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------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- L I B . X R E F . A L F A -- -- -- -- B o d y -- -- -- -- Copyright (C) 2011, 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 Alfa; use Alfa; with Einfo; use Einfo; with Nmake; use Nmake; with Put_Alfa; with GNAT.HTable; separate (Lib.Xref) package body Alfa is --------------------- -- Local Constants -- --------------------- -- Table of Alfa_Entities, True for each entity kind used in Alfa Alfa_Entities : constant array (Entity_Kind) of Boolean := (E_Void => False, E_Variable => True, E_Component => False, E_Constant => True, E_Discriminant => False, E_Loop_Parameter => True, E_In_Parameter => True, E_Out_Parameter => True, E_In_Out_Parameter => True, E_Generic_In_Out_Parameter => False, E_Generic_In_Parameter => False, E_Named_Integer => False, E_Named_Real => False, E_Enumeration_Type => False, E_Enumeration_Subtype => False, E_Signed_Integer_Type => False, E_Signed_Integer_Subtype => False, E_Modular_Integer_Type => False, E_Modular_Integer_Subtype => False, E_Ordinary_Fixed_Point_Type => False, E_Ordinary_Fixed_Point_Subtype => False, E_Decimal_Fixed_Point_Type => False, E_Decimal_Fixed_Point_Subtype => False, E_Floating_Point_Type => False, E_Floating_Point_Subtype => False, E_Access_Type => False, E_Access_Subtype => False, E_Access_Attribute_Type => False, E_Allocator_Type => False, E_General_Access_Type => False, E_Access_Subprogram_Type => False, E_Access_Protected_Subprogram_Type => False, E_Anonymous_Access_Subprogram_Type => False, E_Anonymous_Access_Protected_Subprogram_Type => False, E_Anonymous_Access_Type => False, E_Array_Type => False, E_Array_Subtype => False, E_String_Type => False, E_String_Subtype => False, E_String_Literal_Subtype => False, E_Class_Wide_Type => False, E_Class_Wide_Subtype => False, E_Record_Type => False, E_Record_Subtype => False, E_Record_Type_With_Private => False, E_Record_Subtype_With_Private => False, E_Private_Type => False, E_Private_Subtype => False, E_Limited_Private_Type => False, E_Limited_Private_Subtype => False, E_Incomplete_Type => False, E_Incomplete_Subtype => False, E_Task_Type => False, E_Task_Subtype => False, E_Protected_Type => False, E_Protected_Subtype => False, E_Exception_Type => False, E_Subprogram_Type => False, E_Enumeration_Literal => False, E_Function => True, E_Operator => True, E_Procedure => True, E_Entry => False, E_Entry_Family => False, E_Block => False, E_Entry_Index_Parameter => False, E_Exception => False, E_Generic_Function => False, E_Generic_Package => False, E_Generic_Procedure => False, E_Label => False, E_Loop => False, E_Return_Statement => False, E_Package => False, E_Package_Body => False, E_Protected_Object => False, E_Protected_Body => False, E_Task_Body => False, E_Subprogram_Body => False); -- True for each reference type used in Alfa Alfa_References : constant array (Character) of Boolean := ('m' => True, 'r' => True, 's' => True, others => False); type Entity_Hashed_Range is range 0 .. 255; -- Size of hash table headers --------------------- -- Local Variables -- --------------------- package Drefs is new Table.Table ( Table_Component_Type => Xref_Entry, Table_Index_Type => Xref_Entry_Number, Table_Low_Bound => 1, Table_Initial => Alloc.Xrefs_Initial, Table_Increment => Alloc.Xrefs_Increment, Table_Name => "Drefs"); -- Table of cross-references for reads and writes through explicit -- dereferences, that are output as reads/writes to the special variable -- "Heap". These references are added to the regular references when -- computing Alfa cross-references. ----------------------- -- Local Subprograms -- ----------------------- procedure Add_Alfa_File (U : Unit_Number_Type; D : Nat); -- Add file U and all scopes in U to the tables Alfa_File_Table and -- Alfa_Scope_Table. procedure Add_Alfa_Scope (N : Node_Id); -- Add scope N to the table Alfa_Scope_Table procedure Add_Alfa_Xrefs; -- Filter table Xrefs to add all references used in Alfa to the table -- Alfa_Xref_Table. procedure Detect_And_Add_Alfa_Scope (N : Node_Id); -- Call Add_Alfa_Scope on scopes function Entity_Hash (E : Entity_Id) return Entity_Hashed_Range; -- Hash function for hash table procedure Traverse_Declarations_Or_Statements (L : List_Id; Process : Node_Processing; Inside_Stubs : Boolean); procedure Traverse_Handled_Statement_Sequence (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean); procedure Traverse_Package_Body (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean); procedure Traverse_Package_Declaration (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean); procedure Traverse_Subprogram_Body (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean); -- Traverse the corresponding constructs, calling Process on all -- declarations. ------------------- -- Add_Alfa_File -- ------------------- procedure Add_Alfa_File (U : Unit_Number_Type; D : Nat) is From : Scope_Index; S : constant Source_File_Index := Source_Index (U); begin -- Source file could be inexistant as a result of an error, if option -- gnatQ is used. if S = No_Source_File then return; end if; From := Alfa_Scope_Table.Last + 1; Traverse_Compilation_Unit (Cunit (U), Detect_And_Add_Alfa_Scope'Access, Inside_Stubs => False); -- Update scope numbers declare Count : Nat; begin Count := 1; for S in From .. Alfa_Scope_Table.Last loop declare E : Entity_Id renames Alfa_Scope_Table.Table (S).Scope_Entity; begin if Lib.Get_Source_Unit (E) = U then Alfa_Scope_Table.Table (S).Scope_Num := Count; Alfa_Scope_Table.Table (S).File_Num := D; Count := Count + 1; else -- Mark for removal a scope S which is not located in unit -- U, for example for scope inside generics that get -- instantiated. Alfa_Scope_Table.Table (S).Scope_Num := 0; end if; end; end loop; end; declare Snew : Scope_Index; begin Snew := From; for S in From .. Alfa_Scope_Table.Last loop -- Remove those scopes previously marked for removal if Alfa_Scope_Table.Table (S).Scope_Num /= 0 then Alfa_Scope_Table.Table (Snew) := Alfa_Scope_Table.Table (S); Snew := Snew + 1; end if; end loop; Alfa_Scope_Table.Set_Last (Snew - 1); end; -- Make entry for new file in file table Get_Name_String (Reference_Name (S)); Alfa_File_Table.Append ( (File_Name => new String'(Name_Buffer (1 .. Name_Len)), File_Num => D, From_Scope => From, To_Scope => Alfa_Scope_Table.Last)); end Add_Alfa_File; -------------------- -- Add_Alfa_Scope -- -------------------- procedure Add_Alfa_Scope (N : Node_Id) is E : constant Entity_Id := Defining_Entity (N); Loc : constant Source_Ptr := Sloc (E); Typ : Character; begin -- Ignore scopes without a proper location if Sloc (N) = No_Location then return; end if; case Ekind (E) is when E_Function | E_Generic_Function => Typ := 'V'; when E_Procedure | E_Generic_Procedure => Typ := 'U'; when E_Subprogram_Body => declare Spec : Node_Id; begin Spec := Parent (E); if Nkind (Spec) = N_Defining_Program_Unit_Name then Spec := Parent (Spec); end if; if Nkind (Spec) = N_Function_Specification then Typ := 'V'; else pragma Assert (Nkind (Spec) = N_Procedure_Specification); Typ := 'U'; end if; end; when E_Package | E_Package_Body | E_Generic_Package => Typ := 'K'; when E_Void => -- Compilation of prj-attr.adb with -gnatn creates a node with -- entity E_Void for the package defined at a-charac.ads16:13 -- ??? TBD return; when others => raise Program_Error; end case; -- File_Num and Scope_Num are filled later. From_Xref and To_Xref are -- filled even later, but are initialized to represent an empty range. Alfa_Scope_Table.Append ( (Scope_Name => new String'(Unique_Name (E)), File_Num => 0, Scope_Num => 0, Spec_File_Num => 0, Spec_Scope_Num => 0, Line => Nat (Get_Logical_Line_Number (Loc)), Stype => Typ, Col => Nat (Get_Column_Number (Loc)), From_Xref => 1, To_Xref => 0, Scope_Entity => E)); end Add_Alfa_Scope; -------------------- -- Add_Alfa_Xrefs -- -------------------- procedure Add_Alfa_Xrefs is Cur_Scope_Idx : Scope_Index; From_Xref_Idx : Xref_Index; Cur_Entity : Entity_Id; Cur_Entity_Name : String_Ptr; package Scopes is No_Scope : constant Nat := 0; function Get_Scope_Num (N : Entity_Id) return Nat; procedure Set_Scope_Num (N : Entity_Id; Num : Nat); end Scopes; ------------ -- Scopes -- ------------ package body Scopes is type Scope is record Num : Nat; Entity : Entity_Id; end record; package Scopes is new GNAT.HTable.Simple_HTable (Header_Num => Entity_Hashed_Range, Element => Scope, No_Element => (Num => No_Scope, Entity => Empty), Key => Entity_Id, Hash => Entity_Hash, Equal => "="); ------------------- -- Get_Scope_Num -- ------------------- function Get_Scope_Num (N : Entity_Id) return Nat is begin return Scopes.Get (N).Num; end Get_Scope_Num; ------------------- -- Set_Scope_Num -- ------------------- procedure Set_Scope_Num (N : Entity_Id; Num : Nat) is begin Scopes.Set (K => N, E => Scope'(Num => Num, Entity => N)); end Set_Scope_Num; end Scopes; use Scopes; Nrefs : Nat := Xrefs.Last; -- Number of references in table. This value may get reset (reduced) -- when we eliminate duplicate reference entries as well as references -- not suitable for local cross-references. Nrefs_Add : constant Nat := Drefs.Last; Rnums : array (0 .. Nrefs + Nrefs_Add) of Nat; -- This array contains numbers of references in the Xrefs table. This -- list is sorted in output order. The extra 0'th entry is convenient -- for the call to sort. When we sort the table, we move the entries in -- Rnums around, but we do not move the original table entries. function Lt (Op1, Op2 : Natural) return Boolean; -- Comparison function for Sort call procedure Move (From : Natural; To : Natural); -- Move procedure for Sort call package Sorting is new GNAT.Heap_Sort_G (Move, Lt); -------- -- Lt -- -------- function Lt (Op1, Op2 : Natural) return Boolean is T1 : constant Xref_Entry := Xrefs.Table (Rnums (Nat (Op1))); T2 : constant Xref_Entry := Xrefs.Table (Rnums (Nat (Op2))); begin -- First test: if entity is in different unit, sort by unit. Note: -- that we use Ent_Scope_File rather than Eun, as Eun may refer to -- the file where the generic scope is defined, which may differ from -- the file where the enclosing scope is defined. It is the latter -- which matters for a correct order here. if T1.Ent_Scope_File /= T2.Ent_Scope_File then return Dependency_Num (T1.Ent_Scope_File) < Dependency_Num (T2.Ent_Scope_File); -- Second test: within same unit, sort by location of the scope of -- the entity definition. elsif Get_Scope_Num (T1.Key.Ent_Scope) /= Get_Scope_Num (T2.Key.Ent_Scope) then return Get_Scope_Num (T1.Key.Ent_Scope) < Get_Scope_Num (T2.Key.Ent_Scope); -- Third test: within same unit and scope, sort by location of -- entity definition. elsif T1.Def /= T2.Def then return T1.Def < T2.Def; -- Fourth test: if reference is in same unit as entity definition, -- sort first. elsif T1.Key.Lun /= T2.Key.Lun and then T1.Ent_Scope_File = T1.Key.Lun then return True; elsif T1.Key.Lun /= T2.Key.Lun and then T2.Ent_Scope_File = T2.Key.Lun then return False; -- Fifth test: if reference is in same unit and same scope as entity -- definition, sort first. elsif T1.Ent_Scope_File = T1.Key.Lun and then T1.Key.Ref_Scope /= T2.Key.Ref_Scope and then T1.Key.Ent_Scope = T1.Key.Ref_Scope then return True; elsif T1.Ent_Scope_File = T1.Key.Lun and then T1.Key.Ref_Scope /= T2.Key.Ref_Scope and then T2.Key.Ent_Scope = T2.Key.Ref_Scope then return False; -- Sixth test: for same entity, sort by reference location unit elsif T1.Key.Lun /= T2.Key.Lun then return Dependency_Num (T1.Key.Lun) < Dependency_Num (T2.Key.Lun); -- Seventh test: for same entity, sort by reference location scope elsif Get_Scope_Num (T1.Key.Ref_Scope) /= Get_Scope_Num (T2.Key.Ref_Scope) then return Get_Scope_Num (T1.Key.Ref_Scope) < Get_Scope_Num (T2.Key.Ref_Scope); -- Eighth test: order of location within referencing unit elsif T1.Key.Loc /= T2.Key.Loc then return T1.Key.Loc < T2.Key.Loc; -- Finally, for two locations at the same address prefer the one that -- does NOT have the type 'r', so that a modification or extension -- takes preference, when there are more than one reference at the -- same location. As a result, in the case of entities that are -- in-out actuals, the read reference follows the modify reference. else return T2.Key.Typ = 'r'; end if; end Lt; ---------- -- Move -- ---------- procedure Move (From : Natural; To : Natural) is begin Rnums (Nat (To)) := Rnums (Nat (From)); end Move; Heap : Entity_Id; -- Start of processing for Add_Alfa_Xrefs begin for J in Alfa_Scope_Table.First .. Alfa_Scope_Table.Last loop Set_Scope_Num (N => Alfa_Scope_Table.Table (J).Scope_Entity, Num => Alfa_Scope_Table.Table (J).Scope_Num); end loop; -- Set up the pointer vector for the sort for J in 1 .. Nrefs loop Rnums (J) := J; end loop; -- Add dereferences to the set of regular references, by creating a -- special "Heap" variable for these special references. Name_Len := Name_Of_Heap_Variable'Length; Name_Buffer (1 .. Name_Len) := Name_Of_Heap_Variable; Atree.Unlock; Nlists.Unlock; Heap := Make_Defining_Identifier (Standard_Location, Name_Enter); Atree.Lock; Nlists.Lock; Set_Ekind (Heap, E_Variable); Set_Is_Internal (Heap, True); Set_Has_Fully_Qualified_Name (Heap); for J in Drefs.First .. Drefs.Last loop Xrefs.Append (Drefs.Table (J)); -- Set entity at this point with newly created "Heap" variable Xrefs.Table (Xrefs.Last).Key.Ent := Heap; Nrefs := Nrefs + 1; Rnums (Nrefs) := Xrefs.Last; end loop; -- Eliminate entries not appropriate for Alfa. Done prior to sorting -- cross-references, as it discards useless references which do not have -- a proper format for the comparison function (like no location). Eliminate_Before_Sort : declare NR : Nat; function Is_Alfa_Reference (E : Entity_Id; Typ : Character) return Boolean; -- Return whether entity reference E meets Alfa requirements. Typ -- is the reference type. function Is_Alfa_Scope (E : Entity_Id) return Boolean; -- Return whether the entity or reference scope meets requirements -- for being an Alfa scope. function Is_Global_Constant (E : Entity_Id) return Boolean; -- Return True if E is a global constant for which we should ignore -- reads in Alfa. ----------------------- -- Is_Alfa_Reference -- ----------------------- function Is_Alfa_Reference (E : Entity_Id; Typ : Character) return Boolean is begin -- The only references of interest on callable entities are calls. -- On non-callable entities, the only references of interest are -- reads and writes. if Ekind (E) in Overloadable_Kind then return Typ = 's'; -- References to constant objects are not considered in Alfa -- section, as these will be translated as constants in the -- intermediate language for formal verification, and should -- therefore never appear in frame conditions. elsif Is_Constant_Object (E) then return False; -- Objects of Task type or protected type are not Alfa references elsif Present (Etype (E)) and then Ekind (Etype (E)) in Concurrent_Kind then return False; -- In all other cases, result is true for reference/modify cases, -- and false for all other cases. else return Typ = 'r' or else Typ = 'm'; end if; end Is_Alfa_Reference; ------------------- -- Is_Alfa_Scope -- ------------------- function Is_Alfa_Scope (E : Entity_Id) return Boolean is begin return Present (E) and then not Is_Generic_Unit (E) and then Renamed_Entity (E) = Empty and then Get_Scope_Num (E) /= No_Scope; end Is_Alfa_Scope; ------------------------ -- Is_Global_Constant -- ------------------------ function Is_Global_Constant (E : Entity_Id) return Boolean is begin return Ekind (E) = E_Constant and then Ekind_In (Scope (E), E_Package, E_Package_Body); end Is_Global_Constant; -- Start of processing for Eliminate_Before_Sort begin NR := Nrefs; Nrefs := 0; for J in 1 .. NR loop if Alfa_Entities (Ekind (Xrefs.Table (Rnums (J)).Key.Ent)) and then Alfa_References (Xrefs.Table (Rnums (J)).Key.Typ) and then Is_Alfa_Scope (Xrefs.Table (Rnums (J)).Key.Ent_Scope) and then Is_Alfa_Scope (Xrefs.Table (Rnums (J)).Key.Ref_Scope) and then not Is_Global_Constant (Xrefs.Table (Rnums (J)).Key.Ent) and then Is_Alfa_Reference (Xrefs.Table (Rnums (J)).Key.Ent, Xrefs.Table (Rnums (J)).Key.Typ) then Nrefs := Nrefs + 1; Rnums (Nrefs) := Rnums (J); end if; end loop; end Eliminate_Before_Sort; -- Sort the references Sorting.Sort (Integer (Nrefs)); Eliminate_After_Sort : declare NR : Nat; Crloc : Source_Ptr; -- Current reference location Prevt : Character; -- reference kind of previous reference begin -- Eliminate duplicate entries -- We need this test for NR because if we force ALI file generation -- in case of errors detected, it may be the case that Nrefs is 0, so -- we should not reset it here if Nrefs >= 2 then NR := Nrefs; Nrefs := 1; for J in 2 .. NR loop if Xrefs.Table (Rnums (J)) /= Xrefs.Table (Rnums (Nrefs)) then Nrefs := Nrefs + 1; Rnums (Nrefs) := Rnums (J); end if; end loop; end if; -- Eliminate the reference if it is at the same location as the -- previous one, unless it is a read-reference indicating that the -- entity is an in-out actual in a call. NR := Nrefs; Nrefs := 0; Crloc := No_Location; Prevt := 'm'; for J in 1 .. NR loop if Xrefs.Table (Rnums (J)).Key.Loc /= Crloc or else (Prevt = 'm' and then Xrefs.Table (Rnums (J)).Key.Typ = 'r') then Crloc := Xrefs.Table (Rnums (J)).Key.Loc; Prevt := Xrefs.Table (Rnums (J)).Key.Typ; Nrefs := Nrefs + 1; Rnums (Nrefs) := Rnums (J); end if; end loop; end Eliminate_After_Sort; -- Initialize loop Cur_Scope_Idx := 1; From_Xref_Idx := 1; Cur_Entity := Empty; if Alfa_Scope_Table.Last = 0 then return; end if; -- Loop to output references for Refno in 1 .. Nrefs loop Add_One_Xref : declare ----------------------- -- Local Subprograms -- ----------------------- function Cur_Scope return Node_Id; -- Return scope entity which corresponds to index Cur_Scope_Idx in -- table Alfa_Scope_Table. function Get_Entity_Type (E : Entity_Id) return Character; -- Return a character representing the type of entity function Is_Future_Scope_Entity (E : Entity_Id) return Boolean; -- Check whether entity E is in Alfa_Scope_Table at index -- Cur_Scope_Idx or higher. function Is_Past_Scope_Entity (E : Entity_Id) return Boolean; -- Check whether entity E is in Alfa_Scope_Table at index strictly -- lower than Cur_Scope_Idx. --------------- -- Cur_Scope -- --------------- function Cur_Scope return Node_Id is begin return Alfa_Scope_Table.Table (Cur_Scope_Idx).Scope_Entity; end Cur_Scope; --------------------- -- Get_Entity_Type -- --------------------- function Get_Entity_Type (E : Entity_Id) return Character is C : Character; begin case Ekind (E) is when E_Out_Parameter => C := '<'; when E_In_Out_Parameter => C := '='; when E_In_Parameter => C := '>'; when others => C := '*'; end case; return C; end Get_Entity_Type; ---------------------------- -- Is_Future_Scope_Entity -- ---------------------------- function Is_Future_Scope_Entity (E : Entity_Id) return Boolean is begin for J in Cur_Scope_Idx .. Alfa_Scope_Table.Last loop if E = Alfa_Scope_Table.Table (J).Scope_Entity then return True; end if; end loop; -- If this assertion fails, this means that the scope which we -- are looking for has been treated already, which reveals a -- problem in the order of cross-references. pragma Assert (not Is_Past_Scope_Entity (E)); return False; end Is_Future_Scope_Entity; -------------------------- -- Is_Past_Scope_Entity -- -------------------------- function Is_Past_Scope_Entity (E : Entity_Id) return Boolean is begin for J in Alfa_Scope_Table.First .. Cur_Scope_Idx - 1 loop if E = Alfa_Scope_Table.Table (J).Scope_Entity then return True; end if; end loop; return False; end Is_Past_Scope_Entity; --------------------- -- Local Variables -- --------------------- XE : Xref_Entry renames Xrefs.Table (Rnums (Refno)); begin -- If this assertion fails, the scope which we are looking for is -- not in Alfa scope table, which reveals either a problem in the -- construction of the scope table, or an erroneous scope for the -- current cross-reference. pragma Assert (Is_Future_Scope_Entity (XE.Key.Ent_Scope)); -- Update the range of cross references to which the current scope -- refers to. This may be the empty range only for the first scope -- considered. if XE.Key.Ent_Scope /= Cur_Scope then Alfa_Scope_Table.Table (Cur_Scope_Idx).From_Xref := From_Xref_Idx; Alfa_Scope_Table.Table (Cur_Scope_Idx).To_Xref := Alfa_Xref_Table.Last; From_Xref_Idx := Alfa_Xref_Table.Last + 1; end if; while XE.Key.Ent_Scope /= Cur_Scope loop Cur_Scope_Idx := Cur_Scope_Idx + 1; pragma Assert (Cur_Scope_Idx <= Alfa_Scope_Table.Last); end loop; if XE.Key.Ent /= Cur_Entity then Cur_Entity_Name := new String'(Unique_Name (XE.Key.Ent)); end if; if XE.Key.Ent = Heap then Alfa_Xref_Table.Append ( (Entity_Name => Cur_Entity_Name, Entity_Line => 0, Etype => Get_Entity_Type (XE.Key.Ent), Entity_Col => 0, File_Num => Dependency_Num (XE.Key.Lun), Scope_Num => Get_Scope_Num (XE.Key.Ref_Scope), Line => Int (Get_Logical_Line_Number (XE.Key.Loc)), Rtype => XE.Key.Typ, Col => Int (Get_Column_Number (XE.Key.Loc)))); else Alfa_Xref_Table.Append ( (Entity_Name => Cur_Entity_Name, Entity_Line => Int (Get_Logical_Line_Number (XE.Def)), Etype => Get_Entity_Type (XE.Key.Ent), Entity_Col => Int (Get_Column_Number (XE.Def)), File_Num => Dependency_Num (XE.Key.Lun), Scope_Num => Get_Scope_Num (XE.Key.Ref_Scope), Line => Int (Get_Logical_Line_Number (XE.Key.Loc)), Rtype => XE.Key.Typ, Col => Int (Get_Column_Number (XE.Key.Loc)))); end if; end Add_One_Xref; end loop; -- Update the range of cross references to which the scope refers to Alfa_Scope_Table.Table (Cur_Scope_Idx).From_Xref := From_Xref_Idx; Alfa_Scope_Table.Table (Cur_Scope_Idx).To_Xref := Alfa_Xref_Table.Last; end Add_Alfa_Xrefs; ------------------ -- Collect_Alfa -- ------------------ procedure Collect_Alfa (Sdep_Table : Unit_Ref_Table; Num_Sdep : Nat) is begin -- Cross-references should have been computed first pragma Assert (Xrefs.Last /= 0); Initialize_Alfa_Tables; -- Generate file and scope Alfa information for D in 1 .. Num_Sdep loop Add_Alfa_File (U => Sdep_Table (D), D => D); end loop; -- Fill in the spec information when relevant declare package Entity_Hash_Table is new GNAT.HTable.Simple_HTable (Header_Num => Entity_Hashed_Range, Element => Scope_Index, No_Element => 0, Key => Entity_Id, Hash => Entity_Hash, Equal => "="); begin -- Fill in the hash-table for S in Alfa_Scope_Table.First .. Alfa_Scope_Table.Last loop declare Srec : Alfa_Scope_Record renames Alfa_Scope_Table.Table (S); begin Entity_Hash_Table.Set (Srec.Scope_Entity, S); end; end loop; -- Use the hash-table to locate spec entities for S in Alfa_Scope_Table.First .. Alfa_Scope_Table.Last loop declare Srec : Alfa_Scope_Record renames Alfa_Scope_Table.Table (S); Spec_Entity : constant Entity_Id := Unique_Entity (Srec.Scope_Entity); Spec_Scope : constant Scope_Index := Entity_Hash_Table.Get (Spec_Entity); begin -- Spec of generic may be missing, in which case Spec_Scope is -- zero. if Spec_Entity /= Srec.Scope_Entity and then Spec_Scope /= 0 then Srec.Spec_File_Num := Alfa_Scope_Table.Table (Spec_Scope).File_Num; Srec.Spec_Scope_Num := Alfa_Scope_Table.Table (Spec_Scope).Scope_Num; end if; end; end loop; end; -- Generate cross reference Alfa information Add_Alfa_Xrefs; end Collect_Alfa; ------------------------------- -- Detect_And_Add_Alfa_Scope -- ------------------------------- procedure Detect_And_Add_Alfa_Scope (N : Node_Id) is begin if Nkind_In (N, N_Subprogram_Declaration, N_Subprogram_Body, N_Subprogram_Body_Stub, N_Package_Declaration, N_Package_Body) then Add_Alfa_Scope (N); end if; end Detect_And_Add_Alfa_Scope; ------------------------------------- -- Enclosing_Subprogram_Or_Package -- ------------------------------------- function Enclosing_Subprogram_Or_Package (N : Node_Id) return Entity_Id is Result : Entity_Id; begin -- If N is the defining identifier for a subprogram, then return the -- enclosing subprogram or package, not this subprogram. if Nkind_In (N, N_Defining_Identifier, N_Defining_Operator_Symbol) and then Nkind (Parent (N)) in N_Subprogram_Specification then Result := Parent (Parent (Parent (N))); else Result := N; end if; loop exit when No (Result); case Nkind (Result) is when N_Package_Specification => Result := Defining_Unit_Name (Result); exit; when N_Package_Body => Result := Defining_Unit_Name (Result); exit; when N_Subprogram_Specification => Result := Defining_Unit_Name (Result); exit; when N_Subprogram_Declaration => Result := Defining_Unit_Name (Specification (Result)); exit; when N_Subprogram_Body => Result := Defining_Unit_Name (Specification (Result)); exit; -- The enclosing subprogram for a pre- or postconditions should be -- the subprogram to which the pragma is attached. This is not -- always the case in the AST, as the pragma may be declared after -- the declaration of the subprogram. Return Empty in this case. when N_Pragma => if Get_Pragma_Id (Result) = Pragma_Precondition or else Get_Pragma_Id (Result) = Pragma_Postcondition then return Empty; else Result := Parent (Result); end if; when others => Result := Parent (Result); end case; end loop; if Nkind (Result) = N_Defining_Program_Unit_Name then Result := Defining_Identifier (Result); end if; -- Do no return a scope without a proper location if Present (Result) and then Sloc (Result) = No_Location then return Empty; end if; return Result; end Enclosing_Subprogram_Or_Package; ----------------- -- Entity_Hash -- ----------------- function Entity_Hash (E : Entity_Id) return Entity_Hashed_Range is begin return Entity_Hashed_Range (E mod (Entity_Id (Entity_Hashed_Range'Last) + 1)); end Entity_Hash; -------------------------- -- Generate_Dereference -- -------------------------- procedure Generate_Dereference (N : Node_Id; Typ : Character := 'r') is Indx : Nat; Ref : Source_Ptr; Ref_Scope : Entity_Id; begin Ref := Original_Location (Sloc (N)); if Ref > No_Location then Drefs.Increment_Last; Indx := Drefs.Last; Ref_Scope := Enclosing_Subprogram_Or_Package (N); -- Entity is filled later on with the special "Heap" variable Drefs.Table (Indx).Key.Ent := Empty; Drefs.Table (Indx).Def := No_Location; Drefs.Table (Indx).Key.Loc := Ref; Drefs.Table (Indx).Key.Typ := Typ; -- It is as if the special "Heap" was defined in every scope where it -- is referenced. Drefs.Table (Indx).Key.Eun := Get_Source_Unit (Ref); Drefs.Table (Indx).Key.Lun := Get_Source_Unit (Ref); Drefs.Table (Indx).Key.Ref_Scope := Ref_Scope; Drefs.Table (Indx).Key.Ent_Scope := Ref_Scope; Drefs.Table (Indx).Ent_Scope_File := Get_Source_Unit (Ref_Scope); end if; end Generate_Dereference; ------------------------------------ -- Traverse_All_Compilation_Units -- ------------------------------------ procedure Traverse_All_Compilation_Units (Process : Node_Processing) is begin for U in Units.First .. Last_Unit loop Traverse_Compilation_Unit (Cunit (U), Process, Inside_Stubs => False); end loop; end Traverse_All_Compilation_Units; ------------------------------- -- Traverse_Compilation_Unit -- ------------------------------- procedure Traverse_Compilation_Unit (CU : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean) is Lu : Node_Id; begin -- Get Unit (checking case of subunit) Lu := Unit (CU); if Nkind (Lu) = N_Subunit then Lu := Proper_Body (Lu); end if; -- Call Process on all declarations if Nkind (Lu) in N_Declaration or else Nkind (Lu) in N_Later_Decl_Item then Process (Lu); end if; -- Traverse the unit if Nkind (Lu) = N_Subprogram_Body then Traverse_Subprogram_Body (Lu, Process, Inside_Stubs); elsif Nkind (Lu) = N_Subprogram_Declaration then null; elsif Nkind (Lu) = N_Package_Declaration then Traverse_Package_Declaration (Lu, Process, Inside_Stubs); elsif Nkind (Lu) = N_Package_Body then Traverse_Package_Body (Lu, Process, Inside_Stubs); -- ??? TBD elsif Nkind (Lu) = N_Generic_Package_Declaration then null; -- ??? TBD elsif Nkind (Lu) in N_Generic_Instantiation then null; -- All other cases of compilation units (e.g. renamings), are not -- declarations. else null; end if; end Traverse_Compilation_Unit; ----------------------------------------- -- Traverse_Declarations_Or_Statements -- ----------------------------------------- procedure Traverse_Declarations_Or_Statements (L : List_Id; Process : Node_Processing; Inside_Stubs : Boolean) is N : Node_Id; begin -- Loop through statements or declarations N := First (L); while Present (N) loop -- Call Process on all declarations if Nkind (N) in N_Declaration or else Nkind (N) in N_Later_Decl_Item then Process (N); end if; case Nkind (N) is -- Package declaration when N_Package_Declaration => Traverse_Package_Declaration (N, Process, Inside_Stubs); -- Generic package declaration ??? TBD when N_Generic_Package_Declaration => null; -- Package body when N_Package_Body => if Ekind (Defining_Entity (N)) /= E_Generic_Package then Traverse_Package_Body (N, Process, Inside_Stubs); end if; when N_Package_Body_Stub => if Present (Library_Unit (N)) then declare Body_N : constant Node_Id := Get_Body_From_Stub (N); begin if Inside_Stubs and then Ekind (Defining_Entity (Body_N)) /= E_Generic_Package then Traverse_Package_Body (Body_N, Process, Inside_Stubs); end if; end; end if; -- Subprogram declaration when N_Subprogram_Declaration => null; -- Generic subprogram declaration ??? TBD when N_Generic_Subprogram_Declaration => null; -- Subprogram body when N_Subprogram_Body => if not Is_Generic_Subprogram (Defining_Entity (N)) then Traverse_Subprogram_Body (N, Process, Inside_Stubs); end if; when N_Subprogram_Body_Stub => if Present (Library_Unit (N)) then declare Body_N : constant Node_Id := Get_Body_From_Stub (N); begin if Inside_Stubs and then not Is_Generic_Subprogram (Defining_Entity (Body_N)) then Traverse_Subprogram_Body (Body_N, Process, Inside_Stubs); end if; end; end if; -- Block statement when N_Block_Statement => Traverse_Declarations_Or_Statements (Declarations (N), Process, Inside_Stubs); Traverse_Handled_Statement_Sequence (Handled_Statement_Sequence (N), Process, Inside_Stubs); when N_If_Statement => -- Traverse the statements in the THEN part Traverse_Declarations_Or_Statements (Then_Statements (N), Process, Inside_Stubs); -- Loop through ELSIF parts if present if Present (Elsif_Parts (N)) then declare Elif : Node_Id := First (Elsif_Parts (N)); begin while Present (Elif) loop Traverse_Declarations_Or_Statements (Then_Statements (Elif), Process, Inside_Stubs); Next (Elif); end loop; end; end if; -- Finally traverse the ELSE statements if present Traverse_Declarations_Or_Statements (Else_Statements (N), Process, Inside_Stubs); -- Case statement when N_Case_Statement => -- Process case branches declare Alt : Node_Id; begin Alt := First (Alternatives (N)); while Present (Alt) loop Traverse_Declarations_Or_Statements (Statements (Alt), Process, Inside_Stubs); Next (Alt); end loop; end; -- Extended return statement when N_Extended_Return_Statement => Traverse_Handled_Statement_Sequence (Handled_Statement_Sequence (N), Process, Inside_Stubs); -- Loop when N_Loop_Statement => Traverse_Declarations_Or_Statements (Statements (N), Process, Inside_Stubs); when others => null; end case; Next (N); end loop; end Traverse_Declarations_Or_Statements; ----------------------------------------- -- Traverse_Handled_Statement_Sequence -- ----------------------------------------- procedure Traverse_Handled_Statement_Sequence (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean) is Handler : Node_Id; begin if Present (N) then Traverse_Declarations_Or_Statements (Statements (N), Process, Inside_Stubs); if Present (Exception_Handlers (N)) then Handler := First (Exception_Handlers (N)); while Present (Handler) loop Traverse_Declarations_Or_Statements (Statements (Handler), Process, Inside_Stubs); Next (Handler); end loop; end if; end if; end Traverse_Handled_Statement_Sequence; --------------------------- -- Traverse_Package_Body -- --------------------------- procedure Traverse_Package_Body (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean) is begin Traverse_Declarations_Or_Statements (Declarations (N), Process, Inside_Stubs); Traverse_Handled_Statement_Sequence (Handled_Statement_Sequence (N), Process, Inside_Stubs); end Traverse_Package_Body; ---------------------------------- -- Traverse_Package_Declaration -- ---------------------------------- procedure Traverse_Package_Declaration (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean) is Spec : constant Node_Id := Specification (N); begin Traverse_Declarations_Or_Statements (Visible_Declarations (Spec), Process, Inside_Stubs); Traverse_Declarations_Or_Statements (Private_Declarations (Spec), Process, Inside_Stubs); end Traverse_Package_Declaration; ------------------------------ -- Traverse_Subprogram_Body -- ------------------------------ procedure Traverse_Subprogram_Body (N : Node_Id; Process : Node_Processing; Inside_Stubs : Boolean) is begin Traverse_Declarations_Or_Statements (Declarations (N), Process, Inside_Stubs); Traverse_Handled_Statement_Sequence (Handled_Statement_Sequence (N), Process, Inside_Stubs); end Traverse_Subprogram_Body; end Alfa;
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