1 /* tree.c -- helper functions to build and evaluate the expression tree.
2 Copyright (C) 1990, 91, 92, 93, 94 Free Software Foundation, Inc.
4 This program is free software; you can redistribute it and/or modify
5 it under the terms of the GNU General Public License as published by
6 the Free Software Foundation; either version 2, or (at your option)
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program; if not, write to the Free Software
16 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
19 #include <sys/types.h>
24 static struct predicate
*scan_rest
P_((struct predicate
**input
, struct predicate
*head
, int prev_prec
));
25 static void merge_pred
P_((struct predicate
*beg_list
, struct predicate
*end_list
, struct predicate
**last_p
));
26 static struct predicate
*set_new_parent
P_((struct predicate
*curr
, enum predicate_precedence high_prec
, struct predicate
**prevp
));
28 /* Return a pointer to a tree that represents the
29 expression prior to non-unary operator *INPUT.
30 Set *INPUT to point at the next input predicate node.
32 Only accepts the following:
35 expression [operators of higher precedence]
37 (arbitrary expression)
38 <uni_op>(arbitrary expression)
40 In other words, you can not start out with a bi_op or close_paren.
42 If the following operator (if any) is of a higher precedence than
43 PREV_PREC, the expression just nabbed is part of a following
44 expression, which really is the expression that should be handed to
45 our caller, so get_expr recurses. */
48 get_expr (input
, prev_prec
)
49 struct predicate
**input
;
52 struct predicate
*next
;
55 error (1, 0, "invalid expression");
56 switch ((*input
)->p_type
)
61 error (1, 0, "invalid expression");
66 *input
= (*input
)->pred_next
;
71 *input
= (*input
)->pred_next
;
72 next
->pred_right
= get_expr (input
, NEGATE_PREC
);
76 *input
= (*input
)->pred_next
;
77 next
= get_expr (input
, NO_PREC
);
79 || ((*input
)->p_type
!= CLOSE_PAREN
))
80 error (1, 0, "invalid expression");
81 *input
= (*input
)->pred_next
; /* move over close */
85 error (1, 0, "oops -- invalid expression type!");
89 /* We now have the first expression and are positioned to check
90 out the next operator. If NULL, all done. Otherwise, if
91 PREV_PREC < the current node precedence, we must continue;
92 the expression we just nabbed is more tightly bound to the
93 following expression than to the previous one. */
96 if ((int) (*input
)->p_prec
> (int) prev_prec
)
98 next
= scan_rest (input
, next
, prev_prec
);
100 error (1, 0, "invalid expression");
105 /* Scan across the remainder of a predicate input list starting
106 at *INPUT, building the rest of the expression tree to return.
107 Stop at the first close parenthesis or the end of the input list.
108 Assumes that get_expr has been called to nab the first element
109 of the expression tree.
111 *INPUT points to the current input predicate list element.
112 It is updated as we move along the list to point to the
113 terminating input element.
114 HEAD points to the predicate element that was obtained
115 by the call to get_expr.
116 PREV_PREC is the precedence of the previous predicate element. */
118 static struct predicate
*
119 scan_rest (input
, head
, prev_prec
)
120 struct predicate
**input
;
121 struct predicate
*head
;
124 struct predicate
*tree
; /* The new tree we are building. */
126 if ((*input
== NULL
) || ((*input
)->p_type
== CLOSE_PAREN
))
129 while ((*input
!= NULL
) && ((int) (*input
)->p_prec
> (int) prev_prec
))
131 switch ((*input
)->p_type
)
137 error (1, 0, "invalid expression");
141 (*input
)->pred_left
= tree
;
143 *input
= (*input
)->pred_next
;
144 tree
->pred_right
= get_expr (input
, tree
->p_prec
);
151 error (1, 0, "oops -- invalid expression type!");
158 /* Optimize the ordering of the predicates in the tree. Rearrange
159 them to minimize work. Strategies:
160 * Evaluate predicates that don't need inode information first;
161 the predicates are divided into 1 or more groups separated by
162 predicates (if any) which have "side effects", such as printing.
163 The grouping implements the partial ordering on predicates which
164 those with side effects impose.
165 * Place -name, -path, and -regex at the front of a group, with
166 -name and -path ahead of -regex. Predicates that are moved to the
167 front of a group by definition do not have side effects.
169 This routine "normalizes" the predicate tree by ensuring that
170 all expression predicates have AND (or OR or COMMA) parent nodes
171 which are linked along the left edge of the expression tree.
172 This makes manipulation of subtrees easier.
174 EVAL_TREEP points to the root pointer of the predicate tree
175 to be rearranged. opt_expr may return a new root pointer there.
176 Return true if the tree contains side effects, false if not. */
179 opt_expr (eval_treep
)
180 struct predicate
**eval_treep
;
182 /* List of -name and -path predicates to move. */
183 struct predicate
*name_list
= NULL
;
184 struct predicate
*end_name_list
= NULL
;
185 /* List of -regex predicates to move. */
186 struct predicate
*regex_list
= NULL
;
187 struct predicate
*end_regex_list
= NULL
;
188 struct predicate
*curr
;
189 struct predicate
**prevp
; /* Address of `curr' node. */
190 struct predicate
**last_sidep
; /* Last predicate with side effects. */
192 enum predicate_type p_type
;
193 boolean has_side_effects
= false; /* Return value. */
194 enum predicate_precedence prev_prec
, /* precedence of last BI_OP in branch */
195 biop_prec
; /* topmost BI_OP precedence in branch */
198 if (eval_treep
== NULL
|| *eval_treep
== NULL
)
201 /* Set up to normalize tree as a left-linked list of ANDs or ORs.
202 Set `curr' to the leftmost node, `prevp' to its address, and
203 `pred_func' to the predicate type of its parent. */
205 prev_prec
= AND_PREC
;
207 while (curr
->pred_left
!= NULL
)
209 prevp
= &curr
->pred_left
;
210 prev_prec
= curr
->p_prec
; /* must be a BI_OP */
211 curr
= curr
->pred_left
;
214 /* Link in the appropriate BI_OP for the last expression, if needed. */
215 if (curr
->p_type
!= BI_OP
)
216 set_new_parent (curr
, prev_prec
, prevp
);
219 /* Normalized tree. */
220 printf ("Normalized Eval Tree:\n");
221 print_tree (*eval_treep
, 0);
224 /* Rearrange the predicates. */
226 if ((*prevp
) && (*prevp
)->p_type
== BI_OP
)
227 biop_prec
= (*prevp
)->p_prec
;
228 while ((curr
= *prevp
) != NULL
)
230 /* If there is a BI_OP of different precedence from the first
231 in the pred_left chain, create a new parent of the
232 original precedence, link the new parent to the left of the
233 previous and link CURR to the right of the new parent.
234 This preserves the precedence of expressions in the tree
235 in case we rearrange them. */
236 if (curr
->p_type
== BI_OP
)
238 if (curr
->p_prec
!= biop_prec
)
239 curr
= set_new_parent(curr
, biop_prec
, prevp
);
241 biop_prec
= curr
->p_prec
;
244 /* See which predicate type we have. */
245 p_type
= curr
->pred_right
->p_type
;
246 pred_func
= curr
->pred_right
->pred_func
;
252 /* If it's one of our special primaries, move it to the
253 front of the list for that primary. */
254 if (pred_func
== pred_name
|| pred_func
== pred_path
)
256 *prevp
= curr
->pred_left
;
257 curr
->pred_left
= name_list
;
260 if (end_name_list
== NULL
)
261 end_name_list
= curr
;
266 if (pred_func
== pred_regex
)
268 *prevp
= curr
->pred_left
;
269 curr
->pred_left
= regex_list
;
272 if (end_regex_list
== NULL
)
273 end_regex_list
= curr
;
281 /* For NOT, check the expression trees below the NOT. */
282 curr
->pred_right
->side_effects
283 = opt_expr (&curr
->pred_right
->pred_right
);
287 /* For nested AND or OR, recurse (AND/OR form layers on the left of
288 the tree), and continue scanning this level of AND or OR. */
289 curr
->pred_right
->side_effects
= opt_expr (&curr
->pred_right
);
292 /* At this point, get_expr and scan_rest have already removed
293 all of the user's parentheses. */
296 error (1, 0, "oops -- invalid expression type!");
300 if (curr
->pred_right
->side_effects
== true)
304 /* Incorporate lists and reset list pointers for this group. */
305 if (name_list
!= NULL
)
307 merge_pred (name_list
, end_name_list
, last_sidep
);
308 name_list
= end_name_list
= NULL
;
311 if (regex_list
!= NULL
)
313 merge_pred (regex_list
, end_regex_list
, last_sidep
);
314 regex_list
= end_regex_list
= NULL
;
317 has_side_effects
= true;
320 prevp
= &curr
->pred_left
;
323 /* Do final list merges. */
325 if (name_list
!= NULL
)
326 merge_pred (name_list
, end_name_list
, last_sidep
);
327 if (regex_list
!= NULL
)
328 merge_pred (regex_list
, end_regex_list
, last_sidep
);
330 return (has_side_effects
);
333 /* Link in a new parent BI_OP node for CURR, at *PREVP, with precedence
336 static struct predicate
*
337 set_new_parent (curr
, high_prec
, prevp
)
338 struct predicate
*curr
;
339 enum predicate_precedence high_prec
;
340 struct predicate
**prevp
;
342 struct predicate
*new_parent
;
344 new_parent
= (struct predicate
*) xmalloc (sizeof (struct predicate
));
345 new_parent
->p_type
= BI_OP
;
346 new_parent
->p_prec
= high_prec
;
347 new_parent
->need_stat
= false;
352 new_parent
->pred_func
= pred_comma
;
355 new_parent
->pred_func
= pred_or
;
358 new_parent
->pred_func
= pred_and
;
364 new_parent
->side_effects
= false;
365 new_parent
->args
.str
= NULL
;
366 new_parent
->pred_next
= NULL
;
368 /* Link in new_parent.
369 Pushes rest of left branch down 1 level to new_parent->pred_right. */
370 new_parent
->pred_left
= NULL
;
371 new_parent
->pred_right
= curr
;
375 new_parent
->p_name
= (char *) find_pred_name (new_parent
->pred_func
);
381 /* Merge the predicate list that starts at BEG_LIST and ends at END_LIST
382 into the tree at LAST_P. */
385 merge_pred (beg_list
, end_list
, last_p
)
386 struct predicate
*beg_list
, *end_list
, **last_p
;
388 end_list
->pred_left
= *last_p
;
392 /* Find the first node in expression tree TREE that requires
393 a stat call and mark the operator above it as needing a stat
394 before calling the node. Since the expression precedences
395 are represented in the tree, some preds that need stat may not
396 get executed (because the expression value is determined earlier.)
397 So every expression needing stat must be marked as such, not just
398 the earliest, to be sure to obtain the stat. This still guarantees
399 that a stat is made as late as possible. Return true if the top node
400 in TREE requires a stat, false if not. */
404 struct predicate
*tree
;
406 /* The tree is executed in-order, so walk this way (apologies to Aerosmith)
407 to find the first predicate for which the stat is needed. */
408 switch (tree
->p_type
)
412 return tree
->need_stat
;
415 if (mark_stat (tree
->pred_right
))
416 tree
->need_stat
= true;
420 /* ANDs and ORs are linked along ->left ending in NULL. */
421 if (tree
->pred_left
!= NULL
)
422 mark_stat (tree
->pred_left
);
424 if (mark_stat (tree
->pred_right
))
425 tree
->need_stat
= true;
430 error (1, 0, "oops -- invalid expression type!");