--- /dev/null
+/* Copyright (C) 2000, HELM Team.
+ *
+ * This file is part of HELM, an Hypertextual, Electronic
+ * Library of Mathematics, developed at the Computer Science
+ * Department, University of Bologna, Italy.
+ *
+ * HELM is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU General Public License
+ * as published by the Free Software Foundation; either version 2
+ * of the License, or (at your option) any later version.
+ *
+ * HELM is distributed in the hope that it will be useful,
+ * but WITHOUT 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
+ * along with HELM; if not, write to the Free Software
+ * Foundation, Inc., 59 Temple Place - Suite 330, Boston,
+ * MA 02111-1307, USA.
+ *
+ * For details, see the HELM World-Wide-Web page,
+ * http://cs.unibo.it/helm/.
+ */
+
+/* AUTOR: Ferruccio Guidi <fguidi@cs.unibo.it>
+ */
+
+%{
+ module M = MathQL
+
+ let analyze x =
+ let rec join l1 l2 = match l1, l2 with
+ | [], _ -> l2
+ | _, [] -> l1
+ | s1 :: tl1, s2 :: _ when s1 < s2 -> s1 :: join tl1 l2
+ | s1 :: _, s2 :: tl2 when s2 < s1 -> s2 :: join l1 tl2
+ | s1 :: tl1, s2 :: tl2 -> s1 :: join tl1 tl2
+ in
+ let rec iter f = function
+ | [] -> []
+ | head :: tail -> join (f head) (iter f tail)
+ in
+ let rec an_val = function
+ | M.True -> []
+ | M.False -> []
+ | M.Const _ -> []
+ | M.VVar _ -> []
+ | M.Ex _ -> []
+ | M.Dot (rv,_) -> [rv]
+ | M.Not x -> an_val x
+ | M.StatVal x -> an_val x
+ | M.Count x -> an_val x
+ | M.Align (_,x) -> an_val x
+ | M.Proj (_,x) -> an_set x
+ | M.Test (_,x,y) -> iter an_val [x; y]
+ | M.Set l -> iter an_val l
+ and an_set = function
+ | M.Empty -> []
+ | M.SVar _ -> []
+ | M.AVar _ -> []
+ | M.Subj x -> an_val x
+ | M.Keep (_,_,x) -> an_set x
+ | M.Log (_,_,x) -> an_set x
+ | M.StatQuery x -> an_set x
+ | M.Bin (_,x,y) -> iter an_set [x; y]
+ | M.LetSVar (_,x,y) -> iter an_set [x; y]
+ | M.For (_,_,x,y) -> iter an_set [x; y]
+ | M.Add (_,g,x) -> join (an_grp g) (an_set x)
+ | M.LetVVar (_,x,y) -> join (an_val x) (an_set y)
+ | M.Select (_,x,y) -> join (an_set x) (an_val y)
+ | M.Property (_,_,_,_,c,d,_,_,x) ->
+ join (an_val x) (iter an_con [c; List.concat d])
+ | M.If (x,y,z) -> join (an_val x) (iter an_set [y; z])
+ and fc (_, _, v) = an_val v
+ and an_con c = iter fc c
+ and fg (_, v) = an_val v
+ and an_grp = function
+ | M.Attr g -> iter (iter fg) g
+ | M.From _ -> []
+ in
+ an_val x
+
+ let f (x, y, z) = x
+ let s (x, y, z) = y
+ let t (x, y, z) = z
+%}
+ %token <string> ID STR
+ %token SL IS LC RC CM SC LP RP AT PC DL FS DQ EOF
+ %token ADD ALIGN AND AS ATTR BE BUT COUNT DIFF DISTR ELSE EMPTY EQ EX
+ %token FALSE FOR FROM IF IN INF INTER INV ISF IST KEEP LE LET LOG LT
+ %token MAIN MATCH MEET NOT OF OR PAT PROJ PROP SELECT SOURCE STAT SUB
+ %token SUBJ SUP SUPER THEN TRUE UNION WHERE XOR
+ %nonassoc IN SUP INF ELSE LOG STAT
+ %left DIFF
+ %left UNION
+ %left INTER
+ %nonassoc WHERE EX
+ %left XOR OR
+ %left AND
+ %nonassoc NOT
+ %nonassoc SUB MEET EQ LT LE
+ %nonassoc SUBJ OF PROJ COUNT ALIGN
+
+ %start qstr query result
+ %type <string> qstr
+ %type <MathQL.query> query
+ %type <MathQL.result> result
+%%
+ qstr:
+ | DQ { "" }
+ | STR qstr { $1 ^ $2 }
+ ;
+ svar:
+ | PC ID { $2 }
+ ;
+ avar:
+ | AT ID { $2 }
+ ;
+ vvar:
+ | DL ID { $2 }
+ ;
+ strs:
+ | STR CM strs { $1 :: $3 }
+ | STR { [$1] }
+ ;
+ subpath:
+ | STR SL subpath { $1 :: $3 }
+ | STR { [$1] }
+ ;
+ path:
+ | subpath { $1 }
+ | SL subpath { $2 }
+ | SL { [] }
+ ;
+ paths:
+ | path CM paths { $1 :: $3 }
+ | path { [$1] }
+ inv:
+ | INV { true }
+ | { false }
+ ;
+ ref:
+ | SUB { M.RefineSub }
+ | SUPER { M.RefineSuper }
+ | { M.RefineExact }
+ ;
+ qualif:
+ | inv ref path { $1, $2, $3 }
+ ;
+ cons:
+ | path IN val_exp { (false, $1, $3) }
+ | path MATCH val_exp { (true, $1, $3) }
+ ;
+ conss:
+ | cons CM conss { $1 :: $3 }
+ | cons { [$1] }
+ ;
+ istrue:
+ | IST conss { $2 }
+ | { [] }
+ ;
+ isfalse:
+ | { [] }
+ | ISF conss isfalse { $2 :: $3 }
+ ;
+ mainc:
+ | MAIN path { $2 }
+ | { [] }
+ ;
+ exp:
+ | path AS path { $1, Some $3 }
+ | path { $1, None }
+ ;
+ exps:
+ | exp CM exps { $1 :: $3 }
+ | exp { [$1] }
+ ;
+ attrc:
+ | ATTR exps { $2 }
+ | { [] }
+ ;
+ pattern:
+ | PAT { true }
+ | { false }
+ ;
+ opt_path:
+ | path { Some $1 }
+ | { None }
+ ;
+ ass:
+ | val_exp AS path { ($3, $1) }
+ ;
+ asss:
+ | ass CM asss { $1 :: $3 }
+ | ass { [$1] }
+ ;
+ assg:
+ | asss SC assg { $1 :: $3 }
+ | asss { [$1] }
+ ;
+ distr:
+ | DISTR { true }
+ | { false }
+ ;
+ allbut:
+ | BUT { true }
+ | { false }
+ ;
+ bin_op:
+ | set_exp DIFF set_exp { M.BinFDiff, $1, $3 }
+ | set_exp UNION set_exp { M.BinFJoin, $1, $3 }
+ | set_exp INTER set_exp { M.BinFMeet, $1, $3 }
+ ;
+ gen_op:
+ | SUP set_exp { M.GenFJoin, $2 }
+ | INF set_exp { M.GenFMeet, $2 }
+ ;
+ test_op:
+ | val_exp XOR val_exp { M.Xor, $1, $3 }
+ | val_exp OR val_exp { M.Or, $1, $3 }
+ | val_exp AND val_exp { M.And, $1, $3 }
+ | val_exp SUB val_exp { M.Sub, $1, $3 }
+ | val_exp MEET val_exp { M.Meet, $1, $3 }
+ | val_exp EQ val_exp { M.Eq, $1, $3 }
+ | val_exp LE val_exp { M.Le, $1, $3 }
+ | val_exp LT val_exp { M.Lt, $1, $3 }
+ ;
+ source:
+ | SOURCE { true }
+ | { false }
+ ;
+ xml:
+ | { false}
+ ;
+ grp_exp:
+ | assg { M.Attr $1 }
+ | avar { M.From $1 }
+ ;
+ val_exp:
+ | TRUE { M.True }
+ | FALSE { M.False }
+ | STR { M.Const $1 }
+ | avar FS path { M.Dot ($1,$3) }
+ | vvar { M.VVar $1 }
+ | LC vals RC { M.Set $2 }
+ | LC RC { M.Set [] }
+ | LP val_exp RP { $2 }
+ | STAT val_exp { M.StatVal $2 }
+ | EX val_exp { M.Ex ((analyze $2),$2) }
+ | NOT val_exp { M.Not $2 }
+ | test_op { M.Test ((f $1),(s $1),(t $1)) }
+ | PROJ opt_path set_exp { M.Proj ($2,$3) }
+ | COUNT val_exp { M.Count $2 }
+ | ALIGN STR IN val_exp { M.Align ($2,$4) }
+ ;
+ vals:
+ | val_exp CM vals { $1 :: $3 }
+ | val_exp { [$1] }
+ ;
+ set_exp:
+ | EMPTY { M.Empty }
+ | LP set_exp RP { $2 }
+ | svar { M.SVar $1 }
+ | avar { M.AVar $1 }
+ | LET svar BE set_exp IN set_exp { M.LetSVar ($2,$4,$6) }
+ | LET vvar BE val_exp IN set_exp { M.LetVVar ($2,$4,$6) }
+ | FOR avar IN set_exp gen_op
+ { M.For ((fst $5),$2,$4,(snd $5)) }
+ | ADD distr grp_exp IN set_exp { M.Add ($2,$3,$5) }
+ | IF val_exp THEN set_exp ELSE set_exp { M.If ($2,$4,$6) }
+ | PROP qualif mainc istrue isfalse attrc OF pattern val_exp
+ { M.Property ((f $2),(s $2),(t $2),$3,$4,$5,$6,$8,$9) }
+ | LOG xml source set_exp { M.Log ($2,$3,$4) }
+ | STAT set_exp { M.StatQuery $2 }
+ | KEEP allbut paths IN set_exp { M.Keep ($2,$3,$5) }
+ | KEEP allbut IN set_exp { M.Keep ($2,[],$4) }
+ | bin_op
+ { M.Bin ((f $1),(s $1),(t $1)) }
+ | SELECT avar FROM set_exp WHERE val_exp { M.Select ($2,$4,$6) }
+ | SUBJ val_exp { M.Subj $2 }
+ ;
+ query:
+ | set_exp { $1 }
+ | set_exp error { $1 }
+ | EOF { raise End_of_file }
+ ;
+ attr:
+ | path IS strs { $1, $3 }
+ | path { $1, [] }
+ ;
+ attrs:
+ | attr SC attrs { $1 :: $3 }
+ | attr { [$1] }
+ ;
+ group:
+ LC attrs RC { $2 }
+ ;
+ groups:
+ | group CM groups { $1 :: $3 }
+ | group { [$1] }
+ ;
+ resource:
+ | STR ATTR groups { ($1, $3) }
+ | STR { ($1, []) }
+ ;
+ resources:
+ | resource SC resources { $1 :: $3 }
+ | resource { [$1] }
+ | { [] }
+ ;
+ result:
+ | resources { $1 }
+ | EOF { raise End_of_file }