Present (Comp) then
OC_Count := OC_Count + 1;
OC_Fbit (OC_Count) := Fbit;
OC_Lbit (OC_Count) := Lbit;
end if;
end if;
Next (CC);
end loop;
Sorting.Sort (OC_Count);
Overlap_Check_Required := False;
for J in 1 .. OC_Count - 1 loop
if OC_Lbit (J) >= OC_Fbit (J + 1) then
Overlap_Check_Required := True;
exit;
end if;
end loop;
end Overlap_Check1;
end if;
-- If Overlap_Check_Required is still True, then we have to do the full
-- scale overlap check, since we have at least two fields that do
-- overlap, and we need to know if that is OK since they are in
-- different variant, or whether we have a definite problem.
if Overlap_Check_Required then
Overlap_Check2 : declare
C1_Ent, C2_Ent : Entity_Id;
-- Entities of components being checked for overlap
Clist : Node_Id;
-- Component_List node whose Component_Items are being checked
Citem : Node_Id;
-- Component declaration for component being checked
begin
C1_Ent := First_Entity (Base_Type (Rectype));
-- Loop through all components in record. For each component check
-- for overlap with any of the preceding elements on the component
-- list containing the component and also, if the component is in
-- a variant, check against components outside the case structure.
-- This latter test is repeated recursively up the variant tree.
Main_Component_Loop : while Present (C1_Ent) loop
if not Ekind_In (C1_Ent, E_Component, E_Discriminant) then
goto Continue_Main_Component_Loop;
end if;
-- Skip overlap check if entity has no declaration node. This
-- happens with discriminants in constrained derived types.
-- Possibly we are missing some checks as a result, but that
-- does not seem terribly serious.
if No (Declaration_Node (C1_Ent)) then
goto Continue_Main_Component_Loop;
end if;
Clist := Parent (List_Containing (Declaration_Node (C1_Ent)));
-- Loop through component lists that need checking. Check the
-- current component list and all lists in variants above us.
Component_List_Loop : loop
-- If derived type definition, go to full declaration
-- If at outer level, check discriminants if there are any.
if Nkind (Clist) = N_Derived_Type_Definition then
Clist := Parent (Clist);
end if;
-- Outer level of record definition, check discriminants
if Nkind_In (Clist, N_Full_Type_Declaration,
N_Private_Type_Declaration)
then
if Has_Discriminants (Defining_Identifier (Clist)) then
C2_Ent :=
First_Discriminant (Defining_Identifier (Clist));
while Present (C2_Ent) loop
exit when C1_Ent = C2_Ent;
Check_Component_Overlap (C1_Ent, C2_Ent);
Next_Discriminant (C2_Ent);
end loop;
end if;
-- Record extension case
elsif Nkind (Clist) = N_Derived_Type_Definition then
Clist := Empty;
-- Otherwise check one component list
else
Citem := First (Component_Items (Clist));
while Present (Citem) loop
if Nkind (Citem) = N_Component_Declaration then
C2_Ent := Defining_Identifier (Citem);
exit when C1_Ent = C2_Ent;
Check_Component_Overlap (C1_Ent, C2_Ent);
end if;
Next (Citem);
end loop;
end if;
-- Check for variants above us (the parent of the Clist can
-- be a variant, in which case its parent is a variant part,
-- and the parent of the variant part is a component list
-- whose components must all be checked against the current
-- component for overlap).
if Nkind (Parent (Clist)) = N_Variant then
Clist := Parent (Parent (Parent (Clist)));
-- Check for possible discriminant part in record, this
-- is treated essentially as another level in the
-- recursion. For this case the parent of the component
-- list is the record definition, and its parent is the
-- full type declaration containing the discriminant
-- specifications.
elsif Nkind (Parent (Clist)) = N_Record_Definition then
Clist := Parent (Parent ((Clist)));
-- If neither of these two cases, we are at the top of
-- the tree.
else
exit Component_List_Loop;
end if;
end loop Component_List_Loop;
<<Continue_Main_Component_Loop>>
Next_Entity (C1_Ent);
end loop Main_Component_Loop;
end Overlap_Check2;
end if;
-- The following circuit deals with warning on record holes (gaps). We
-- skip this check if overlap was detected, since it makes sense for the
-- programmer to fix this illegality before worrying about warnings.
if not Overlap_Detected and Warn_On_Record_Holes then
Record_Hole_Check : declare
Decl : constant Node_Id := Declaration_Node (Base_Type (Rectype));
-- Full declaration of record type
procedure Check_Component_List
(CL : Node_Id;
Sbit : Uint;
DS : List_Id);
-- Check component list CL for holes. The starting bit should be
-- Sbit. which is zero for the main record component list and set
-- appropriately for recursive calls for variants. DS is set to
-- a list of discriminant specifications to be included in the
-- consideration of components. It is No_List if none to consider.
--------------------------
-- Check_Component_List --
--------------------------
procedure Check_Component_List
(CL : Node_Id;
Sbit : Uint;
DS : List_Id)
is
Compl : Integer;
begin
Compl := Integer (List_Length (Component_Items (CL)));
if DS /= No_List then
Compl := Compl + Integer (List_Length (DS));
end if;
declare
Comps : array (Natural range 0 .. Compl) of Entity_Id;
-- Gather components (zero entry is for sort routine)
Ncomps : Natural := 0;
-- Number of entries stored in Comps (starting at Comps (1))
Citem : Node_Id;
-- One component item or discriminant specification
Nbit : Uint;
-- Starting bit for next component
CEnt : Entity_Id;
-- Component entity
Variant : Node_Id;
-- One variant
function Lt (Op1, Op2 : Natural) return Boolean;
-- Compare routine for Sort
procedure Move (From : Natural; To : Natural);
-- Move routine for Sort
package Sorting is new GNAT.Heap_Sort_G (Move, Lt);
--------
-- Lt --
--------
function Lt (Op1, Op2 : Natural) return Boolean is
begin
return Component_Bit_Offset (Comps (Op1))
<
Component_Bit_Offset (Comps (Op2));
end Lt;
----------
-- Move --
----------
procedure Move (From : Natural; To : Natural) is
begin
Comps (To) := Comps (From);
end Move;
begin
-- Gather discriminants into Comp
if DS /= No_List then
Citem := First (DS);
while Present (Citem) loop
if Nkind (Citem) = N_Discriminant_Specification then
declare
Ent : constant Entity_Id :=
Defining_Identifier (Citem);
begin
if Ekind (Ent) = E_Discriminant then
Ncomps := Ncomps + 1;
Comps (Ncomps) := Ent;
end if;
end;
end if;
Next (Citem);
end loop;
end if;
-- Gather component entities into Comp
Citem := First (Component_Items (CL));
while Present (Citem) loop
if Nkind (Citem) = N_Component_Declaration then
Ncomps := Ncomps + 1;
Comps (Ncomps) := Defining_Identifier (Citem);
end if;
Next (Citem);
end loop;
-- Now sort the component entities based on the first bit.
-- Note we already know there are no overlapping components.
Sorting.Sort (Ncomps);
-- Loop through entries checking for holes
Nbit := Sbit;
for J in 1 .. Ncomps loop
CEnt := Comps (J);
Error_Msg_Uint_1 := Component_Bit_Offset (CEnt) - Nbit;
if Error_Msg_Uint_1 > 0 then
Error_Msg_NE
("?^-bit gap before component&",
Component_Name (Component_Clause (CEnt)), CEnt);
end if;
Nbit := Component_Bit_Offset (CEnt) + Esize (CEnt);
end loop;
-- Process variant parts recursively if present
if Present (Variant_Part (CL)) then
Variant := First (Variants (Variant_Part (CL)));
while Present (Variant) loop
Check_Component_List
(Component_List (Variant), Nbit, No_List);
Next (Variant);
end loop;
end if;
end;
end Check_Component_List;
-- Start of processing for Record_Hole_Check
begin
declare
Sbit : Uint;
begin
if Is_Tagged_Type (Rectype) then
Sbit := UI_From_Int (System_Address_Size);
else
Sbit := Uint_0;
end if;
if Nkind (Decl) = N_Full_Type_Declaration
and then Nkind (Type_Definition (Decl)) = N_Record_Definition
then
Check_Component_List
(Component_List (Type_Definition (Decl)),
Sbit,
Discriminant_Specifications (Decl));
end if;
end;
end Record_Hole_Check;
end if;
-- For records that have component clauses for all components, and whose
-- size is less than or equal to 32, we need to know the size in the
-- front end to activate possible packed array processing where the
-- component type is a record.
-- At this stage Hbit + 1 represents the first unused bit from all the
-- component clauses processed, so if the component clauses are
-- complete, then this is the length of the record.
-- For records longer than System.Storage_Unit, and for those where not
-- all components have component clauses, the back end determines the
-- length (it may for example be appropriate to round up the size
-- to some convenient boundary, based on alignment considerations, etc).
if Unknown_RM_Size (Rectype) and then Hbit + 1 <= 32 then
-- Nothing to do if at least one component has no component clause
Comp := First_Component_Or_Discriminant (Rectype);
while Present (Comp) loop
exit when No (Component_Clause (Comp));
Next_Component_Or_Discriminant (Comp);
end loop;
-- If we fall out of loop, all components have component clauses
-- and so we can set the size to the maximum value.
if No (Comp) then
Set_RM_Size (Rectype, Hbit + 1);
end if;
end if;
end Check_Record_Representation_Clause;
----------------
-- Check_Size --
----------------
procedure Check_Size
(N : Node_Id;
T : Entity_Id;
Siz : Uint;
Biased : out Boolean)
is
UT : constant Entity_Id := Underlying_Type (T);
M : Uint;
begin
Biased := False;
-- Dismiss cases for generic types or types with previous errors
if No (UT)
or else UT = Any_Type
or else Is_Generic_Type (UT)
or else Is_Generic_Type (Root_Type (UT))
then
return;
-- Check case of bit packed array
elsif Is_Array_Type (UT)
and then Known_Static_Component_Size (UT)
and then Is_Bit_Packed_Array (UT)
then
declare
Asiz : Uint;
Indx : Node_Id;
Ityp : Entity_Id;
begin
Asiz := Component_Size (UT);
Indx := First_Index (UT);
loop
Ityp := Etype (Indx);
-- If non-static bound, then we are not in the business of
-- trying to check the length, and indeed an error will be
-- issued elsewhere, since sizes of non-static array types
-- cannot be set implicitly or explicitly.
if not Is_Static_Subtype (Ityp) then
return;
end if;
-- Otherwise accumulate next dimension
Asiz := Asiz * (Expr_Value (Type_High_Bound (Ityp)) -
Expr_Value (Type_Low_Bound (Ityp)) +
Uint_1);
Next_Index (Indx);
exit when No (Indx);
end loop;
if Asiz <= Siz then
return;
else
Error_Msg_Uint_1 := Asiz;
Error_Msg_NE
("size for& too small, minimum allowed is ^", N, T);
Set_Esize (T, Asiz);
Set_RM_Size (T, Asiz);
end if;
end;
-- All other composite types are ignored
elsif Is_Composite_Type (UT) then
return;
-- For fixed-point types, don't check minimum if type is not frozen,
-- since we don't know all the characteristics of the type that can
-- affect the size (e.g. a specified small) till freeze time.
elsif Is_Fixed_Point_Type (UT)
and then not Is_Frozen (UT)
then
null;
-- Cases for which a minimum check is required
else
-- Ignore if specified size is correct for the type
if Known_Esize (UT) and then Siz = Esize (UT) then
return;
end if;
-- Otherwise get minimum size
M := UI_From_Int (Minimum_Size (UT));
if Siz < M then
-- Size is less than minimum size, but one possibility remains
-- that we can manage with the new size if we bias the type.
M := UI_From_Int (Minimum_Size (UT, Biased => True));
if Siz < M then
Error_Msg_Uint_1 := M;
Error_Msg_NE
("size for& too small, minimum allowed is ^", N, T);
Set_Esize (T, M);
Set_RM_Size (T, M);
else
Biased := True;
end if;
end if;
end if;
end Check_Size;
-------------------------
-- Get_Alignment_Value --
-------------------------
function Get_Alignment_Value (Expr : Node_Id) return Uint is
Align : constant Uint := Static_Integer (Expr);
begin
if Align = No_Uint then
return No_Uint;
elsif Align <= 0 then
Error_Msg_N ("alignment value must be positive", Expr);
return No_Uint;
else
for J in Int range 0 .. 64 loop
declare
M : constant Uint := Uint_2 ** J;
begin
exit when M = Align;
if M > Align then
Error_Msg_N
("alignment value must be power of 2", Expr);
return No_Uint;
end if;
end;
end loop;
return Align;
end if;
end Get_Alignment_Value;
----------------
-- Initialize --
----------------
procedure Initialize is
begin
Address_Clause_Checks.Init;
Independence_Checks.Init;
Unchecked_Conversions.Init;
end Initialize;
-------------------------
-- Is_Operational_Item --
-------------------------
function Is_Operational_Item (N : Node_Id) return Boolean is
begin
if Nkind (N) /= N_Attribute_Definition_Clause then
return False;
else
declare
Id : constant Attribute_Id := Get_Attribute_Id (Chars (N));
begin
return Id = Attribute_Input
or else Id = Attribute_Output
or else Id = Attribute_Read
or else Id = Attribute_Write
or else Id = Attribute_External_Tag;
end;
end if;
end Is_Operational_Item;
------------------
-- Minimum_Size --
------------------
function Minimum_Size
(T : Entity_Id;
Biased : Boolean := False) return Nat
is
Lo : Uint := No_Uint;
Hi : Uint := No_Uint;
LoR : Ureal := No_Ureal;
HiR : Ureal := No_Ureal;
LoSet : Boolean := False;
HiSet : Boolean := False;
B : Uint;
S : Nat;
Ancest : Entity_Id;
R_Typ : constant Entity_Id := Root_Type (T);
begin
-- If bad type, return 0
if T = Any_Type then
return 0;
-- For generic types, just return zero. There cannot be any legitimate
-- need to know such a size, but this routine may be called with a
-- generic type as part of normal processing.
elsif Is_Generic_Type (R_Typ)
or else R_Typ = Any_Type
then
return 0;
-- Access types. Normally an access type cannot have a size smaller
-- than the size of System.Address. The exception is on VMS, where
-- we have short and long addresses, and it is possible for an access
-- type to have a short address size (and thus be less than the size
-- of System.Address itself). We simply skip the check for VMS, and
-- leave it to the back end to do the check.
elsif Is_Access_Type (T) then
if OpenVMS_On_Target then
return 0;
else
return System_Address_Size;
end if;
-- Floating-point types
elsif Is_Floating_Point_Type (T) then
return UI_To_Int (Esize (R_Typ));
-- Discrete types
elsif Is_Discrete_Type (T) then
-- The following loop is looking for the nearest compile time known
-- bounds following the ancestor subtype chain. The idea is to find
-- the most restrictive known bounds information.
Ancest := T;
loop
if Ancest = Any_Type or else Etype (Ancest) = Any_Type then
return 0;
end if;
if not LoSet then
if Compile_Time_Known_Value (Type_Low_Bound (Ancest)) then
Lo := Expr_Rep_Value (Type_Low_Bound (Ancest));
LoSet := True;
exit when HiSet;
end if;
end if;
if not HiSet then
if Compile_Time_Known_Value (Type_High_Bound (Ancest)) then
Hi := Expr_Rep_Value (Type_High_Bound (Ancest));
HiSet := True;
exit when LoSet;
end if;
end if;
Ancest := Ancestor_Subtype (Ancest);
if No (Ancest) then
Ancest := Base_Type (T);
if Is_Generic_Type (Ancest) then
return 0;
end if;
end if;
end loop;
-- Fixed-point types. We can't simply use Expr_Value to get the
-- Corresponding_Integer_Value values of the bounds, since these do not
-- get set till the type is frozen, and this routine can be called
-- before the type is frozen. Similarly the test for bounds being static
-- needs to include the case where we have unanalyzed real literals for
-- the same reason.
elsif Is_Fixed_Point_Type (T) then
-- The following loop is looking for the nearest compile time known
-- bounds following the ancestor subtype chain. The idea is to find
-- the most restrictive known bounds information.
Ancest := T;
loop
if Ancest = Any_Type or else Etype (Ancest) = Any_Type then
return 0;
end if;
-- Note: In the following two tests for LoSet and HiSet, it may
-- seem redundant to test for N_Real_Literal here since normally
-- one would assume that the test for the value being known at
-- compile time includes this case. However, there is a glitch.
-- If the real literal comes from folding a non-static expression,
-- then we don't consider any non- static expression to be known
-- at compile time if we are in configurable run time mode (needed
-- in some cases to give a clearer definition of what is and what
-- is not accepted). So the test is indeed needed. Without it, we
-- would set neither Lo_Set nor Hi_Set and get an infinite loop.
if not LoSet then
if Nkind (Type_Low_Bound (Ancest)) = N_Real_Literal
or else Compile_Time_Known_Value (Type_Low_Bound (Ancest))
then
LoR := Expr_Value_R (Type_Low_Bound (Ancest));
LoSet := True;
exit when HiSet;
end if;
end if;
if not HiSet then
if Nkind (Type_High_Bound (Ancest)) = N_Real_Literal
or else Compile_Time_Known_Value (Type_High_Bound (Ancest))
then
HiR := Expr_Value_R (Type_High_Bound (Ancest));
HiSet := True;
exit when LoSet;
end if;
end if;
Ancest := Ancestor_Subtype (Ancest);
if No (Ancest) then
Ancest := Base_Type (T);
if Is_Generic_Type (Ancest) then
return 0;
end if;
end if;
end loop;
Lo := UR_To_Uint (LoR / Small_Value (T));
Hi := UR_To_Uint (HiR / Small_Value (T));
-- No other types allowed
else
raise Program_Error;
end if;
-- Fall through with Hi and Lo set. Deal with biased case
if (Biased
and then not Is_Fixed_Point_Type (T)
and then not (Is_Enumeration_Type (T)
and then Has_Non_Standard_Rep (T)))
or else Has_Biased_Representation (T)
then
Hi := Hi - Lo;
Lo := Uint_0;
end if;
-- Signed case. Note that we consider types like range 1 .. -1 to be
-- signed for the purpose of computing the size, since the bounds have
-- to be accommodated in the base type.
if Lo < 0 or else Hi < 0 then
S := 1;
B := Uint_1;
-- S = size, B = 2 ** (size - 1) (can accommodate -B .. +(B - 1))
-- Note that we accommodate the case where the bounds cross. This
-- can happen either because of the way the bounds are declared
-- or because of the algorithm in Freeze_Fixed_Point_Type.
while Lo < -B
or else Hi < -B
or else Lo >= B
or else Hi >= B
loop
B := Uint_2 ** S;
S := S + 1;
end loop;
-- Unsigned case
else
-- If both bounds are positive, make sure that both are represen-
-- table in the case where the bounds are crossed. This can happen
-- either because of the way the bounds are declared, or because of
-- the algorithm in Freeze_Fixed_Point_Type.
if Lo > Hi then
Hi := Lo;
end if;
-- S = size, (can accommodate 0 .. (2**size - 1))
S := 0;
while Hi >= Uint_2 ** S loop
S := S + 1;
end loop;
end if;
return S;
end Minimum_Size;
---------------------------
-- New_Stream_Subprogram --
---------------------------
procedure New_Stream_Subprogram
(N : Node_Id;
Ent : Entity_Id;
Subp : Entity_Id;
Nam : TSS_Name_Type)
is
Loc : constant Source_Ptr := Sloc (N);
Sname : constant Name_Id := Make_TSS_Name (Base_Type (Ent), Nam);
Subp_Id : Entity_Id;
Subp_Decl : Node_Id;
F : Entity_Id;
Etyp : Entity_Id;
Defer_Declaration : constant Boolean :=
Is_Tagged_Type (Ent) or else Is_Private_Type (Ent);
-- For a tagged type, there is a declaration for each stream attribute
-- at the freeze point, and we must generate only a completion of this
-- declaration. We do the same for private types, because the full view
-- might be tagged. Otherwise we generate a declaration at the point of
-- the attribute definition clause.
function Build_Spec return Node_Id;
-- Used for declaration and renaming declaration, so that this is
-- treated as a renaming_as_body.
----------------
-- Build_Spec --
----------------
function Build_Spec return Node_Id is
Out_P : constant Boolean := (Nam = TSS_Stream_Read);
Formals : List_Id;
Spec : Node_Id;
T_Ref : constant Node_Id := New_Reference_To (Etyp, Loc);
begin
Subp_Id := Make_Defining_Identifier (Loc, Sname);
-- S : access Root_Stream_Type'Class
Formals := New_List (
Make_Parameter_Specification (Loc,
Defining_Identifier =>
Make_Defining_Identifier (Loc, Name_S),
Parameter_Type =>
Make_Access_Definition (Loc,
Subtype_Mark =>
New_Reference_To (
Designated_Type (Etype (F)), Loc))));
if Nam = TSS_Stream_Input then
Spec := Make_Function_Specification (Loc,
Defining_Unit_Name => Subp_Id,
Parameter_Specifications => Formals,
Result_Definition => T_Ref);
else
-- V : [out] T
Append_To (Formals,
Make_Parameter_Specification (Loc,
Defining_Identifier => Make_Defining_Identifier (Loc, Name_V),
Out_Present => Out_P,
Parameter_Type => T_Ref));
Spec :=
Make_Procedure_Specification (Loc,
Defining_Unit_Name => Subp_Id,
Parameter_Specifications => Formals);
end if;
return Spec;
end Build_Spec;
-- Start of processing for New_Stream_Subprogram
begin
F := First_Formal (Subp);
if Ekind (Subp) = E_Procedure then
Etyp := Etype (Next_Formal (F));
else
Etyp := Etype (Subp);
end if;
-- Prepare subprogram declaration and insert it as an action on the
-- clause node. The visibility for this entity is used to test for
-- visibility of the attribute definition clause (in the sense of
-- 8.3(23) as amended by AI-195).
if not Defer_Declaration then
Subp_Decl :=
Make_Subprogram_Declaration (Loc,
Specification => Build_Spec);
-- For a tagged type, there is always a visible declaration for each
-- stream TSS (it is a predefined primitive operation), and the
-- completion of this declaration occurs at the freeze point, which is
-- not always visible at places where the attribute definition clause is
-- visible. So, we create a dummy entity here for the purpose of
-- tracking the visibility of the attribute definition clause itself.
else
Subp_Id :=
Make_Defining_Identifier (Loc, New_External_Name (Sname, 'V'));
Subp_Decl :=
Make_Object_Declaration (Loc,
Defining_Identifier => Subp_Id,
Object_Definition => New_Occurrence_Of (Standard_Boolean, Loc));
end if;
Insert_Action (N, Subp_Decl);
Set_Entity (N, Subp_Id);
Subp_Decl :=
Make_Subprogram_Renaming_Declaration (Loc,
Specification => Build_Spec,
Name => New_Reference_To (Subp, Loc));
if Defer_Declaration then
Set_TSS (Base_Type (Ent), Subp_Id);
else
Insert_Action (N, Subp_Decl);
Copy_TSS (Subp_Id, Base_Type (Ent));
end if;
end New_Stream_Subprogram;
------------------------
-- Rep_Item_Too_Early --
------------------------
function Rep_Item_Too_Early (T : Entity_Id; N : Node_Id) return Boolean is
begin
-- Cannot apply non-operational rep items to generic types
if Is_Operational_Item (N) then
return False;
elsif Is_Type (T)
and then Is_Generic_Type (Root_Type (T))
then
Error_Msg_N ("representation item not allowed for generic type", N);
return True;
end if;
-- Otherwise check for incomplete type
if Is_Incomplete_Or_Private_Type (T)
and then No (Underlying_Type (T))
then
Error_Msg_N
("representation item must be after full type declaration", N);
return True;
-- If the type has incomplete components, a representation clause is
-- illegal but stream attributes and Convention pragmas are correct.
elsif Has_Private_Component (T) then
if Nkind (N) = N_Pragma then
return False;
else
Error_Msg_N
("representation item must appear after type is fully defined",
N);
return True;
end if;
else
return False;
end if;
end Rep_Item_Too_Early;
-----------------------
-- Rep_Item_Too_Late --
-----------------------
function Rep_Item_Too_Late
(T : Entity_Id;
N : Node_Id;
FOnly : Boolean := False) return Boolean
is
S : Entity_Id;
Parent_Type : Entity_Id;
procedure Too_Late;
-- Output the too late message. Note that this is not considered a
-- serious error, since the effect is simply that we ignore the
-- representation clause in this case.
--------------
-- Too_Late --
--------------
procedure Too_Late is
begin
Error_Msg_N ("|representation item appears too late!", N);
end Too_Late;
-- Start of processing for Rep_Item_Too_Late
begin
-- First make sure entity is not frozen (RM 13.1(9)). Exclude imported
-- types, which may be frozen if they appear in a representation clause
-- for a local type.
if Is_Frozen (T)
and then not From_With_Type (T)
then
Too_Late;
S := First_Subtype (T);
if Present (Freeze_Node (S)) then
Error_Msg_NE
("?no more representation items for }", Freeze_Node (S), S);
end if;
return True;
-- Check for case of non-tagged derived type whose parent either has
-- primitive operations, or is a by reference type (RM 13.1(10)).
elsif Is_Type (T)
and then not FOnly
and then Is_Derived_Type (T)
and then not Is_Tagged_Type (T)
then
Parent_Type := Etype (Base_Type (T));
if Has_Primitive_Operations (Parent_Type) then
Too_Late;
Error_Msg_NE
("primitive operations already defined for&!", N, Parent_Type);
return True;
elsif Is_By_Reference_Type (Parent_Type) then
Too_Late;
Error_Msg_NE
("parent type & is a by reference type!", N, Parent_Type);
return True;
end if;
end if;
-- No error, link item into head of chain of rep items for the entity,
-- but avoid chaining if we have an overloadable entity, and the pragma
-- is one that can apply to multiple overloaded entities.
if Is_Overloadable (T)
and then Nkind (N) = N_Pragma
then
declare
Pname : constant Name_Id := Pragma_Name (N);
begin
if Pname = Name_Convention or else
Pname = Name_Import or else
Pname = Name_Export or else
Pname = Name_External or else
Pname = Name_Interface
then
return False;
end if;
end;
end if;
Record_Rep_Item (T, N);
return False;
end Rep_Item_Too_Late;
-------------------------------------
-- Replace_Type_References_Generic --
-------------------------------------
procedure Replace_Type_References_Generic (N : Node_Id; TName : Name_Id) is
function Replace_Node (N : Node_Id) return Traverse_Result;
-- Processes a single node in the traversal procedure below, checking
-- if node N should be replaced, and if so, doing the replacement.
procedure Replace_Type_Refs is new Traverse_Proc (Replace_Node);
-- This instantiation provides the body of Replace_Type_References
------------------
-- Replace_Node --
------------------
function Replace_Node (N : Node_Id) return Traverse_Result is
S : Entity_Id;
P : Node_Id;
begin
-- Case of identifier
if Nkind (N) = N_Identifier then
-- If not the type name, all done with this node
if Chars (N) /= TName then
return Skip;
-- Otherwise do the replacement and we are done with this node
else
Replace_Type_Reference (N);
return Skip;
end if;
-- Case of selected component (which is what a qualification
-- looks like in the unanalyzed tree, which is what we have.
elsif Nkind (N) = N_Selected_Component then
-- If selector name is not our type, keeping going (we might
-- still have an occurrence of the type in the prefix).
if Nkind (Selector_Name (N)) /= N_Identifier
or else Chars (Selector_Name (N)) /= TName
then
return OK;
-- Selector name is our type, check qualification
else
-- Loop through scopes and prefixes, doing comparison
S := Current_Scope;
P := Prefix (N);
loop
-- Continue if no more scopes or scope with no name
if No (S) or else Nkind (S) not in N_Has_Chars then
return OK;
end if;
-- Do replace if prefix is an identifier matching the
-- scope that we are currently looking at.
if Nkind (P) = N_Identifier
and then Chars (P) = Chars (S)
then
Replace_Type_Reference (N);
return Skip;
end if;
-- Go check scope above us if prefix is itself of the
-- form of a selected component, whose selector matches
-- the scope we are currently looking at.
if Nkind (P) = N_Selected_Component
and then Nkind (Selector_Name (P)) = N_Identifier
and then Chars (Selector_Name (P)) = Chars (S)
then
S := Scope (S);
P := Prefix (P);
-- For anything else, we don't have a match, so keep on
-- going, there are still some weird cases where we may
-- still have a replacement within the prefix.
else
return OK;
end if;
end loop;
end if;
-- Continue for any other node kind
else
return OK;
end if;
end Replace_Node;
begin
Replace_Type_Refs (N);
end Replace_Type_References_Generic;
-------------------------
-- Same_Representation --
-------------------------
function Same_Representation (Typ1, Typ2 : Entity_Id) return Boolean is
T1 : constant Entity_Id := Underlying_Type (Typ1);
T2 : constant Entity_Id := Underlying_Type (Typ2);
begin
-- A quick check, if base types are the same, then we definitely have
-- the same representation, because the subtype specific representation
-- attributes (Size and Alignment) do not affect representation from
-- the point of view of this test.
if Base_Type (T1) = Base_Type (T2) then
return True;
elsif Is_Private_Type (Base_Type (T2))
and then Base_Type (T1) = Full_View (Base_Type (T2))
then
return True;
end if;
-- Tagged types never have differing representations
if Is_Tagged_Type (T1) then
return True;
end if;
-- Representations are definitely different if conventions differ
if Convention (T1) /= Convention (T2) then
return False;
end if;
-- Representations are different if component alignments differ
if (Is_Record_Type (T1) or else Is_Array_Type (T1))
and then
(Is_Record_Type (T2) or else Is_Array_Type (T2))
and then Component_Alignment (T1) /= Component_Alignment (T2)
then
return False;
end if;
-- For arrays, the only real issue is component size. If we know the
-- component size for both arrays, and it is the same, then that's
-- good enough to know we don't have a change of representation.
if Is_Array_Type (T1) then
if Known_Component_Size (T1)
and then Known_Component_Size (T2)
and then Component_Size (T1) = Component_Size (T2)
then
return True;
end if;
end if;
-- Types definitely have same representation if neither has non-standard
-- representation since default representations are always consistent.
-- If only one has non-standard representation, and the other does not,
-- then we consider that they do not have the same representation. They
-- might, but there is no way of telling early enough.
if Has_Non_Standard_Rep (T1) then
if not Has_Non_Standard_Rep (T2) then
return False;
end if;
else
return not Has_Non_Standard_Rep (T2);
end if;
-- Here the two types both have non-standard representation, and we need
-- to determine if they have the same non-standard representation.
-- For arrays, we simply need to test if the component sizes are the
-- same. Pragma Pack is reflected in modified component sizes, so this
-- check also deals with pragma Pack.
if Is_Array_Type (T1) then
return Component_Size (T1) = Component_Size (T2);
-- Tagged types always have the same representation, because it is not
-- possible to specify different representations for common fields.
elsif Is_Tagged_Type (T1) then
return True;
-- Case of record types
elsif Is_Record_Type (T1) then
-- Packed status must conform
if Is_Packed (T1) /= Is_Packed (T2) then
return False;
-- Otherwise we must check components. Typ2 maybe a constrained
-- subtype with fewer components, so we compare the components
-- of the base types.
else
Record_Case : declare
CD1, CD2 : Entity_Id;
function Same_Rep return Boolean;
-- CD1 and CD2 are either components or discriminants. This
-- function tests whether the two have the same representation
--------------
-- Same_Rep --
--------------
function Same_Rep return Boolean is
begin
if No (Component_Clause (CD1)) then
return No (Component_Clause (CD2));
else
return
Present (Component_Clause (CD2))
and then
Component_Bit_Offset (CD1) = Component_Bit_Offset (CD2)
and then
Esize (CD1) = Esize (CD2);
end if;
end Same_Rep;
-- Start of processing for Record_Case
begin
if Has_Discriminants (T1) then
CD1 := First_Discriminant (T1);
CD2 := First_Discriminant (T2);
-- The number of discriminants may be different if the
-- derived type has fewer (constrained by values). The
-- invisible discriminants retain the representation of
-- the original, so the discrepancy does not per se
-- indicate a different representation.
while Present (CD1)
and then Present (CD2)
loop
if not Same_Rep then
return False;
else
Next_Discriminant (CD1);
Next_Discriminant (CD2);
end if;
end loop;
end if;
CD1 := First_Component (Underlying_Type (Base_Type (T1)));
CD2 := First_Component (Underlying_Type (Base_Type (T2)));
while Present (CD1) loop
if not Same_Rep then
return False;
else
Next_Component (CD1);
Next_Component (CD2);
end if;
end loop;
return True;
end Record_Case;
end if;
-- For enumeration types, we must check each literal to see if the
-- representation is the same. Note that we do not permit enumeration
-- representation clauses for Character and Wide_Character, so these
-- cases were already dealt with.
elsif Is_Enumeration_Type (T1) then
Enumeration_Case : declare
L1, L2 : Entity_Id;
begin
L1 := First_Literal (T1);
L2 := First_Literal (T2);
while Present (L1) loop
if Enumeration_Rep (L1) /= Enumeration_Rep (L2) then
return False;
else
Next_Literal (L1);
Next_Literal (L2);
end if;
end loop;
return True;
end Enumeration_Case;
-- Any other types have the same representation for these purposes
else
return True;
end if;
end Same_Representation;
----------------
-- Set_Biased --
----------------
procedure Set_Biased
(E : Entity_Id;
N : Node_Id;
Msg : String;
Biased : Boolean := True)
is
begin
if Biased then
Set_Has_Biased_Representation (E);
if Warn_On_Biased_Representation then
Error_Msg_NE
("?" & Msg & " forces biased representation for&", N, E);
end if;
end if;
end Set_Biased;
--------------------
-- Set_Enum_Esize --
--------------------
procedure Set_Enum_Esize (T : Entity_Id) is
Lo : Uint;
Hi : Uint;
Sz : Nat;
begin
Init_Alignment (T);
-- Find the minimum standard size (8,16,32,64) that fits
Lo := Enumeration_Rep (Entity (Type_Low_Bound (T)));
Hi := Enumeration_Rep (Entity (Type_High_Bound (T)));
if Lo < 0 then
if Lo >= -Uint_2**07 and then Hi < Uint_2**07 then
Sz := Standard_Character_Size; -- May be > 8 on some targets
elsif Lo >= -Uint_2**15 and then Hi < Uint_2**15 then
Sz := 16;
elsif Lo >= -Uint_2**31 and then Hi < Uint_2**31 then
Sz := 32;
else pragma Assert (Lo >= -Uint_2**63 and then Hi < Uint_2**63);
Sz := 64;
end if;
else
if Hi < Uint_2**08 then
Sz := Standard_Character_Size; -- May be > 8 on some targets
elsif Hi < Uint_2**16 then
Sz := 16;
elsif Hi < Uint_2**32 then
Sz := 32;
else pragma Assert (Hi < Uint_2**63);
Sz := 64;
end if;
end if;
-- That minimum is the proper size unless we have a foreign convention
-- and the size required is 32 or less, in which case we bump the size
-- up to 32. This is required for C and C++ and seems reasonable for
-- all other foreign conventions.
if Has_Foreign_Convention (T)
and then Esize (T) < Standard_Integer_Size
then
Init_Esize (T, Standard_Integer_Size);
else
Init_Esize (T, Sz);
end if;
end Set_Enum_Esize;
------------------------------
-- Validate_Address_Clauses --
------------------------------
procedure Validate_Address_Clauses is
begin
for J in Address_Clause_Checks.First .. Address_Clause_Checks.Last loop
declare
ACCR : Address_Clause_Check_Record
renames Address_Clause_Checks.Table (J);
Expr : Node_Id;
X_Alignment : Uint;
Y_Alignment : Uint;
X_Size : Uint;
Y_Size : Uint;
begin
-- Skip processing of this entry if warning already posted
if not Address_Warning_Posted (ACCR.N) then
Expr := Original_Node (Expression (ACCR.N));
-- Get alignments
X_Alignment := Alignment (ACCR.X);
Y_Alignment := Alignment (ACCR.Y);
-- Similarly obtain sizes
X_Size := Esize (ACCR.X);
Y_Size := Esize (ACCR.Y);
-- Check for large object overlaying smaller one
if Y_Size > Uint_0
and then X_Size > Uint_0
and then X_Size > Y_Size
then
Error_Msg_NE
("?& overlays smaller object", ACCR.N, ACCR.X);
Error_Msg_N
("\?program execution may be erroneous", ACCR.N);
Error_Msg_Uint_1 := X_Size;
Error_Msg_NE
("\?size of & is ^", ACCR.N, ACCR.X);
Error_Msg_Uint_1 := Y_Size;
Error_Msg_NE
("\?size of & is ^", ACCR.N, ACCR.Y);
-- Check for inadequate alignment, both of the base object
-- and of the offset, if any.
-- Note: we do not check the alignment if we gave a size
-- warning, since it would likely be redundant.
elsif Y_Alignment /= Uint_0
and then (Y_Alignment < X_Alignment
or else (ACCR.Off
and then
Nkind (Expr) = N_Attribute_Reference
and then
Attribute_Name (Expr) = Name_Address
and then
Has_Compatible_Alignment
(ACCR.X, Prefix (Expr))
/= Known_Compatible))
then
Error_Msg_NE
("?specified address for& may be inconsistent "
& "with alignment",
ACCR.N, ACCR.X);
Error_Msg_N
("\?program execution may be erroneous (RM 13.3(27))",
ACCR.N);
Error_Msg_Uint_1 := X_Alignment;
Error_Msg_NE
("\?alignment of & is ^",
ACCR.N, ACCR.X);
Error_Msg_Uint_1 := Y_Alignment;
Error_Msg_NE
("\?alignment of & is ^",
ACCR.N, ACCR.Y);
if Y_Alignment >= X_Alignment then
Error_Msg_N
("\?but offset is not multiple of alignment",
ACCR.N);
end if;
end if;
end if;
end;
end loop;
end Validate_Address_Clauses;
---------------------------
-- Validate_Independence --
---------------------------
procedure Validate_Independence is
SU : constant Uint := UI_From_Int (System_Storage_Unit);
N : Node_Id;
E : Entity_Id;
IC : Boolean;
Comp : Entity_Id;
Addr : Node_Id;
P : Node_Id;
procedure Check_Array_Type (Atyp : Entity_Id);
-- Checks if the array type Atyp has independent components, and
-- if not, outputs an appropriate set of error messages.
procedure No_Independence;
-- Output message that independence cannot be guaranteed
function OK_Component (C : Entity_Id) return Boolean;
-- Checks one component to see if it is independently accessible, and
-- if so yields True, otherwise yields False if independent access
-- cannot be guaranteed. This is a conservative routine, it only
-- returns True if it knows for sure, it returns False if it knows
-- there is a problem, or it cannot be sure there is no problem.
procedure Reason_Bad_Component (C : Entity_Id);
-- Outputs continuation message if a reason can be determined for
-- the component C being bad.
----------------------
-- Check_Array_Type --
----------------------
procedure Check_Array_Type (Atyp : Entity_Id) is
Ctyp : constant Entity_Id := Component_Type (Atyp);
begin
-- OK if no alignment clause, no pack, and no component size
if not Has_Component_Size_Clause (Atyp)
and then not Has_Alignment_Clause (Atyp)
and then not Is_Packed (Atyp)
then
return;
end if;
-- Check actual component size
if not Known_Component_Size (Atyp)
or else not (Addressable (Component_Size (Atyp))
and then Component_Size (Atyp) < 64)
or else Component_Size (Atyp) mod Esize (Ctyp) /= 0
then
No_Independence;
-- Bad component size, check reason
if Has_Component_Size_Clause (Atyp) then
P :=
Get_Attribute_Definition_Clause
(Atyp, Attribute_Component_Size);
if Present (P) then
Error_Msg_Sloc := Sloc (P);
Error_Msg_N ("\because of Component_Size clause#", N);
return;
end if;
end if;
if Is_Packed (Atyp) then
P := Get_Rep_Pragma (Atyp, Name_Pack);
if Present (P) then
Error_Msg_Sloc := Sloc (P);
Error_Msg_N ("\because of pragma Pack#", N);
return;
end if;
end if;
-- No reason found, just return
return;
end if;
-- Array type is OK independence-wise
return;
end Check_Array_Type;
---------------------
-- No_Independence --
---------------------
procedure No_Independence is
begin
if Pragma_Name (N) = Name_Independent then
Error_Msg_NE
("independence cannot be guaranteed for&", N, E);
else
Error_Msg_NE
("independent components cannot be guaranteed for&", N, E);
end if;
end No_Independence;
------------------
-- OK_Component --
------------------
function OK_Component (C : Entity_Id) return Boolean is
Rec : constant Entity_Id := Scope (C);
Ctyp : constant Entity_Id := Etype (C);
begin
-- OK if no component clause, no Pack, and no alignment clause
if No (Component_Clause (C))
and then not Is_Packed (Rec)
and then not Has_Alignment_Clause (Rec)
then
return True;
end if;
-- Here we look at the actual component layout. A component is
-- addressable if its size is a multiple of the Esize of the
-- component type, and its starting position in the record has
-- appropriate alignment, and the record itself has appropriate
-- alignment to guarantee the component alignment.
-- Make sure sizes are static, always assume the worst for any
-- cases where we cannot check static values.
if not (Known_Static_Esize (C)
and then Known_Static_Esize (Ctyp))
then
return False;
end if;
-- Size of component must be addressable or greater than 64 bits
-- and a multiple of bytes.
if not Addressable (Esize (C))
and then Esize (C) < Uint_64
then
return False;
end if;
-- Check size is proper multiple
if Esize (C) mod Esize (Ctyp) /= 0 then
return False;
end if;
-- Check alignment of component is OK
if not Known_Component_Bit_Offset (C)
or else Component_Bit_Offset (C) < Uint_0
or else Component_Bit_Offset (C) mod Esize (Ctyp) /= 0
then
return False;
end if;
-- Check alignment of record type is OK
if not Known_Alignment (Rec)
or else (Alignment (Rec) * SU) mod Esize (Ctyp) /= 0
then
return False;
end if;
-- All tests passed, component is addressable
return True;
end OK_Component;
--------------------------
-- Reason_Bad_Component --
--------------------------
procedure Reason_Bad_Component (C : Entity_Id) is
Rec : constant Entity_Id := Scope (C);
Ctyp : constant Entity_Id := Etype (C);
begin
-- If component clause present assume that's the problem
if Present (Component_Clause (C)) then
Error_Msg_Sloc := Sloc (Component_Clause (C));
Error_Msg_N ("\because of Component_Clause#", N);
return;
end if;
-- If pragma Pack clause present, assume that's the problem
if Is_Packed (Rec) then
P := Get_Rep_Pragma (Rec, Name_Pack);
if Present (P) then
Error_Msg_Sloc := Sloc (P);
Error_Msg_N ("\because of pragma Pack#", N);
return;
end if;
end if;
-- See if record has bad alignment clause
if Has_Alignment_Clause (Rec)
and then Known_Alignment (Rec)
and then (Alignment (Rec) * SU) mod Esize (Ctyp) /= 0
then
P := Get_Attribute_Definition_Clause (Rec, Attribute_Alignment);
if Present (P) then
Error_Msg_Sloc := Sloc (P);
Error_Msg_N ("\because of Alignment clause#", N);
end if;
end if;
-- Couldn't find a reason, so return without a message
return;
end Reason_Bad_Component;
-- Start of processing for Validate_Independence
begin
for J in Independence_Checks.First .. Independence_Checks.Last loop
N := Independence_Checks.Table (J).N;
E := Independence_Checks.Table (J).E;
IC := Pragma_Name (N) = Name_Independent_Components;
-- Deal with component case
if Ekind (E) = E_Discriminant or else Ekind (E) = E_Component then
if not OK_Component (E) then
No_Independence;
Reason_Bad_Component (E);
goto Continue;
end if;
end if;
-- Deal with record with Independent_Components
if IC and then Is_Record_Type (E) then
Comp := First_Component_Or_Discriminant (E);
while Present (Comp) loop
if not OK_Component (Comp) then
No_Independence;
Reason_Bad_Component (Comp);
goto Continue;
end if;
Next_Component_Or_Discriminant (Comp);
end loop;
end if;
-- Deal with address clause case
if Is_Object (E) then
Addr := Address_Clause (E);
if Present (Addr) then
No_Independence;
Error_Msg_Sloc := Sloc (Addr);
Error_Msg_N ("\because of Address clause#", N);
goto Continue;
end if;
end if;
-- Deal with independent components for array type
if IC and then Is_Array_Type (E) then
Check_Array_Type (E);
end if;
-- Deal with independent components for array object
if IC and then Is_Object (E) and then Is_Array_Type (Etype (E)) then
Check_Array_Type (Etype (E));
end if;
<<Continue>> null;
end loop;
end Validate_Independence;
-----------------------------------
-- Validate_Unchecked_Conversion --
-----------------------------------
procedure Validate_Unchecked_Conversion
(N : Node_Id;
Act_Unit : Entity_Id)
is
Source : Entity_Id;
Target : Entity_Id;
Vnode : Node_Id;
begin
-- Obtain source and target types. Note that we call Ancestor_Subtype
-- here because the processing for generic instantiation always makes
-- subtypes, and we want the original frozen actual types.
-- If we are dealing with private types, then do the check on their
-- fully declared counterparts if the full declarations have been
-- encountered (they don't have to be visible, but they must exist!)
Source := Ancestor_Subtype (Etype (First_Formal (Act_Unit)));
if Is_Private_Type (Source)
and then Present (Underlying_Type (Source))
then
Source := Underlying_Type (Source);
end if;
Target := Ancestor_Subtype (Etype (Act_Unit));
-- If either type is generic, the instantiation happens within a generic
-- unit, and there is nothing to check. The proper check
-- will happen when the enclosing generic is instantiated.
if Is_Generic_Type (Source) or else Is_Generic_Type (Target) then
return;
end if;
if Is_Private_Type (Target)
and then Present (Underlying_Type (Target))
then
Target := Underlying_Type (Target);
end if;
-- Source may be unconstrained array, but not target
if Is_Array_Type (Target)
and then not Is_Constrained (Target)
then
Error_Msg_N
("unchecked conversion to unconstrained array not allowed", N);
return;
end if;
-- Warn if conversion between two different convention pointers
if Is_Access_Type (Target)
and then Is_Access_Type (Source)
and then Convention (Target) /= Convention (Source)
and then Warn_On_Unchecked_Conversion
then
-- Give warnings for subprogram pointers only on most targets. The
-- exception is VMS, where data pointers can have different lengths
-- depending on the pointer convention.
if Is_Access_Subprogram_Type (Target)
or else Is_Access_Subprogram_Type (Source)
or else OpenVMS_On_Target
then
Error_Msg_N
("?conversion between pointers with different conventions!", N);
end if;
end if;
-- Warn if one of the operands is Ada.Calendar.Time. Do not emit a
-- warning when compiling GNAT-related sources.
if Warn_On_Unchecked_Conversion
and then not In_Predefined_Unit (N)
and then RTU_Loaded (Ada_Calendar)
and then
(Chars (Source) = Name_Time
or else
Chars (Target) = Name_Time)
then
-- If Ada.Calendar is loaded and the name of one of the operands is
-- Time, there is a good chance that this is Ada.Calendar.Time.
declare
Calendar_Time : constant Entity_Id :=
Full_View (RTE (RO_CA_Time));
begin
pragma Assert (Present (Calendar_Time));
if Source = Calendar_Time
or else Target = Calendar_Time
then
Error_Msg_N
("?representation of 'Time values may change between " &
"'G'N'A'T versions", N);
end if;
end;
end if;
-- Make entry in unchecked conversion table for later processing by
-- Validate_Unchecked_Conversions, which will check sizes and alignments
-- (using values set by the back-end where possible). This is only done
-- if the appropriate warning is active.
if Warn_On_Unchecked_Conversion then
Unchecked_Conversions.Append
(New_Val => UC_Entry'
(Eloc => Sloc (N),
Source => Source,
Target => Target));
-- If both sizes are known statically now, then back end annotation
-- is not required to do a proper check but if either size is not
-- known statically, then we need the annotation.
if Known_Static_RM_Size (Source)
and then Known_Static_RM_Size (Target)
then
null;
else
Back_Annotate_Rep_Info := True;
end if;
end if;
-- If unchecked conversion to access type, and access type is declared
-- in the same unit as the unchecked conversion, then set the
-- No_Strict_Aliasing flag (no strict aliasing is implicit in this
-- situation).
if Is_Access_Type (Target) and then
In_Same_Source_Unit (Target, N)
then
Set_No_Strict_Aliasing (Implementation_Base_Type (Target));
end if;
-- Generate N_Validate_Unchecked_Conversion node for back end in
-- case the back end needs to perform special validation checks.
-- Shouldn't this be in Exp_Ch13, since the check only gets done
-- if we have full expansion and the back end is called ???
Vnode :=
Make_Validate_Unchecked_Conversion (Sloc (N));
Set_Source_Type (Vnode, Source);
Set_Target_Type (Vnode, Target);
-- If the unchecked conversion node is in a list, just insert before it.
-- If not we have some strange case, not worth bothering about.
if Is_List_Member (N) then
Insert_After (N, Vnode);
end if;
end Validate_Unchecked_Conversion;
------------------------------------
-- Validate_Unchecked_Conversions --
------------------------------------
procedure Validate_Unchecked_Conversions is
begin
for N in Unchecked_Conversions.First .. Unchecked_Conversions.Last loop
declare
T : UC_Entry renames Unchecked_Conversions.Table (N);
Eloc : constant Source_Ptr := T.Eloc;
Source : constant Entity_Id := T.Source;
Target : constant Entity_Id := T.Target;
Source_Siz : Uint;
Target_Siz : Uint;
begin
-- This validation check, which warns if we have unequal sizes for
-- unchecked conversion, and thus potentially implementation
-- dependent semantics, is one of the few occasions on which we
-- use the official RM size instead of Esize. See description in
-- Einfo "Handling of Type'Size Values" for details.
if Serious_Errors_Detected = 0
and then Known_Static_RM_Size (Source)
and then Known_Static_RM_Size (Target)
-- Don't do the check if warnings off for either type, note the
-- deliberate use of OR here instead of OR ELSE to get the flag
-- Warnings_Off_Used set for both types if appropriate.
and then not (Has_Warnings_Off (Source)
or
Has_Warnings_Off (Target))
then
Source_Siz := RM_Size (Source);
Target_Siz := RM_Size (Target);
if Source_Siz /= Target_Siz then
Error_Msg
("?types for unchecked conversion have different sizes!",
Eloc);
if All_Errors_Mode then
Error_Msg_Name_1 := Chars (Source);
Error_Msg_Uint_1 := Source_Siz;
Error_Msg_Name_2 := Chars (Target);
Error_Msg_Uint_2 := Target_Siz;
Error_Msg ("\size of % is ^, size of % is ^?", Eloc);
Error_Msg_Uint_1 := UI_Abs (Source_Siz - Target_Siz);
if Is_Discrete_Type (Source)
and then Is_Discrete_Type (Target)
then
if Source_Siz > Target_Siz then
Error_Msg
("\?^ high order bits of source will be ignored!",
Eloc);
elsif Is_Unsigned_Type (Source) then
Error_Msg
("\?source will be extended with ^ high order " &
"zero bits?!", Eloc);
else
Error_Msg
("\?source will be extended with ^ high order " &
"sign bits!",
Eloc);
end if;
elsif Source_Siz < Target_Siz then
if Is_Discrete_Type (Target) then
if Bytes_Big_Endian then
Error_Msg
("\?target value will include ^ undefined " &
"low order bits!",
Eloc);
else
Error_Msg
("\?target value will include ^ undefined " &
"high order bits!",
Eloc);
end if;
else
Error_Msg
("\?^ trailing bits of target value will be " &
"undefined!", Eloc);
end if;
else pragma Assert (Source_Siz > Target_Siz);
Error_Msg
("\?^ trailing bits of source will be ignored!",
Eloc);
end if;
end if;
end if;
end if;
-- If both types are access types, we need to check the alignment.
-- If the alignment of both is specified, we can do it here.
if Serious_Errors_Detected = 0
and then Ekind (Source) in Access_Kind
and then Ekind (Target) in Access_Kind
and then Target_Strict_Alignment
and then Present (Designated_Type (Source))
and then Present (Designated_Type (Target))
then
declare
D_Source : constant Entity_Id := Designated_Type (Source);
D_Target : constant Entity_Id := Designated_Type (Target);
begin
if Known_Alignment (D_Source)
and then Known_Alignment (D_Target)
then
declare
Source_Align : constant Uint := Alignment (D_Source);
Target_Align : constant Uint := Alignment (D_Target);
begin
if Source_Align < Target_Align
and then not Is_Tagged_Type (D_Source)
-- Suppress warning if warnings suppressed on either
-- type or either designated type. Note the use of
-- OR here instead of OR ELSE. That is intentional,
-- we would like to set flag Warnings_Off_Used in
-- all types for which warnings are suppressed.
and then not (Has_Warnings_Off (D_Source)
or
Has_Warnings_Off (D_Target)
or
Has_Warnings_Off (Source)
or
Has_Warnings_Off (Target))
then
Error_Msg_Uint_1 := Target_Align;
Error_Msg_Uint_2 := Source_Align;
Error_Msg_Node_1 := D_Target;
Error_Msg_Node_2 := D_Source;
Error_Msg
("?alignment of & (^) is stricter than " &
"alignment of & (^)!", Eloc);
Error_Msg
("\?resulting access value may have invalid " &
"alignment!", Eloc);
end if;
end;
end if;
end;
end if;
end;
end loop;
end Validate_Unchecked_Conversions;
end Sem_Ch13;
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