2 * Copyright 2010, INRIA, University of Copenhagen
3 * Julia Lawall, Rene Rydhof Hansen, Gilles Muller, Nicolas Palix
4 * Copyright 2005-2009, Ecole des Mines de Nantes, University of Copenhagen
5 * Yoann Padioleau, Julia Lawall, Rene Rydhof Hansen, Henrik Stuart, Gilles Muller, Nicolas Palix
6 * This file is part of Coccinelle.
8 * Coccinelle is free software: you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation, according to version 2 of the License.
12 * Coccinelle is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
17 * You should have received a copy of the GNU General Public License
18 * along with Coccinelle. If not, see <http://www.gnu.org/licenses/>.
20 * The authors reserve the right to distribute this or future versions of
21 * Coccinelle under other licenses.
25 (* Detects subtrees that are all minus/plus and nodes that are "binding
26 context nodes". The latter is a node whose structure and immediate tokens
27 are the same in the minus and plus trees, and such that for every child,
28 the set of context nodes in the child subtree is the same in the minus and
31 module Ast
= Ast_cocci
32 module Ast0
= Ast0_cocci
33 module V0
= Visitor_ast0
34 module VT0
= Visitor_ast0_types
35 module U
= Unparse_ast0
37 (* --------------------------------------------------------------------- *)
38 (* Generic access to code *)
40 let set_mcodekind x mcodekind
=
42 Ast0.DotsExprTag
(d
) -> Ast0.set_mcodekind d mcodekind
43 | Ast0.DotsInitTag
(d
) -> Ast0.set_mcodekind d mcodekind
44 | Ast0.DotsParamTag
(d
) -> Ast0.set_mcodekind d mcodekind
45 | Ast0.DotsStmtTag
(d
) -> Ast0.set_mcodekind d mcodekind
46 | Ast0.DotsDeclTag
(d
) -> Ast0.set_mcodekind d mcodekind
47 | Ast0.DotsCaseTag
(d
) -> Ast0.set_mcodekind d mcodekind
48 | Ast0.IdentTag
(d
) -> Ast0.set_mcodekind d mcodekind
49 | Ast0.ExprTag
(d
) -> Ast0.set_mcodekind d mcodekind
50 | Ast0.ArgExprTag
(d
) | Ast0.TestExprTag
(d
) ->
51 failwith
"not possible - iso only"
52 | Ast0.TypeCTag
(d
) -> Ast0.set_mcodekind d mcodekind
53 | Ast0.ParamTag
(d
) -> Ast0.set_mcodekind d mcodekind
54 | Ast0.DeclTag
(d
) -> Ast0.set_mcodekind d mcodekind
55 | Ast0.InitTag
(d
) -> Ast0.set_mcodekind d mcodekind
56 | Ast0.StmtTag
(d
) -> Ast0.set_mcodekind d mcodekind
57 | Ast0.CaseLineTag
(d
) -> Ast0.set_mcodekind d mcodekind
58 | Ast0.TopTag
(d
) -> Ast0.set_mcodekind d mcodekind
59 | Ast0.IsoWhenTag
(_
) -> failwith
"only within iso phase"
60 | Ast0.IsoWhenTTag
(_
) -> failwith
"only within iso phase"
61 | Ast0.IsoWhenFTag
(_
) -> failwith
"only within iso phase"
62 | Ast0.MetaPosTag
(p
) -> failwith
"metapostag only within iso phase"
64 let set_index x index
=
66 Ast0.DotsExprTag
(d
) -> Ast0.set_index d index
67 | Ast0.DotsInitTag
(d
) -> Ast0.set_index d index
68 | Ast0.DotsParamTag
(d
) -> Ast0.set_index d index
69 | Ast0.DotsStmtTag
(d
) -> Ast0.set_index d index
70 | Ast0.DotsDeclTag
(d
) -> Ast0.set_index d index
71 | Ast0.DotsCaseTag
(d
) -> Ast0.set_index d index
72 | Ast0.IdentTag
(d
) -> Ast0.set_index d index
73 | Ast0.ExprTag
(d
) -> Ast0.set_index d index
74 | Ast0.ArgExprTag
(d
) | Ast0.TestExprTag
(d
) ->
75 failwith
"not possible - iso only"
76 | Ast0.TypeCTag
(d
) -> Ast0.set_index d index
77 | Ast0.ParamTag
(d
) -> Ast0.set_index d index
78 | Ast0.InitTag
(d
) -> Ast0.set_index d index
79 | Ast0.DeclTag
(d
) -> Ast0.set_index d index
80 | Ast0.StmtTag
(d
) -> Ast0.set_index d index
81 | Ast0.CaseLineTag
(d
) -> Ast0.set_index d index
82 | Ast0.TopTag
(d
) -> Ast0.set_index d index
83 | Ast0.IsoWhenTag
(_
) -> failwith
"only within iso phase"
84 | Ast0.IsoWhenTTag
(_
) -> failwith
"only within iso phase"
85 | Ast0.IsoWhenFTag
(_
) -> failwith
"only within iso phase"
86 | Ast0.MetaPosTag
(p
) -> failwith
"metapostag only within iso phase"
88 let get_index = function
89 Ast0.DotsExprTag
(d
) -> Index.expression_dots d
90 | Ast0.DotsInitTag
(d
) -> Index.initialiser_dots d
91 | Ast0.DotsParamTag
(d
) -> Index.parameter_dots d
92 | Ast0.DotsStmtTag
(d
) -> Index.statement_dots d
93 | Ast0.DotsDeclTag
(d
) -> Index.declaration_dots d
94 | Ast0.DotsCaseTag
(d
) -> Index.case_line_dots d
95 | Ast0.IdentTag
(d
) -> Index.ident d
96 | Ast0.ExprTag
(d
) -> Index.expression d
97 | Ast0.ArgExprTag
(d
) | Ast0.TestExprTag
(d
) ->
98 failwith
"not possible - iso only"
99 | Ast0.TypeCTag
(d
) -> Index.typeC d
100 | Ast0.ParamTag
(d
) -> Index.parameterTypeDef d
101 | Ast0.InitTag
(d
) -> Index.initialiser d
102 | Ast0.DeclTag
(d
) -> Index.declaration d
103 | Ast0.StmtTag
(d
) -> Index.statement d
104 | Ast0.CaseLineTag
(d
) -> Index.case_line d
105 | Ast0.TopTag
(d
) -> Index.top_level d
106 | Ast0.IsoWhenTag
(_
) -> failwith
"only within iso phase"
107 | Ast0.IsoWhenTTag
(_
) -> failwith
"only within iso phase"
108 | Ast0.IsoWhenFTag
(_
) -> failwith
"only within iso phase"
109 | Ast0.MetaPosTag
(p
) -> failwith
"metapostag only within iso phase"
111 (* --------------------------------------------------------------------- *)
112 (* Collect the line numbers of the plus code. This is used for disjunctions.
113 It is not completely clear why this is necessary, but it seems like an easy
114 fix for whatever is the problem that is discussed in disj_cases *)
116 let plus_lines = ref ([] : int list
)
119 let rec loop = function
122 match compare n x
with
126 | _
-> failwith
"not possible" in
127 plus_lines := loop !plus_lines
130 let rec loop = function
132 | [x
] -> if n
< x
then (min
,x
) else (x
,max
)
136 else if n
> x1
&& n
< x2
then (x1
,x2
) else loop (x2
::rest
) in
139 let collect_plus_lines top
=
142 let option_default = () in
143 let donothing r k e
= k e
in
144 let mcode (_
,_
,info
,mcodekind
,_
,_
) =
146 Ast0.PLUS _
-> insert info
.Ast0.pos_info
.Ast0.line_start
149 V0.flat_combiner
bind option_default
150 mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode
151 donothing donothing donothing donothing donothing donothing
152 donothing donothing donothing donothing donothing donothing donothing
153 donothing donothing in
154 fn.VT0.combiner_rec_top_level top
156 (* --------------------------------------------------------------------- *)
159 Neutral
| AllMarked
of Ast.count
| NotAllMarked
(* marked means + or - *)
161 (* --------------------------------------------------------------------- *)
162 (* The first part analyzes each of the minus tree and the plus tree
165 (* ints are unique token indices (offset field) *)
167 Token
(* tokens *) of kind
* int (* unique index *) * Ast0.mcodekind
*
168 int list
(* context tokens *)
169 | Recursor
(* children *) of kind
*
170 int list
(* indices of all tokens at the level below *) *
171 Ast0.mcodekind list
(* tokens at the level below *) *
173 | Bind
(* neighbors *) of kind
*
174 int list
(* indices of all tokens at current level *) *
175 Ast0.mcodekind list
(* tokens at current level *) *
176 int list
(* indices of all tokens at the level below *) *
177 Ast0.mcodekind list
(* tokens at the level below *)
180 let kind2c = function
182 | AllMarked _
-> "allmarked"
183 | NotAllMarked
-> "notallmarked"
185 let node2c = function
186 Token
(k
,_
,_
,_
) -> Printf.sprintf
"token %s\n" (kind2c k
)
187 | Recursor
(k
,_
,_
,_
) -> Printf.sprintf
"recursor %s\n" (kind2c k
)
188 | Bind
(k
,_
,_
,_
,_
,_
) -> Printf.sprintf
"bind %s\n" (kind2c k
)
190 (* goal: detect negative in both tokens and recursors, or context only in
194 (k1
,k2
) when k1
= k2
-> k1
195 | (Neutral
,AllMarked c
) -> AllMarked c
196 | (AllMarked c
,Neutral
) -> AllMarked c
197 | _
-> NotAllMarked
in
200 (* there are tokens at this level, so ignore the level below *)
201 (Token
(k1
,i1
,t1
,l1
),Token
(k2
,i2
,t2
,l2
)) ->
202 Bind
(lub(k1
,k2
),[i1
;i2
],[t1
;t2
],[],[],[l1
;l2
])
205 (* there are tokens at this level, so ignore the level below *)
206 | (Token
(k1
,i1
,t1
,l1
),Recursor
(k2
,_
,_
,l2
)) ->
207 Bind
(lub(k1
,k2
),[i1
],[t1
],[],[],[l1
;l2
])
208 | (Recursor
(k1
,_
,_
,l1
),Token
(k2
,i2
,t2
,l2
)) ->
209 Bind
(lub(k1
,k2
),[i2
],[t2
],[],[],[l1
;l2
])
212 (* there are tokens at this level, so ignore the level below *)
213 | (Token
(k1
,i1
,t1
,l1
),Bind
(k2
,i2
,t2
,_
,_
,l2
)) ->
214 Bind
(lub(k1
,k2
),i1
::i2
,t1
::t2
,[],[],l1
::l2
)
215 | (Bind
(k1
,i1
,t1
,_
,_
,l1
),Token
(k2
,i2
,t2
,l2
)) ->
216 Bind
(lub(k1
,k2
),i1
@[i2
],t1
@[t2
],[],[],l1
@[l2
])
219 | (Recursor
(k1
,bi1
,bt1
,l1
),Bind
(k2
,i2
,t2
,bi2
,bt2
,l2
)) ->
220 Bind
(lub(k1
,k2
),i2
,t2
,bi1
@bi2
,bt1
@bt2
,l1
::l2
)
221 | (Bind
(k1
,i1
,t1
,bi1
,bt1
,l1
),Recursor
(k2
,bi2
,bt2
,l2
)) ->
222 Bind
(lub(k1
,k2
),i1
,t1
,bi1
@bi2
,bt1
@bt2
,l1
@[l2
])
224 (* recursor/recursor and bind/bind - not likely to ever occur *)
225 | (Recursor
(k1
,bi1
,bt1
,l1
),Recursor
(k2
,bi2
,bt2
,l2
)) ->
226 Bind
(lub(k1
,k2
),[],[],bi1
@bi2
,bt1
@bt2
,[l1
;l2
])
227 | (Bind
(k1
,i1
,t1
,bi1
,bt1
,l1
),Bind
(k2
,i2
,t2
,bi2
,bt2
,l2
)) ->
228 Bind
(lub(k1
,k2
),i1
@i2
,t1
@t2
,bi1
@bi2
,bt1
@bt2
,l1
@l2
)
231 let option_default = (*Bind(Neutral,[],[],[],[],[])*)
232 Recursor
(Neutral
,[],[],[])
234 let mcode (_
,_
,info
,mcodekind
,pos
,_
) =
235 let offset = info
.Ast0.pos_info
.Ast0.offset in
237 Ast0.MINUS
(_
) -> Token
(AllMarked
Ast.ONE
,offset,mcodekind
,[])
238 | Ast0.PLUS c
-> Token
(AllMarked c
,offset,mcodekind
,[])
239 | Ast0.CONTEXT
(_
) -> Token
(NotAllMarked
,offset,mcodekind
,[offset])
240 | _
-> failwith
"not possible"
242 let neutral_mcode (_
,_
,info
,mcodekind
,pos
,_
) =
243 let offset = info
.Ast0.pos_info
.Ast0.offset in
245 Ast0.MINUS
(_
) -> Token
(Neutral
,offset,mcodekind
,[])
246 | Ast0.PLUS _
-> Token
(Neutral
,offset,mcodekind
,[])
247 | Ast0.CONTEXT
(_
) -> Token
(Neutral
,offset,mcodekind
,[offset])
248 | _
-> failwith
"not possible"
250 (* neutral for context; used for mcode in bef aft nodes that don't represent
251 anything if they don't contain some information *)
252 let nc_mcode (_
,_
,info
,mcodekind
,pos
,_
) =
253 (* distinguish from the offset of some real token *)
254 let offset = (-1) * info
.Ast0.pos_info
.Ast0.offset in
256 Ast0.MINUS
(_
) -> Token
(AllMarked
Ast.ONE
,offset,mcodekind
,[])
257 | Ast0.PLUS c
-> Token
(AllMarked c
,offset,mcodekind
,[])
259 (* Unlike the other mcode cases, we drop the offset from the context
260 offsets. This is because we don't know whether the term this is
261 associated with is - or context. In any case, the context offsets are
262 used for identification, and this invisible node should not be needed
264 Token
(Neutral
,offset,mcodekind
,[])
265 | _
-> failwith
"not possible"
267 let is_context = function Ast0.CONTEXT
(_
) -> true | _
-> false
269 let union_all l
= List.fold_left
Common.union_set
[] l
271 (* is minus is true when we are processing minus code that might be
272 intermingled with plus code. it is used in disj_cases *)
273 let classify is_minus all_marked table code
=
274 let mkres builder k il tl bil btl l e
=
277 Ast0.set_mcodekind e
(all_marked count
) (* definitive *)
279 let check_index il tl
=
280 if List.for_all
is_context tl
282 (let e1 = builder e
in
283 let index = (get_index e1)@il
in
285 let _ = Hashtbl.find table
index in
287 (Printf.sprintf
"line %d: index %s already used\n"
288 (Ast0.get_info e
).Ast0.pos_info
.Ast0.line_start
289 (String.concat
" " (List.map string_of_int
index)))
290 with Not_found
-> Hashtbl.add table
index (e1,l
)) in
291 if il
= [] then check_index bil btl
else check_index il tl
);
293 then Recursor
(k
, bil
, btl
, union_all l
)
294 else Recursor
(k
, il
, tl
, union_all l
) in
296 let compute_result builder e
= function
297 Bind
(k
,il
,tl
,bil
,btl
,l
) -> mkres builder k il tl bil btl l e
298 | Token
(k
,il
,tl
,l
) -> mkres builder k
[il
] [tl
] [] [] [l
] e
299 | Recursor
(k
,bil
,btl
,l
) -> mkres builder k
[] [] bil btl
[l
] e
in
301 let make_not_marked = function
302 Bind
(k
,il
,tl
,bil
,btl
,l
) -> Bind
(NotAllMarked
,il
,tl
,bil
,btl
,l
)
303 | Token
(k
,il
,tl
,l
) -> Token
(NotAllMarked
,il
,tl
,l
)
304 | Recursor
(k
,bil
,btl
,l
) -> Recursor
(NotAllMarked
,bil
,btl
,l
) in
306 let do_nothing builder r k e
= compute_result builder e
(k e
) in
308 let disj_cases disj starter code
fn ender
=
309 (* neutral_mcode used so starter and ender don't have an affect on
310 whether the code is considered all plus/minus, but so that they are
311 consider in the index list, which is needed to make a disj with
312 something in one branch and nothing in the other different from code
313 that just has the something (starter/ender enough, mids not needed
314 for this). Cannot agglomerate + code over | boundaries, because two -
315 cases might have different + code, and don't want to put the + code
316 together into one unit. *)
317 let make_not_marked =
320 (let min = Ast0.get_line disj
in
321 let max = Ast0.get_line_end disj
in
322 let (plus_min
,plus_max
) = find min (min-1) (max+1) in
323 if max > plus_max
then make_not_marked else (function x
-> x
))
324 else make_not_marked in
325 bind (neutral_mcode starter
)
326 (bind (List.fold_right
bind
327 (List.map
make_not_marked (List.map
fn code
))
329 (neutral_mcode ender
)) in
331 (* no whencode in plus tree so have to drop it *)
332 (* need special cases for dots, nests, and disjs *)
333 let expression r k e
=
334 compute_result Ast0.expr e
335 (match Ast0.unwrap e
with
336 Ast0.NestExpr
(starter
,exp
,ender
,whencode
,multi
) ->
337 k
(Ast0.rewrap e
(Ast0.NestExpr
(starter
,exp
,ender
,None
,multi
)))
338 | Ast0.Edots
(dots
,whencode
) ->
339 k
(Ast0.rewrap e
(Ast0.Edots
(dots
,None
)))
340 | Ast0.Ecircles
(dots
,whencode
) ->
341 k
(Ast0.rewrap e
(Ast0.Ecircles
(dots
,None
)))
342 | Ast0.Estars
(dots
,whencode
) ->
343 k
(Ast0.rewrap e
(Ast0.Estars
(dots
,None
)))
344 | Ast0.DisjExpr
(starter
,expr_list
,_,ender
) ->
345 disj_cases e starter expr_list r
.VT0.combiner_rec_expression ender
348 (* not clear why we have the next two cases, since DisjDecl and
349 DisjType shouldn't have been constructed yet, as they only come from isos *)
350 let declaration r k e
=
351 compute_result Ast0.decl e
352 (match Ast0.unwrap e
with
353 Ast0.DisjDecl
(starter
,decls
,_,ender
) ->
354 disj_cases e starter decls r
.VT0.combiner_rec_declaration ender
355 | Ast0.Ddots
(dots
,whencode
) ->
356 k
(Ast0.rewrap e
(Ast0.Ddots
(dots
,None
)))
357 (* Need special cases for the following so that the type will be
358 considered as a unit, rather than distributed around the
359 declared variable. This needs to be done because of the call to
360 compute_result, ie the processing of each term should make a
361 side-effect on the complete term structure as well as collecting
362 some information about it. So we have to visit each complete
363 term structure. In (all?) other such cases, we visit the terms
364 using rebuilder, which just visits the subterms, rather than
365 reordering their components. *)
366 | Ast0.Init
(stg
,ty
,id
,eq
,ini
,sem
) ->
367 bind (match stg
with Some stg
-> mcode stg
| _ -> option_default)
368 (bind (r
.VT0.combiner_rec_typeC ty
)
369 (bind (r
.VT0.combiner_rec_ident id
)
371 (bind (r
.VT0.combiner_rec_initialiser ini
) (mcode sem
)))))
372 | Ast0.UnInit
(stg
,ty
,id
,sem
) ->
373 bind (match stg
with Some stg
-> mcode stg
| _ -> option_default)
374 (bind (r
.VT0.combiner_rec_typeC ty
)
375 (bind (r
.VT0.combiner_rec_ident id
) (mcode sem
)))
379 compute_result Ast0.param e
380 (match Ast0.unwrap e
with
381 Ast0.Param
(ty
,Some id
) ->
382 (* needed for the same reason as in the Init and UnInit cases *)
383 bind (r
.VT0.combiner_rec_typeC ty
) (r
.VT0.combiner_rec_ident id
)
387 compute_result Ast0.typeC e
388 (match Ast0.unwrap e
with
389 Ast0.DisjType
(starter
,types
,_,ender
) ->
390 disj_cases e starter types r
.VT0.combiner_rec_typeC ender
393 let initialiser r k i
=
394 compute_result Ast0.ini i
395 (match Ast0.unwrap i
with
396 Ast0.Idots
(dots
,whencode
) ->
397 k
(Ast0.rewrap i
(Ast0.Idots
(dots
,None
)))
400 let case_line r k e
=
401 compute_result Ast0.case_line e
402 (match Ast0.unwrap e
with
403 Ast0.DisjCase
(starter
,case_list
,_,ender
) ->
404 disj_cases e starter case_list r
.VT0.combiner_rec_case_line ender
407 let statement r k s
=
408 compute_result Ast0.stmt s
409 (match Ast0.unwrap s
with
410 Ast0.Nest
(started
,stm_dots
,ender
,whencode
,multi
) ->
411 k
(Ast0.rewrap s
(Ast0.Nest
(started
,stm_dots
,ender
,[],multi
)))
412 | Ast0.Dots
(dots
,whencode
) ->
413 k
(Ast0.rewrap s
(Ast0.Dots
(dots
,[])))
414 | Ast0.Circles
(dots
,whencode
) ->
415 k
(Ast0.rewrap s
(Ast0.Circles
(dots
,[])))
416 | Ast0.Stars
(dots
,whencode
) ->
417 k
(Ast0.rewrap s
(Ast0.Stars
(dots
,[])))
418 | Ast0.Disj
(starter
,statement_dots_list
,_,ender
) ->
419 disj_cases s starter statement_dots_list r
.VT0.combiner_rec_statement_dots
421 (* cases for everything with extra mcode *)
422 | Ast0.FunDecl
((info
,bef
),_,_,_,_,_,_,_,_)
423 | Ast0.Decl
((info
,bef
),_) ->
424 bind (nc_mcode ((),(),info
,bef
,(),-1)) (k s
)
425 | Ast0.IfThen
(_,_,_,_,_,(info
,aft
))
426 | Ast0.IfThenElse
(_,_,_,_,_,_,_,(info
,aft
))
427 | Ast0.Iterator
(_,_,_,_,_,(info
,aft
))
428 | Ast0.While
(_,_,_,_,_,(info
,aft
))
429 | Ast0.For
(_,_,_,_,_,_,_,_,_,(info
,aft
)) ->
430 bind (k s
) (nc_mcode ((),(),info
,aft
,(),-1))
435 let do_top builder r k e
= compute_result builder e
(k e
) in
438 V0.flat_combiner
bind option_default
439 mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode
440 (do_nothing Ast0.dotsExpr
) (do_nothing Ast0.dotsInit
)
441 (do_nothing Ast0.dotsParam
) (do_nothing Ast0.dotsStmt
)
442 (do_nothing Ast0.dotsDecl
) (do_nothing Ast0.dotsCase
)
443 (do_nothing Ast0.ident
) expression typeC initialiser param declaration
444 statement case_line (do_top Ast0.top
) in
445 combiner.VT0.combiner_rec_top_level code
447 (* --------------------------------------------------------------------- *)
448 (* Traverse the hash tables and find corresponding context nodes that have
449 the same context children *)
451 (* this is just a sanity check - really only need to look at the top-level
453 let equal_mcode (_,_,info1
,_,_,_) (_,_,info2
,_,_,_) =
454 info1
.Ast0.pos_info
.Ast0.offset = info2
.Ast0.pos_info
.Ast0.offset
456 let equal_option e1 e2
=
458 (Some x
, Some y
) -> equal_mcode x y
459 | (None
, None
) -> true
463 match (Ast0.unwrap d1
,Ast0.unwrap d2
) with
464 (Ast0.DOTS
(l1
),Ast0.DOTS
(l2
)) -> List.length l1
= List.length l2
465 | (Ast0.CIRCLES
(l1
),Ast0.CIRCLES
(l2
)) -> List.length l1
= List.length l2
466 | (Ast0.STARS
(l1
),Ast0.STARS
(l2
)) -> List.length l1
= List.length l2
469 let rec equal_ident i1 i2
=
470 match (Ast0.unwrap i1
,Ast0.unwrap i2
) with
471 (Ast0.Id
(name1
),Ast0.Id
(name2
)) -> equal_mcode name1 name2
472 | (Ast0.MetaId
(name1
,_,_),Ast0.MetaId
(name2
,_,_)) ->
473 equal_mcode name1 name2
474 | (Ast0.MetaFunc
(name1
,_,_),Ast0.MetaFunc
(name2
,_,_)) ->
475 equal_mcode name1 name2
476 | (Ast0.MetaLocalFunc
(name1
,_,_),Ast0.MetaLocalFunc
(name2
,_,_)) ->
477 equal_mcode name1 name2
478 | (Ast0.OptIdent
(_),Ast0.OptIdent
(_)) -> true
479 | (Ast0.UniqueIdent
(_),Ast0.UniqueIdent
(_)) -> true
482 let rec equal_expression e1 e2
=
483 match (Ast0.unwrap
e1,Ast0.unwrap e2
) with
484 (Ast0.Ident
(_),Ast0.Ident
(_)) -> true
485 | (Ast0.Constant
(const1
),Ast0.Constant
(const2
)) -> equal_mcode const1 const2
486 | (Ast0.FunCall
(_,lp1
,_,rp1
),Ast0.FunCall
(_,lp2
,_,rp2
)) ->
487 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
488 | (Ast0.Assignment
(_,op1
,_,_),Ast0.Assignment
(_,op2
,_,_)) ->
490 | (Ast0.CondExpr
(_,why1
,_,colon1
,_),Ast0.CondExpr
(_,why2
,_,colon2
,_)) ->
491 equal_mcode why1 why2
&& equal_mcode colon1 colon2
492 | (Ast0.Postfix
(_,op1
),Ast0.Postfix
(_,op2
)) -> equal_mcode op1 op2
493 | (Ast0.Infix
(_,op1
),Ast0.Infix
(_,op2
)) -> equal_mcode op1 op2
494 | (Ast0.Unary
(_,op1
),Ast0.Unary
(_,op2
)) -> equal_mcode op1 op2
495 | (Ast0.Binary
(_,op1
,_),Ast0.Binary
(_,op2
,_)) -> equal_mcode op1 op2
496 | (Ast0.Paren
(lp1
,_,rp1
),Ast0.Paren
(lp2
,_,rp2
)) ->
497 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
498 | (Ast0.ArrayAccess
(_,lb1
,_,rb1
),Ast0.ArrayAccess
(_,lb2
,_,rb2
)) ->
499 equal_mcode lb1 lb2
&& equal_mcode rb1 rb2
500 | (Ast0.RecordAccess
(_,pt1
,_),Ast0.RecordAccess
(_,pt2
,_)) ->
502 | (Ast0.RecordPtAccess
(_,ar1
,_),Ast0.RecordPtAccess
(_,ar2
,_)) ->
504 | (Ast0.Cast
(lp1
,_,rp1
,_),Ast0.Cast
(lp2
,_,rp2
,_)) ->
505 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
506 | (Ast0.SizeOfExpr
(szf1
,_),Ast0.SizeOfExpr
(szf2
,_)) ->
507 equal_mcode szf1 szf2
508 | (Ast0.SizeOfType
(szf1
,lp1
,_,rp1
),Ast0.SizeOfType
(szf2
,lp2
,_,rp2
)) ->
509 equal_mcode szf1 szf2
&& equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
510 | (Ast0.TypeExp
(_),Ast0.TypeExp
(_)) -> true
511 | (Ast0.MetaErr
(name1
,_,_),Ast0.MetaErr
(name2
,_,_))
512 | (Ast0.MetaExpr
(name1
,_,_,_,_),Ast0.MetaExpr
(name2
,_,_,_,_))
513 | (Ast0.MetaExprList
(name1
,_,_),Ast0.MetaExprList
(name2
,_,_)) ->
514 equal_mcode name1 name2
515 | (Ast0.EComma
(cm1
),Ast0.EComma
(cm2
)) -> equal_mcode cm1 cm2
516 | (Ast0.DisjExpr
(starter1
,_,mids1
,ender1
),
517 Ast0.DisjExpr
(starter2
,_,mids2
,ender2
)) ->
518 equal_mcode starter1 starter2
&&
519 List.for_all2
equal_mcode mids1 mids2
&&
520 equal_mcode ender1 ender2
521 | (Ast0.NestExpr
(starter1
,_,ender1
,_,m1
),
522 Ast0.NestExpr
(starter2
,_,ender2
,_,m2
)) ->
523 equal_mcode starter1 starter2
&& equal_mcode ender1 ender2
&& m1
= m2
524 | (Ast0.Edots
(dots1
,_),Ast0.Edots
(dots2
,_))
525 | (Ast0.Ecircles
(dots1
,_),Ast0.Ecircles
(dots2
,_))
526 | (Ast0.Estars
(dots1
,_),Ast0.Estars
(dots2
,_)) -> equal_mcode dots1 dots2
527 | (Ast0.OptExp
(_),Ast0.OptExp
(_)) -> true
528 | (Ast0.UniqueExp
(_),Ast0.UniqueExp
(_)) -> true
531 let rec equal_typeC t1 t2
=
532 match (Ast0.unwrap t1
,Ast0.unwrap t2
) with
533 (Ast0.ConstVol
(cv1
,_),Ast0.ConstVol
(cv2
,_)) -> equal_mcode cv1 cv2
534 | (Ast0.BaseType
(ty1
,stringsa
),Ast0.BaseType
(ty2
,stringsb
)) ->
535 List.for_all2
equal_mcode stringsa stringsb
536 | (Ast0.Signed
(sign1
,_),Ast0.Signed
(sign2
,_)) ->
537 equal_mcode sign1 sign2
538 | (Ast0.Pointer
(_,star1
),Ast0.Pointer
(_,star2
)) ->
539 equal_mcode star1 star2
540 | (Ast0.Array
(_,lb1
,_,rb1
),Ast0.Array
(_,lb2
,_,rb2
)) ->
541 equal_mcode lb1 lb2
&& equal_mcode rb1 rb2
542 | (Ast0.EnumName
(kind1
,_),Ast0.EnumName
(kind2
,_)) ->
543 equal_mcode kind1 kind2
544 | (Ast0.EnumDef
(_,lb1
,_,rb1
),Ast0.EnumDef
(_,lb2
,_,rb2
)) ->
545 equal_mcode lb1 lb2
&& equal_mcode rb1 rb2
546 | (Ast0.StructUnionName
(kind1
,_),Ast0.StructUnionName
(kind2
,_)) ->
547 equal_mcode kind1 kind2
548 | (Ast0.FunctionType
(ty1
,lp1
,p1
,rp1
),Ast0.FunctionType
(ty2
,lp2
,p2
,rp2
)) ->
549 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
550 | (Ast0.StructUnionDef
(_,lb1
,_,rb1
),
551 Ast0.StructUnionDef
(_,lb2
,_,rb2
)) ->
552 equal_mcode lb1 lb2
&& equal_mcode rb1 rb2
553 | (Ast0.TypeName
(name1
),Ast0.TypeName
(name2
)) -> equal_mcode name1 name2
554 | (Ast0.MetaType
(name1
,_),Ast0.MetaType
(name2
,_)) ->
555 equal_mcode name1 name2
556 | (Ast0.DisjType
(starter1
,_,mids1
,ender1
),
557 Ast0.DisjType
(starter2
,_,mids2
,ender2
)) ->
558 equal_mcode starter1 starter2
&&
559 List.for_all2
equal_mcode mids1 mids2
&&
560 equal_mcode ender1 ender2
561 | (Ast0.OptType
(_),Ast0.OptType
(_)) -> true
562 | (Ast0.UniqueType
(_),Ast0.UniqueType
(_)) -> true
565 let equal_declaration d1 d2
=
566 match (Ast0.unwrap d1
,Ast0.unwrap d2
) with
567 (Ast0.MetaDecl
(name1
,_),Ast0.MetaDecl
(name2
,_))
568 | (Ast0.MetaField
(name1
,_),Ast0.MetaField
(name2
,_)) ->
569 equal_mcode name1 name2
570 | (Ast0.Init
(stg1
,_,_,eq1
,_,sem1
),Ast0.Init
(stg2
,_,_,eq2
,_,sem2
)) ->
571 equal_option stg1 stg2
&& equal_mcode eq1 eq2
&& equal_mcode sem1 sem2
572 | (Ast0.UnInit
(stg1
,_,_,sem1
),Ast0.UnInit
(stg2
,_,_,sem2
)) ->
573 equal_option stg1 stg2
&& equal_mcode sem1 sem2
574 | (Ast0.MacroDecl
(nm1
,lp1
,_,rp1
,sem1
),Ast0.MacroDecl
(nm2
,lp2
,_,rp2
,sem2
)) ->
575 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
&& equal_mcode sem1 sem2
576 | (Ast0.TyDecl
(_,sem1
),Ast0.TyDecl
(_,sem2
)) -> equal_mcode sem1 sem2
577 | (Ast0.Ddots
(dots1
,_),Ast0.Ddots
(dots2
,_)) -> equal_mcode dots1 dots2
578 | (Ast0.OptDecl
(_),Ast0.OptDecl
(_)) -> true
579 | (Ast0.UniqueDecl
(_),Ast0.UniqueDecl
(_)) -> true
580 | (Ast0.DisjDecl
_,_) | (_,Ast0.DisjDecl
_) ->
581 failwith
"DisjDecl not expected here"
584 let equal_designator d1 d2
=
586 (Ast0.DesignatorField
(dot1
,_),Ast0.DesignatorField
(dot2
,_)) ->
587 equal_mcode dot1 dot2
588 | (Ast0.DesignatorIndex
(lb1
,_,rb1
),Ast0.DesignatorIndex
(lb2
,_,rb2
)) ->
589 (equal_mcode lb1 lb2
) && (equal_mcode rb1 rb2
)
590 | (Ast0.DesignatorRange
(lb1
,_,dots1
,_,rb1
),
591 Ast0.DesignatorRange
(lb2
,_,dots2
,_,rb2
)) ->
592 (equal_mcode lb1 lb2
) && (equal_mcode dots1 dots2
) &&
593 (equal_mcode rb1 rb2
)
596 let equal_initialiser i1 i2
=
597 match (Ast0.unwrap i1
,Ast0.unwrap i2
) with
598 (Ast0.MetaInit
(name1
,_),Ast0.MetaInit
(name2
,_)) ->
599 equal_mcode name1 name2
600 | (Ast0.InitExpr
(_),Ast0.InitExpr
(_)) -> true
601 | (Ast0.InitList
(lb1
,_,rb1
,o1
),Ast0.InitList
(lb2
,_,rb2
,o2
)) ->
602 (* can't compare orderedness, because this can differ between -
604 (equal_mcode lb1 lb2
) && (equal_mcode rb1 rb2
)
605 | (Ast0.InitGccExt
(designators1
,eq1
,_),
606 Ast0.InitGccExt
(designators2
,eq2
,_)) ->
607 (List.for_all2
equal_designator designators1 designators2
) &&
608 (equal_mcode eq1 eq2
)
609 | (Ast0.InitGccName
(_,eq1
,_),Ast0.InitGccName
(_,eq2
,_)) ->
611 | (Ast0.IComma
(cm1
),Ast0.IComma
(cm2
)) -> equal_mcode cm1 cm2
612 | (Ast0.Idots
(d1
,_),Ast0.Idots
(d2
,_)) -> equal_mcode d1 d2
613 | (Ast0.OptIni
(_),Ast0.OptIni
(_)) -> true
614 | (Ast0.UniqueIni
(_),Ast0.UniqueIni
(_)) -> true
617 let equal_parameterTypeDef p1 p2
=
618 match (Ast0.unwrap p1
,Ast0.unwrap p2
) with
619 (Ast0.VoidParam
(_),Ast0.VoidParam
(_)) -> true
620 | (Ast0.Param
(_,_),Ast0.Param
(_,_)) -> true
621 | (Ast0.MetaParam
(name1
,_),Ast0.MetaParam
(name2
,_))
622 | (Ast0.MetaParamList
(name1
,_,_),Ast0.MetaParamList
(name2
,_,_)) ->
623 equal_mcode name1 name2
624 | (Ast0.PComma
(cm1
),Ast0.PComma
(cm2
)) -> equal_mcode cm1 cm2
625 | (Ast0.Pdots
(dots1
),Ast0.Pdots
(dots2
))
626 | (Ast0.Pcircles
(dots1
),Ast0.Pcircles
(dots2
)) -> equal_mcode dots1 dots2
627 | (Ast0.OptParam
(_),Ast0.OptParam
(_)) -> true
628 | (Ast0.UniqueParam
(_),Ast0.UniqueParam
(_)) -> true
631 let rec equal_statement s1 s2
=
632 match (Ast0.unwrap s1
,Ast0.unwrap s2
) with
633 (Ast0.FunDecl
(_,fninfo1
,_,lp1
,_,rp1
,lbrace1
,_,rbrace1
),
634 Ast0.FunDecl
(_,fninfo2
,_,lp2
,_,rp2
,lbrace2
,_,rbrace2
)) ->
635 (List.length fninfo1
) = (List.length fninfo2
) &&
636 List.for_all2 equal_fninfo fninfo1 fninfo2
&&
637 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
&&
638 equal_mcode lbrace1 lbrace2
&& equal_mcode rbrace1 rbrace2
639 | (Ast0.Decl
(_,_),Ast0.Decl
(_,_)) -> true
640 | (Ast0.Seq
(lbrace1
,_,rbrace1
),Ast0.Seq
(lbrace2
,_,rbrace2
)) ->
641 equal_mcode lbrace1 lbrace2
&& equal_mcode rbrace1 rbrace2
642 | (Ast0.ExprStatement
(_,sem1
),Ast0.ExprStatement
(_,sem2
)) ->
643 equal_mcode sem1 sem2
644 | (Ast0.IfThen
(iff1
,lp1
,_,rp1
,_,_),Ast0.IfThen
(iff2
,lp2
,_,rp2
,_,_)) ->
645 equal_mcode iff1 iff2
&& equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
646 | (Ast0.IfThenElse
(iff1
,lp1
,_,rp1
,_,els1
,_,_),
647 Ast0.IfThenElse
(iff2
,lp2
,_,rp2
,_,els2
,_,_)) ->
648 equal_mcode iff1 iff2
&&
649 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
&& equal_mcode els1 els2
650 | (Ast0.While
(whl1
,lp1
,_,rp1
,_,_),Ast0.While
(whl2
,lp2
,_,rp2
,_,_)) ->
651 equal_mcode whl1 whl2
&& equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
652 | (Ast0.Do
(d1
,_,whl1
,lp1
,_,rp1
,sem1
),Ast0.Do
(d2
,_,whl2
,lp2
,_,rp2
,sem2
)) ->
653 equal_mcode whl1 whl2
&& equal_mcode d1 d2
&&
654 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
&& equal_mcode sem1 sem2
655 | (Ast0.For
(fr1
,lp1
,_,sem11
,_,sem21
,_,rp1
,_,_),
656 Ast0.For
(fr2
,lp2
,_,sem12
,_,sem22
,_,rp2
,_,_)) ->
657 equal_mcode fr1 fr2
&& equal_mcode lp1 lp2
&&
658 equal_mcode sem11 sem12
&& equal_mcode sem21 sem22
&&
660 | (Ast0.Iterator
(nm1
,lp1
,_,rp1
,_,_),Ast0.Iterator
(nm2
,lp2
,_,rp2
,_,_)) ->
661 equal_mcode lp1 lp2
&& equal_mcode rp1 rp2
662 | (Ast0.Switch
(switch1
,lp1
,_,rp1
,lb1
,_,_,rb1
),
663 Ast0.Switch
(switch2
,lp2
,_,rp2
,lb2
,_,_,rb2
)) ->
664 equal_mcode switch1 switch2
&& equal_mcode lp1 lp2
&&
665 equal_mcode rp1 rp2
&& equal_mcode lb1 lb2
&&
667 | (Ast0.Break
(br1
,sem1
),Ast0.Break
(br2
,sem2
)) ->
668 equal_mcode br1 br2
&& equal_mcode sem1 sem2
669 | (Ast0.Continue
(cont1
,sem1
),Ast0.Continue
(cont2
,sem2
)) ->
670 equal_mcode cont1 cont2
&& equal_mcode sem1 sem2
671 | (Ast0.Label
(_,dd1
),Ast0.Label
(_,dd2
)) ->
673 | (Ast0.Goto
(g1
,_,sem1
),Ast0.Goto
(g2
,_,sem2
)) ->
674 equal_mcode g1 g2
&& equal_mcode sem1 sem2
675 | (Ast0.Return
(ret1
,sem1
),Ast0.Return
(ret2
,sem2
)) ->
676 equal_mcode ret1 ret2
&& equal_mcode sem1 sem2
677 | (Ast0.ReturnExpr
(ret1
,_,sem1
),Ast0.ReturnExpr
(ret2
,_,sem2
)) ->
678 equal_mcode ret1 ret2
&& equal_mcode sem1 sem2
679 | (Ast0.MetaStmt
(name1
,_),Ast0.MetaStmt
(name2
,_))
680 | (Ast0.MetaStmtList
(name1
,_),Ast0.MetaStmtList
(name2
,_)) ->
681 equal_mcode name1 name2
682 | (Ast0.Disj
(starter1
,_,mids1
,ender1
),Ast0.Disj
(starter2
,_,mids2
,ender2
)) ->
683 equal_mcode starter1 starter2
&&
684 List.for_all2
equal_mcode mids1 mids2
&&
685 equal_mcode ender1 ender2
686 | (Ast0.Nest
(starter1
,_,ender1
,_,m1
),Ast0.Nest
(starter2
,_,ender2
,_,m2
)) ->
687 equal_mcode starter1 starter2
&& equal_mcode ender1 ender2
&& m1
= m2
688 | (Ast0.Exp
(_),Ast0.Exp
(_)) -> true
689 | (Ast0.TopExp
(_),Ast0.TopExp
(_)) -> true
690 | (Ast0.Ty
(_),Ast0.Ty
(_)) -> true
691 | (Ast0.TopInit
(_),Ast0.TopInit
(_)) -> true
692 | (Ast0.Dots
(d1
,_),Ast0.Dots
(d2
,_))
693 | (Ast0.Circles
(d1
,_),Ast0.Circles
(d2
,_))
694 | (Ast0.Stars
(d1
,_),Ast0.Stars
(d2
,_)) -> equal_mcode d1 d2
695 | (Ast0.Include
(inc1
,name1
),Ast0.Include
(inc2
,name2
)) ->
696 equal_mcode inc1 inc2
&& equal_mcode name1 name2
697 | (Ast0.Define
(def1
,_,_,_),Ast0.Define
(def2
,_,_,_)) ->
698 equal_mcode def1 def2
699 | (Ast0.OptStm
(_),Ast0.OptStm
(_)) -> true
700 | (Ast0.UniqueStm
(_),Ast0.UniqueStm
(_)) -> true
703 and equal_fninfo x y
=
705 (Ast0.FStorage
(s1
),Ast0.FStorage
(s2
)) -> equal_mcode s1 s2
706 | (Ast0.FType
(_),Ast0.FType
(_)) -> true
707 | (Ast0.FInline
(i1
),Ast0.FInline
(i2
)) -> equal_mcode i1 i2
708 | (Ast0.FAttr
(i1
),Ast0.FAttr
(i2
)) -> equal_mcode i1 i2
711 let equal_case_line c1 c2
=
712 match (Ast0.unwrap c1
,Ast0.unwrap c2
) with
713 (Ast0.Default
(def1
,colon1
,_),Ast0.Default
(def2
,colon2
,_)) ->
714 equal_mcode def1 def2
&& equal_mcode colon1 colon2
715 | (Ast0.Case
(case1
,_,colon1
,_),Ast0.Case
(case2
,_,colon2
,_)) ->
716 equal_mcode case1 case2
&& equal_mcode colon1 colon2
717 | (Ast0.DisjCase
(starter1
,_,mids1
,ender1
),
718 Ast0.DisjCase
(starter2
,_,mids2
,ender2
)) ->
719 equal_mcode starter1 starter2
&&
720 List.for_all2
equal_mcode mids1 mids2
&&
721 equal_mcode ender1 ender2
722 | (Ast0.OptCase
(_),Ast0.OptCase
(_)) -> true
725 let rec equal_top_level t1 t2
=
726 match (Ast0.unwrap t1
,Ast0.unwrap t2
) with
727 (Ast0.DECL
(_),Ast0.DECL
(_)) -> true
728 | (Ast0.FILEINFO
(old_file1
,new_file1
),Ast0.FILEINFO
(old_file2
,new_file2
)) ->
729 equal_mcode old_file1 old_file2
&& equal_mcode new_file1 new_file2
730 | (Ast0.CODE
(_),Ast0.CODE
(_)) -> true
731 | (Ast0.ERRORWORDS
(_),Ast0.ERRORWORDS
(_)) -> true
734 let root_equal e1 e2
=
736 (Ast0.DotsExprTag
(d1
),Ast0.DotsExprTag
(d2
)) -> dots equal_expression d1 d2
737 | (Ast0.DotsParamTag
(d1
),Ast0.DotsParamTag
(d2
)) ->
738 dots equal_parameterTypeDef d1 d2
739 | (Ast0.DotsStmtTag
(d1
),Ast0.DotsStmtTag
(d2
)) -> dots equal_statement d1 d2
740 | (Ast0.DotsDeclTag
(d1
),Ast0.DotsDeclTag
(d2
)) -> dots equal_declaration d1 d2
741 | (Ast0.DotsCaseTag
(d1
),Ast0.DotsCaseTag
(d2
)) -> dots equal_case_line d1 d2
742 | (Ast0.IdentTag
(i1
),Ast0.IdentTag
(i2
)) -> equal_ident i1 i2
743 | (Ast0.ExprTag
(e1),Ast0.ExprTag
(e2
)) -> equal_expression e1 e2
744 | (Ast0.ArgExprTag
(d
),_) -> failwith
"not possible - iso only"
745 | (Ast0.TypeCTag
(t1
),Ast0.TypeCTag
(t2
)) -> equal_typeC t1 t2
746 | (Ast0.ParamTag
(p1
),Ast0.ParamTag
(p2
)) -> equal_parameterTypeDef p1 p2
747 | (Ast0.InitTag
(d1
),Ast0.InitTag
(d2
)) -> equal_initialiser d1 d2
748 | (Ast0.DeclTag
(d1
),Ast0.DeclTag
(d2
)) -> equal_declaration d1 d2
749 | (Ast0.StmtTag
(s1
),Ast0.StmtTag
(s2
)) -> equal_statement s1 s2
750 | (Ast0.TopTag
(t1
),Ast0.TopTag
(t2
)) -> equal_top_level t1 t2
751 | (Ast0.IsoWhenTag
(_),_) | (_,Ast0.IsoWhenTag
(_))
752 | (Ast0.IsoWhenTTag
(_),_) | (_,Ast0.IsoWhenTTag
(_))
753 | (Ast0.IsoWhenFTag
(_),_) | (_,Ast0.IsoWhenFTag
(_)) ->
754 failwith
"only within iso phase"
757 let default_context _ =
758 Ast0.CONTEXT
(ref(Ast.NOTHING
,
759 Ast0.default_token_info
,Ast0.default_token_info
))
761 let traverse minus_table plus_table
=
766 let (plus_e
,plus_l
) = Hashtbl.find plus_table key
in
767 if root_equal e plus_e
&&
768 List.for_all
(function x
-> x
)
769 (List.map2
Common.equal_set l plus_l
)
771 let i = Ast0.fresh_index
() in
772 (set_index e
i; set_index plus_e
i;
773 set_mcodekind e
(default_context());
774 set_mcodekind plus_e
(default_context()))
775 with Not_found
-> ())
778 (* --------------------------------------------------------------------- *)
779 (* contextify the whencode *)
783 let option_default = () in
785 let do_nothing r k e
= Ast0.set_mcodekind e
(default_context()); k e
in
787 V0.flat_combiner
bind option_default
788 mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode mcode
789 do_nothing do_nothing do_nothing do_nothing do_nothing do_nothing
790 do_nothing do_nothing do_nothing do_nothing do_nothing do_nothing
791 do_nothing do_nothing do_nothing
793 let contextify_whencode =
795 let option_default = () in
797 let expression r k e
=
799 match Ast0.unwrap e
with
800 Ast0.NestExpr
(_,_,_,Some whencode
,_)
801 | Ast0.Edots
(_,Some whencode
)
802 | Ast0.Ecircles
(_,Some whencode
)
803 | Ast0.Estars
(_,Some whencode
) ->
804 contextify_all.VT0.combiner_rec_expression whencode
807 let initialiser r k
i =
808 match Ast0.unwrap
i with
809 Ast0.Idots
(dots,Some whencode
) ->
810 contextify_all.VT0.combiner_rec_initialiser whencode
813 let whencode = function
814 Ast0.WhenNot sd
-> contextify_all.VT0.combiner_rec_statement_dots sd
815 | Ast0.WhenAlways s
-> contextify_all.VT0.combiner_rec_statement s
816 | Ast0.WhenModifier
(_) -> ()
817 | Ast0.WhenNotTrue
(e
) -> contextify_all.VT0.combiner_rec_expression e
818 | Ast0.WhenNotFalse
(e
) -> contextify_all.VT0.combiner_rec_expression e
in
820 let statement r k
(s
: Ast0.statement) =
822 match Ast0.unwrap s
with
823 Ast0.Nest
(_,_,_,whn
,_)
824 | Ast0.Dots
(_,whn
) | Ast0.Circles
(_,whn
) | Ast0.Stars
(_,whn
) ->
825 List.iter
whencode whn
829 V0.combiner bind option_default
830 {V0.combiner_functions
with
831 VT0.combiner_exprfn
= expression;
832 VT0.combiner_initfn
= initialiser;
833 VT0.combiner_stmtfn
= statement} in
834 combiner.VT0.combiner_rec_top_level
836 (* --------------------------------------------------------------------- *)
838 (* the first int list is the tokens in the node, the second is the tokens
839 in the descendents *)
841 (Hashtbl.create
(50) : (int list
, Ast0.anything
* int list list
) Hashtbl.t
)
843 (Hashtbl.create
(50) : (int list
, Ast0.anything
* int list list
) Hashtbl.t
)
846 match Ast0.unwrap t
with
848 | Ast0.FILEINFO
(_) -> true
849 | Ast0.ERRORWORDS
(_) -> false
850 | Ast0.CODE
(_) -> true
851 | Ast0.OTHER
(_) -> failwith
"unexpected top level code"
853 (* ------------------------------------------------------------------- *)
854 (* alignment of minus and plus *)
856 let concat = function
860 let rec loop = function
863 (match Ast0.unwrap x
with
864 Ast0.DECL
(s
) -> let stms = loop rest
in s
::stms
866 let stms = loop rest
in
867 (match Ast0.unwrap ss
with
868 Ast0.DOTS
(d
) -> d
@stms
869 | _ -> failwith
"no dots allowed in pure plus code")
870 | _ -> failwith
"plus code is being discarded") in
872 Compute_lines.compute_statement_dots_lines
false
873 (Ast0.rewrap
(List.hd l
) (Ast0.DOTS
(loop l
))) in
874 [Ast0.rewrap
res (Ast0.CODE
res)]
876 let collect_up_to m plus
=
877 let minfo = Ast0.get_info m
in
878 let mend = minfo.Ast0.pos_info
.Ast0.logical_end
in
879 let rec loop = function
882 let pinfo = Ast0.get_info p
in
883 let pstart = pinfo.Ast0.pos_info
.Ast0.logical_start
in
886 else let (plus
,rest
) = loop plus
in (p
::plus
,rest
) in
887 let (plus
,rest
) = loop plus
in
890 let realign minus plus
=
891 let rec loop = function
892 ([],_) -> failwith
"not possible, some context required"
893 | ([m
],p
) -> ([m
],concat p
)
895 let (p
,plus
) = collect_up_to m plus
in
896 let (minus
,plus
) = loop (minus
,plus
) in
900 (* ------------------------------------------------------------------- *)
901 (* check compatible: check that at the top level the minus and plus code is
902 of the same kind. Could go further and make the correspondence between the
903 code between ...s. *)
905 let isonly f l
= match Ast0.undots l
with [s
] -> f s
| _ -> false
907 let isall f l
= List.for_all
(isonly f
) l
910 match Ast0.unwrap s
with
912 | Ast0.Disj
(_,stmts
,_,_) -> isall is_exp stmts
916 match Ast0.unwrap s
with
918 | Ast0.Disj
(_,stmts
,_,_) -> isall is_ty stmts
922 match Ast0.unwrap s
with
923 Ast0.TopInit
(e
) -> true
924 | Ast0.Disj
(_,stmts
,_,_) -> isall is_init stmts
928 match Ast0.unwrap s
with
929 Ast0.Decl
(_,e
) -> true
930 | Ast0.FunDecl
(_,_,_,_,_,_,_,_,_) -> true
931 | Ast0.Disj
(_,stmts
,_,_) -> isall is_decl stmts
934 let rec is_fndecl s
=
935 match Ast0.unwrap s
with
936 Ast0.FunDecl
(_,_,_,_,_,_,_,_,_) -> true
937 | Ast0.Disj
(_,stmts
,_,_) -> isall is_fndecl stmts
940 let rec is_toplevel s
=
941 match Ast0.unwrap s
with
942 Ast0.Decl
(_,e
) -> true
943 | Ast0.FunDecl
(_,_,_,_,_,_,_,_,_) -> true
944 | Ast0.Disj
(_,stmts
,_,_) -> isall is_toplevel stmts
945 | Ast0.ExprStatement
(fc
,_) ->
946 (match Ast0.unwrap fc
with
947 Ast0.FunCall
(_,_,_,_) -> true
949 | Ast0.Include
(_,_) -> true
950 | Ast0.Define
(_,_,_,_) -> true
953 let check_compatible m p
=
957 "incompatible minus and plus code starting on lines %d and %d"
958 (Ast0.get_line m
) (Ast0.get_line p
)) in
959 match (Ast0.unwrap m
, Ast0.unwrap p
) with
960 (Ast0.DECL
(decl1
),Ast0.DECL
(decl2
)) ->
961 if not
(is_decl decl1
&& is_decl decl2
)
963 | (Ast0.DECL
(decl1
),Ast0.CODE
(code2
)) ->
964 let v1 = is_decl decl1
in
965 let v2 = List.for_all
is_toplevel (Ast0.undots code2
) in
966 if !Flag.make_hrule
= None
&& v1 && not
v2 then fail()
967 | (Ast0.CODE
(code1
),Ast0.DECL
(decl2
)) ->
968 let v1 = List.for_all
is_toplevel (Ast0.undots code1
) in
969 let v2 = is_decl decl2
in
970 if v1 && not
v2 then fail()
971 | (Ast0.CODE
(code1
),Ast0.CODE
(code2
)) ->
972 let v1 = isonly is_init code1
in
973 let v2a = isonly is_init code2
in
974 let v2b = isonly is_exp code2
in
976 then (if not
(v2a || v2b) then fail())
978 let testers = [is_exp;is_ty] in
981 let v1 = isonly tester code1
in
982 let v2 = isonly tester code2
in
983 if (v1 && not
v2) or (!Flag.make_hrule
= None
&& v2 && not
v1)
986 let v1 = isonly is_fndecl code1
in
987 let v2 = List.for_all
is_toplevel (Ast0.undots code2
) in
988 if !Flag.make_hrule
= None
&& v1 && not
v2 then fail()
989 | (Ast0.FILEINFO
(_,_),Ast0.FILEINFO
(_,_)) -> ()
990 | (Ast0.OTHER
(_),Ast0.OTHER
(_)) -> ()
993 (* ------------------------------------------------------------------- *)
995 (* returns a list of corresponding minus and plus trees *)
996 let context_neg minus plus
=
997 Hashtbl.clear
minus_table;
998 Hashtbl.clear
plus_table;
999 List.iter
contextify_whencode minus
;
1000 let (minus
,plus
) = realign minus plus
in
1001 let rec loop = function
1004 failwith
(Printf.sprintf
"%d plus things remaining" (List.length l
))
1011 (function _ -> Ast0.MINUS
(ref([],Ast0.default_token_info
)))
1015 | (((m
::minus
) as mall
),((p
::plus
) as pall
)) ->
1016 let minfo = Ast0.get_info m
in
1017 let pinfo = Ast0.get_info p
in
1018 let mstart = minfo.Ast0.pos_info
.Ast0.logical_start
in
1019 let mend = minfo.Ast0.pos_info
.Ast0.logical_end
in
1020 let pstart = pinfo.Ast0.pos_info
.Ast0.logical_start
in
1021 let pend = pinfo.Ast0.pos_info
.Ast0.logical_end
in
1022 if (iscode m
or iscode p
) &&
1023 (mend + 1 = pstart or pend + 1 = mstart or (* adjacent *)
1024 (mstart <= pstart && mend >= pstart) or
1025 (pstart <= mstart && pend >= mstart)) (* overlapping or nested *)
1028 (* ensure that the root of each tree has a unique index,
1029 although it might get overwritten if the node is a context
1031 let i = Ast0.fresh_index
() in
1032 Ast0.set_index m
i; Ast0.set_index p
i;
1033 check_compatible m p
;
1034 collect_plus_lines p
;
1037 (function _ -> Ast0.MINUS
(ref([],Ast0.default_token_info
)))
1039 let _ = classify false (function c
-> Ast0.PLUS c
) plus_table p
in
1040 traverse minus_table plus_table;
1041 (m
,p
)::loop(minus
,plus
)
1044 if not
(iscode m
or iscode p
)
1045 then loop(minus
,plus
)
1053 (function _ -> Ast0.MINUS
(ref([],Ast0.default_token_info
)))
1057 else loop(mall
,plus
) in