1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1992-2010, Free Software Foundation, Inc. --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
24 ------------------------------------------------------------------------------
26 with Binderr
; use Binderr
;
27 with Butil
; use Butil
;
28 with Debug
; use Debug
;
29 with Fname
; use Fname
;
30 with Namet
; use Namet
;
33 with Output
; use Output
;
34 with Targparm
; use Targparm
;
36 with System
.Case_Util
; use System
.Case_Util
;
40 -- The following data structures are used to represent the graph that is
41 -- used to determine the elaboration order (using a topological sort).
43 -- The following structures are used to record successors. If A is a
44 -- successor of B in this table, it means that A must be elaborated
45 -- before B is elaborated.
47 type Successor_Id
is new Nat
;
48 -- Identification of single successor entry
50 No_Successor
: constant Successor_Id
:= 0;
51 -- Used to indicate end of list of successors
53 type Elab_All_Id
is new Nat
;
54 -- Identification of Elab_All entry link
56 No_Elab_All_Link
: constant Elab_All_Id
:= 0;
57 -- Used to indicate end of list
59 -- Succ_Reason indicates the reason for a particular elaboration link
63 -- After directly with's Before, so the spec of Before must be
64 -- elaborated before After is elaborated.
67 -- After directly mentions Before in a pragma Elaborate, so the
68 -- body of Before must be elaborate before After is elaborated.
71 -- After either mentions Before directly in a pragma Elaborate_All,
72 -- or mentions a third unit, X, which itself requires that Before be
73 -- elaborated before unit X is elaborated. The Elab_All_Link list
74 -- traces the dependencies in the latter case.
77 -- This is just like Elab_All, except that the elaborate all was not
78 -- explicitly present in the source, but rather was created by the
79 -- front end, which decided that it was "desirable".
82 -- This is just like Elab, except that the elaborate was not
83 -- explicitly present in the source, but rather was created by the
84 -- front end, which decided that it was "desirable".
87 -- After is a body, and Before is the corresponding spec
89 -- Successor_Link contains the information for one link
91 type Successor_Link
is record
99 -- Next successor on this list
101 Reason
: Succ_Reason
;
102 -- Reason for this link
105 -- Set True if this link is needed for the special Elaborate_Body
106 -- processing described below.
108 Reason_Unit
: Unit_Id
;
109 -- For Reason = Elab, or Elab_All or Elab_Desirable, records the unit
110 -- containing the pragma leading to the link.
112 Elab_All_Link
: Elab_All_Id
;
113 -- If Reason = Elab_All or Elab_Desirable, then this points to the
114 -- first elment in a list of Elab_All entries that record the with
115 -- chain leading resulting in this particular dependency.
119 -- Note on handling of Elaborate_Body. Basically, if we have a pragma
120 -- Elaborate_Body in a unit, it means that the spec and body have to
121 -- be handled as a single entity from the point of view of determining
122 -- an elaboration order. What we do is to essentially remove the body
123 -- from consideration completely, and transfer all its links (other
124 -- than the spec link) to the spec. Then when then the spec gets chosen,
125 -- we choose the body right afterwards. We mark the links that get moved
126 -- from the body to the spec by setting their Elab_Body flag True, so
127 -- that we can understand what is going on!
129 Succ_First
: constant := 1;
131 package Succ
is new Table
.Table
(
132 Table_Component_Type
=> Successor_Link
,
133 Table_Index_Type
=> Successor_Id
,
134 Table_Low_Bound
=> Succ_First
,
135 Table_Initial
=> 500,
136 Table_Increment
=> 200,
137 Table_Name
=> "Succ");
139 -- For the case of Elaborate_All, the following table is used to record
140 -- chains of with relationships that lead to the Elab_All link. These
141 -- are used solely for diagnostic purposes
143 type Elab_All_Entry
is record
144 Needed_By
: Unit_Name_Type
;
145 -- Name of unit from which referencing unit was with'ed or otherwise
146 -- needed as a result of Elaborate_All or Elaborate_Desirable.
148 Next_Elab
: Elab_All_Id
;
149 -- Link to next entry on chain (No_Elab_All_Link marks end of list)
152 package Elab_All_Entries
is new Table
.Table
(
153 Table_Component_Type
=> Elab_All_Entry
,
154 Table_Index_Type
=> Elab_All_Id
,
155 Table_Low_Bound
=> 1,
156 Table_Initial
=> 2000,
157 Table_Increment
=> 200,
158 Table_Name
=> "Elab_All_Entries");
160 -- A Unit_Node record is built for each active unit
162 type Unit_Node_Record
is record
164 Successors
: Successor_Id
;
165 -- Pointer to list of links for successor nodes
168 -- Number of predecessors for this unit. Normally non-negative, but
169 -- can go negative in the case of units chosen by the diagnose error
170 -- procedure (when cycles are being removed from the graph).
173 -- Forward pointer for list of units with no predecessors
176 -- Position in elaboration order (zero = not placed yet)
179 -- Used in computing transitive closure for elaborate all and
180 -- also in locating cycles and paths in the diagnose routines.
182 Elab_Position
: Natural;
183 -- Initialized to zero. Set non-zero when a unit is chosen and
184 -- placed in the elaboration order. The value represents the
185 -- ordinal position in the elaboration order.
189 package UNR
is new Table
.Table
(
190 Table_Component_Type
=> Unit_Node_Record
,
191 Table_Index_Type
=> Unit_Id
,
192 Table_Low_Bound
=> First_Unit_Entry
,
193 Table_Initial
=> 500,
194 Table_Increment
=> 200,
195 Table_Name
=> "UNR");
198 -- Head of list of items with no predecessors
201 -- Number of entries not yet dealt with
204 -- Current unit, set by Gather_Dependencies, and picked up in Build_Link
205 -- to set the Reason_Unit field of the created dependency link.
207 Num_Chosen
: Natural := 0;
208 -- Number of units chosen in the elaboration order so far
210 -----------------------
211 -- Local Subprograms --
212 -----------------------
214 function Better_Choice
(U1
, U2
: Unit_Id
) return Boolean;
215 -- U1 and U2 are both permitted candidates for selection as the next unit
216 -- to be elaborated. This function determines whether U1 is a better choice
217 -- than U2, i.e. should be elaborated in preference to U2, based on a set
218 -- of heuristics that establish a friendly and predictable order (see body
219 -- for details). The result is True if U1 is a better choice than U2, and
220 -- False if it is a worse choice, or there is no preference between them.
226 Ea_Id
: Elab_All_Id
:= No_Elab_All_Link
);
227 -- Establish a successor link, Before must be elaborated before After, and
228 -- the reason for the link is R. Ea_Id is the contents to be placed in the
229 -- Elab_All_Link of the entry.
231 procedure Choose
(Chosen
: Unit_Id
);
232 -- Chosen is the next entry chosen in the elaboration order. This procedure
233 -- updates all data structures appropriately.
235 function Corresponding_Body
(U
: Unit_Id
) return Unit_Id
;
236 pragma Inline
(Corresponding_Body
);
237 -- Given a unit which is a spec for which there is a separate body, return
238 -- the unit id of the body. It is an error to call this routine with a unit
239 -- that is not a spec, or which does not have a separate body.
241 function Corresponding_Spec
(U
: Unit_Id
) return Unit_Id
;
242 pragma Inline
(Corresponding_Spec
);
243 -- Given a unit which is a body for which there is a separate spec, return
244 -- the unit id of the spec. It is an error to call this routine with a unit
245 -- that is not a body, or which does not have a separate spec.
247 procedure Diagnose_Elaboration_Problem
;
248 -- Called when no elaboration order can be found. Outputs an appropriate
249 -- diagnosis of the problem, and then abandons the bind.
251 procedure Elab_All_Links
254 Reason
: Succ_Reason
;
256 -- Used to compute the transitive closure of elaboration links for an
257 -- Elaborate_All pragma (Reason = Elab_All) or for an indication of
258 -- Elaborate_All_Desirable (Reason = Elab_All_Desirable). Unit After has
259 -- a pragma Elaborate_All or the front end has determined that a reference
260 -- probably requires Elaborate_All is required, and unit Before must be
261 -- previously elaborated. First a link is built making sure that unit
262 -- Before is elaborated before After, then a recursive call ensures that
263 -- we also build links for any units needed by Before (i.e. these units
264 -- must/should also be elaborated before After). Link is used to build
265 -- a chain of Elab_All_Entries to explain the reason for a link. The
266 -- value passed is the chain so far.
268 procedure Elab_Error_Msg
(S
: Successor_Id
);
269 -- Given a successor link, outputs an error message of the form
270 -- "$ must be elaborated before $ ..." where ... is the reason.
272 procedure Gather_Dependencies
;
273 -- Compute dependencies, building the Succ and UNR tables
275 function Is_Body_Unit
(U
: Unit_Id
) return Boolean;
276 pragma Inline
(Is_Body_Unit
);
277 -- Determines if given unit is a body
279 function Is_Pure_Or_Preelab_Unit
(U
: Unit_Id
) return Boolean;
280 -- Returns True if corresponding unit is Pure or Preelaborate. Includes
281 -- dealing with testing flags on spec if it is given a body.
283 function Is_Waiting_Body
(U
: Unit_Id
) return Boolean;
284 pragma Inline
(Is_Waiting_Body
);
285 -- Determines if U is a waiting body, defined as a body which has
286 -- not been elaborated, but whose spec has been elaborated.
288 function Make_Elab_Entry
289 (Unam
: Unit_Name_Type
;
290 Link
: Elab_All_Id
) return Elab_All_Id
;
291 -- Make an Elab_All_Entries table entry with the given Unam and Link
293 function Pessimistic_Better_Choice
(U1
, U2
: Unit_Id
) return Boolean;
294 -- This is like Better_Choice, and has the same interface, but returns
295 -- true if U1 is a worse choice than U2 in the sense of the -p (pessimistic
296 -- elaboration order) switch. We still have to obey Ada rules, so it is
297 -- not quite the direct inverse of Better_Choice.
299 function Unit_Id_Of
(Uname
: Unit_Name_Type
) return Unit_Id
;
300 -- This function uses the Info field set in the names table to obtain
301 -- the unit Id of a unit, given its name id value.
303 procedure Write_Dependencies
;
304 -- Write out dependencies (called only if appropriate option is set)
306 procedure Write_Elab_All_Chain
(S
: Successor_Id
);
307 -- If the reason for the link S is Elaborate_All or Elaborate_Desirable,
308 -- then this routine will output the "needed by" explanation chain.
314 function Better_Choice
(U1
, U2
: Unit_Id
) return Boolean is
315 UT1
: Unit_Record
renames Units
.Table
(U1
);
316 UT2
: Unit_Record
renames Units
.Table
(U2
);
320 Write_Str
("Better_Choice (");
321 Write_Unit_Name
(UT1
.Uname
);
323 Write_Unit_Name
(UT2
.Uname
);
327 -- Note: the checks here are applied in sequence, and the ordering is
328 -- significant (i.e. the more important criteria are applied first).
330 -- Prefer a waiting body to one that is not a waiting body
332 if Is_Waiting_Body
(U1
) and then not Is_Waiting_Body
(U2
) then
334 Write_Line
(" True: u1 is waiting body, u2 is not");
339 elsif Is_Waiting_Body
(U2
) and then not Is_Waiting_Body
(U1
) then
341 Write_Line
(" False: u2 is waiting body, u1 is not");
346 -- Prefer a predefined unit to a non-predefined unit
348 elsif UT1
.Predefined
and then not UT2
.Predefined
then
350 Write_Line
(" True: u1 is predefined, u2 is not");
355 elsif UT2
.Predefined
and then not UT1
.Predefined
then
357 Write_Line
(" False: u2 is predefined, u1 is not");
362 -- Prefer an internal unit to a non-internal unit
364 elsif UT1
.Internal
and then not UT2
.Internal
then
366 Write_Line
(" True: u1 is internal, u2 is not");
370 elsif UT2
.Internal
and then not UT1
.Internal
then
372 Write_Line
(" False: u2 is internal, u1 is not");
377 -- Prefer a pure or preelaborable unit to one that is not
379 elsif Is_Pure_Or_Preelab_Unit
(U1
)
381 Is_Pure_Or_Preelab_Unit
(U2
)
384 Write_Line
(" True: u1 is pure/preelab, u2 is not");
389 elsif Is_Pure_Or_Preelab_Unit
(U2
)
391 Is_Pure_Or_Preelab_Unit
(U1
)
394 Write_Line
(" False: u2 is pure/preelab, u1 is not");
399 -- Prefer a body to a spec
401 elsif Is_Body_Unit
(U1
) and then not Is_Body_Unit
(U2
) then
403 Write_Line
(" True: u1 is body, u2 is not");
408 elsif Is_Body_Unit
(U2
) and then not Is_Body_Unit
(U1
) then
410 Write_Line
(" False: u2 is body, u1 is not");
415 -- If both are waiting bodies, then prefer the one whose spec is
416 -- more recently elaborated. Consider the following:
422 -- The normal waiting body preference would have placed the body of
423 -- A before the spec of B if it could. Since it could not, there it
424 -- must be the case that A depends on B. It is therefore a good idea
425 -- to put the body of B first.
427 elsif Is_Waiting_Body
(U1
) and then Is_Waiting_Body
(U2
) then
429 Result
: constant Boolean :=
430 UNR
.Table
(Corresponding_Spec
(U1
)).Elab_Position
>
431 UNR
.Table
(Corresponding_Spec
(U2
)).Elab_Position
;
435 Write_Line
(" True: based on waiting body elab positions");
437 Write_Line
(" False: based on waiting body elab positions");
445 -- Remaining choice rules are disabled by Debug flag -do
447 if not Debug_Flag_O
then
449 -- The following deal with the case of specs which have been marked
450 -- as Elaborate_Body_Desirable. We generally want to delay these
451 -- specs as long as possible, so that the bodies have a better chance
452 -- of being elaborated closer to the specs.
454 -- If we have two units, one of which is a spec for which this flag
455 -- is set, and the other is not, we prefer to delay the spec for
456 -- which the flag is set.
458 if not UT1
.Elaborate_Body_Desirable
459 and then UT2
.Elaborate_Body_Desirable
462 Write_Line
(" True: u1 is elab body desirable, u2 is not");
467 elsif not UT2
.Elaborate_Body_Desirable
468 and then UT1
.Elaborate_Body_Desirable
471 Write_Line
(" False: u1 is elab body desirable, u2 is not");
476 -- If we have two specs that are both marked as Elaborate_Body
477 -- desirable, we prefer the one whose body is nearer to being able
478 -- to be elaborated, based on the Num_Pred count. This helps to
479 -- ensure bodies are as close to specs as possible.
481 elsif UT1
.Elaborate_Body_Desirable
482 and then UT2
.Elaborate_Body_Desirable
485 Result
: constant Boolean :=
486 UNR
.Table
(Corresponding_Body
(U1
)).Num_Pred
<
487 UNR
.Table
(Corresponding_Body
(U2
)).Num_Pred
;
491 Write_Line
(" True based on Num_Pred compare");
493 Write_Line
(" False based on Num_Pred compare");
502 -- If we fall through, it means that no preference rule applies, so we
503 -- use alphabetical order to at least give a deterministic result.
506 Write_Line
(" choose on alpha order");
509 return Uname_Less
(UT1
.Uname
, UT2
.Uname
);
520 Ea_Id
: Elab_All_Id
:= No_Elab_All_Link
)
526 Succ
.Table
(Succ
.Last
).Before
:= Before
;
527 Succ
.Table
(Succ
.Last
).Next
:= UNR
.Table
(Before
).Successors
;
528 UNR
.Table
(Before
).Successors
:= Succ
.Last
;
529 Succ
.Table
(Succ
.Last
).Reason
:= R
;
530 Succ
.Table
(Succ
.Last
).Reason_Unit
:= Cur_Unit
;
531 Succ
.Table
(Succ
.Last
).Elab_All_Link
:= Ea_Id
;
533 -- Deal with special Elab_Body case. If the After of this link is
534 -- a body whose spec has Elaborate_All set, and this is not the link
535 -- directly from the body to the spec, then we make the After of the
536 -- link reference its spec instead, marking the link appropriately.
538 if Units
.Table
(After
).Utype
= Is_Body
then
539 Cspec
:= Corresponding_Spec
(After
);
541 if Units
.Table
(Cspec
).Elaborate_Body
542 and then Cspec
/= Before
544 Succ
.Table
(Succ
.Last
).After
:= Cspec
;
545 Succ
.Table
(Succ
.Last
).Elab_Body
:= True;
546 UNR
.Table
(Cspec
).Num_Pred
:= UNR
.Table
(Cspec
).Num_Pred
+ 1;
551 -- Fall through on normal case
553 Succ
.Table
(Succ
.Last
).After
:= After
;
554 Succ
.Table
(Succ
.Last
).Elab_Body
:= False;
555 UNR
.Table
(After
).Num_Pred
:= UNR
.Table
(After
).Num_Pred
+ 1;
562 procedure Choose
(Chosen
: Unit_Id
) is
568 Write_Str
("Choosing Unit ");
569 Write_Unit_Name
(Units
.Table
(Chosen
).Uname
);
573 -- Add to elaboration order. Note that units having no elaboration
574 -- code are not treated specially yet. The special casing of this
575 -- is in Bindgen, where Gen_Elab_Calls skips over them. Meanwhile
576 -- we need them here, because the object file list is also driven
577 -- by the contents of the Elab_Order table.
579 Elab_Order
.Increment_Last
;
580 Elab_Order
.Table
(Elab_Order
.Last
) := Chosen
;
582 -- Remove from No_Pred list. This is a little inefficient and may
583 -- be we should doubly link the list, but it will do for now!
585 if No_Pred
= Chosen
then
586 No_Pred
:= UNR
.Table
(Chosen
).Nextnp
;
589 -- Note that we just ignore the situation where it does not
590 -- appear in the No_Pred list, this happens in calls from the
591 -- Diagnose_Elaboration_Problem routine, where cycles are being
592 -- removed arbitrarily from the graph.
595 while U
/= No_Unit_Id
loop
596 if UNR
.Table
(U
).Nextnp
= Chosen
then
597 UNR
.Table
(U
).Nextnp
:= UNR
.Table
(Chosen
).Nextnp
;
601 U
:= UNR
.Table
(U
).Nextnp
;
605 -- For all successors, decrement the number of predecessors, and
606 -- if it becomes zero, then add to no predecessor list.
608 S
:= UNR
.Table
(Chosen
).Successors
;
609 while S
/= No_Successor
loop
610 U
:= Succ
.Table
(S
).After
;
611 UNR
.Table
(U
).Num_Pred
:= UNR
.Table
(U
).Num_Pred
- 1;
614 Write_Str
(" decrementing Num_Pred for unit ");
615 Write_Unit_Name
(Units
.Table
(U
).Uname
);
616 Write_Str
(" new value = ");
617 Write_Int
(Int
(UNR
.Table
(U
).Num_Pred
));
621 if UNR
.Table
(U
).Num_Pred
= 0 then
622 UNR
.Table
(U
).Nextnp
:= No_Pred
;
626 S
:= Succ
.Table
(S
).Next
;
629 -- All done, adjust number of units left count and set elaboration pos
631 Num_Left
:= Num_Left
- 1;
632 Num_Chosen
:= Num_Chosen
+ 1;
633 UNR
.Table
(Chosen
).Elab_Position
:= Num_Chosen
;
634 Units
.Table
(Chosen
).Elab_Position
:= Num_Chosen
;
636 -- If we just chose a spec with Elaborate_Body set, then we
637 -- must immediately elaborate the body, before any other units.
639 if Units
.Table
(Chosen
).Elaborate_Body
then
641 -- If the unit is a spec only, then there is no body. This is a bit
642 -- odd given that Elaborate_Body is here, but it is valid in an
643 -- RCI unit, where we only have the interface in the stub bind.
645 if Units
.Table
(Chosen
).Utype
= Is_Spec_Only
646 and then Units
.Table
(Chosen
).RCI
650 Choose
(Corresponding_Body
(Chosen
));
655 ------------------------
656 -- Corresponding_Body --
657 ------------------------
659 -- Currently if the body and spec are separate, then they appear as
660 -- two separate units in the same ALI file, with the body appearing
661 -- first and the spec appearing second.
663 function Corresponding_Body
(U
: Unit_Id
) return Unit_Id
is
665 pragma Assert
(Units
.Table
(U
).Utype
= Is_Spec
);
667 end Corresponding_Body
;
669 ------------------------
670 -- Corresponding_Spec --
671 ------------------------
673 -- Currently if the body and spec are separate, then they appear as
674 -- two separate units in the same ALI file, with the body appearing
675 -- first and the spec appearing second.
677 function Corresponding_Spec
(U
: Unit_Id
) return Unit_Id
is
679 pragma Assert
(Units
.Table
(U
).Utype
= Is_Body
);
681 end Corresponding_Spec
;
683 ----------------------------------
684 -- Diagnose_Elaboration_Problem --
685 ----------------------------------
687 procedure Diagnose_Elaboration_Problem
is
689 function Find_Path
(Ufrom
, Uto
: Unit_Id
; ML
: Nat
) return Boolean;
690 -- Recursive routine used to find a path from node Ufrom to node Uto.
691 -- If a path exists, returns True and outputs an appropriate set of
692 -- error messages giving the path. Also calls Choose for each of the
693 -- nodes so that they get removed from the remaining set. There are
694 -- two cases of calls, either Ufrom = Uto for an attempt to find a
695 -- cycle, or Ufrom is a spec and Uto the corresponding body for the
696 -- case of an unsatisfiable Elaborate_Body pragma. ML is the minimum
697 -- acceptable length for a path.
703 function Find_Path
(Ufrom
, Uto
: Unit_Id
; ML
: Nat
) return Boolean is
705 function Find_Link
(U
: Unit_Id
; PL
: Nat
) return Boolean;
706 -- This is the inner recursive routine, it determines if a path
707 -- exists from U to Uto, and if so returns True and outputs the
708 -- appropriate set of error messages. PL is the path length
714 function Find_Link
(U
: Unit_Id
; PL
: Nat
) return Boolean is
718 -- Recursion ends if we are at terminating node and the path
719 -- is sufficiently long, generate error message and return True.
721 if U
= Uto
and then PL
>= ML
then
725 -- All done if already visited, otherwise mark as visited
727 elsif UNR
.Table
(U
).Visited
then
730 -- Otherwise mark as visited and look at all successors
733 UNR
.Table
(U
).Visited
:= True;
735 S
:= UNR
.Table
(U
).Successors
;
736 while S
/= No_Successor
loop
737 if Find_Link
(Succ
.Table
(S
).After
, PL
+ 1) then
743 S
:= Succ
.Table
(S
).Next
;
746 -- Falling through means this does not lead to a path
752 -- Start of processing for Find_Path
755 -- Initialize all non-chosen nodes to not visisted yet
757 for U
in Units
.First
.. Units
.Last
loop
758 UNR
.Table
(U
).Visited
:= UNR
.Table
(U
).Elab_Position
/= 0;
761 -- Now try to find the path
763 return Find_Link
(Ufrom
, 0);
766 -- Start of processing for Diagnose_Elaboration_Error
771 -- Output state of things if debug flag N set
780 Write_Str
("Diagnose_Elaboration_Problem called");
782 Write_Str
("List of remaining unchosen units and predecessors");
785 for U
in Units
.First
.. Units
.Last
loop
786 if UNR
.Table
(U
).Elab_Position
= 0 then
787 NP
:= UNR
.Table
(U
).Num_Pred
;
789 Write_Str
(" Unchosen unit: #");
792 Write_Unit_Name
(Units
.Table
(U
).Uname
);
793 Write_Str
(" (Num_Pred = ");
799 if Units
.Table
(U
).Elaborate_Body
then
801 (" (not chosen because of Elaborate_Body)");
804 Write_Str
(" ****************** why not chosen?");
809 -- Search links list to find unchosen predecessors
811 for S
in Succ
.First
.. Succ
.Last
loop
813 SL
: Successor_Link
renames Succ
.Table
(S
);
817 and then UNR
.Table
(SL
.Before
).Elab_Position
= 0
819 Write_Str
(" unchosen predecessor: #");
820 Write_Int
(Int
(SL
.Before
));
822 Write_Unit_Name
(Units
.Table
(SL
.Before
).Uname
);
830 Write_Str
(" **************** Num_Pred value wrong!");
838 -- Output the header for the error, and manually increment the
839 -- error count. We are using Error_Msg_Output rather than Error_Msg
840 -- here for two reasons:
842 -- This is really only one error, not one for each line
843 -- We want this output on standard output since it is voluminous
845 -- But we do need to deal with the error count manually in this case
847 Errors_Detected
:= Errors_Detected
+ 1;
848 Error_Msg_Output
("elaboration circularity detected", Info
=> False);
850 -- Try to find cycles starting with any of the remaining nodes that have
851 -- not yet been chosen. There must be at least one (there is some reason
852 -- we are being called!)
854 for U
in Units
.First
.. Units
.Last
loop
855 if UNR
.Table
(U
).Elab_Position
= 0 then
856 if Find_Path
(U
, U
, 1) then
857 raise Unrecoverable_Error
;
862 -- We should never get here, since we were called for some reason,
863 -- and we should have found and eliminated at least one bad path.
866 end Diagnose_Elaboration_Problem
;
872 procedure Elab_All_Links
875 Reason
: Succ_Reason
;
879 if UNR
.Table
(Before
).Visited
then
883 -- Build the direct link for Before
885 UNR
.Table
(Before
).Visited
:= True;
886 Build_Link
(Before
, After
, Reason
, Link
);
888 -- Process all units with'ed by Before recursively
891 Units
.Table
(Before
).First_With
.. Units
.Table
(Before
).Last_With
893 -- Skip if this with is an interface to a stand-alone library.
894 -- Skip also if no ALI file for this WITH, happens for language
895 -- defined generics while bootstrapping the compiler (see body of
896 -- Lib.Writ.Write_With_Lines). Finally, skip if it is a limited
897 -- with clause, which does not impose an elaboration link.
899 if not Withs
.Table
(W
).SAL_Interface
900 and then Withs
.Table
(W
).Afile
/= No_File
901 and then not Withs
.Table
(W
).Limited_With
904 Info
: constant Int
:=
906 (Withs
.Table
(W
).Uname
);
909 -- If the unit is unknown, for some unknown reason, fail
910 -- graciously explaining that the unit is unknown. Without
911 -- this check, gnatbind will crash in Unit_Id_Of.
913 if Info
= 0 or else Unit_Id
(Info
) = No_Unit_Id
then
916 Get_Name_String
(Withs
.Table
(W
).Uname
);
917 Last_Withed
: Natural := Withed
'Last;
920 (Units
.Table
(Before
).Uname
);
921 Last_Withing
: Natural := Withing
'Last;
922 Spec_Body
: String := " (Spec)";
928 if Last_Withed
> 2 and then
929 Withed
(Last_Withed
- 1) = '%'
931 Last_Withed
:= Last_Withed
- 2;
934 if Last_Withing
> 2 and then
935 Withing
(Last_Withing
- 1) = '%'
937 Last_Withing
:= Last_Withing
- 2;
940 if Units
.Table
(Before
).Utype
= Is_Body
or else
941 Units
.Table
(Before
).Utype
= Is_Body_Only
943 Spec_Body
:= " (Body)";
947 ("could not find unit "
948 & Withed
(Withed
'First .. Last_Withed
) & " needed by "
949 & Withing
(Withing
'First .. Last_Withing
) & Spec_Body
);
954 (Unit_Id_Of
(Withs
.Table
(W
).Uname
),
957 Make_Elab_Entry
(Withs
.Table
(W
).Uname
, Link
));
962 -- Process corresponding body, if there is one
964 if Units
.Table
(Before
).Utype
= Is_Spec
then
966 (Corresponding_Body
(Before
),
969 (Units
.Table
(Corresponding_Body
(Before
)).Uname
, Link
));
977 procedure Elab_Error_Msg
(S
: Successor_Id
) is
978 SL
: Successor_Link
renames Succ
.Table
(S
);
981 -- Nothing to do if internal unit involved and no -da flag
985 (Is_Internal_File_Name
(Units
.Table
(SL
.Before
).Sfile
)
987 Is_Internal_File_Name
(Units
.Table
(SL
.After
).Sfile
))
992 -- Here we want to generate output
994 Error_Msg_Unit_1
:= Units
.Table
(SL
.Before
).Uname
;
997 Error_Msg_Unit_2
:= Units
.Table
(Corresponding_Body
(SL
.After
)).Uname
;
999 Error_Msg_Unit_2
:= Units
.Table
(SL
.After
).Uname
;
1002 Error_Msg_Output
(" $ must be elaborated before $", Info
=> True);
1004 Error_Msg_Unit_1
:= Units
.Table
(SL
.Reason_Unit
).Uname
;
1009 (" reason: with clause",
1014 (" reason: pragma Elaborate in unit $",
1019 (" reason: pragma Elaborate_All in unit $",
1022 when Elab_All_Desirable
=>
1024 (" reason: implicit Elaborate_All in unit $",
1028 (" recompile $ with -gnatwl for full details",
1031 when Elab_Desirable
=>
1033 (" reason: implicit Elaborate in unit $",
1037 (" recompile $ with -gnatwl for full details",
1042 (" reason: spec always elaborated before body",
1046 Write_Elab_All_Chain
(S
);
1048 if SL
.Elab_Body
then
1049 Error_Msg_Unit_1
:= Units
.Table
(SL
.Before
).Uname
;
1050 Error_Msg_Unit_2
:= Units
.Table
(SL
.After
).Uname
;
1052 (" $ must therefore be elaborated before $",
1055 Error_Msg_Unit_1
:= Units
.Table
(SL
.After
).Uname
;
1057 (" (because $ has a pragma Elaborate_Body)",
1061 if not Zero_Formatting
then
1066 ---------------------
1067 -- Find_Elab_Order --
1068 ---------------------
1070 procedure Find_Elab_Order
is
1072 Best_So_Far
: Unit_Id
;
1076 Num_Left
:= Int
(Units
.Last
- Units
.First
+ 1);
1078 -- Initialize unit table for elaboration control
1080 for U
in Units
.First
.. Units
.Last
loop
1082 UNR
.Table
(UNR
.Last
).Successors
:= No_Successor
;
1083 UNR
.Table
(UNR
.Last
).Num_Pred
:= 0;
1084 UNR
.Table
(UNR
.Last
).Nextnp
:= No_Unit_Id
;
1085 UNR
.Table
(UNR
.Last
).Elab_Order
:= 0;
1086 UNR
.Table
(UNR
.Last
).Elab_Position
:= 0;
1089 -- Output warning if -p used with no -gnatE units
1091 if Pessimistic_Elab_Order
1092 and not Dynamic_Elaboration_Checks_Specified
1094 if OpenVMS_On_Target
then
1095 Error_Msg
("?use of /PESSIMISTIC_ELABORATION questionable");
1097 Error_Msg
("?use of -p switch questionable");
1100 Error_Msg
("?since all units compiled with static elaboration model");
1103 -- Gather dependencies and output them if option set
1105 Gather_Dependencies
;
1107 -- Output elaboration dependencies if option is set
1109 if Elab_Dependency_Output
or Debug_Flag_E
then
1113 -- Initialize the no predecessor list
1115 No_Pred
:= No_Unit_Id
;
1117 for U
in UNR
.First
.. UNR
.Last
loop
1118 if UNR
.Table
(U
).Num_Pred
= 0 then
1119 UNR
.Table
(U
).Nextnp
:= No_Pred
;
1124 -- OK, now we determine the elaboration order proper. All we do is to
1125 -- select the best choice from the no predecessor list until all the
1126 -- nodes have been chosen.
1130 -- If there are no nodes with predecessors, then either we are
1131 -- done, as indicated by Num_Left being set to zero, or we have
1132 -- a circularity. In the latter case, diagnose the circularity,
1133 -- removing it from the graph and continue
1135 Get_No_Pred
: while No_Pred
= No_Unit_Id
loop
1136 exit Outer
when Num_Left
< 1;
1137 Diagnose_Elaboration_Problem
;
1138 end loop Get_No_Pred
;
1141 Best_So_Far
:= No_Unit_Id
;
1143 -- Loop to choose best entry in No_Pred list
1145 No_Pred_Search
: loop
1146 if Debug_Flag_N
then
1147 Write_Str
(" considering choice of ");
1148 Write_Unit_Name
(Units
.Table
(U
).Uname
);
1151 if Units
.Table
(U
).Elaborate_Body
then
1153 (" Elaborate_Body = True, Num_Pred for body = ");
1155 (Int
(UNR
.Table
(Corresponding_Body
(U
)).Num_Pred
));
1158 (" Elaborate_Body = False");
1164 -- This is a candididate to be considered for choice
1166 if Best_So_Far
= No_Unit_Id
1167 or else ((not Pessimistic_Elab_Order
)
1168 and then Better_Choice
(U
, Best_So_Far
))
1169 or else (Pessimistic_Elab_Order
1170 and then Pessimistic_Better_Choice
(U
, Best_So_Far
))
1172 if Debug_Flag_N
then
1173 Write_Str
(" tentatively chosen (best so far)");
1180 U
:= UNR
.Table
(U
).Nextnp
;
1181 exit No_Pred_Search
when U
= No_Unit_Id
;
1182 end loop No_Pred_Search
;
1184 -- If no candididate chosen, it means that no unit has No_Pred = 0,
1185 -- but there are units left, hence we have a circular dependency,
1186 -- which we will get Diagnose_Elaboration_Problem to diagnose it.
1188 if Best_So_Far
= No_Unit_Id
then
1189 Diagnose_Elaboration_Problem
;
1191 -- Otherwise choose the best candidate found
1194 Choose
(Best_So_Far
);
1197 end Find_Elab_Order
;
1199 -------------------------
1200 -- Gather_Dependencies --
1201 -------------------------
1203 procedure Gather_Dependencies
is
1204 Withed_Unit
: Unit_Id
;
1207 -- Loop through all units
1209 for U
in Units
.First
.. Units
.Last
loop
1212 -- If this is not an interface to a stand-alone library and
1213 -- there is a body and a spec, then spec must be elaborated first
1214 -- Note that the corresponding spec immediately follows the body
1216 if not Units
.Table
(U
).SAL_Interface
1217 and then Units
.Table
(U
).Utype
= Is_Body
1219 Build_Link
(Corresponding_Spec
(U
), U
, Spec_First
);
1222 -- If this unit is not an interface to a stand-alone library,
1223 -- process WITH references for this unit ignoring generic units and
1224 -- interfaces to stand-alone libraries.
1226 if not Units
.Table
(U
).SAL_Interface
then
1228 W
in Units
.Table
(U
).First_With
.. Units
.Table
(U
).Last_With
1230 if Withs
.Table
(W
).Sfile
/= No_File
1231 and then (not Withs
.Table
(W
).SAL_Interface
)
1233 -- Check for special case of withing a unit that does not
1234 -- exist any more. If the unit was completely missing we
1235 -- would already have detected this, but a nasty case arises
1236 -- when we have a subprogram body with no spec, and some
1237 -- obsolete unit with's a previous (now disappeared) spec.
1239 if Get_Name_Table_Info
(Withs
.Table
(W
).Uname
) = 0 then
1240 Error_Msg_File_1
:= Units
.Table
(U
).Sfile
;
1241 Error_Msg_Unit_1
:= Withs
.Table
(W
).Uname
;
1242 Error_Msg
("{ depends on $ which no longer exists");
1247 Unit_Id
(Unit_Id_Of
(Withs
.Table
(W
).Uname
));
1249 -- Pragma Elaborate_All case, for this we use the recursive
1250 -- Elab_All_Links procedure to establish the links.
1252 if Withs
.Table
(W
).Elaborate_All
then
1254 -- Reset flags used to stop multiple visits to a given
1257 for Uref
in UNR
.First
.. UNR
.Last
loop
1258 UNR
.Table
(Uref
).Visited
:= False;
1261 -- Now establish all the links we need
1264 (Withed_Unit
, U
, Elab_All
,
1266 (Withs
.Table
(W
).Uname
, No_Elab_All_Link
));
1268 -- Elaborate_All_Desirable case, for this we establish the
1269 -- same links as above, but with a different reason.
1271 elsif Withs
.Table
(W
).Elab_All_Desirable
then
1273 -- Reset flags used to stop multiple visits to a given
1276 for Uref
in UNR
.First
.. UNR
.Last
loop
1277 UNR
.Table
(Uref
).Visited
:= False;
1280 -- Now establish all the links we need
1283 (Withed_Unit
, U
, Elab_All_Desirable
,
1285 (Withs
.Table
(W
).Uname
, No_Elab_All_Link
));
1287 -- Pragma Elaborate case. We must build a link for the
1288 -- withed unit itself, and also the corresponding body if
1291 -- However, skip this processing if there is no ALI file for
1292 -- the WITH entry, because this means it is a generic (even
1293 -- when we fix the generics so that an ALI file is present,
1294 -- we probably still will have no ALI file for unchecked and
1295 -- other special cases).
1297 elsif Withs
.Table
(W
).Elaborate
1298 and then Withs
.Table
(W
).Afile
/= No_File
1300 Build_Link
(Withed_Unit
, U
, Withed
);
1302 if Units
.Table
(Withed_Unit
).Utype
= Is_Spec
then
1304 (Corresponding_Body
(Withed_Unit
), U
, Elab
);
1307 -- Elaborate_Desirable case, for this we establish
1308 -- the same links as above, but with a different reason.
1310 elsif Withs
.Table
(W
).Elab_Desirable
then
1311 Build_Link
(Withed_Unit
, U
, Withed
);
1313 if Units
.Table
(Withed_Unit
).Utype
= Is_Spec
then
1315 (Corresponding_Body
(Withed_Unit
),
1319 -- A limited_with does not establish an elaboration
1320 -- dependence (that's the whole point!).
1322 elsif Withs
.Table
(W
).Limited_With
then
1325 -- Case of normal WITH with no elaboration pragmas, just
1326 -- build the single link to the directly referenced unit
1329 Build_Link
(Withed_Unit
, U
, Withed
);
1338 end Gather_Dependencies
;
1344 function Is_Body_Unit
(U
: Unit_Id
) return Boolean is
1346 return Units
.Table
(U
).Utype
= Is_Body
1347 or else Units
.Table
(U
).Utype
= Is_Body_Only
;
1350 -----------------------------
1351 -- Is_Pure_Or_Preelab_Unit --
1352 -----------------------------
1354 function Is_Pure_Or_Preelab_Unit
(U
: Unit_Id
) return Boolean is
1356 -- If we have a body with separate spec, test flags on the spec
1358 if Units
.Table
(U
).Utype
= Is_Body
then
1359 return Units
.Table
(U
+ 1).Preelab
1361 Units
.Table
(U
+ 1).Pure
;
1363 -- Otherwise we have a spec or body acting as spec, test flags on unit
1366 return Units
.Table
(U
).Preelab
1368 Units
.Table
(U
).Pure
;
1370 end Is_Pure_Or_Preelab_Unit
;
1372 ---------------------
1373 -- Is_Waiting_Body --
1374 ---------------------
1376 function Is_Waiting_Body
(U
: Unit_Id
) return Boolean is
1378 return Units
.Table
(U
).Utype
= Is_Body
1379 and then UNR
.Table
(Corresponding_Spec
(U
)).Elab_Position
/= 0;
1380 end Is_Waiting_Body
;
1382 ---------------------
1383 -- Make_Elab_Entry --
1384 ---------------------
1386 function Make_Elab_Entry
1387 (Unam
: Unit_Name_Type
;
1388 Link
: Elab_All_Id
) return Elab_All_Id
1391 Elab_All_Entries
.Increment_Last
;
1392 Elab_All_Entries
.Table
(Elab_All_Entries
.Last
).Needed_By
:= Unam
;
1393 Elab_All_Entries
.Table
(Elab_All_Entries
.Last
).Next_Elab
:= Link
;
1394 return Elab_All_Entries
.Last
;
1395 end Make_Elab_Entry
;
1397 -------------------------------
1398 -- Pessimistic_Better_Choice --
1399 -------------------------------
1401 function Pessimistic_Better_Choice
(U1
, U2
: Unit_Id
) return Boolean is
1402 UT1
: Unit_Record
renames Units
.Table
(U1
);
1403 UT2
: Unit_Record
renames Units
.Table
(U2
);
1406 if Debug_Flag_B
then
1407 Write_Str
("Pessimistic_Better_Choice (");
1408 Write_Unit_Name
(UT1
.Uname
);
1410 Write_Unit_Name
(UT2
.Uname
);
1414 -- Note: the checks here are applied in sequence, and the ordering is
1415 -- significant (i.e. the more important criteria are applied first).
1417 -- If either unit is predefined or internal, then we use the normal
1418 -- Better_Choice rule, since we don't want to disturb the elaboration
1419 -- rules of the language with -p, same treatment for Pure/Preelab.
1421 -- Prefer a predefined unit to a non-predefined unit
1423 if UT1
.Predefined
and then not UT2
.Predefined
then
1424 if Debug_Flag_B
then
1425 Write_Line
(" True: u1 is predefined, u2 is not");
1430 elsif UT2
.Predefined
and then not UT1
.Predefined
then
1431 if Debug_Flag_B
then
1432 Write_Line
(" False: u2 is predefined, u1 is not");
1437 -- Prefer an internal unit to a non-internal unit
1439 elsif UT1
.Internal
and then not UT2
.Internal
then
1440 if Debug_Flag_B
then
1441 Write_Line
(" True: u1 is internal, u2 is not");
1446 elsif UT2
.Internal
and then not UT1
.Internal
then
1447 if Debug_Flag_B
then
1448 Write_Line
(" False: u2 is internal, u1 is not");
1453 -- Prefer a pure or preelaborable unit to one that is not
1455 elsif Is_Pure_Or_Preelab_Unit
(U1
)
1457 Is_Pure_Or_Preelab_Unit
(U2
)
1459 if Debug_Flag_B
then
1460 Write_Line
(" True: u1 is pure/preelab, u2 is not");
1465 elsif Is_Pure_Or_Preelab_Unit
(U2
)
1467 Is_Pure_Or_Preelab_Unit
(U1
)
1469 if Debug_Flag_B
then
1470 Write_Line
(" False: u2 is pure/preelab, u1 is not");
1475 -- Prefer anything else to a waiting body. We want to make bodies wait
1476 -- as long as possible, till we are forced to choose them!
1478 elsif Is_Waiting_Body
(U1
) and then not Is_Waiting_Body
(U2
) then
1479 if Debug_Flag_B
then
1480 Write_Line
(" False: u1 is waiting body, u2 is not");
1485 elsif Is_Waiting_Body
(U2
) and then not Is_Waiting_Body
(U1
) then
1486 if Debug_Flag_B
then
1487 Write_Line
(" True: u2 is waiting body, u1 is not");
1492 -- Prefer a spec to a body (!)
1494 elsif Is_Body_Unit
(U1
) and then not Is_Body_Unit
(U2
) then
1495 if Debug_Flag_B
then
1496 Write_Line
(" False: u1 is body, u2 is not");
1501 elsif Is_Body_Unit
(U2
) and then not Is_Body_Unit
(U1
) then
1502 if Debug_Flag_B
then
1503 Write_Line
(" True: u2 is body, u1 is not");
1508 -- If both are waiting bodies, then prefer the one whose spec is
1509 -- less recently elaborated. Consider the following:
1515 -- The normal waiting body preference would have placed the body of
1516 -- A before the spec of B if it could. Since it could not, there it
1517 -- must be the case that A depends on B. It is therefore a good idea
1518 -- to put the body of B last so that if there is an elaboration order
1519 -- problem, we will find it (that's what pssimistic order is about)
1521 elsif Is_Waiting_Body
(U1
) and then Is_Waiting_Body
(U2
) then
1523 Result
: constant Boolean :=
1524 UNR
.Table
(Corresponding_Spec
(U1
)).Elab_Position
<
1525 UNR
.Table
(Corresponding_Spec
(U2
)).Elab_Position
;
1527 if Debug_Flag_B
then
1529 Write_Line
(" True: based on waiting body elab positions");
1531 Write_Line
(" False: based on waiting body elab positions");
1539 -- Remaining choice rules are disabled by Debug flag -do
1541 if not Debug_Flag_O
then
1543 -- The following deal with the case of specs which have been marked
1544 -- as Elaborate_Body_Desirable. In the normal case, we generally want
1545 -- to delay the elaboration of these specs as long as possible, so
1546 -- that bodies have better chance of being elaborated closer to the
1547 -- specs. Pessimistic_Better_Choice as usual wants to do the opposite
1548 -- and elaborate such specs as early as possible.
1550 -- If we have two units, one of which is a spec for which this flag
1551 -- is set, and the other is not, we normally prefer to delay the spec
1552 -- for which the flag is set, so again Pessimistic_Better_Choice does
1555 if not UT1
.Elaborate_Body_Desirable
1556 and then UT2
.Elaborate_Body_Desirable
1558 if Debug_Flag_B
then
1559 Write_Line
(" False: u1 is elab body desirable, u2 is not");
1564 elsif not UT2
.Elaborate_Body_Desirable
1565 and then UT1
.Elaborate_Body_Desirable
1567 if Debug_Flag_B
then
1568 Write_Line
(" True: u1 is elab body desirable, u2 is not");
1573 -- If we have two specs that are both marked as Elaborate_Body
1574 -- desirable, we normally prefer the one whose body is nearer to
1575 -- being able to be elaborated, based on the Num_Pred count. This
1576 -- helps to ensure bodies are as close to specs as possible. As
1577 -- usual, Pessimistic_Better_Choice does the opposite.
1579 elsif UT1
.Elaborate_Body_Desirable
1580 and then UT2
.Elaborate_Body_Desirable
1583 Result
: constant Boolean :=
1584 UNR
.Table
(Corresponding_Body
(U1
)).Num_Pred
>=
1585 UNR
.Table
(Corresponding_Body
(U2
)).Num_Pred
;
1587 if Debug_Flag_B
then
1589 Write_Line
(" True based on Num_Pred compare");
1591 Write_Line
(" False based on Num_Pred compare");
1600 -- If we fall through, it means that no preference rule applies, so we
1601 -- use alphabetical order to at least give a deterministic result. Since
1602 -- Pessimistic_Better_Choice is in the business of stirring up the
1603 -- order, we will use reverse alphabetical ordering.
1605 if Debug_Flag_B
then
1606 Write_Line
(" choose on reverse alpha order");
1609 return Uname_Less
(UT2
.Uname
, UT1
.Uname
);
1610 end Pessimistic_Better_Choice
;
1616 function Unit_Id_Of
(Uname
: Unit_Name_Type
) return Unit_Id
is
1617 Info
: constant Int
:= Get_Name_Table_Info
(Uname
);
1619 pragma Assert
(Info
/= 0 and then Unit_Id
(Info
) /= No_Unit_Id
);
1620 return Unit_Id
(Info
);
1623 ------------------------
1624 -- Write_Dependencies --
1625 ------------------------
1627 procedure Write_Dependencies
is
1629 if not Zero_Formatting
then
1631 Write_Str
(" ELABORATION ORDER DEPENDENCIES");
1636 Info_Prefix_Suppress
:= True;
1638 for S
in Succ_First
.. Succ
.Last
loop
1642 Info_Prefix_Suppress
:= False;
1644 if not Zero_Formatting
then
1647 end Write_Dependencies
;
1649 --------------------------
1650 -- Write_Elab_All_Chain --
1651 --------------------------
1653 procedure Write_Elab_All_Chain
(S
: Successor_Id
) is
1654 ST
: constant Successor_Link
:= Succ
.Table
(S
);
1655 After
: constant Unit_Name_Type
:= Units
.Table
(ST
.After
).Uname
;
1658 Nam
: Unit_Name_Type
;
1660 First_Name
: Boolean := True;
1663 if ST
.Reason
in Elab_All
.. Elab_All_Desirable
then
1664 L
:= ST
.Elab_All_Link
;
1665 while L
/= No_Elab_All_Link
loop
1666 Nam
:= Elab_All_Entries
.Table
(L
).Needed_By
;
1667 Error_Msg_Unit_1
:= Nam
;
1668 Error_Msg_Output
(" $", Info
=> True);
1670 Get_Name_String
(Nam
);
1672 if Name_Buffer
(Name_Len
) = 'b' then
1675 (" must be elaborated along with its spec:",
1680 (" which must be elaborated " &
1681 "along with its spec:",
1693 (" which is withed by:",
1698 First_Name
:= False;
1700 L
:= Elab_All_Entries
.Table
(L
).Next_Elab
;
1703 Error_Msg_Unit_1
:= After
;
1704 Error_Msg_Output
(" $", Info
=> True);
1706 end Write_Elab_All_Chain
;