xref: /dragonfly/contrib/gcc-8.0/gcc/genmatch.c (revision 95059079af47f9a66a175f374f2da1a5020e3255)
1 /* Generate pattern matching and transform code shared between
2    GENERIC and GIMPLE folding code from match-and-simplify description.
3 
4    Copyright (C) 2014-2018 Free Software Foundation, Inc.
5    Contributed by Richard Biener <rguenther@suse.de>
6    and Prathamesh Kulkarni  <bilbotheelffriend@gmail.com>
7 
8 This file is part of GCC.
9 
10 GCC is free software; you can redistribute it and/or modify it under
11 the terms of the GNU General Public License as published by the Free
12 Software Foundation; either version 3, or (at your option) any later
13 version.
14 
15 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
16 WARRANTY; without even the implied warranty of MERCHANTABILITY or
17 FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
18 for more details.
19 
20 You should have received a copy of the GNU General Public License
21 along with GCC; see the file COPYING3.  If not see
22 <http://www.gnu.org/licenses/>.  */
23 
24 #include "bconfig.h"
25 #include "system.h"
26 #include "coretypes.h"
27 #include <cpplib.h>
28 #include "errors.h"
29 #include "hash-table.h"
30 #include "hash-set.h"
31 #include "is-a.h"
32 
33 
34 /* Stubs for GGC referenced through instantiations triggered by hash-map.  */
ggc_internal_cleared_alloc(size_t,void (*)(void *),size_t,size_t MEM_STAT_DECL)35 void *ggc_internal_cleared_alloc (size_t, void (*)(void *),
36                                           size_t, size_t MEM_STAT_DECL)
37 {
38   return NULL;
39 }
ggc_free(void *)40 void ggc_free (void *)
41 {
42 }
43 
44 
45 /* Global state.  */
46 
47 /* Verboseness.  0 is quiet, 1 adds some warnings, 2 is for debugging.  */
48 unsigned verbose;
49 
50 
51 /* libccp helpers.  */
52 
53 static struct line_maps *line_table;
54 
55 /* The rich_location class within libcpp requires a way to expand
56    source_location instances, and relies on the client code
57    providing a symbol named
58      linemap_client_expand_location_to_spelling_point
59    to do this.
60 
61    This is the implementation for genmatch.  */
62 
63 expanded_location
linemap_client_expand_location_to_spelling_point(source_location loc,enum location_aspect)64 linemap_client_expand_location_to_spelling_point (source_location loc,
65                                                               enum location_aspect)
66 {
67   const struct line_map_ordinary *map;
68   loc = linemap_resolve_location (line_table, loc, LRK_SPELLING_LOCATION, &map);
69   return linemap_expand_location (line_table, map, loc);
70 }
71 
72 static bool
73 #if GCC_VERSION >= 4001
74 __attribute__((format (printf, 5, 0)))
75 #endif
error_cb(cpp_reader *,int errtype,int,rich_location * richloc,const char * msg,va_list * ap)76 error_cb (cpp_reader *, int errtype, int, rich_location *richloc,
77             const char *msg, va_list *ap)
78 {
79   const line_map_ordinary *map;
80   source_location location = richloc->get_loc ();
81   linemap_resolve_location (line_table, location, LRK_SPELLING_LOCATION, &map);
82   expanded_location loc = linemap_expand_location (line_table, map, location);
83   fprintf (stderr, "%s:%d:%d %s: ", loc.file, loc.line, loc.column,
84              (errtype == CPP_DL_WARNING) ? "warning" : "error");
85   vfprintf (stderr, msg, *ap);
86   fprintf (stderr, "\n");
87   FILE *f = fopen (loc.file, "r");
88   if (f)
89     {
90       char buf[128];
91       while (loc.line > 0)
92           {
93             if (!fgets (buf, 128, f))
94               goto notfound;
95             if (buf[strlen (buf) - 1] != '\n')
96               {
97                 if (loc.line > 1)
98                     loc.line++;
99               }
100             loc.line--;
101           }
102       fprintf (stderr, "%s", buf);
103       for (int i = 0; i < loc.column - 1; ++i)
104           fputc (' ', stderr);
105       fputc ('^', stderr);
106       fputc ('\n', stderr);
107 notfound:
108       fclose (f);
109     }
110 
111   if (errtype == CPP_DL_FATAL)
112     exit (1);
113   return false;
114 }
115 
116 static void
117 #if GCC_VERSION >= 4001
118 __attribute__((format (printf, 2, 3)))
119 #endif
fatal_at(const cpp_token * tk,const char * msg,...)120 fatal_at (const cpp_token *tk, const char *msg, ...)
121 {
122   rich_location richloc (line_table, tk->src_loc);
123   va_list ap;
124   va_start (ap, msg);
125   error_cb (NULL, CPP_DL_FATAL, 0, &richloc, msg, &ap);
126   va_end (ap);
127 }
128 
129 static void
130 #if GCC_VERSION >= 4001
131 __attribute__((format (printf, 2, 3)))
132 #endif
fatal_at(source_location loc,const char * msg,...)133 fatal_at (source_location loc, const char *msg, ...)
134 {
135   rich_location richloc (line_table, loc);
136   va_list ap;
137   va_start (ap, msg);
138   error_cb (NULL, CPP_DL_FATAL, 0, &richloc, msg, &ap);
139   va_end (ap);
140 }
141 
142 static void
143 #if GCC_VERSION >= 4001
144 __attribute__((format (printf, 2, 3)))
145 #endif
warning_at(const cpp_token * tk,const char * msg,...)146 warning_at (const cpp_token *tk, const char *msg, ...)
147 {
148   rich_location richloc (line_table, tk->src_loc);
149   va_list ap;
150   va_start (ap, msg);
151   error_cb (NULL, CPP_DL_WARNING, 0, &richloc, msg, &ap);
152   va_end (ap);
153 }
154 
155 static void
156 #if GCC_VERSION >= 4001
157 __attribute__((format (printf, 2, 3)))
158 #endif
warning_at(source_location loc,const char * msg,...)159 warning_at (source_location loc, const char *msg, ...)
160 {
161   rich_location richloc (line_table, loc);
162   va_list ap;
163   va_start (ap, msg);
164   error_cb (NULL, CPP_DL_WARNING, 0, &richloc, msg, &ap);
165   va_end (ap);
166 }
167 
168 /* Like fprintf, but print INDENT spaces at the beginning.  */
169 
170 static void
171 #if GCC_VERSION >= 4001
172 __attribute__((format (printf, 3, 4)))
173 #endif
fprintf_indent(FILE * f,unsigned int indent,const char * format,...)174 fprintf_indent (FILE *f, unsigned int indent, const char *format, ...)
175 {
176   va_list ap;
177   for (; indent >= 8; indent -= 8)
178     fputc ('\t', f);
179   fprintf (f, "%*s", indent, "");
180   va_start (ap, format);
181   vfprintf (f, format, ap);
182   va_end (ap);
183 }
184 
185 static void
186 output_line_directive (FILE *f, source_location location,
187                            bool dumpfile = false)
188 {
189   const line_map_ordinary *map;
190   linemap_resolve_location (line_table, location, LRK_SPELLING_LOCATION, &map);
191   expanded_location loc = linemap_expand_location (line_table, map, location);
192   if (dumpfile)
193     {
194       /* When writing to a dumpfile only dump the filename.  */
195       const char *file = strrchr (loc.file, DIR_SEPARATOR);
196 #if defined(DIR_SEPARATOR_2)
197       const char *pos2 = strrchr (loc.file, DIR_SEPARATOR_2);
198       if (pos2 && (!file || (pos2 > file)))
199           file = pos2;
200 #endif
201       if (!file)
202           file = loc.file;
203       else
204           ++file;
205       fprintf (f, "%s:%d", file, loc.line);
206     }
207   else
208     /* Other gen programs really output line directives here, at least for
209        development it's right now more convenient to have line information
210        from the generated file.  Still keep the directives as comment for now
211        to easily back-point to the meta-description.  */
212     fprintf (f, "/* #line %d \"%s\" */\n", loc.line, loc.file);
213 }
214 
215 
216 /* Pull in tree codes and builtin function codes from their
217    definition files.  */
218 
219 #define DEFTREECODE(SYM, STRING, TYPE, NARGS)   SYM,
220 enum tree_code {
221 #include "tree.def"
222 CONVERT0,
223 CONVERT1,
224 CONVERT2,
225 VIEW_CONVERT0,
226 VIEW_CONVERT1,
227 VIEW_CONVERT2,
228 MAX_TREE_CODES
229 };
230 #undef DEFTREECODE
231 
232 #define DEF_BUILTIN(ENUM, N, C, T, LT, B, F, NA, AT, IM, COND) ENUM,
233 enum built_in_function {
234 #include "builtins.def"
235 END_BUILTINS
236 };
237 
238 #define DEF_INTERNAL_FN(CODE, FLAGS, FNSPEC) IFN_##CODE,
239 enum internal_fn {
240 #include "internal-fn.def"
241   IFN_LAST
242 };
243 
244 /* Return true if CODE represents a commutative tree code.  Otherwise
245    return false.  */
246 bool
commutative_tree_code(enum tree_code code)247 commutative_tree_code (enum tree_code code)
248 {
249   switch (code)
250     {
251     case PLUS_EXPR:
252     case MULT_EXPR:
253     case MULT_HIGHPART_EXPR:
254     case MIN_EXPR:
255     case MAX_EXPR:
256     case BIT_IOR_EXPR:
257     case BIT_XOR_EXPR:
258     case BIT_AND_EXPR:
259     case NE_EXPR:
260     case EQ_EXPR:
261     case UNORDERED_EXPR:
262     case ORDERED_EXPR:
263     case UNEQ_EXPR:
264     case LTGT_EXPR:
265     case TRUTH_AND_EXPR:
266     case TRUTH_XOR_EXPR:
267     case TRUTH_OR_EXPR:
268     case WIDEN_MULT_EXPR:
269     case VEC_WIDEN_MULT_HI_EXPR:
270     case VEC_WIDEN_MULT_LO_EXPR:
271     case VEC_WIDEN_MULT_EVEN_EXPR:
272     case VEC_WIDEN_MULT_ODD_EXPR:
273       return true;
274 
275     default:
276       break;
277     }
278   return false;
279 }
280 
281 /* Return true if CODE represents a ternary tree code for which the
282    first two operands are commutative.  Otherwise return false.  */
283 bool
commutative_ternary_tree_code(enum tree_code code)284 commutative_ternary_tree_code (enum tree_code code)
285 {
286   switch (code)
287     {
288     case WIDEN_MULT_PLUS_EXPR:
289     case WIDEN_MULT_MINUS_EXPR:
290     case DOT_PROD_EXPR:
291     case FMA_EXPR:
292       return true;
293 
294     default:
295       break;
296     }
297   return false;
298 }
299 
300 /* Return true if CODE is a comparison.  */
301 
302 bool
comparison_code_p(enum tree_code code)303 comparison_code_p (enum tree_code code)
304 {
305   switch (code)
306     {
307     case EQ_EXPR:
308     case NE_EXPR:
309     case ORDERED_EXPR:
310     case UNORDERED_EXPR:
311     case LTGT_EXPR:
312     case UNEQ_EXPR:
313     case GT_EXPR:
314     case GE_EXPR:
315     case LT_EXPR:
316     case LE_EXPR:
317     case UNGT_EXPR:
318     case UNGE_EXPR:
319     case UNLT_EXPR:
320     case UNLE_EXPR:
321       return true;
322 
323     default:
324       break;
325     }
326   return false;
327 }
328 
329 
330 /* Base class for all identifiers the parser knows.  */
331 
332 struct id_base : nofree_ptr_hash<id_base>
333 {
334   enum id_kind { CODE, FN, PREDICATE, USER, NULL_ID } kind;
335 
336   id_base (id_kind, const char *, int = -1);
337 
338   hashval_t hashval;
339   int nargs;
340   const char *id;
341 
342   /* hash_table support.  */
343   static inline hashval_t hash (const id_base *);
344   static inline int equal (const id_base *, const id_base *);
345 };
346 
347 inline hashval_t
hash(const id_base * op)348 id_base::hash (const id_base *op)
349 {
350   return op->hashval;
351 }
352 
353 inline int
equal(const id_base * op1,const id_base * op2)354 id_base::equal (const id_base *op1,
355                               const id_base *op2)
356 {
357   return (op1->hashval == op2->hashval
358             && strcmp (op1->id, op2->id) == 0);
359 }
360 
361 /* The special id "null", which matches nothing.  */
362 static id_base *null_id;
363 
364 /* Hashtable of known pattern operators.  This is pre-seeded from
365    all known tree codes and all known builtin function ids.  */
366 static hash_table<id_base> *operators;
367 
id_base(id_kind kind_,const char * id_,int nargs_)368 id_base::id_base (id_kind kind_, const char *id_, int nargs_)
369 {
370   kind = kind_;
371   id = id_;
372   nargs = nargs_;
373   hashval = htab_hash_string (id);
374 }
375 
376 /* Identifier that maps to a tree code.  */
377 
378 struct operator_id : public id_base
379 {
operator_idoperator_id380   operator_id (enum tree_code code_, const char *id_, unsigned nargs_,
381                  const char *tcc_)
382       : id_base (id_base::CODE, id_, nargs_), code (code_), tcc (tcc_) {}
383   enum tree_code code;
384   const char *tcc;
385 };
386 
387 /* Identifier that maps to a builtin or internal function code.  */
388 
389 struct fn_id : public id_base
390 {
fn_idfn_id391   fn_id (enum built_in_function fn_, const char *id_)
392       : id_base (id_base::FN, id_), fn (fn_) {}
fn_idfn_id393   fn_id (enum internal_fn fn_, const char *id_)
394       : id_base (id_base::FN, id_), fn (int (END_BUILTINS) + int (fn_)) {}
395   unsigned int fn;
396 };
397 
398 struct simplify;
399 
400 /* Identifier that maps to a user-defined predicate.  */
401 
402 struct predicate_id : public id_base
403 {
predicate_idpredicate_id404   predicate_id (const char *id_)
405     : id_base (id_base::PREDICATE, id_), matchers (vNULL) {}
406   vec<simplify *> matchers;
407 };
408 
409 /* Identifier that maps to a operator defined by a 'for' directive.  */
410 
411 struct user_id : public id_base
412 {
413   user_id (const char *id_, bool is_oper_list_ = false)
id_baseuser_id414     : id_base (id_base::USER, id_), substitutes (vNULL),
415       used (false), is_oper_list (is_oper_list_) {}
416   vec<id_base *> substitutes;
417   bool used;
418   bool is_oper_list;
419 };
420 
421 template<>
422 template<>
423 inline bool
test(id_base * id)424 is_a_helper <fn_id *>::test (id_base *id)
425 {
426   return id->kind == id_base::FN;
427 }
428 
429 template<>
430 template<>
431 inline bool
test(id_base * id)432 is_a_helper <operator_id *>::test (id_base *id)
433 {
434   return id->kind == id_base::CODE;
435 }
436 
437 template<>
438 template<>
439 inline bool
test(id_base * id)440 is_a_helper <predicate_id *>::test (id_base *id)
441 {
442   return id->kind == id_base::PREDICATE;
443 }
444 
445 template<>
446 template<>
447 inline bool
test(id_base * id)448 is_a_helper <user_id *>::test (id_base *id)
449 {
450   return id->kind == id_base::USER;
451 }
452 
453 /* Add a predicate identifier to the hash.  */
454 
455 static predicate_id *
add_predicate(const char * id)456 add_predicate (const char *id)
457 {
458   predicate_id *p = new predicate_id (id);
459   id_base **slot = operators->find_slot_with_hash (p, p->hashval, INSERT);
460   if (*slot)
461     fatal ("duplicate id definition");
462   *slot = p;
463   return p;
464 }
465 
466 /* Add a tree code identifier to the hash.  */
467 
468 static void
add_operator(enum tree_code code,const char * id,const char * tcc,unsigned nargs)469 add_operator (enum tree_code code, const char *id,
470                 const char *tcc, unsigned nargs)
471 {
472   if (strcmp (tcc, "tcc_unary") != 0
473       && strcmp (tcc, "tcc_binary") != 0
474       && strcmp (tcc, "tcc_comparison") != 0
475       && strcmp (tcc, "tcc_expression") != 0
476       /* For {REAL,IMAG}PART_EXPR and VIEW_CONVERT_EXPR.  */
477       && strcmp (tcc, "tcc_reference") != 0
478       /* To have INTEGER_CST and friends as "predicate operators".  */
479       && strcmp (tcc, "tcc_constant") != 0
480       /* And allow CONSTRUCTOR for vector initializers.  */
481       && !(code == CONSTRUCTOR)
482       /* Allow SSA_NAME as predicate operator.  */
483       && !(code == SSA_NAME))
484     return;
485   /* Treat ADDR_EXPR as atom, thus don't allow matching its operand.  */
486   if (code == ADDR_EXPR)
487     nargs = 0;
488   operator_id *op = new operator_id (code, id, nargs, tcc);
489   id_base **slot = operators->find_slot_with_hash (op, op->hashval, INSERT);
490   if (*slot)
491     fatal ("duplicate id definition");
492   *slot = op;
493 }
494 
495 /* Add a built-in or internal function identifier to the hash.  ID is
496    the name of its CFN_* enumeration value.  */
497 
498 template <typename T>
499 static void
add_function(T code,const char * id)500 add_function (T code, const char *id)
501 {
502   fn_id *fn = new fn_id (code, id);
503   id_base **slot = operators->find_slot_with_hash (fn, fn->hashval, INSERT);
504   if (*slot)
505     fatal ("duplicate id definition");
506   *slot = fn;
507 }
508 
509 /* Helper for easy comparing ID with tree code CODE.  */
510 
511 static bool
512 operator==(id_base &id, enum tree_code code)
513 {
514   if (operator_id *oid = dyn_cast <operator_id *> (&id))
515     return oid->code == code;
516   return false;
517 }
518 
519 /* Lookup the identifier ID.  Allow "null" if ALLOW_NULL.  */
520 
521 id_base *
522 get_operator (const char *id, bool allow_null = false)
523 {
524   if (allow_null && strcmp (id, "null") == 0)
525     return null_id;
526 
527   id_base tem (id_base::CODE, id);
528 
529   id_base *op = operators->find_with_hash (&tem, tem.hashval);
530   if (op)
531     {
532       /* If this is a user-defined identifier track whether it was used.  */
533       if (user_id *uid = dyn_cast<user_id *> (op))
534           uid->used = true;
535       return op;
536     }
537 
538   char *id2;
539   bool all_upper = true;
540   bool all_lower = true;
541   for (unsigned int i = 0; id[i]; ++i)
542     if (ISUPPER (id[i]))
543       all_lower = false;
544     else if (ISLOWER (id[i]))
545       all_upper = false;
546   if (all_lower)
547     {
548       /* Try in caps with _EXPR appended.  */
549       id2 = ACONCAT ((id, "_EXPR", NULL));
550       for (unsigned int i = 0; id2[i]; ++i)
551           id2[i] = TOUPPER (id2[i]);
552     }
553   else if (all_upper && strncmp (id, "IFN_", 4) == 0)
554     /* Try CFN_ instead of IFN_.  */
555     id2 = ACONCAT (("CFN_", id + 4, NULL));
556   else if (all_upper && strncmp (id, "BUILT_IN_", 9) == 0)
557     /* Try prepending CFN_.  */
558     id2 = ACONCAT (("CFN_", id, NULL));
559   else
560     return NULL;
561 
562   new (&tem) id_base (id_base::CODE, id2);
563   return operators->find_with_hash (&tem, tem.hashval);
564 }
565 
566 /* Return the comparison operators that results if the operands are
567    swapped.  This is safe for floating-point.  */
568 
569 id_base *
swap_tree_comparison(operator_id * p)570 swap_tree_comparison (operator_id *p)
571 {
572   switch (p->code)
573     {
574     case EQ_EXPR:
575     case NE_EXPR:
576     case ORDERED_EXPR:
577     case UNORDERED_EXPR:
578     case LTGT_EXPR:
579     case UNEQ_EXPR:
580       return p;
581     case GT_EXPR:
582       return get_operator ("LT_EXPR");
583     case GE_EXPR:
584       return get_operator ("LE_EXPR");
585     case LT_EXPR:
586       return get_operator ("GT_EXPR");
587     case LE_EXPR:
588       return get_operator ("GE_EXPR");
589     case UNGT_EXPR:
590       return get_operator ("UNLT_EXPR");
591     case UNGE_EXPR:
592       return get_operator ("UNLE_EXPR");
593     case UNLT_EXPR:
594       return get_operator ("UNGT_EXPR");
595     case UNLE_EXPR:
596       return get_operator ("UNGE_EXPR");
597     default:
598       gcc_unreachable ();
599     }
600 }
601 
602 typedef hash_map<nofree_string_hash, unsigned> cid_map_t;
603 
604 
605 /* The AST produced by parsing of the pattern definitions.  */
606 
607 struct dt_operand;
608 struct capture_info;
609 
610 /* The base class for operands.  */
611 
612 struct operand {
613   enum op_type { OP_PREDICATE, OP_EXPR, OP_CAPTURE, OP_C_EXPR, OP_IF, OP_WITH };
operandoperand614   operand (enum op_type type_, source_location loc_)
615     : type (type_), location (loc_) {}
616   enum op_type type;
617   source_location location;
618   virtual void gen_transform (FILE *, int, const char *, bool, int,
619                                     const char *, capture_info *,
620                                     dt_operand ** = 0,
621                                     int = 0)
622     { gcc_unreachable  (); }
623 };
624 
625 /* A predicate operand.  Predicates are leafs in the AST.  */
626 
627 struct predicate : public operand
628 {
predicatepredicate629   predicate (predicate_id *p_, source_location loc)
630     : operand (OP_PREDICATE, loc), p (p_) {}
631   predicate_id *p;
632 };
633 
634 /* An operand that constitutes an expression.  Expressions include
635    function calls and user-defined predicate invocations.  */
636 
637 struct expr : public operand
638 {
639   expr (id_base *operation_, source_location loc, bool is_commutative_ = false)
operandexpr640     : operand (OP_EXPR, loc), operation (operation_),
641       ops (vNULL), expr_type (NULL), is_commutative (is_commutative_),
642       is_generic (false), force_single_use (false) {}
exprexpr643   expr (expr *e)
644     : operand (OP_EXPR, e->location), operation (e->operation),
645       ops (vNULL), expr_type (e->expr_type), is_commutative (e->is_commutative),
646       is_generic (e->is_generic), force_single_use (e->force_single_use) {}
append_opexpr647   void append_op (operand *op) { ops.safe_push (op); }
648   /* The operator and its operands.  */
649   id_base *operation;
650   vec<operand *> ops;
651   /* An explicitely specified type - used exclusively for conversions.  */
652   const char *expr_type;
653   /* Whether the operation is to be applied commutatively.  This is
654      later lowered to two separate patterns.  */
655   bool is_commutative;
656   /* Whether the expression is expected to be in GENERIC form.  */
657   bool is_generic;
658   /* Whether pushing any stmt to the sequence should be conditional
659      on this expression having a single-use.  */
660   bool force_single_use;
661   virtual void gen_transform (FILE *f, int, const char *, bool, int,
662                                     const char *, capture_info *,
663                                     dt_operand ** = 0, int = 0);
664 };
665 
666 /* An operator that is represented by native C code.  This is always
667    a leaf operand in the AST.  This class is also used to represent
668    the code to be generated for 'if' and 'with' expressions.  */
669 
670 struct c_expr : public operand
671 {
672   /* A mapping of an identifier and its replacement.  Used to apply
673      'for' lowering.  */
674   struct id_tab {
675     const char *id;
676     const char *oper;
id_tabc_expr::id_tab677     id_tab (const char *id_, const char *oper_): id (id_), oper (oper_) {}
678   };
679 
c_exprc_expr680   c_expr (cpp_reader *r_, source_location loc,
681             vec<cpp_token> code_, unsigned nr_stmts_,
682             vec<id_tab> ids_, cid_map_t *capture_ids_)
683     : operand (OP_C_EXPR, loc), r (r_), code (code_),
684       capture_ids (capture_ids_), nr_stmts (nr_stmts_), ids (ids_) {}
685   /* cpplib tokens and state to transform this back to source.  */
686   cpp_reader *r;
687   vec<cpp_token> code;
688   cid_map_t *capture_ids;
689   /* The number of statements parsed (well, the number of ';'s).  */
690   unsigned nr_stmts;
691   /* The identifier replacement vector.  */
692   vec<id_tab> ids;
693   virtual void gen_transform (FILE *f, int, const char *, bool, int,
694                                     const char *, capture_info *,
695                                     dt_operand ** = 0, int = 0);
696 };
697 
698 /* A wrapper around another operand that captures its value.  */
699 
700 struct capture : public operand
701 {
capturecapture702   capture (source_location loc, unsigned where_, operand *what_, bool value_)
703       : operand (OP_CAPTURE, loc), where (where_), value_match (value_),
704         what (what_) {}
705   /* Identifier index for the value.  */
706   unsigned where;
707   /* Whether in a match of two operands the compare should be for
708      equal values rather than equal atoms (boils down to a type
709      check or not).  */
710   bool value_match;
711   /* The captured value.  */
712   operand *what;
713   virtual void gen_transform (FILE *f, int, const char *, bool, int,
714                                     const char *, capture_info *,
715                                     dt_operand ** = 0, int = 0);
716 };
717 
718 /* if expression.  */
719 
720 struct if_expr : public operand
721 {
if_exprif_expr722   if_expr (source_location loc)
723     : operand (OP_IF, loc), cond (NULL), trueexpr (NULL), falseexpr (NULL) {}
724   c_expr *cond;
725   operand *trueexpr;
726   operand *falseexpr;
727 };
728 
729 /* with expression.  */
730 
731 struct with_expr : public operand
732 {
with_exprwith_expr733   with_expr (source_location loc)
734     : operand (OP_WITH, loc), with (NULL), subexpr (NULL) {}
735   c_expr *with;
736   operand *subexpr;
737 };
738 
739 template<>
740 template<>
741 inline bool
test(operand * op)742 is_a_helper <capture *>::test (operand *op)
743 {
744   return op->type == operand::OP_CAPTURE;
745 }
746 
747 template<>
748 template<>
749 inline bool
test(operand * op)750 is_a_helper <predicate *>::test (operand *op)
751 {
752   return op->type == operand::OP_PREDICATE;
753 }
754 
755 template<>
756 template<>
757 inline bool
test(operand * op)758 is_a_helper <c_expr *>::test (operand *op)
759 {
760   return op->type == operand::OP_C_EXPR;
761 }
762 
763 template<>
764 template<>
765 inline bool
test(operand * op)766 is_a_helper <expr *>::test (operand *op)
767 {
768   return op->type == operand::OP_EXPR;
769 }
770 
771 template<>
772 template<>
773 inline bool
test(operand * op)774 is_a_helper <if_expr *>::test (operand *op)
775 {
776   return op->type == operand::OP_IF;
777 }
778 
779 template<>
780 template<>
781 inline bool
test(operand * op)782 is_a_helper <with_expr *>::test (operand *op)
783 {
784   return op->type == operand::OP_WITH;
785 }
786 
787 /* The main class of a pattern and its transform.  This is used to
788    represent both (simplify ...) and (match ...) kinds.  The AST
789    duplicates all outer 'if' and 'for' expressions here so each
790    simplify can exist in isolation.  */
791 
792 struct simplify
793 {
794   enum simplify_kind { SIMPLIFY, MATCH };
795 
simplifysimplify796   simplify (simplify_kind kind_, unsigned id_, operand *match_,
797               operand *result_, vec<vec<user_id *> > for_vec_,
798               cid_map_t *capture_ids_)
799       : kind (kind_), id (id_), match (match_), result (result_),
800       for_vec (for_vec_), for_subst_vec (vNULL),
801       capture_ids (capture_ids_), capture_max (capture_ids_->elements () - 1) {}
802 
803   simplify_kind kind;
804   /* ID.  This is kept to easily associate related simplifies expanded
805      from the same original one.  */
806   unsigned id;
807   /* The expression that is matched against the GENERIC or GIMPLE IL.  */
808   operand *match;
809   /* For a (simplify ...) an expression with ifs and withs with the expression
810      produced when the pattern applies in the leafs.
811      For a (match ...) the leafs are either empty if it is a simple predicate
812      or the single expression specifying the matched operands.  */
813   struct operand *result;
814   /* Collected 'for' expression operators that have to be replaced
815      in the lowering phase.  */
816   vec<vec<user_id *> > for_vec;
817   vec<std::pair<user_id *, id_base *> > for_subst_vec;
818   /* A map of capture identifiers to indexes.  */
819   cid_map_t *capture_ids;
820   int capture_max;
821 };
822 
823 /* Debugging routines for dumping the AST.  */
824 
825 DEBUG_FUNCTION void
826 print_operand (operand *o, FILE *f = stderr, bool flattened = false)
827 {
828   if (capture *c = dyn_cast<capture *> (o))
829     {
830       if (c->what && flattened == false)
831           print_operand (c->what, f, flattened);
832       fprintf (f, "@%u", c->where);
833     }
834 
835   else if (predicate *p = dyn_cast<predicate *> (o))
836     fprintf (f, "%s", p->p->id);
837 
838   else if (is_a<c_expr *> (o))
839     fprintf (f, "c_expr");
840 
841   else if (expr *e = dyn_cast<expr *> (o))
842     {
843       if (e->ops.length () == 0)
844           fprintf (f, "%s", e->operation->id);
845       else
846           {
847             fprintf (f, "(%s", e->operation->id);
848 
849             if (flattened == false)
850               {
851                 for (unsigned i = 0; i < e->ops.length (); ++i)
852                     {
853                       putc (' ', f);
854                       print_operand (e->ops[i], f, flattened);
855                     }
856               }
857             putc (')', f);
858           }
859     }
860 
861   else
862     gcc_unreachable ();
863 }
864 
865 DEBUG_FUNCTION void
866 print_matches (struct simplify *s, FILE *f = stderr)
867 {
868   fprintf (f, "for expression: ");
869   print_operand (s->match, f);
870   putc ('\n', f);
871 }
872 
873 
874 /* AST lowering.  */
875 
876 /* Lowering of commutative operators.  */
877 
878 static void
cartesian_product(const vec<vec<operand * >> & ops_vector,vec<vec<operand * >> & result,vec<operand * > & v,unsigned n)879 cartesian_product (const vec< vec<operand *> >& ops_vector,
880                        vec< vec<operand *> >& result, vec<operand *>& v, unsigned n)
881 {
882   if (n == ops_vector.length ())
883     {
884       vec<operand *> xv = v.copy ();
885       result.safe_push (xv);
886       return;
887     }
888 
889   for (unsigned i = 0; i < ops_vector[n].length (); ++i)
890     {
891       v[n] = ops_vector[n][i];
892       cartesian_product (ops_vector, result, v, n + 1);
893     }
894 }
895 
896 /* Lower OP to two operands in case it is marked as commutative.  */
897 
898 static vec<operand *>
commutate(operand * op,vec<vec<user_id * >> & for_vec)899 commutate (operand *op, vec<vec<user_id *> > &for_vec)
900 {
901   vec<operand *> ret = vNULL;
902 
903   if (capture *c = dyn_cast <capture *> (op))
904     {
905       if (!c->what)
906           {
907             ret.safe_push (op);
908             return ret;
909           }
910       vec<operand *> v = commutate (c->what, for_vec);
911       for (unsigned i = 0; i < v.length (); ++i)
912           {
913             capture *nc = new capture (c->location, c->where, v[i],
914                                              c->value_match);
915             ret.safe_push (nc);
916           }
917       return ret;
918     }
919 
920   expr *e = dyn_cast <expr *> (op);
921   if (!e || e->ops.length () == 0)
922     {
923       ret.safe_push (op);
924       return ret;
925     }
926 
927   vec< vec<operand *> > ops_vector = vNULL;
928   for (unsigned i = 0; i < e->ops.length (); ++i)
929     ops_vector.safe_push (commutate (e->ops[i], for_vec));
930 
931   auto_vec< vec<operand *> > result;
932   auto_vec<operand *> v (e->ops.length ());
933   v.quick_grow_cleared (e->ops.length ());
934   cartesian_product (ops_vector, result, v, 0);
935 
936 
937   for (unsigned i = 0; i < result.length (); ++i)
938     {
939       expr *ne = new expr (e);
940       ne->is_commutative = false;
941       for (unsigned j = 0; j < result[i].length (); ++j)
942           ne->append_op (result[i][j]);
943       ret.safe_push (ne);
944     }
945 
946   if (!e->is_commutative)
947     return ret;
948 
949   for (unsigned i = 0; i < result.length (); ++i)
950     {
951       expr *ne = new expr (e);
952       if (operator_id *p = dyn_cast <operator_id *> (ne->operation))
953           {
954             if (comparison_code_p (p->code))
955               ne->operation = swap_tree_comparison (p);
956           }
957       else if (user_id *p = dyn_cast <user_id *> (ne->operation))
958           {
959             bool found_compare = false;
960             for (unsigned j = 0; j < p->substitutes.length (); ++j)
961               if (operator_id *q = dyn_cast <operator_id *> (p->substitutes[j]))
962                 {
963                     if (comparison_code_p (q->code)
964                         && swap_tree_comparison (q) != q)
965                       {
966                         found_compare = true;
967                         break;
968                       }
969                 }
970             if (found_compare)
971               {
972                 user_id *newop = new user_id ("<internal>");
973                 for (unsigned j = 0; j < p->substitutes.length (); ++j)
974                     {
975                       id_base *subst = p->substitutes[j];
976                       if (operator_id *q = dyn_cast <operator_id *> (subst))
977                         {
978                           if (comparison_code_p (q->code))
979                               subst = swap_tree_comparison (q);
980                         }
981                       newop->substitutes.safe_push (subst);
982                     }
983                 ne->operation = newop;
984                 /* Search for 'p' inside the for vector and push 'newop'
985                    to the same level.  */
986                 for (unsigned j = 0; newop && j < for_vec.length (); ++j)
987                     for (unsigned k = 0; k < for_vec[j].length (); ++k)
988                       if (for_vec[j][k] == p)
989                         {
990                           for_vec[j].safe_push (newop);
991                           newop = NULL;
992                           break;
993                         }
994               }
995           }
996       ne->is_commutative = false;
997       // result[i].length () is 2 since e->operation is binary
998       for (unsigned j = result[i].length (); j; --j)
999           ne->append_op (result[i][j-1]);
1000       ret.safe_push (ne);
1001     }
1002 
1003   return ret;
1004 }
1005 
1006 /* Lower operations marked as commutative in the AST of S and push
1007    the resulting patterns to SIMPLIFIERS.  */
1008 
1009 static void
lower_commutative(simplify * s,vec<simplify * > & simplifiers)1010 lower_commutative (simplify *s, vec<simplify *>& simplifiers)
1011 {
1012   vec<operand *> matchers = commutate (s->match, s->for_vec);
1013   for (unsigned i = 0; i < matchers.length (); ++i)
1014     {
1015       simplify *ns = new simplify (s->kind, s->id, matchers[i], s->result,
1016                                            s->for_vec, s->capture_ids);
1017       simplifiers.safe_push (ns);
1018     }
1019 }
1020 
1021 /* Strip conditional conversios using operator OPER from O and its
1022    children if STRIP, else replace them with an unconditional convert.  */
1023 
1024 operand *
lower_opt_convert(operand * o,enum tree_code oper,enum tree_code to_oper,bool strip)1025 lower_opt_convert (operand *o, enum tree_code oper,
1026                        enum tree_code to_oper, bool strip)
1027 {
1028   if (capture *c = dyn_cast<capture *> (o))
1029     {
1030       if (c->what)
1031           return new capture (c->location, c->where,
1032                                   lower_opt_convert (c->what, oper, to_oper, strip),
1033                                   c->value_match);
1034       else
1035           return c;
1036     }
1037 
1038   expr *e = dyn_cast<expr *> (o);
1039   if (!e)
1040     return o;
1041 
1042   if (*e->operation == oper)
1043     {
1044       if (strip)
1045           return lower_opt_convert (e->ops[0], oper, to_oper, strip);
1046 
1047       expr *ne = new expr (e);
1048       ne->operation = (to_oper == CONVERT_EXPR
1049                            ? get_operator ("CONVERT_EXPR")
1050                            : get_operator ("VIEW_CONVERT_EXPR"));
1051       ne->append_op (lower_opt_convert (e->ops[0], oper, to_oper, strip));
1052       return ne;
1053     }
1054 
1055   expr *ne = new expr (e);
1056   for (unsigned i = 0; i < e->ops.length (); ++i)
1057     ne->append_op (lower_opt_convert (e->ops[i], oper, to_oper, strip));
1058 
1059   return ne;
1060 }
1061 
1062 /* Determine whether O or its children uses the conditional conversion
1063    operator OPER.  */
1064 
1065 static bool
has_opt_convert(operand * o,enum tree_code oper)1066 has_opt_convert (operand *o, enum tree_code oper)
1067 {
1068   if (capture *c = dyn_cast<capture *> (o))
1069     {
1070       if (c->what)
1071           return has_opt_convert (c->what, oper);
1072       else
1073           return false;
1074     }
1075 
1076   expr *e = dyn_cast<expr *> (o);
1077   if (!e)
1078     return false;
1079 
1080   if (*e->operation == oper)
1081     return true;
1082 
1083   for (unsigned i = 0; i < e->ops.length (); ++i)
1084     if (has_opt_convert (e->ops[i], oper))
1085       return true;
1086 
1087   return false;
1088 }
1089 
1090 /* Lower conditional convert operators in O, expanding it to a vector
1091    if required.  */
1092 
1093 static vec<operand *>
lower_opt_convert(operand * o)1094 lower_opt_convert (operand *o)
1095 {
1096   vec<operand *> v1 = vNULL, v2;
1097 
1098   v1.safe_push (o);
1099 
1100   enum tree_code opers[]
1101     = { CONVERT0, CONVERT_EXPR,
1102           CONVERT1, CONVERT_EXPR,
1103           CONVERT2, CONVERT_EXPR,
1104           VIEW_CONVERT0, VIEW_CONVERT_EXPR,
1105           VIEW_CONVERT1, VIEW_CONVERT_EXPR,
1106           VIEW_CONVERT2, VIEW_CONVERT_EXPR };
1107 
1108   /* Conditional converts are lowered to a pattern with the
1109      conversion and one without.  The three different conditional
1110      convert codes are lowered separately.  */
1111 
1112   for (unsigned i = 0; i < sizeof (opers) / sizeof (enum tree_code); i += 2)
1113     {
1114       v2 = vNULL;
1115       for (unsigned j = 0; j < v1.length (); ++j)
1116           if (has_opt_convert (v1[j], opers[i]))
1117             {
1118               v2.safe_push (lower_opt_convert (v1[j],
1119                                                        opers[i], opers[i+1], false));
1120               v2.safe_push (lower_opt_convert (v1[j],
1121                                                        opers[i], opers[i+1], true));
1122             }
1123 
1124       if (v2 != vNULL)
1125           {
1126             v1 = vNULL;
1127             for (unsigned j = 0; j < v2.length (); ++j)
1128               v1.safe_push (v2[j]);
1129           }
1130     }
1131 
1132   return v1;
1133 }
1134 
1135 /* Lower conditional convert operators in the AST of S and push
1136    the resulting multiple patterns to SIMPLIFIERS.  */
1137 
1138 static void
lower_opt_convert(simplify * s,vec<simplify * > & simplifiers)1139 lower_opt_convert (simplify *s, vec<simplify *>& simplifiers)
1140 {
1141   vec<operand *> matchers = lower_opt_convert (s->match);
1142   for (unsigned i = 0; i < matchers.length (); ++i)
1143     {
1144       simplify *ns = new simplify (s->kind, s->id, matchers[i], s->result,
1145                                            s->for_vec, s->capture_ids);
1146       simplifiers.safe_push (ns);
1147     }
1148 }
1149 
1150 /* Lower the compare operand of COND_EXPRs and VEC_COND_EXPRs to a
1151    GENERIC and a GIMPLE variant.  */
1152 
1153 static vec<operand *>
lower_cond(operand * o)1154 lower_cond (operand *o)
1155 {
1156   vec<operand *> ro = vNULL;
1157 
1158   if (capture *c = dyn_cast<capture *> (o))
1159     {
1160       if (c->what)
1161           {
1162             vec<operand *> lop = vNULL;
1163             lop = lower_cond (c->what);
1164 
1165             for (unsigned i = 0; i < lop.length (); ++i)
1166               ro.safe_push (new capture (c->location, c->where, lop[i],
1167                                                c->value_match));
1168             return ro;
1169           }
1170     }
1171 
1172   expr *e = dyn_cast<expr *> (o);
1173   if (!e || e->ops.length () == 0)
1174     {
1175       ro.safe_push (o);
1176       return ro;
1177     }
1178 
1179   vec< vec<operand *> > ops_vector = vNULL;
1180   for (unsigned i = 0; i < e->ops.length (); ++i)
1181     ops_vector.safe_push (lower_cond (e->ops[i]));
1182 
1183   auto_vec< vec<operand *> > result;
1184   auto_vec<operand *> v (e->ops.length ());
1185   v.quick_grow_cleared (e->ops.length ());
1186   cartesian_product (ops_vector, result, v, 0);
1187 
1188   for (unsigned i = 0; i < result.length (); ++i)
1189     {
1190       expr *ne = new expr (e);
1191       for (unsigned j = 0; j < result[i].length (); ++j)
1192           ne->append_op (result[i][j]);
1193       ro.safe_push (ne);
1194       /* If this is a COND with a captured expression or an
1195          expression with two operands then also match a GENERIC
1196            form on the compare.  */
1197       if ((*e->operation == COND_EXPR
1198              || *e->operation == VEC_COND_EXPR)
1199             && ((is_a <capture *> (e->ops[0])
1200                  && as_a <capture *> (e->ops[0])->what
1201                  && is_a <expr *> (as_a <capture *> (e->ops[0])->what)
1202                  && as_a <expr *>
1203                       (as_a <capture *> (e->ops[0])->what)->ops.length () == 2)
1204                 || (is_a <expr *> (e->ops[0])
1205                       && as_a <expr *> (e->ops[0])->ops.length () == 2)))
1206           {
1207             expr *ne = new expr (e);
1208             for (unsigned j = 0; j < result[i].length (); ++j)
1209               ne->append_op (result[i][j]);
1210             if (capture *c = dyn_cast <capture *> (ne->ops[0]))
1211               {
1212                 expr *ocmp = as_a <expr *> (c->what);
1213                 expr *cmp = new expr (ocmp);
1214                 for (unsigned j = 0; j < ocmp->ops.length (); ++j)
1215                     cmp->append_op (ocmp->ops[j]);
1216                 cmp->is_generic = true;
1217                 ne->ops[0] = new capture (c->location, c->where, cmp,
1218                                                   c->value_match);
1219               }
1220             else
1221               {
1222                 expr *ocmp = as_a <expr *> (ne->ops[0]);
1223                 expr *cmp = new expr (ocmp);
1224                 for (unsigned j = 0; j < ocmp->ops.length (); ++j)
1225                     cmp->append_op (ocmp->ops[j]);
1226                 cmp->is_generic = true;
1227                 ne->ops[0] = cmp;
1228               }
1229             ro.safe_push (ne);
1230           }
1231     }
1232 
1233   return ro;
1234 }
1235 
1236 /* Lower the compare operand of COND_EXPRs and VEC_COND_EXPRs to a
1237    GENERIC and a GIMPLE variant.  */
1238 
1239 static void
lower_cond(simplify * s,vec<simplify * > & simplifiers)1240 lower_cond (simplify *s, vec<simplify *>& simplifiers)
1241 {
1242   vec<operand *> matchers = lower_cond (s->match);
1243   for (unsigned i = 0; i < matchers.length (); ++i)
1244     {
1245       simplify *ns = new simplify (s->kind, s->id, matchers[i], s->result,
1246                                            s->for_vec, s->capture_ids);
1247       simplifiers.safe_push (ns);
1248     }
1249 }
1250 
1251 /* Return true if O refers to ID.  */
1252 
1253 bool
contains_id(operand * o,user_id * id)1254 contains_id (operand *o, user_id *id)
1255 {
1256   if (capture *c = dyn_cast<capture *> (o))
1257     return c->what && contains_id (c->what, id);
1258 
1259   if (expr *e = dyn_cast<expr *> (o))
1260     {
1261       if (e->operation == id)
1262           return true;
1263       for (unsigned i = 0; i < e->ops.length (); ++i)
1264           if (contains_id (e->ops[i], id))
1265             return true;
1266       return false;
1267     }
1268 
1269   if (with_expr *w = dyn_cast <with_expr *> (o))
1270     return (contains_id (w->with, id)
1271               || contains_id (w->subexpr, id));
1272 
1273   if (if_expr *ife = dyn_cast <if_expr *> (o))
1274     return (contains_id (ife->cond, id)
1275               || contains_id (ife->trueexpr, id)
1276               || (ife->falseexpr && contains_id (ife->falseexpr, id)));
1277 
1278   if (c_expr *ce = dyn_cast<c_expr *> (o))
1279     return ce->capture_ids && ce->capture_ids->get (id->id);
1280 
1281   return false;
1282 }
1283 
1284 
1285 /* In AST operand O replace operator ID with operator WITH.  */
1286 
1287 operand *
replace_id(operand * o,user_id * id,id_base * with)1288 replace_id (operand *o, user_id *id, id_base *with)
1289 {
1290   /* Deep-copy captures and expressions, replacing operations as
1291      needed.  */
1292   if (capture *c = dyn_cast<capture *> (o))
1293     {
1294       if (!c->what)
1295           return c;
1296       return new capture (c->location, c->where,
1297                                 replace_id (c->what, id, with), c->value_match);
1298     }
1299   else if (expr *e = dyn_cast<expr *> (o))
1300     {
1301       expr *ne = new expr (e);
1302       if (e->operation == id)
1303           ne->operation = with;
1304       for (unsigned i = 0; i < e->ops.length (); ++i)
1305           ne->append_op (replace_id (e->ops[i], id, with));
1306       return ne;
1307     }
1308   else if (with_expr *w = dyn_cast <with_expr *> (o))
1309     {
1310       with_expr *nw = new with_expr (w->location);
1311       nw->with = as_a <c_expr *> (replace_id (w->with, id, with));
1312       nw->subexpr = replace_id (w->subexpr, id, with);
1313       return nw;
1314     }
1315   else if (if_expr *ife = dyn_cast <if_expr *> (o))
1316     {
1317       if_expr *nife = new if_expr (ife->location);
1318       nife->cond = as_a <c_expr *> (replace_id (ife->cond, id, with));
1319       nife->trueexpr = replace_id (ife->trueexpr, id, with);
1320       if (ife->falseexpr)
1321           nife->falseexpr = replace_id (ife->falseexpr, id, with);
1322       return nife;
1323     }
1324 
1325   /* For c_expr we simply record a string replacement table which is
1326      applied at code-generation time.  */
1327   if (c_expr *ce = dyn_cast<c_expr *> (o))
1328     {
1329       vec<c_expr::id_tab> ids = ce->ids.copy ();
1330       ids.safe_push (c_expr::id_tab (id->id, with->id));
1331       return new c_expr (ce->r, ce->location,
1332                                ce->code, ce->nr_stmts, ids, ce->capture_ids);
1333     }
1334 
1335   return o;
1336 }
1337 
1338 /* Return true if the binary operator OP is ok for delayed substitution
1339    during for lowering.  */
1340 
1341 static bool
binary_ok(operator_id * op)1342 binary_ok (operator_id *op)
1343 {
1344   switch (op->code)
1345     {
1346     case PLUS_EXPR:
1347     case MINUS_EXPR:
1348     case MULT_EXPR:
1349     case TRUNC_DIV_EXPR:
1350     case CEIL_DIV_EXPR:
1351     case FLOOR_DIV_EXPR:
1352     case ROUND_DIV_EXPR:
1353     case TRUNC_MOD_EXPR:
1354     case CEIL_MOD_EXPR:
1355     case FLOOR_MOD_EXPR:
1356     case ROUND_MOD_EXPR:
1357     case RDIV_EXPR:
1358     case EXACT_DIV_EXPR:
1359     case MIN_EXPR:
1360     case MAX_EXPR:
1361     case BIT_IOR_EXPR:
1362     case BIT_XOR_EXPR:
1363     case BIT_AND_EXPR:
1364       return true;
1365     default:
1366       return false;
1367     }
1368 }
1369 
1370 /* Lower recorded fors for SIN and output to SIMPLIFIERS.  */
1371 
1372 static void
lower_for(simplify * sin,vec<simplify * > & simplifiers)1373 lower_for (simplify *sin, vec<simplify *>& simplifiers)
1374 {
1375   vec<vec<user_id *> >& for_vec = sin->for_vec;
1376   unsigned worklist_start = 0;
1377   auto_vec<simplify *> worklist;
1378   worklist.safe_push (sin);
1379 
1380   /* Lower each recorded for separately, operating on the
1381      set of simplifiers created by the previous one.
1382      Lower inner-to-outer so inner for substitutes can refer
1383      to operators replaced by outer fors.  */
1384   for (int fi = for_vec.length () - 1; fi >= 0; --fi)
1385     {
1386       vec<user_id *>& ids = for_vec[fi];
1387       unsigned n_ids = ids.length ();
1388       unsigned max_n_opers = 0;
1389       bool can_delay_subst = (sin->kind == simplify::SIMPLIFY);
1390       for (unsigned i = 0; i < n_ids; ++i)
1391           {
1392             if (ids[i]->substitutes.length () > max_n_opers)
1393               max_n_opers = ids[i]->substitutes.length ();
1394             /* Require that all substitutes are of the same kind so that
1395                if we delay substitution to the result op code generation
1396                can look at the first substitute for deciding things like
1397                types of operands.  */
1398             enum id_base::id_kind kind = ids[i]->substitutes[0]->kind;
1399             for (unsigned j = 0; j < ids[i]->substitutes.length (); ++j)
1400               if (ids[i]->substitutes[j]->kind != kind)
1401                 can_delay_subst = false;
1402               else if (operator_id *op
1403                            = dyn_cast <operator_id *> (ids[i]->substitutes[j]))
1404                 {
1405                     operator_id *op0
1406                       = as_a <operator_id *> (ids[i]->substitutes[0]);
1407                     if (strcmp (op->tcc, "tcc_comparison") == 0
1408                         && strcmp (op0->tcc, "tcc_comparison") == 0)
1409                       ;
1410                     /* Unfortunately we can't just allow all tcc_binary.  */
1411                     else if (strcmp (op->tcc, "tcc_binary") == 0
1412                                && strcmp (op0->tcc, "tcc_binary") == 0
1413                                && binary_ok (op)
1414                                && binary_ok (op0))
1415                       ;
1416                     else if ((strcmp (op->id + 1, "SHIFT_EXPR") == 0
1417                                 || strcmp (op->id + 1, "ROTATE_EXPR") == 0)
1418                                && (strcmp (op0->id + 1, "SHIFT_EXPR") == 0
1419                                    || strcmp (op0->id + 1, "ROTATE_EXPR") == 0))
1420                       ;
1421                     else
1422                       can_delay_subst = false;
1423                 }
1424               else if (is_a <fn_id *> (ids[i]->substitutes[j]))
1425                 ;
1426               else
1427                 can_delay_subst = false;
1428           }
1429 
1430       unsigned worklist_end = worklist.length ();
1431       for (unsigned si = worklist_start; si < worklist_end; ++si)
1432           {
1433             simplify *s = worklist[si];
1434             for (unsigned j = 0; j < max_n_opers; ++j)
1435               {
1436                 operand *match_op = s->match;
1437                 operand *result_op = s->result;
1438                 auto_vec<std::pair<user_id *, id_base *> > subst (n_ids);
1439                 bool skip = false;
1440                 for (unsigned i = 0; i < n_ids; ++i)
1441                     {
1442                       user_id *id = ids[i];
1443                       id_base *oper = id->substitutes[j % id->substitutes.length ()];
1444                       if (oper == null_id
1445                           && (contains_id (match_op, id)
1446                                 || contains_id (result_op, id)))
1447                         {
1448                           skip = true;
1449                           break;
1450                         }
1451                       subst.quick_push (std::make_pair (id, oper));
1452                       match_op = replace_id (match_op, id, oper);
1453                       if (result_op
1454                           && !can_delay_subst)
1455                         result_op = replace_id (result_op, id, oper);
1456                     }
1457                 if (skip)
1458                     continue;
1459 
1460                 simplify *ns = new simplify (s->kind, s->id, match_op, result_op,
1461                                                      vNULL, s->capture_ids);
1462                 ns->for_subst_vec.safe_splice (s->for_subst_vec);
1463                 if (result_op
1464                       && can_delay_subst)
1465                     ns->for_subst_vec.safe_splice (subst);
1466 
1467                 worklist.safe_push (ns);
1468               }
1469           }
1470       worklist_start = worklist_end;
1471     }
1472 
1473   /* Copy out the result from the last for lowering.  */
1474   for (unsigned i = worklist_start; i < worklist.length (); ++i)
1475     simplifiers.safe_push (worklist[i]);
1476 }
1477 
1478 /* Lower the AST for everything in SIMPLIFIERS.  */
1479 
1480 static void
lower(vec<simplify * > & simplifiers,bool gimple)1481 lower (vec<simplify *>& simplifiers, bool gimple)
1482 {
1483   auto_vec<simplify *> out_simplifiers;
1484   for (unsigned i = 0; i < simplifiers.length (); ++i)
1485     lower_opt_convert (simplifiers[i], out_simplifiers);
1486 
1487   simplifiers.truncate (0);
1488   for (unsigned i = 0; i < out_simplifiers.length (); ++i)
1489     lower_commutative (out_simplifiers[i], simplifiers);
1490 
1491   out_simplifiers.truncate (0);
1492   if (gimple)
1493     for (unsigned i = 0; i < simplifiers.length (); ++i)
1494       lower_cond (simplifiers[i], out_simplifiers);
1495   else
1496     out_simplifiers.safe_splice (simplifiers);
1497 
1498 
1499   simplifiers.truncate (0);
1500   for (unsigned i = 0; i < out_simplifiers.length (); ++i)
1501     lower_for (out_simplifiers[i], simplifiers);
1502 }
1503 
1504 
1505 
1506 
1507 /* The decision tree built for generating GIMPLE and GENERIC pattern
1508    matching code.  It represents the 'match' expression of all
1509    simplifies and has those as its leafs.  */
1510 
1511 struct dt_simplify;
1512 
1513 /* A hash-map collecting semantically equivalent leafs in the decision
1514    tree for splitting out to separate functions.  */
1515 struct sinfo
1516 {
1517   dt_simplify *s;
1518 
1519   const char *fname;
1520   unsigned cnt;
1521 };
1522 
1523 struct sinfo_hashmap_traits : simple_hashmap_traits<pointer_hash<dt_simplify>,
1524                                                                 sinfo *>
1525 {
1526   static inline hashval_t hash (const key_type &);
1527   static inline bool equal_keys (const key_type &, const key_type &);
removesinfo_hashmap_traits1528   template <typename T> static inline void remove (T &) {}
1529 };
1530 
1531 typedef hash_map<void * /* unused */, sinfo *, sinfo_hashmap_traits>
1532   sinfo_map_t;
1533 
1534 /* Current simplifier ID we are processing during insertion into the
1535    decision tree.  */
1536 static unsigned current_id;
1537 
1538 /* Decision tree base class, used for DT_NODE.  */
1539 
1540 struct dt_node
1541 {
1542   enum dt_type { DT_NODE, DT_OPERAND, DT_TRUE, DT_MATCH, DT_SIMPLIFY };
1543 
1544   enum dt_type type;
1545   unsigned level;
1546   dt_node *parent;
1547   vec<dt_node *> kids;
1548 
1549   /* Statistics.  */
1550   unsigned num_leafs;
1551   unsigned total_size;
1552   unsigned max_level;
1553 
dt_nodedt_node1554   dt_node (enum dt_type type_, dt_node *parent_)
1555     : type (type_), level (0), parent (parent_), kids (vNULL) {}
1556 
1557   dt_node *append_node (dt_node *);
1558   dt_node *append_op (operand *, dt_node *parent, unsigned pos);
1559   dt_node *append_true_op (operand *, dt_node *parent, unsigned pos);
1560   dt_node *append_match_op (operand *, dt_operand *, dt_node *parent,
1561                                   unsigned pos);
1562   dt_node *append_simplify (simplify *, unsigned, dt_operand **);
1563 
gendt_node1564   virtual void gen (FILE *, int, bool) {}
1565 
1566   void gen_kids (FILE *, int, bool);
1567   void gen_kids_1 (FILE *, int, bool,
1568                        vec<dt_operand *>, vec<dt_operand *>, vec<dt_operand *>,
1569                        vec<dt_operand *>, vec<dt_operand *>, vec<dt_node *>);
1570 
1571   void analyze (sinfo_map_t &);
1572 };
1573 
1574 /* Generic decision tree node used for DT_OPERAND, DT_MATCH and DT_TRUE.  */
1575 
1576 struct dt_operand : public dt_node
1577 {
1578   operand *op;
1579   dt_operand *match_dop;
1580   unsigned pos;
1581   bool value_match;
1582   unsigned for_id;
1583 
dt_operanddt_operand1584   dt_operand (enum dt_type type, operand *op_, dt_operand *match_dop_,
1585                 dt_operand *parent_, unsigned pos_)
1586       : dt_node (type, parent_), op (op_), match_dop (match_dop_),
1587       pos (pos_), value_match (false), for_id (current_id) {}
1588 
1589   void gen (FILE *, int, bool);
1590   unsigned gen_predicate (FILE *, int, const char *, bool);
1591   unsigned gen_match_op (FILE *, int, const char *, bool);
1592 
1593   unsigned gen_gimple_expr (FILE *, int);
1594   unsigned gen_generic_expr (FILE *, int, const char *);
1595 
1596   char *get_name (char *);
1597   void gen_opname (char *, unsigned);
1598 };
1599 
1600 /* Leaf node of the decision tree, used for DT_SIMPLIFY.  */
1601 
1602 struct dt_simplify : public dt_node
1603 {
1604   simplify *s;
1605   unsigned pattern_no;
1606   dt_operand **indexes;
1607   sinfo *info;
1608 
dt_simplifydt_simplify1609   dt_simplify (simplify *s_, unsigned pattern_no_, dt_operand **indexes_)
1610           : dt_node (DT_SIMPLIFY, NULL), s (s_), pattern_no (pattern_no_),
1611             indexes (indexes_), info (NULL)  {}
1612 
1613   void gen_1 (FILE *, int, bool, operand *);
1614   void gen (FILE *f, int, bool);
1615 };
1616 
1617 template<>
1618 template<>
1619 inline bool
test(dt_node * n)1620 is_a_helper <dt_operand *>::test (dt_node *n)
1621 {
1622   return (n->type == dt_node::DT_OPERAND
1623             || n->type == dt_node::DT_MATCH
1624             || n->type == dt_node::DT_TRUE);
1625 }
1626 
1627 template<>
1628 template<>
1629 inline bool
test(dt_node * n)1630 is_a_helper <dt_simplify *>::test (dt_node *n)
1631 {
1632   return n->type == dt_node::DT_SIMPLIFY;
1633 }
1634 
1635 
1636 
1637 /* A container for the actual decision tree.  */
1638 
1639 struct decision_tree
1640 {
1641   dt_node *root;
1642 
1643   void insert (struct simplify *, unsigned);
1644   void gen (FILE *f, bool gimple);
1645   void print (FILE *f = stderr);
1646 
decision_treedecision_tree1647   decision_tree () { root = new dt_node (dt_node::DT_NODE, NULL); }
1648 
1649   static dt_node *insert_operand (dt_node *, operand *, dt_operand **indexes,
1650                                           unsigned pos = 0, dt_node *parent = 0);
1651   static dt_node *find_node (vec<dt_node *>&, dt_node *);
1652   static bool cmp_node (dt_node *, dt_node *);
1653   static void print_node (dt_node *, FILE *f = stderr, unsigned = 0);
1654 };
1655 
1656 /* Compare two AST operands O1 and O2 and return true if they are equal.  */
1657 
1658 bool
cmp_operand(operand * o1,operand * o2)1659 cmp_operand (operand *o1, operand *o2)
1660 {
1661   if (!o1 || !o2 || o1->type != o2->type)
1662     return false;
1663 
1664   if (o1->type == operand::OP_PREDICATE)
1665     {
1666       predicate *p1 = as_a<predicate *>(o1);
1667       predicate *p2 = as_a<predicate *>(o2);
1668       return p1->p == p2->p;
1669     }
1670   else if (o1->type == operand::OP_EXPR)
1671     {
1672       expr *e1 = static_cast<expr *>(o1);
1673       expr *e2 = static_cast<expr *>(o2);
1674       return (e1->operation == e2->operation
1675                 && e1->is_generic == e2->is_generic);
1676     }
1677   else
1678     return false;
1679 }
1680 
1681 /* Compare two decision tree nodes N1 and N2 and return true if they
1682    are equal.  */
1683 
1684 bool
cmp_node(dt_node * n1,dt_node * n2)1685 decision_tree::cmp_node (dt_node *n1, dt_node *n2)
1686 {
1687   if (!n1 || !n2 || n1->type != n2->type)
1688     return false;
1689 
1690   if (n1 == n2)
1691     return true;
1692 
1693   if (n1->type == dt_node::DT_TRUE)
1694     return false;
1695 
1696   if (n1->type == dt_node::DT_OPERAND)
1697     return cmp_operand ((as_a<dt_operand *> (n1))->op,
1698                               (as_a<dt_operand *> (n2))->op);
1699   else if (n1->type == dt_node::DT_MATCH)
1700     return (((as_a<dt_operand *> (n1))->match_dop
1701                == (as_a<dt_operand *> (n2))->match_dop)
1702               && ((as_a<dt_operand *> (n1))->value_match
1703                     == (as_a<dt_operand *> (n2))->value_match));
1704   return false;
1705 }
1706 
1707 /* Search OPS for a decision tree node like P and return it if found.  */
1708 
1709 dt_node *
find_node(vec<dt_node * > & ops,dt_node * p)1710 decision_tree::find_node (vec<dt_node *>& ops, dt_node *p)
1711 {
1712   /* We can merge adjacent DT_TRUE.  */
1713   if (p->type == dt_node::DT_TRUE
1714       && !ops.is_empty ()
1715       && ops.last ()->type == dt_node::DT_TRUE)
1716     return ops.last ();
1717   dt_operand *true_node = NULL;
1718   for (int i = ops.length () - 1; i >= 0; --i)
1719     {
1720       /* But we can't merge across DT_TRUE nodes as they serve as
1721          pattern order barriers to make sure that patterns apply
1722            in order of appearance in case multiple matches are possible.  */
1723       if (ops[i]->type == dt_node::DT_TRUE)
1724           {
1725             if (! true_node
1726                 || as_a <dt_operand *> (ops[i])->for_id > true_node->for_id)
1727               true_node = as_a <dt_operand *> (ops[i]);
1728           }
1729       if (decision_tree::cmp_node (ops[i], p))
1730           {
1731             /* Unless we are processing the same pattern or the blocking
1732                pattern is before the one we are going to merge with.  */
1733             if (true_node
1734                 && true_node->for_id != current_id
1735                 && true_node->for_id > as_a <dt_operand *> (ops[i])->for_id)
1736               {
1737                 if (verbose >= 1)
1738                     {
1739                       source_location p_loc = 0;
1740                       if (p->type == dt_node::DT_OPERAND)
1741                         p_loc = as_a <dt_operand *> (p)->op->location;
1742                       source_location op_loc = 0;
1743                       if (ops[i]->type == dt_node::DT_OPERAND)
1744                         op_loc = as_a <dt_operand *> (ops[i])->op->location;
1745                       source_location true_loc = 0;
1746                       true_loc = true_node->op->location;
1747                       warning_at (p_loc,
1748                                     "failed to merge decision tree node");
1749                       warning_at (op_loc,
1750                                     "with the following");
1751                       warning_at (true_loc,
1752                                     "because of the following which serves as ordering "
1753                                     "barrier");
1754                     }
1755                 return NULL;
1756               }
1757             return ops[i];
1758           }
1759     }
1760   return NULL;
1761 }
1762 
1763 /* Append N to the decision tree if it there is not already an existing
1764    identical child.  */
1765 
1766 dt_node *
append_node(dt_node * n)1767 dt_node::append_node (dt_node *n)
1768 {
1769   dt_node *kid;
1770 
1771   kid = decision_tree::find_node (kids, n);
1772   if (kid)
1773     return kid;
1774 
1775   kids.safe_push (n);
1776   n->level = this->level + 1;
1777 
1778   return n;
1779 }
1780 
1781 /* Append OP to the decision tree.  */
1782 
1783 dt_node *
append_op(operand * op,dt_node * parent,unsigned pos)1784 dt_node::append_op (operand *op, dt_node *parent, unsigned pos)
1785 {
1786   dt_operand *parent_ = safe_as_a<dt_operand *> (parent);
1787   dt_operand *n = new dt_operand (DT_OPERAND, op, 0, parent_, pos);
1788   return append_node (n);
1789 }
1790 
1791 /* Append a DT_TRUE decision tree node.  */
1792 
1793 dt_node *
append_true_op(operand * op,dt_node * parent,unsigned pos)1794 dt_node::append_true_op (operand *op, dt_node *parent, unsigned pos)
1795 {
1796   dt_operand *parent_ = safe_as_a<dt_operand *> (parent);
1797   dt_operand *n = new dt_operand (DT_TRUE, op, 0, parent_, pos);
1798   return append_node (n);
1799 }
1800 
1801 /* Append a DT_MATCH decision tree node.  */
1802 
1803 dt_node *
append_match_op(operand * op,dt_operand * match_dop,dt_node * parent,unsigned pos)1804 dt_node::append_match_op (operand *op, dt_operand *match_dop,
1805                                 dt_node *parent, unsigned pos)
1806 {
1807   dt_operand *parent_ = as_a<dt_operand *> (parent);
1808   dt_operand *n = new dt_operand (DT_MATCH, op, match_dop, parent_, pos);
1809   return append_node (n);
1810 }
1811 
1812 /* Append S to the decision tree.  */
1813 
1814 dt_node *
append_simplify(simplify * s,unsigned pattern_no,dt_operand ** indexes)1815 dt_node::append_simplify (simplify *s, unsigned pattern_no,
1816                                 dt_operand **indexes)
1817 {
1818   dt_simplify *n = new dt_simplify (s, pattern_no, indexes);
1819   for (unsigned i = 0; i < kids.length (); ++i)
1820     if (dt_simplify *s2 = dyn_cast <dt_simplify *> (kids[i]))
1821       {
1822           warning_at (s->match->location, "duplicate pattern");
1823           warning_at (s2->s->match->location, "previous pattern defined here");
1824           print_operand (s->match, stderr);
1825           fprintf (stderr, "\n");
1826       }
1827   return append_node (n);
1828 }
1829 
1830 /* Analyze the node and its children.  */
1831 
1832 void
analyze(sinfo_map_t & map)1833 dt_node::analyze (sinfo_map_t &map)
1834 {
1835   num_leafs = 0;
1836   total_size = 1;
1837   max_level = level;
1838 
1839   if (type == DT_SIMPLIFY)
1840     {
1841       /* Populate the map of equivalent simplifies.  */
1842       dt_simplify *s = as_a <dt_simplify *> (this);
1843       bool existed;
1844       sinfo *&si = map.get_or_insert (s, &existed);
1845       if (!existed)
1846           {
1847             si = new sinfo;
1848             si->s = s;
1849             si->cnt = 1;
1850             si->fname = NULL;
1851           }
1852       else
1853           si->cnt++;
1854       s->info = si;
1855       num_leafs = 1;
1856       return;
1857     }
1858 
1859   for (unsigned i = 0; i < kids.length (); ++i)
1860     {
1861       kids[i]->analyze (map);
1862       num_leafs += kids[i]->num_leafs;
1863       total_size += kids[i]->total_size;
1864       max_level = MAX (max_level, kids[i]->max_level);
1865     }
1866 }
1867 
1868 /* Insert O into the decision tree and return the decision tree node found
1869    or created.  */
1870 
1871 dt_node *
insert_operand(dt_node * p,operand * o,dt_operand ** indexes,unsigned pos,dt_node * parent)1872 decision_tree::insert_operand (dt_node *p, operand *o, dt_operand **indexes,
1873                                      unsigned pos, dt_node *parent)
1874 {
1875   dt_node *q, *elm = 0;
1876 
1877   if (capture *c = dyn_cast<capture *> (o))
1878     {
1879       unsigned capt_index = c->where;
1880 
1881       if (indexes[capt_index] == 0)
1882           {
1883             if (c->what)
1884               q = insert_operand (p, c->what, indexes, pos, parent);
1885             else
1886               {
1887                 q = elm = p->append_true_op (o, parent, pos);
1888                 goto at_assert_elm;
1889               }
1890             // get to the last capture
1891             for (operand *what = c->what;
1892                  what && is_a<capture *> (what);
1893                  c = as_a<capture *> (what), what = c->what)
1894               ;
1895 
1896             if (!c->what)
1897               {
1898                 unsigned cc_index = c->where;
1899                 dt_operand *match_op = indexes[cc_index];
1900 
1901                 dt_operand temp (dt_node::DT_TRUE, 0, 0, 0, 0);
1902                 elm = decision_tree::find_node (p->kids, &temp);
1903 
1904                 if (elm == 0)
1905                     {
1906                       dt_operand temp (dt_node::DT_MATCH, 0, match_op, 0, 0);
1907                       temp.value_match = c->value_match;
1908                       elm = decision_tree::find_node (p->kids, &temp);
1909                     }
1910               }
1911             else
1912               {
1913                 dt_operand temp (dt_node::DT_OPERAND, c->what, 0, 0, 0);
1914                 elm = decision_tree::find_node (p->kids, &temp);
1915               }
1916 
1917 at_assert_elm:
1918             gcc_assert (elm->type == dt_node::DT_TRUE
1919                           || elm->type == dt_node::DT_OPERAND
1920                           || elm->type == dt_node::DT_MATCH);
1921             indexes[capt_index] = static_cast<dt_operand *> (elm);
1922             return q;
1923           }
1924       else
1925           {
1926             p = p->append_match_op (o, indexes[capt_index], parent, pos);
1927             as_a <dt_operand *>(p)->value_match = c->value_match;
1928             if (c->what)
1929               return insert_operand (p, c->what, indexes, 0, p);
1930             else
1931               return p;
1932           }
1933     }
1934   p = p->append_op (o, parent, pos);
1935   q = p;
1936 
1937   if (expr *e = dyn_cast <expr *>(o))
1938     {
1939       for (unsigned i = 0; i < e->ops.length (); ++i)
1940           q = decision_tree::insert_operand (q, e->ops[i], indexes, i, p);
1941     }
1942 
1943   return q;
1944 }
1945 
1946 /* Insert S into the decision tree.  */
1947 
1948 void
insert(struct simplify * s,unsigned pattern_no)1949 decision_tree::insert (struct simplify *s, unsigned pattern_no)
1950 {
1951   current_id = s->id;
1952   dt_operand **indexes = XCNEWVEC (dt_operand *, s->capture_max + 1);
1953   dt_node *p = decision_tree::insert_operand (root, s->match, indexes);
1954   p->append_simplify (s, pattern_no, indexes);
1955 }
1956 
1957 /* Debug functions to dump the decision tree.  */
1958 
1959 DEBUG_FUNCTION void
print_node(dt_node * p,FILE * f,unsigned indent)1960 decision_tree::print_node (dt_node *p, FILE *f, unsigned indent)
1961 {
1962   if (p->type == dt_node::DT_NODE)
1963     fprintf (f, "root");
1964   else
1965     {
1966       fprintf (f, "|");
1967       for (unsigned i = 0; i < indent; i++)
1968           fprintf (f, "-");
1969 
1970       if (p->type == dt_node::DT_OPERAND)
1971           {
1972             dt_operand *dop = static_cast<dt_operand *>(p);
1973             print_operand (dop->op, f, true);
1974           }
1975       else if (p->type == dt_node::DT_TRUE)
1976           fprintf (f, "true");
1977       else if (p->type == dt_node::DT_MATCH)
1978           fprintf (f, "match (%p)", (void *)((as_a<dt_operand *>(p))->match_dop));
1979       else if (p->type == dt_node::DT_SIMPLIFY)
1980           {
1981             dt_simplify *s = static_cast<dt_simplify *> (p);
1982             fprintf (f, "simplify_%u { ", s->pattern_no);
1983             for (int i = 0; i <= s->s->capture_max; ++i)
1984               fprintf (f, "%p, ", (void *) s->indexes[i]);
1985             fprintf (f, " } ");
1986           }
1987       if (is_a <dt_operand *> (p))
1988           fprintf (f, " [%u]", as_a <dt_operand *> (p)->for_id);
1989     }
1990 
1991   fprintf (stderr, " (%p, %p), %u, %u\n",
1992              (void *) p, (void *) p->parent, p->level, p->kids.length ());
1993 
1994   for (unsigned i = 0; i < p->kids.length (); ++i)
1995     decision_tree::print_node (p->kids[i], f, indent + 2);
1996 }
1997 
1998 DEBUG_FUNCTION void
print(FILE * f)1999 decision_tree::print (FILE *f)
2000 {
2001   return decision_tree::print_node (root, f);
2002 }
2003 
2004 
2005 /* For GENERIC we have to take care of wrapping multiple-used
2006    expressions with side-effects in save_expr and preserve side-effects
2007    of expressions with omit_one_operand.  Analyze captures in
2008    match, result and with expressions and perform early-outs
2009    on the outermost match expression operands for cases we cannot
2010    handle.  */
2011 
2012 struct capture_info
2013 {
2014   capture_info (simplify *s, operand *, bool);
2015   void walk_match (operand *o, unsigned toplevel_arg, bool, bool);
2016   bool walk_result (operand *o, bool, operand *);
2017   void walk_c_expr (c_expr *);
2018 
2019   struct cinfo
2020     {
2021       bool expr_p;
2022       bool cse_p;
2023       bool force_no_side_effects_p;
2024       bool force_single_use;
2025       bool cond_expr_cond_p;
2026       unsigned long toplevel_msk;
2027       unsigned match_use_count;
2028       unsigned result_use_count;
2029       unsigned same_as;
2030       capture *c;
2031     };
2032 
2033   auto_vec<cinfo> info;
2034   unsigned long force_no_side_effects;
2035   bool gimple;
2036 };
2037 
2038 /* Analyze captures in S.  */
2039 
capture_info(simplify * s,operand * result,bool gimple_)2040 capture_info::capture_info (simplify *s, operand *result, bool gimple_)
2041 {
2042   gimple = gimple_;
2043 
2044   expr *e;
2045   if (s->kind == simplify::MATCH)
2046     {
2047       force_no_side_effects = -1;
2048       return;
2049     }
2050 
2051   force_no_side_effects = 0;
2052   info.safe_grow_cleared (s->capture_max + 1);
2053   for (int i = 0; i <= s->capture_max; ++i)
2054     info[i].same_as = i;
2055 
2056   e = as_a <expr *> (s->match);
2057   for (unsigned i = 0; i < e->ops.length (); ++i)
2058     walk_match (e->ops[i], i,
2059                     (i != 0 && *e->operation == COND_EXPR)
2060                     || *e->operation == TRUTH_ANDIF_EXPR
2061                     || *e->operation == TRUTH_ORIF_EXPR,
2062                     i == 0
2063                     && (*e->operation == COND_EXPR
2064                         || *e->operation == VEC_COND_EXPR));
2065 
2066   walk_result (s->result, false, result);
2067 }
2068 
2069 /* Analyze captures in the match expression piece O.  */
2070 
2071 void
walk_match(operand * o,unsigned toplevel_arg,bool conditional_p,bool cond_expr_cond_p)2072 capture_info::walk_match (operand *o, unsigned toplevel_arg,
2073                                 bool conditional_p, bool cond_expr_cond_p)
2074 {
2075   if (capture *c = dyn_cast <capture *> (o))
2076     {
2077       unsigned where = c->where;
2078       info[where].match_use_count++;
2079       info[where].toplevel_msk |= 1 << toplevel_arg;
2080       info[where].force_no_side_effects_p |= conditional_p;
2081       info[where].cond_expr_cond_p |= cond_expr_cond_p;
2082       if (!info[where].c)
2083           info[where].c = c;
2084       if (!c->what)
2085           return;
2086       /* Recurse to exprs and captures.  */
2087       if (is_a <capture *> (c->what)
2088             || is_a <expr *> (c->what))
2089           walk_match (c->what, toplevel_arg, conditional_p, false);
2090       /* We need to look past multiple captures to find a captured
2091            expression as with conditional converts two captures
2092            can be collapsed onto the same expression.  Also collect
2093            what captures capture the same thing.  */
2094       while (c->what && is_a <capture *> (c->what))
2095           {
2096             c = as_a <capture *> (c->what);
2097             if (info[c->where].same_as != c->where
2098                 && info[c->where].same_as != info[where].same_as)
2099               fatal_at (c->location, "cannot handle this collapsed capture");
2100             info[c->where].same_as = info[where].same_as;
2101           }
2102       /* Mark expr (non-leaf) captures and forced single-use exprs.  */
2103       expr *e;
2104       if (c->what
2105             && (e = dyn_cast <expr *> (c->what)))
2106           {
2107             /* Zero-operand expression captures like ADDR_EXPR@0 are
2108                similar as predicates -- if they are not mentioned in
2109                the result we have to force them to have no side-effects.  */
2110             if (e->ops.length () != 0)
2111               info[where].expr_p = true;
2112             info[where].force_single_use |= e->force_single_use;
2113           }
2114     }
2115   else if (expr *e = dyn_cast <expr *> (o))
2116     {
2117       for (unsigned i = 0; i < e->ops.length (); ++i)
2118           {
2119             bool cond_p = conditional_p;
2120             bool cond_expr_cond_p = false;
2121             if (i != 0 && *e->operation == COND_EXPR)
2122               cond_p = true;
2123             else if (*e->operation == TRUTH_ANDIF_EXPR
2124                        || *e->operation == TRUTH_ORIF_EXPR)
2125               cond_p = true;
2126             if (i == 0
2127                 && (*e->operation == COND_EXPR
2128                       || *e->operation == VEC_COND_EXPR))
2129               cond_expr_cond_p = true;
2130             walk_match (e->ops[i], toplevel_arg, cond_p, cond_expr_cond_p);
2131           }
2132     }
2133   else if (is_a <predicate *> (o))
2134     {
2135       /* Mark non-captured leafs toplevel arg for checking.  */
2136       force_no_side_effects |= 1 << toplevel_arg;
2137       if (verbose >= 1
2138             && !gimple)
2139           warning_at (o->location,
2140                         "forcing no side-effects on possibly lost leaf");
2141     }
2142   else
2143     gcc_unreachable ();
2144 }
2145 
2146 /* Analyze captures in the result expression piece O.  Return true
2147    if RESULT was visited in one of the children.  Only visit
2148    non-if/with children if they are rooted on RESULT.  */
2149 
2150 bool
walk_result(operand * o,bool conditional_p,operand * result)2151 capture_info::walk_result (operand *o, bool conditional_p, operand *result)
2152 {
2153   if (capture *c = dyn_cast <capture *> (o))
2154     {
2155       unsigned where = info[c->where].same_as;
2156       info[where].result_use_count++;
2157       /* If we substitute an expression capture we don't know
2158          which captures this will end up using (well, we don't
2159            compute that).  Force the uses to be side-effect free
2160            which means forcing the toplevels that reach the
2161            expression side-effect free.  */
2162       if (info[where].expr_p)
2163           force_no_side_effects |= info[where].toplevel_msk;
2164       /* Mark CSE capture uses as forced to have no side-effects. */
2165       if (c->what
2166             && is_a <expr *> (c->what))
2167           {
2168             info[where].cse_p = true;
2169             walk_result (c->what, true, result);
2170           }
2171     }
2172   else if (expr *e = dyn_cast <expr *> (o))
2173     {
2174       id_base *opr = e->operation;
2175       if (user_id *uid = dyn_cast <user_id *> (opr))
2176           opr = uid->substitutes[0];
2177       for (unsigned i = 0; i < e->ops.length (); ++i)
2178           {
2179             bool cond_p = conditional_p;
2180             if (i != 0 && *e->operation == COND_EXPR)
2181               cond_p = true;
2182             else if (*e->operation == TRUTH_ANDIF_EXPR
2183                        || *e->operation == TRUTH_ORIF_EXPR)
2184               cond_p = true;
2185             walk_result (e->ops[i], cond_p, result);
2186           }
2187     }
2188   else if (if_expr *e = dyn_cast <if_expr *> (o))
2189     {
2190       /* 'if' conditions should be all fine.  */
2191       if (e->trueexpr == result)
2192           {
2193             walk_result (e->trueexpr, false, result);
2194             return true;
2195           }
2196       if (e->falseexpr == result)
2197           {
2198             walk_result (e->falseexpr, false, result);
2199             return true;
2200           }
2201       bool res = false;
2202       if (is_a <if_expr *> (e->trueexpr)
2203             || is_a <with_expr *> (e->trueexpr))
2204           res |= walk_result (e->trueexpr, false, result);
2205       if (e->falseexpr
2206             && (is_a <if_expr *> (e->falseexpr)
2207                 || is_a <with_expr *> (e->falseexpr)))
2208           res |= walk_result (e->falseexpr, false, result);
2209       return res;
2210     }
2211   else if (with_expr *e = dyn_cast <with_expr *> (o))
2212     {
2213       bool res = (e->subexpr == result);
2214       if (res
2215             || is_a <if_expr *> (e->subexpr)
2216             || is_a <with_expr *> (e->subexpr))
2217           res |= walk_result (e->subexpr, false, result);
2218       if (res)
2219           walk_c_expr (e->with);
2220       return res;
2221     }
2222   else if (c_expr *e = dyn_cast <c_expr *> (o))
2223     walk_c_expr (e);
2224   else
2225     gcc_unreachable ();
2226 
2227   return false;
2228 }
2229 
2230 /* Look for captures in the C expr E.  */
2231 
2232 void
walk_c_expr(c_expr * e)2233 capture_info::walk_c_expr (c_expr *e)
2234 {
2235   /* Give up for C exprs mentioning captures not inside TREE_TYPE,
2236      TREE_REAL_CST, TREE_CODE or a predicate where they cannot
2237      really escape through.  */
2238   unsigned p_depth = 0;
2239   for (unsigned i = 0; i < e->code.length (); ++i)
2240     {
2241       const cpp_token *t = &e->code[i];
2242       const cpp_token *n = i < e->code.length () - 1 ? &e->code[i+1] : NULL;
2243       id_base *id;
2244       if (t->type == CPP_NAME
2245             && (strcmp ((const char *)CPP_HASHNODE
2246                           (t->val.node.node)->ident.str, "TREE_TYPE") == 0
2247                 || strcmp ((const char *)CPP_HASHNODE
2248                                (t->val.node.node)->ident.str, "TREE_CODE") == 0
2249                 || strcmp ((const char *)CPP_HASHNODE
2250                                (t->val.node.node)->ident.str, "TREE_REAL_CST") == 0
2251                 || ((id = get_operator ((const char *)CPP_HASHNODE
2252                                               (t->val.node.node)->ident.str))
2253                       && is_a <predicate_id *> (id)))
2254             && n->type == CPP_OPEN_PAREN)
2255           p_depth++;
2256       else if (t->type == CPP_CLOSE_PAREN
2257                  && p_depth > 0)
2258           p_depth--;
2259       else if (p_depth == 0
2260                  && t->type == CPP_ATSIGN
2261                  && (n->type == CPP_NUMBER
2262                        || n->type == CPP_NAME)
2263                  && !(n->flags & PREV_WHITE))
2264           {
2265             const char *id;
2266             if (n->type == CPP_NUMBER)
2267               id = (const char *)n->val.str.text;
2268             else
2269               id = (const char *)CPP_HASHNODE (n->val.node.node)->ident.str;
2270             unsigned *where = e->capture_ids->get(id);
2271             if (! where)
2272               fatal_at (n, "unknown capture id '%s'", id);
2273             info[info[*where].same_as].force_no_side_effects_p = true;
2274             if (verbose >= 1
2275                 && !gimple)
2276               warning_at (t, "capture escapes");
2277           }
2278     }
2279 }
2280 
2281 
2282 /* Code generation off the decision tree and the refered AST nodes.  */
2283 
2284 bool
is_conversion(id_base * op)2285 is_conversion (id_base *op)
2286 {
2287   return (*op == CONVERT_EXPR
2288             || *op == NOP_EXPR
2289             || *op == FLOAT_EXPR
2290             || *op == FIX_TRUNC_EXPR
2291             || *op == VIEW_CONVERT_EXPR);
2292 }
2293 
2294 /* Get the type to be used for generating operand POS of OP from the
2295    various sources.  */
2296 
2297 static const char *
get_operand_type(id_base * op,unsigned pos,const char * in_type,const char * expr_type,const char * other_oprnd_type)2298 get_operand_type (id_base *op, unsigned pos,
2299                       const char *in_type,
2300                       const char *expr_type,
2301                       const char *other_oprnd_type)
2302 {
2303   /* Generally operands whose type does not match the type of the
2304      expression generated need to know their types but match and
2305      thus can fall back to 'other_oprnd_type'.  */
2306   if (is_conversion (op))
2307     return other_oprnd_type;
2308   else if (*op == REALPART_EXPR
2309              || *op == IMAGPART_EXPR)
2310     return other_oprnd_type;
2311   else if (is_a <operator_id *> (op)
2312              && strcmp (as_a <operator_id *> (op)->tcc, "tcc_comparison") == 0)
2313     return other_oprnd_type;
2314   else if (*op == COND_EXPR
2315              && pos == 0)
2316     return "boolean_type_node";
2317   else
2318     {
2319       /* Otherwise all types should match - choose one in order of
2320          preference.  */
2321       if (expr_type)
2322           return expr_type;
2323       else if (in_type)
2324           return in_type;
2325       else
2326           return other_oprnd_type;
2327     }
2328 }
2329 
2330 /* Generate transform code for an expression.  */
2331 
2332 void
gen_transform(FILE * f,int indent,const char * dest,bool gimple,int depth,const char * in_type,capture_info * cinfo,dt_operand ** indexes,int)2333 expr::gen_transform (FILE *f, int indent, const char *dest, bool gimple,
2334                          int depth, const char *in_type, capture_info *cinfo,
2335                          dt_operand **indexes, int)
2336 {
2337   id_base *opr = operation;
2338   /* When we delay operator substituting during lowering of fors we
2339      make sure that for code-gen purposes the effects of each substitute
2340      are the same.  Thus just look at that.  */
2341   if (user_id *uid = dyn_cast <user_id *> (opr))
2342     opr = uid->substitutes[0];
2343 
2344   bool conversion_p = is_conversion (opr);
2345   const char *type = expr_type;
2346   char optype[64];
2347   if (type)
2348     /* If there was a type specification in the pattern use it.  */
2349     ;
2350   else if (conversion_p)
2351     /* For conversions we need to build the expression using the
2352        outer type passed in.  */
2353     type = in_type;
2354   else if (*opr == REALPART_EXPR
2355              || *opr == IMAGPART_EXPR)
2356     {
2357       /* __real and __imag use the component type of its operand.  */
2358       sprintf (optype, "TREE_TYPE (TREE_TYPE (ops%d[0]))", depth);
2359       type = optype;
2360     }
2361   else if (is_a <operator_id *> (opr)
2362              && !strcmp (as_a <operator_id *> (opr)->tcc, "tcc_comparison"))
2363     {
2364       /* comparisons use boolean_type_node (or what gets in), but
2365          their operands need to figure out the types themselves.  */
2366       if (in_type)
2367           type = in_type;
2368       else
2369           {
2370             sprintf (optype, "boolean_type_node");
2371             type = optype;
2372           }
2373       in_type = NULL;
2374     }
2375   else if (*opr == COND_EXPR
2376              || *opr == VEC_COND_EXPR)
2377     {
2378       /* Conditions are of the same type as their first alternative.  */
2379       sprintf (optype, "TREE_TYPE (ops%d[1])", depth);
2380       type = optype;
2381     }
2382   else
2383     {
2384       /* Other operations are of the same type as their first operand.  */
2385       sprintf (optype, "TREE_TYPE (ops%d[0])", depth);
2386       type = optype;
2387     }
2388   if (!type)
2389     fatal_at (location, "cannot determine type of operand");
2390 
2391   fprintf_indent (f, indent, "{\n");
2392   indent += 2;
2393   fprintf_indent (f, indent, "tree ops%d[%u], res;\n", depth, ops.length ());
2394   char op0type[64];
2395   snprintf (op0type, 64, "TREE_TYPE (ops%d[0])", depth);
2396   for (unsigned i = 0; i < ops.length (); ++i)
2397     {
2398       char dest[32];
2399       snprintf (dest, 32, "ops%d[%u]", depth, i);
2400       const char *optype
2401           = get_operand_type (opr, i, in_type, expr_type,
2402                                   i == 0 ? NULL : op0type);
2403       ops[i]->gen_transform (f, indent, dest, gimple, depth + 1, optype,
2404                                    cinfo, indexes,
2405                                    (*opr == COND_EXPR
2406                                     || *opr == VEC_COND_EXPR) && i == 0 ? 1 : 2);
2407     }
2408 
2409   const char *opr_name;
2410   if (*operation == CONVERT_EXPR)
2411     opr_name = "NOP_EXPR";
2412   else
2413     opr_name = operation->id;
2414 
2415   if (gimple)
2416     {
2417       if (*opr == CONVERT_EXPR)
2418           {
2419             fprintf_indent (f, indent,
2420                                 "if (%s != TREE_TYPE (ops%d[0])\n",
2421                                 type, depth);
2422             fprintf_indent (f, indent,
2423                                 "    && !useless_type_conversion_p (%s, TREE_TYPE (ops%d[0])))\n",
2424                                 type, depth);
2425             fprintf_indent (f, indent + 2, "{\n");
2426             indent += 4;
2427           }
2428       /* ???  Building a stmt can fail for various reasons here, seq being
2429          NULL or the stmt referencing SSA names occuring in abnormal PHIs.
2430            So if we fail here we should continue matching other patterns.  */
2431       fprintf_indent (f, indent, "code_helper tem_code = %s;\n", opr_name);
2432       fprintf_indent (f, indent, "tree tem_ops[3] = { ");
2433       for (unsigned i = 0; i < ops.length (); ++i)
2434           fprintf (f, "ops%d[%u]%s", depth, i,
2435                      i == ops.length () - 1 ? " };\n" : ", ");
2436       fprintf_indent (f, indent,
2437                           "gimple_resimplify%d (lseq, &tem_code, %s, tem_ops, valueize);\n",
2438                           ops.length (), type);
2439       fprintf_indent (f, indent,
2440                           "res = maybe_push_res_to_seq (tem_code, %s, tem_ops, lseq);\n",
2441                           type);
2442       fprintf_indent (f, indent,
2443                           "if (!res) return false;\n");
2444       if (*opr == CONVERT_EXPR)
2445           {
2446             indent -= 4;
2447             fprintf_indent (f, indent, "  }\n");
2448             fprintf_indent (f, indent, "else\n");
2449             fprintf_indent (f, indent, "  res = ops%d[0];\n", depth);
2450           }
2451     }
2452   else
2453     {
2454       if (*opr == CONVERT_EXPR)
2455           {
2456             fprintf_indent (f, indent, "if (TREE_TYPE (ops%d[0]) != %s)\n",
2457                                 depth, type);
2458             indent += 2;
2459           }
2460       if (opr->kind == id_base::CODE)
2461           fprintf_indent (f, indent, "res = fold_build%d_loc (loc, %s, %s",
2462                               ops.length(), opr_name, type);
2463       else
2464           {
2465             fprintf_indent (f, indent, "{\n");
2466             fprintf_indent (f, indent, "  res = maybe_build_call_expr_loc (loc, "
2467                                 "%s, %s, %d", opr_name, type, ops.length());
2468           }
2469       for (unsigned i = 0; i < ops.length (); ++i)
2470           fprintf (f, ", ops%d[%u]", depth, i);
2471       fprintf (f, ");\n");
2472       if (opr->kind != id_base::CODE)
2473           {
2474             fprintf_indent (f, indent, "  if (!res)\n");
2475             fprintf_indent (f, indent, "    return NULL_TREE;\n");
2476             fprintf_indent (f, indent, "}\n");
2477           }
2478       if (*opr == CONVERT_EXPR)
2479           {
2480             indent -= 2;
2481             fprintf_indent (f, indent, "else\n");
2482             fprintf_indent (f, indent, "  res = ops%d[0];\n", depth);
2483           }
2484     }
2485   fprintf_indent (f, indent, "%s = res;\n", dest);
2486   indent -= 2;
2487   fprintf_indent (f, indent, "}\n");
2488 }
2489 
2490 /* Generate code for a c_expr which is either the expression inside
2491    an if statement or a sequence of statements which computes a
2492    result to be stored to DEST.  */
2493 
2494 void
gen_transform(FILE * f,int indent,const char * dest,bool,int,const char *,capture_info *,dt_operand **,int)2495 c_expr::gen_transform (FILE *f, int indent, const char *dest,
2496                            bool, int, const char *, capture_info *,
2497                            dt_operand **, int)
2498 {
2499   if (dest && nr_stmts == 1)
2500     fprintf_indent (f, indent, "%s = ", dest);
2501 
2502   unsigned stmt_nr = 1;
2503   for (unsigned i = 0; i < code.length (); ++i)
2504     {
2505       const cpp_token *token = &code[i];
2506 
2507       /* Replace captures for code-gen.  */
2508       if (token->type == CPP_ATSIGN)
2509           {
2510             const cpp_token *n = &code[i+1];
2511             if ((n->type == CPP_NUMBER
2512                  || n->type == CPP_NAME)
2513                 && !(n->flags & PREV_WHITE))
2514               {
2515                 if (token->flags & PREV_WHITE)
2516                     fputc (' ', f);
2517                 const char *id;
2518                 if (n->type == CPP_NUMBER)
2519                     id = (const char *)n->val.str.text;
2520                 else
2521                     id = (const char *)CPP_HASHNODE (n->val.node.node)->ident.str;
2522                 unsigned *cid = capture_ids->get (id);
2523                 if (!cid)
2524                     fatal_at (token, "unknown capture id");
2525                 fprintf (f, "captures[%u]", *cid);
2526                 ++i;
2527                 continue;
2528               }
2529           }
2530 
2531       if (token->flags & PREV_WHITE)
2532           fputc (' ', f);
2533 
2534       if (token->type == CPP_NAME)
2535           {
2536             const char *id = (const char *) NODE_NAME (token->val.node.node);
2537             unsigned j;
2538             for (j = 0; j < ids.length (); ++j)
2539               {
2540               if (strcmp (id, ids[j].id) == 0)
2541                 {
2542                     fprintf (f, "%s", ids[j].oper);
2543                     break;
2544                 }
2545               }
2546             if (j < ids.length ())
2547               continue;
2548           }
2549 
2550       /* Output the token as string.  */
2551       char *tk = (char *)cpp_token_as_text (r, token);
2552       fputs (tk, f);
2553 
2554       if (token->type == CPP_SEMICOLON)
2555           {
2556             stmt_nr++;
2557             fputc ('\n', f);
2558             if (dest && stmt_nr == nr_stmts)
2559               fprintf_indent (f, indent, "%s = ", dest);
2560           }
2561     }
2562 }
2563 
2564 /* Generate transform code for a capture.  */
2565 
2566 void
gen_transform(FILE * f,int indent,const char * dest,bool gimple,int depth,const char * in_type,capture_info * cinfo,dt_operand ** indexes,int cond_handling)2567 capture::gen_transform (FILE *f, int indent, const char *dest, bool gimple,
2568                               int depth, const char *in_type, capture_info *cinfo,
2569                               dt_operand **indexes, int cond_handling)
2570 {
2571   if (what && is_a<expr *> (what))
2572     {
2573       if (indexes[where] == 0)
2574           {
2575             char buf[20];
2576             sprintf (buf, "captures[%u]", where);
2577             what->gen_transform (f, indent, buf, gimple, depth, in_type,
2578                                      cinfo, NULL);
2579           }
2580     }
2581 
2582   /* If in GENERIC some capture is used multiple times, unshare it except
2583      when emitting the last use.  */
2584   if (!gimple
2585       && cinfo->info.exists ()
2586       && cinfo->info[cinfo->info[where].same_as].result_use_count > 1)
2587     {
2588       fprintf_indent (f, indent, "%s = unshare_expr (captures[%u]);\n",
2589                           dest, where);
2590       cinfo->info[cinfo->info[where].same_as].result_use_count--;
2591     }
2592   else
2593     fprintf_indent (f, indent, "%s = captures[%u];\n", dest, where);
2594 
2595   /* ???  Stupid tcc_comparison GENERIC trees in COND_EXPRs.  Deal
2596      with substituting a capture of that.  */
2597   if (gimple
2598       && cond_handling != 0
2599       && cinfo->info[where].cond_expr_cond_p)
2600     {
2601       /* If substituting into a cond_expr condition, unshare.  */
2602       if (cond_handling == 1)
2603           fprintf_indent (f, indent, "%s = unshare_expr (%s);\n", dest, dest);
2604       /* If substituting elsewhere we might need to decompose it.  */
2605       else if (cond_handling == 2)
2606           {
2607             /* ???  Returning false here will also not allow any other patterns
2608                to match unless this generator was split out.  */
2609             fprintf_indent (f, indent, "if (COMPARISON_CLASS_P (%s))\n", dest);
2610             fprintf_indent (f, indent, "  {\n");
2611             fprintf_indent (f, indent, "    if (!seq) return false;\n");
2612             fprintf_indent (f, indent, "    %s = gimple_build (seq,"
2613                                 " TREE_CODE (%s),"
2614                                 " TREE_TYPE (%s), TREE_OPERAND (%s, 0),"
2615                                 " TREE_OPERAND (%s, 1));\n",
2616                                 dest, dest, dest, dest, dest);
2617             fprintf_indent (f, indent, "  }\n");
2618           }
2619     }
2620 }
2621 
2622 /* Return the name of the operand representing the decision tree node.
2623    Use NAME as space to generate it.  */
2624 
2625 char *
get_name(char * name)2626 dt_operand::get_name (char *name)
2627 {
2628   if (! parent)
2629     sprintf (name, "t");
2630   else if (parent->level == 1)
2631     sprintf (name, "op%u", pos);
2632   else if (parent->type == dt_node::DT_MATCH)
2633     return as_a <dt_operand *> (parent)->get_name (name);
2634   else
2635     sprintf (name, "o%u%u", parent->level, pos);
2636   return name;
2637 }
2638 
2639 /* Fill NAME with the operand name at position POS.  */
2640 
2641 void
gen_opname(char * name,unsigned pos)2642 dt_operand::gen_opname (char *name, unsigned pos)
2643 {
2644   if (! parent)
2645     sprintf (name, "op%u", pos);
2646   else
2647     sprintf (name, "o%u%u", level, pos);
2648 }
2649 
2650 /* Generate matching code for the decision tree operand which is
2651    a predicate.  */
2652 
2653 unsigned
gen_predicate(FILE * f,int indent,const char * opname,bool gimple)2654 dt_operand::gen_predicate (FILE *f, int indent, const char *opname, bool gimple)
2655 {
2656   predicate *p = as_a <predicate *> (op);
2657 
2658   if (p->p->matchers.exists ())
2659     {
2660       /* If this is a predicate generated from a pattern mangle its
2661            name and pass on the valueize hook.  */
2662       if (gimple)
2663           fprintf_indent (f, indent, "if (gimple_%s (%s, valueize))\n",
2664                               p->p->id, opname);
2665       else
2666           fprintf_indent (f, indent, "if (tree_%s (%s))\n", p->p->id, opname);
2667     }
2668   else
2669     fprintf_indent (f, indent, "if (%s (%s))\n", p->p->id, opname);
2670   fprintf_indent (f, indent + 2, "{\n");
2671   return 1;
2672 }
2673 
2674 /* Generate matching code for the decision tree operand which is
2675    a capture-match.  */
2676 
2677 unsigned
gen_match_op(FILE * f,int indent,const char * opname,bool)2678 dt_operand::gen_match_op (FILE *f, int indent, const char *opname, bool)
2679 {
2680   char match_opname[20];
2681   match_dop->get_name (match_opname);
2682   if (value_match)
2683     fprintf_indent (f, indent, "if ((%s == %s && ! TREE_SIDE_EFFECTS (%s)) "
2684                         "|| operand_equal_p (%s, %s, 0))\n",
2685                         opname, match_opname, opname, opname, match_opname);
2686   else
2687     fprintf_indent (f, indent, "if ((%s == %s && ! TREE_SIDE_EFFECTS (%s)) "
2688                         "|| (operand_equal_p (%s, %s, 0) "
2689                         "&& types_match (%s, %s)))\n",
2690                         opname, match_opname, opname, opname, match_opname,
2691                         opname, match_opname);
2692   fprintf_indent (f, indent + 2, "{\n");
2693   return 1;
2694 }
2695 
2696 /* Generate GIMPLE matching code for the decision tree operand.  */
2697 
2698 unsigned
gen_gimple_expr(FILE * f,int indent)2699 dt_operand::gen_gimple_expr (FILE *f, int indent)
2700 {
2701   expr *e = static_cast<expr *> (op);
2702   id_base *id = e->operation;
2703   unsigned n_ops = e->ops.length ();
2704   unsigned n_braces = 0;
2705 
2706   for (unsigned i = 0; i < n_ops; ++i)
2707     {
2708       char child_opname[20];
2709       gen_opname (child_opname, i);
2710 
2711       if (id->kind == id_base::CODE)
2712           {
2713             if (e->is_generic
2714                 || *id == REALPART_EXPR || *id == IMAGPART_EXPR
2715                 || *id == BIT_FIELD_REF || *id == VIEW_CONVERT_EXPR)
2716               {
2717                 /* ???  If this is a memory operation we can't (and should not)
2718                      match this.  The only sensible operand types are
2719                      SSA names and invariants.  */
2720                 if (e->is_generic)
2721                     {
2722                       char opname[20];
2723                       get_name (opname);
2724                       fprintf_indent (f, indent,
2725                                           "tree %s = TREE_OPERAND (%s, %i);\n",
2726                                           child_opname, opname, i);
2727                     }
2728                 else
2729                     fprintf_indent (f, indent,
2730                                         "tree %s = TREE_OPERAND "
2731                                         "(gimple_assign_rhs1 (def), %i);\n",
2732                                         child_opname, i);
2733                 fprintf_indent (f, indent,
2734                                     "if ((TREE_CODE (%s) == SSA_NAME\n",
2735                                     child_opname);
2736                 fprintf_indent (f, indent,
2737                                     "     || is_gimple_min_invariant (%s)))\n",
2738                                     child_opname);
2739                 fprintf_indent (f, indent,
2740                                     "  {\n");
2741                 indent += 4;
2742                 n_braces++;
2743                 fprintf_indent (f, indent,
2744                                     "%s = do_valueize (valueize, %s);\n",
2745                                     child_opname, child_opname);
2746                 continue;
2747               }
2748             else
2749               fprintf_indent (f, indent,
2750                                   "tree %s = gimple_assign_rhs%u (def);\n",
2751                                   child_opname, i + 1);
2752           }
2753       else
2754           fprintf_indent (f, indent,
2755                               "tree %s = gimple_call_arg (def, %u);\n",
2756                               child_opname, i);
2757       fprintf_indent (f, indent,
2758                           "%s = do_valueize (valueize, %s);\n",
2759                           child_opname, child_opname);
2760     }
2761   /* While the toplevel operands are canonicalized by the caller
2762      after valueizing operands of sub-expressions we have to
2763      re-canonicalize operand order.  */
2764   if (operator_id *code = dyn_cast <operator_id *> (id))
2765     {
2766       /* ???  We can't canonicalize tcc_comparison operands here
2767          because that requires changing the comparison code which
2768            we already matched...  */
2769       if (commutative_tree_code (code->code)
2770             || commutative_ternary_tree_code (code->code))
2771           {
2772             char child_opname0[20], child_opname1[20];
2773             gen_opname (child_opname0, 0);
2774             gen_opname (child_opname1, 1);
2775             fprintf_indent (f, indent,
2776                                 "if (tree_swap_operands_p (%s, %s))\n",
2777                                 child_opname0, child_opname1);
2778             fprintf_indent (f, indent,
2779                                 "  std::swap (%s, %s);\n",
2780                                 child_opname0, child_opname1);
2781           }
2782     }
2783 
2784   return n_braces;
2785 }
2786 
2787 /* Generate GENERIC matching code for the decision tree operand.  */
2788 
2789 unsigned
gen_generic_expr(FILE * f,int indent,const char * opname)2790 dt_operand::gen_generic_expr (FILE *f, int indent, const char *opname)
2791 {
2792   expr *e = static_cast<expr *> (op);
2793   unsigned n_ops = e->ops.length ();
2794 
2795   for (unsigned i = 0; i < n_ops; ++i)
2796     {
2797       char child_opname[20];
2798       gen_opname (child_opname, i);
2799 
2800       if (e->operation->kind == id_base::CODE)
2801           fprintf_indent (f, indent, "tree %s = TREE_OPERAND (%s, %u);\n",
2802                               child_opname, opname, i);
2803       else
2804           fprintf_indent (f, indent, "tree %s = CALL_EXPR_ARG (%s, %u);\n",
2805                               child_opname, opname, i);
2806     }
2807 
2808   return 0;
2809 }
2810 
2811 /* Generate matching code for the children of the decision tree node.  */
2812 
2813 void
gen_kids(FILE * f,int indent,bool gimple)2814 dt_node::gen_kids (FILE *f, int indent, bool gimple)
2815 {
2816   auto_vec<dt_operand *> gimple_exprs;
2817   auto_vec<dt_operand *> generic_exprs;
2818   auto_vec<dt_operand *> fns;
2819   auto_vec<dt_operand *> generic_fns;
2820   auto_vec<dt_operand *> preds;
2821   auto_vec<dt_node *> others;
2822 
2823   for (unsigned i = 0; i < kids.length (); ++i)
2824     {
2825       if (kids[i]->type == dt_node::DT_OPERAND)
2826           {
2827             dt_operand *op = as_a<dt_operand *> (kids[i]);
2828             if (expr *e = dyn_cast <expr *> (op->op))
2829               {
2830                 if (e->ops.length () == 0
2831                       && (!gimple || !(*e->operation == CONSTRUCTOR)))
2832                     generic_exprs.safe_push (op);
2833                 else if (e->operation->kind == id_base::FN)
2834                     {
2835                       if (gimple)
2836                         fns.safe_push (op);
2837                       else
2838                         generic_fns.safe_push (op);
2839                     }
2840                 else if (e->operation->kind == id_base::PREDICATE)
2841                     preds.safe_push (op);
2842                 else
2843                     {
2844                       if (gimple && !e->is_generic)
2845                         gimple_exprs.safe_push (op);
2846                       else
2847                         generic_exprs.safe_push (op);
2848                     }
2849               }
2850             else if (op->op->type == operand::OP_PREDICATE)
2851               others.safe_push (kids[i]);
2852             else
2853               gcc_unreachable ();
2854           }
2855       else if (kids[i]->type == dt_node::DT_SIMPLIFY)
2856           others.safe_push (kids[i]);
2857       else if (kids[i]->type == dt_node::DT_MATCH
2858                  || kids[i]->type == dt_node::DT_TRUE)
2859           {
2860             /* A DT_TRUE operand serves as a barrier - generate code now
2861                for what we have collected sofar.
2862                Like DT_TRUE, DT_MATCH serves as a barrier as it can cause
2863                dependent matches to get out-of-order.  Generate code now
2864                for what we have collected sofar.  */
2865             gen_kids_1 (f, indent, gimple, gimple_exprs, generic_exprs,
2866                           fns, generic_fns, preds, others);
2867             /* And output the true operand itself.  */
2868             kids[i]->gen (f, indent, gimple);
2869             gimple_exprs.truncate (0);
2870             generic_exprs.truncate (0);
2871             fns.truncate (0);
2872             generic_fns.truncate (0);
2873             preds.truncate (0);
2874             others.truncate (0);
2875           }
2876       else
2877           gcc_unreachable ();
2878     }
2879 
2880   /* Generate code for the remains.  */
2881   gen_kids_1 (f, indent, gimple, gimple_exprs, generic_exprs,
2882                 fns, generic_fns, preds, others);
2883 }
2884 
2885 /* Generate matching code for the children of the decision tree node.  */
2886 
2887 void
gen_kids_1(FILE * f,int indent,bool gimple,vec<dt_operand * > gimple_exprs,vec<dt_operand * > generic_exprs,vec<dt_operand * > fns,vec<dt_operand * > generic_fns,vec<dt_operand * > preds,vec<dt_node * > others)2888 dt_node::gen_kids_1 (FILE *f, int indent, bool gimple,
2889                          vec<dt_operand *> gimple_exprs,
2890                          vec<dt_operand *> generic_exprs,
2891                          vec<dt_operand *> fns,
2892                          vec<dt_operand *> generic_fns,
2893                          vec<dt_operand *> preds,
2894                          vec<dt_node *> others)
2895 {
2896   char buf[128];
2897   char *kid_opname = buf;
2898 
2899   unsigned exprs_len = gimple_exprs.length ();
2900   unsigned gexprs_len = generic_exprs.length ();
2901   unsigned fns_len = fns.length ();
2902   unsigned gfns_len = generic_fns.length ();
2903 
2904   if (exprs_len || fns_len || gexprs_len || gfns_len)
2905     {
2906       if (exprs_len)
2907           gimple_exprs[0]->get_name (kid_opname);
2908       else if (fns_len)
2909           fns[0]->get_name (kid_opname);
2910       else if (gfns_len)
2911           generic_fns[0]->get_name (kid_opname);
2912       else
2913           generic_exprs[0]->get_name (kid_opname);
2914 
2915       fprintf_indent (f, indent, "switch (TREE_CODE (%s))\n", kid_opname);
2916       fprintf_indent (f, indent, "  {\n");
2917       indent += 2;
2918     }
2919 
2920   if (exprs_len || fns_len)
2921     {
2922       fprintf_indent (f, indent,
2923                           "case SSA_NAME:\n");
2924       fprintf_indent (f, indent,
2925                           "  if (gimple *def_stmt = get_def (valueize, %s))\n",
2926                           kid_opname);
2927       fprintf_indent (f, indent,
2928                           "    {\n");
2929       indent += 6;
2930       if (exprs_len)
2931           {
2932             fprintf_indent (f, indent,
2933                                 "if (gassign *def = dyn_cast <gassign *> (def_stmt))\n");
2934             fprintf_indent (f, indent,
2935                                 "  switch (gimple_assign_rhs_code (def))\n");
2936             indent += 4;
2937             fprintf_indent (f, indent, "{\n");
2938             for (unsigned i = 0; i < exprs_len; ++i)
2939               {
2940                 expr *e = as_a <expr *> (gimple_exprs[i]->op);
2941                 id_base *op = e->operation;
2942                 if (*op == CONVERT_EXPR || *op == NOP_EXPR)
2943                     fprintf_indent (f, indent, "CASE_CONVERT:\n");
2944                 else
2945                     fprintf_indent (f, indent, "case %s:\n", op->id);
2946                 fprintf_indent (f, indent, "  {\n");
2947                 gimple_exprs[i]->gen (f, indent + 4, true);
2948                 fprintf_indent (f, indent, "    break;\n");
2949                 fprintf_indent (f, indent, "  }\n");
2950               }
2951             fprintf_indent (f, indent, "default:;\n");
2952             fprintf_indent (f, indent, "}\n");
2953             indent -= 4;
2954           }
2955 
2956       if (fns_len)
2957           {
2958             fprintf_indent (f, indent,
2959                                 "%sif (gcall *def = dyn_cast <gcall *>"
2960                                 " (def_stmt))\n",
2961                                 exprs_len ? "else " : "");
2962             fprintf_indent (f, indent,
2963                                 "  switch (gimple_call_combined_fn (def))\n");
2964 
2965             indent += 4;
2966             fprintf_indent (f, indent, "{\n");
2967             for (unsigned i = 0; i < fns_len; ++i)
2968               {
2969                 expr *e = as_a <expr *>(fns[i]->op);
2970                 fprintf_indent (f, indent, "case %s:\n", e->operation->id);
2971                 fprintf_indent (f, indent, "  {\n");
2972                 fns[i]->gen (f, indent + 4, true);
2973                 fprintf_indent (f, indent, "    break;\n");
2974                 fprintf_indent (f, indent, "  }\n");
2975               }
2976 
2977             fprintf_indent (f, indent, "default:;\n");
2978             fprintf_indent (f, indent, "}\n");
2979             indent -= 4;
2980           }
2981 
2982       indent -= 6;
2983       fprintf_indent (f, indent, "    }\n");
2984       /* See if there is SSA_NAME among generic_exprs and if yes, emit it
2985            here rather than in the next loop.  */
2986       for (unsigned i = 0; i < generic_exprs.length (); ++i)
2987           {
2988             expr *e = as_a <expr *>(generic_exprs[i]->op);
2989             id_base *op = e->operation;
2990             if (*op == SSA_NAME && (exprs_len || fns_len))
2991               {
2992                 fprintf_indent (f, indent + 4, "{\n");
2993                 generic_exprs[i]->gen (f, indent + 6, gimple);
2994                 fprintf_indent (f, indent + 4, "}\n");
2995               }
2996           }
2997 
2998       fprintf_indent (f, indent, "  break;\n");
2999     }
3000 
3001   for (unsigned i = 0; i < generic_exprs.length (); ++i)
3002     {
3003       expr *e = as_a <expr *>(generic_exprs[i]->op);
3004       id_base *op = e->operation;
3005       if (*op == CONVERT_EXPR || *op == NOP_EXPR)
3006           fprintf_indent (f, indent, "CASE_CONVERT:\n");
3007       else if (*op == SSA_NAME && (exprs_len || fns_len))
3008           /* Already handled above.  */
3009           continue;
3010       else
3011           fprintf_indent (f, indent, "case %s:\n", op->id);
3012       fprintf_indent (f, indent, "  {\n");
3013       generic_exprs[i]->gen (f, indent + 4, gimple);
3014       fprintf_indent (f, indent, "    break;\n");
3015       fprintf_indent (f, indent, "  }\n");
3016     }
3017 
3018   if (gfns_len)
3019     {
3020       fprintf_indent (f, indent,
3021                           "case CALL_EXPR:\n");
3022       fprintf_indent (f, indent,
3023                           "  switch (get_call_combined_fn (%s))\n",
3024                           kid_opname);
3025       fprintf_indent (f, indent,
3026                           "    {\n");
3027       indent += 4;
3028 
3029       for (unsigned j = 0; j < generic_fns.length (); ++j)
3030           {
3031             expr *e = as_a <expr *>(generic_fns[j]->op);
3032             gcc_assert (e->operation->kind == id_base::FN);
3033 
3034             fprintf_indent (f, indent, "case %s:\n", e->operation->id);
3035             fprintf_indent (f, indent, "  {\n");
3036             generic_fns[j]->gen (f, indent + 4, false);
3037             fprintf_indent (f, indent, "    break;\n");
3038             fprintf_indent (f, indent, "  }\n");
3039           }
3040       fprintf_indent (f, indent, "default:;\n");
3041 
3042       indent -= 4;
3043       fprintf_indent (f, indent, "    }\n");
3044       fprintf_indent (f, indent, "  break;\n");
3045     }
3046 
3047   /* Close switch (TREE_CODE ()).  */
3048   if (exprs_len || fns_len || gexprs_len || gfns_len)
3049     {
3050       indent -= 4;
3051       fprintf_indent (f, indent, "    default:;\n");
3052       fprintf_indent (f, indent, "    }\n");
3053     }
3054 
3055   for (unsigned i = 0; i < preds.length (); ++i)
3056     {
3057       expr *e = as_a <expr *> (preds[i]->op);
3058       predicate_id *p = as_a <predicate_id *> (e->operation);
3059       preds[i]->get_name (kid_opname);
3060       fprintf_indent (f, indent, "{\n");
3061       indent += 2;
3062       fprintf_indent (f, indent, "tree %s_pops[%d];\n", kid_opname, p->nargs);
3063       fprintf_indent (f, indent, "if (%s_%s (%s, %s_pops%s))\n",
3064                  gimple ? "gimple" : "tree",
3065                  p->id, kid_opname, kid_opname,
3066                  gimple ? ", valueize" : "");
3067       fprintf_indent (f, indent, "  {\n");
3068       for (int j = 0; j < p->nargs; ++j)
3069           {
3070             char child_opname[20];
3071             preds[i]->gen_opname (child_opname, j);
3072             fprintf_indent (f, indent + 4, "tree %s = %s_pops[%d];\n",
3073                                 child_opname, kid_opname, j);
3074           }
3075       preds[i]->gen_kids (f, indent + 4, gimple);
3076       fprintf (f, "}\n");
3077       indent -= 2;
3078       fprintf_indent (f, indent, "}\n");
3079     }
3080 
3081   for (unsigned i = 0; i < others.length (); ++i)
3082     others[i]->gen (f, indent, gimple);
3083 }
3084 
3085 /* Generate matching code for the decision tree operand.  */
3086 
3087 void
gen(FILE * f,int indent,bool gimple)3088 dt_operand::gen (FILE *f, int indent, bool gimple)
3089 {
3090   char opname[20];
3091   get_name (opname);
3092 
3093   unsigned n_braces = 0;
3094 
3095   if (type == DT_OPERAND)
3096     switch (op->type)
3097       {
3098           case operand::OP_PREDICATE:
3099             n_braces = gen_predicate (f, indent, opname, gimple);
3100             break;
3101 
3102           case operand::OP_EXPR:
3103             if (gimple)
3104               n_braces = gen_gimple_expr (f, indent);
3105             else
3106               n_braces = gen_generic_expr (f, indent, opname);
3107             break;
3108 
3109           default:
3110             gcc_unreachable ();
3111       }
3112   else if (type == DT_TRUE)
3113     ;
3114   else if (type == DT_MATCH)
3115     n_braces = gen_match_op (f, indent, opname, gimple);
3116   else
3117     gcc_unreachable ();
3118 
3119   indent += 4 * n_braces;
3120   gen_kids (f, indent, gimple);
3121 
3122   for (unsigned i = 0; i < n_braces; ++i)
3123     {
3124       indent -= 4;
3125       if (indent < 0)
3126           indent = 0;
3127       fprintf_indent (f, indent, "  }\n");
3128     }
3129 }
3130 
3131 
3132 /* Generate code for the '(if ...)', '(with ..)' and actual transform
3133    step of a '(simplify ...)' or '(match ...)'.  This handles everything
3134    that is not part of the decision tree (simplify->match).
3135    Main recursive worker.  */
3136 
3137 void
gen_1(FILE * f,int indent,bool gimple,operand * result)3138 dt_simplify::gen_1 (FILE *f, int indent, bool gimple, operand *result)
3139 {
3140   if (result)
3141     {
3142       if (with_expr *w = dyn_cast <with_expr *> (result))
3143           {
3144             fprintf_indent (f, indent, "{\n");
3145             indent += 4;
3146             output_line_directive (f, w->location);
3147             w->with->gen_transform (f, indent, NULL, true, 1, "type", NULL);
3148             gen_1 (f, indent, gimple, w->subexpr);
3149             indent -= 4;
3150             fprintf_indent (f, indent, "}\n");
3151             return;
3152           }
3153       else if (if_expr *ife = dyn_cast <if_expr *> (result))
3154           {
3155             output_line_directive (f, ife->location);
3156             fprintf_indent (f, indent, "if (");
3157             ife->cond->gen_transform (f, indent, NULL, true, 1, "type", NULL);
3158             fprintf (f, ")\n");
3159             fprintf_indent (f, indent + 2, "{\n");
3160             indent += 4;
3161             gen_1 (f, indent, gimple, ife->trueexpr);
3162             indent -= 4;
3163             fprintf_indent (f, indent + 2, "}\n");
3164             if (ife->falseexpr)
3165               {
3166                 fprintf_indent (f, indent, "else\n");
3167                 fprintf_indent (f, indent + 2, "{\n");
3168                 indent += 4;
3169                 gen_1 (f, indent, gimple, ife->falseexpr);
3170                 indent -= 4;
3171                 fprintf_indent (f, indent + 2, "}\n");
3172               }
3173             return;
3174           }
3175     }
3176 
3177   /* Analyze captures and perform early-outs on the incoming arguments
3178      that cover cases we cannot handle.  */
3179   capture_info cinfo (s, result, gimple);
3180   if (s->kind == simplify::SIMPLIFY)
3181     {
3182       if (!gimple)
3183           {
3184             for (unsigned i = 0; i < as_a <expr *> (s->match)->ops.length (); ++i)
3185               if (cinfo.force_no_side_effects & (1 << i))
3186                 {
3187                     fprintf_indent (f, indent,
3188                                         "if (TREE_SIDE_EFFECTS (op%d)) return NULL_TREE;\n",
3189                                         i);
3190                     if (verbose >= 1)
3191                       warning_at (as_a <expr *> (s->match)->ops[i]->location,
3192                                     "forcing toplevel operand to have no "
3193                                     "side-effects");
3194                 }
3195             for (int i = 0; i <= s->capture_max; ++i)
3196               if (cinfo.info[i].cse_p)
3197                 ;
3198               else if (cinfo.info[i].force_no_side_effects_p
3199                          && (cinfo.info[i].toplevel_msk
3200                                & cinfo.force_no_side_effects) == 0)
3201                 {
3202                     fprintf_indent (f, indent,
3203                                         "if (TREE_SIDE_EFFECTS (captures[%d])) "
3204                                         "return NULL_TREE;\n", i);
3205                     if (verbose >= 1)
3206                       warning_at (cinfo.info[i].c->location,
3207                                     "forcing captured operand to have no "
3208                                     "side-effects");
3209                 }
3210               else if ((cinfo.info[i].toplevel_msk
3211                           & cinfo.force_no_side_effects) != 0)
3212                 /* Mark capture as having no side-effects if we had to verify
3213                      that via forced toplevel operand checks.  */
3214                 cinfo.info[i].force_no_side_effects_p = true;
3215           }
3216       if (gimple)
3217           {
3218             /* Force single-use restriction by only allowing simple
3219                results via setting seq to NULL.  */
3220             fprintf_indent (f, indent, "gimple_seq *lseq = seq;\n");
3221             bool first_p = true;
3222             for (int i = 0; i <= s->capture_max; ++i)
3223               if (cinfo.info[i].force_single_use)
3224                 {
3225                     if (first_p)
3226                       {
3227                         fprintf_indent (f, indent, "if (lseq\n");
3228                         fprintf_indent (f, indent, "    && (");
3229                         first_p = false;
3230                       }
3231                     else
3232                       {
3233                         fprintf (f, "\n");
3234                         fprintf_indent (f, indent, "        || ");
3235                       }
3236                     fprintf (f, "!single_use (captures[%d])", i);
3237                 }
3238             if (!first_p)
3239               {
3240                 fprintf (f, "))\n");
3241                 fprintf_indent (f, indent, "  lseq = NULL;\n");
3242               }
3243           }
3244     }
3245 
3246   fprintf_indent (f, indent, "if (dump_file && (dump_flags & TDF_FOLDING)) "
3247              "fprintf (dump_file, \"Applying pattern ");
3248   output_line_directive (f,
3249                                result ? result->location : s->match->location, true);
3250   fprintf (f, ", %%s:%%d\\n\", __FILE__, __LINE__);\n");
3251 
3252   if (!result)
3253     {
3254       /* If there is no result then this is a predicate implementation.  */
3255       fprintf_indent (f, indent, "return true;\n");
3256     }
3257   else if (gimple)
3258     {
3259       /* For GIMPLE simply drop NON_LVALUE_EXPR (which only appears
3260          in outermost position).  */
3261       if (result->type == operand::OP_EXPR
3262             && *as_a <expr *> (result)->operation == NON_LVALUE_EXPR)
3263           result = as_a <expr *> (result)->ops[0];
3264       if (result->type == operand::OP_EXPR)
3265           {
3266             expr *e = as_a <expr *> (result);
3267             id_base *opr = e->operation;
3268             bool is_predicate = false;
3269             /* When we delay operator substituting during lowering of fors we
3270                make sure that for code-gen purposes the effects of each substitute
3271                are the same.  Thus just look at that.  */
3272             if (user_id *uid = dyn_cast <user_id *> (opr))
3273               opr = uid->substitutes[0];
3274             else if (is_a <predicate_id *> (opr))
3275               is_predicate = true;
3276             if (!is_predicate)
3277               fprintf_indent (f, indent, "*res_code = %s;\n",
3278                                   *e->operation == CONVERT_EXPR
3279                                   ? "NOP_EXPR" : e->operation->id);
3280             for (unsigned j = 0; j < e->ops.length (); ++j)
3281               {
3282                 char dest[32];
3283                 snprintf (dest, 32, "res_ops[%d]", j);
3284                 const char *optype
3285                     = get_operand_type (opr, j,
3286                                             "type", e->expr_type,
3287                                             j == 0 ? NULL : "TREE_TYPE (res_ops[0])");
3288                 /* We need to expand GENERIC conditions we captured from
3289                    COND_EXPRs and we need to unshare them when substituting
3290                      into COND_EXPRs.  */
3291                 int cond_handling = 0;
3292                 if (!is_predicate)
3293                     cond_handling = ((*opr == COND_EXPR
3294                                           || *opr == VEC_COND_EXPR) && j == 0) ? 1 : 2;
3295                 e->ops[j]->gen_transform (f, indent, dest, true, 1, optype,
3296                                                   &cinfo, indexes, cond_handling);
3297               }
3298 
3299             /* Re-fold the toplevel result.  It's basically an embedded
3300                gimple_build w/o actually building the stmt.  */
3301             if (!is_predicate)
3302               fprintf_indent (f, indent,
3303                                   "gimple_resimplify%d (lseq, res_code, type, "
3304                                   "res_ops, valueize);\n", e->ops.length ());
3305           }
3306       else if (result->type == operand::OP_CAPTURE
3307                  || result->type == operand::OP_C_EXPR)
3308           {
3309             result->gen_transform (f, indent, "res_ops[0]", true, 1, "type",
3310                                          &cinfo, indexes);
3311             fprintf_indent (f, indent, "*res_code = TREE_CODE (res_ops[0]);\n");
3312             if (is_a <capture *> (result)
3313                 && cinfo.info[as_a <capture *> (result)->where].cond_expr_cond_p)
3314               {
3315                 /* ???  Stupid tcc_comparison GENERIC trees in COND_EXPRs.  Deal
3316                      with substituting a capture of that.  */
3317                 fprintf_indent (f, indent,
3318                                     "if (COMPARISON_CLASS_P (res_ops[0]))\n");
3319                 fprintf_indent (f, indent,
3320                                     "  {\n");
3321                 fprintf_indent (f, indent,
3322                                     "    tree tem = res_ops[0];\n");
3323                 fprintf_indent (f, indent,
3324                                     "    res_ops[0] = TREE_OPERAND (tem, 0);\n");
3325                 fprintf_indent (f, indent,
3326                                     "    res_ops[1] = TREE_OPERAND (tem, 1);\n");
3327                 fprintf_indent (f, indent,
3328                                     "  }\n");
3329               }
3330           }
3331       else
3332           gcc_unreachable ();
3333       fprintf_indent (f, indent, "return true;\n");
3334     }
3335   else /* GENERIC */
3336     {
3337       bool is_predicate = false;
3338       if (result->type == operand::OP_EXPR)
3339           {
3340             expr *e = as_a <expr *> (result);
3341             id_base *opr = e->operation;
3342             /* When we delay operator substituting during lowering of fors we
3343                make sure that for code-gen purposes the effects of each substitute
3344                are the same.  Thus just look at that.  */
3345             if (user_id *uid = dyn_cast <user_id *> (opr))
3346               opr = uid->substitutes[0];
3347             else if (is_a <predicate_id *> (opr))
3348               is_predicate = true;
3349             /* Search for captures used multiple times in the result expression
3350                and wrap them in a SAVE_EXPR.  Allow as many uses as in the
3351                original expression.  */
3352             if (!is_predicate)
3353               for (int i = 0; i < s->capture_max + 1; ++i)
3354                 {
3355                     if (cinfo.info[i].same_as != (unsigned)i
3356                         || cinfo.info[i].cse_p)
3357                       continue;
3358                     if (cinfo.info[i].result_use_count
3359                         > cinfo.info[i].match_use_count)
3360                       fprintf_indent (f, indent,
3361                                           "if (! tree_invariant_p (captures[%d])) "
3362                                           "return NULL_TREE;\n", i);
3363                 }
3364             for (unsigned j = 0; j < e->ops.length (); ++j)
3365               {
3366                 char dest[32];
3367                 if (is_predicate)
3368                     snprintf (dest, 32, "res_ops[%d]", j);
3369                 else
3370                     {
3371                       fprintf_indent (f, indent, "tree res_op%d;\n", j);
3372                       snprintf (dest, 32, "res_op%d", j);
3373                     }
3374                 const char *optype
3375                   = get_operand_type (opr, j,
3376                                             "type", e->expr_type,
3377                                             j == 0
3378                                             ? NULL : "TREE_TYPE (res_op0)");
3379                 e->ops[j]->gen_transform (f, indent, dest, false, 1, optype,
3380                                                   &cinfo, indexes);
3381               }
3382             if (is_predicate)
3383               fprintf_indent (f, indent, "return true;\n");
3384             else
3385               {
3386                 fprintf_indent (f, indent, "tree res;\n");
3387                 /* Re-fold the toplevel result.  Use non_lvalue to
3388                    build NON_LVALUE_EXPRs so they get properly
3389                      ignored when in GIMPLE form.  */
3390                 if (*opr == NON_LVALUE_EXPR)
3391                     fprintf_indent (f, indent,
3392                                         "res = non_lvalue_loc (loc, res_op0);\n");
3393                 else
3394                     {
3395                       if (is_a <operator_id *> (opr))
3396                         fprintf_indent (f, indent,
3397                                             "res = fold_build%d_loc (loc, %s, type",
3398                                             e->ops.length (),
3399                                             *e->operation == CONVERT_EXPR
3400                                             ? "NOP_EXPR" : e->operation->id);
3401                       else
3402                         fprintf_indent (f, indent,
3403                                             "res = maybe_build_call_expr_loc (loc, "
3404                                             "%s, type, %d", e->operation->id,
3405                                             e->ops.length());
3406                       for (unsigned j = 0; j < e->ops.length (); ++j)
3407                         fprintf (f, ", res_op%d", j);
3408                       fprintf (f, ");\n");
3409                       if (!is_a <operator_id *> (opr))
3410                         {
3411                           fprintf_indent (f, indent, "if (!res)\n");
3412                           fprintf_indent (f, indent, "  return NULL_TREE;\n");
3413                         }
3414                     }
3415               }
3416           }
3417       else if (result->type == operand::OP_CAPTURE
3418                  || result->type == operand::OP_C_EXPR)
3419 
3420           {
3421             fprintf_indent (f, indent, "tree res;\n");
3422             result->gen_transform (f, indent, "res", false, 1, "type",
3423                                             &cinfo, indexes);
3424           }
3425       else
3426           gcc_unreachable ();
3427       if (!is_predicate)
3428           {
3429             /* Search for captures not used in the result expression and dependent
3430                on TREE_SIDE_EFFECTS emit omit_one_operand.  */
3431             for (int i = 0; i < s->capture_max + 1; ++i)
3432               {
3433                 if (cinfo.info[i].same_as != (unsigned)i)
3434                     continue;
3435                 if (!cinfo.info[i].force_no_side_effects_p
3436                       && !cinfo.info[i].expr_p
3437                       && cinfo.info[i].result_use_count == 0)
3438                     {
3439                       fprintf_indent (f, indent,
3440                                           "if (TREE_SIDE_EFFECTS (captures[%d]))\n",
3441                                           i);
3442                       fprintf_indent (f, indent + 2,
3443                                           "res = build2_loc (loc, COMPOUND_EXPR, type, "
3444                                           "fold_ignored_result (captures[%d]), res);\n",
3445                                           i);
3446                     }
3447               }
3448             fprintf_indent (f, indent, "return res;\n");
3449           }
3450     }
3451 }
3452 
3453 /* Generate code for the '(if ...)', '(with ..)' and actual transform
3454    step of a '(simplify ...)' or '(match ...)'.  This handles everything
3455    that is not part of the decision tree (simplify->match).  */
3456 
3457 void
gen(FILE * f,int indent,bool gimple)3458 dt_simplify::gen (FILE *f, int indent, bool gimple)
3459 {
3460   fprintf_indent (f, indent, "{\n");
3461   indent += 2;
3462   output_line_directive (f,
3463                                s->result ? s->result->location : s->match->location);
3464   if (s->capture_max >= 0)
3465     {
3466       char opname[20];
3467       fprintf_indent (f, indent, "tree captures[%u] ATTRIBUTE_UNUSED = { %s",
3468                           s->capture_max + 1, indexes[0]->get_name (opname));
3469 
3470       for (int i = 1; i <= s->capture_max; ++i)
3471           {
3472             if (!indexes[i])
3473               break;
3474             fprintf (f, ", %s", indexes[i]->get_name (opname));
3475           }
3476       fprintf (f, " };\n");
3477     }
3478 
3479   /* If we have a split-out function for the actual transform, call it.  */
3480   if (info && info->fname)
3481     {
3482       if (gimple)
3483           {
3484             fprintf_indent (f, indent, "if (%s (res_code, res_ops, seq, "
3485                                 "valueize, type, captures", info->fname);
3486             for (unsigned i = 0; i < s->for_subst_vec.length (); ++i)
3487               if (s->for_subst_vec[i].first->used)
3488                 fprintf (f, ", %s", s->for_subst_vec[i].second->id);
3489             fprintf (f, "))\n");
3490             fprintf_indent (f, indent, "  return true;\n");
3491           }
3492       else
3493           {
3494             fprintf_indent (f, indent, "tree res = %s (loc, type",
3495                                 info->fname);
3496             for (unsigned i = 0; i < as_a <expr *> (s->match)->ops.length (); ++i)
3497               fprintf (f, ", op%d", i);
3498             fprintf (f, ", captures");
3499             for (unsigned i = 0; i < s->for_subst_vec.length (); ++i)
3500               {
3501                 if (s->for_subst_vec[i].first->used)
3502                     fprintf (f, ", %s", s->for_subst_vec[i].second->id);
3503               }
3504             fprintf (f, ");\n");
3505             fprintf_indent (f, indent, "if (res) return res;\n");
3506           }
3507     }
3508   else
3509     {
3510       for (unsigned i = 0; i < s->for_subst_vec.length (); ++i)
3511           {
3512             if (! s->for_subst_vec[i].first->used)
3513               continue;
3514             if (is_a <operator_id *> (s->for_subst_vec[i].second))
3515               fprintf_indent (f, indent, "const enum tree_code %s = %s;\n",
3516                                   s->for_subst_vec[i].first->id,
3517                                   s->for_subst_vec[i].second->id);
3518             else if (is_a <fn_id *> (s->for_subst_vec[i].second))
3519               fprintf_indent (f, indent, "const combined_fn %s = %s;\n",
3520                                   s->for_subst_vec[i].first->id,
3521                                   s->for_subst_vec[i].second->id);
3522             else
3523               gcc_unreachable ();
3524           }
3525       gen_1 (f, indent, gimple, s->result);
3526     }
3527 
3528   indent -= 2;
3529   fprintf_indent (f, indent, "}\n");
3530 }
3531 
3532 
3533 /* Hash function for finding equivalent transforms.  */
3534 
3535 hashval_t
hash(const key_type & v)3536 sinfo_hashmap_traits::hash (const key_type &v)
3537 {
3538   /* Only bother to compare those originating from the same source pattern.  */
3539   return v->s->result->location;
3540 }
3541 
3542 /* Compare function for finding equivalent transforms.  */
3543 
3544 static bool
compare_op(operand * o1,simplify * s1,operand * o2,simplify * s2)3545 compare_op (operand *o1, simplify *s1, operand *o2, simplify *s2)
3546 {
3547   if (o1->type != o2->type)
3548     return false;
3549 
3550   switch (o1->type)
3551     {
3552     case operand::OP_IF:
3553       {
3554           if_expr *if1 = as_a <if_expr *> (o1);
3555           if_expr *if2 = as_a <if_expr *> (o2);
3556           /* ???  Properly compare c-exprs.  */
3557           if (if1->cond != if2->cond)
3558             return false;
3559           if (!compare_op (if1->trueexpr, s1, if2->trueexpr, s2))
3560             return false;
3561           if (if1->falseexpr != if2->falseexpr
3562               || (if1->falseexpr
3563                     && !compare_op (if1->falseexpr, s1, if2->falseexpr, s2)))
3564             return false;
3565           return true;
3566       }
3567     case operand::OP_WITH:
3568       {
3569           with_expr *with1 = as_a <with_expr *> (o1);
3570           with_expr *with2 = as_a <with_expr *> (o2);
3571           if (with1->with != with2->with)
3572             return false;
3573           return compare_op (with1->subexpr, s1, with2->subexpr, s2);
3574       }
3575     default:;
3576     }
3577 
3578   /* We've hit a result.  Time to compare capture-infos - this is required
3579      in addition to the conservative pointer-equivalency of the result IL.  */
3580   capture_info cinfo1 (s1, o1, true);
3581   capture_info cinfo2 (s2, o2, true);
3582 
3583   if (cinfo1.force_no_side_effects != cinfo2.force_no_side_effects
3584       || cinfo1.info.length () != cinfo2.info.length ())
3585     return false;
3586 
3587   for (unsigned i = 0; i < cinfo1.info.length (); ++i)
3588     {
3589       if (cinfo1.info[i].expr_p != cinfo2.info[i].expr_p
3590             || cinfo1.info[i].cse_p != cinfo2.info[i].cse_p
3591             || (cinfo1.info[i].force_no_side_effects_p
3592                 != cinfo2.info[i].force_no_side_effects_p)
3593             || cinfo1.info[i].force_single_use != cinfo2.info[i].force_single_use
3594             || cinfo1.info[i].cond_expr_cond_p != cinfo2.info[i].cond_expr_cond_p
3595             /* toplevel_msk is an optimization */
3596             || cinfo1.info[i].result_use_count != cinfo2.info[i].result_use_count
3597             || cinfo1.info[i].same_as != cinfo2.info[i].same_as
3598             /* the pointer back to the capture is for diagnostics only */)
3599           return false;
3600     }
3601 
3602   /* ???  Deep-compare the actual result.  */
3603   return o1 == o2;
3604 }
3605 
3606 bool
equal_keys(const key_type & v,const key_type & candidate)3607 sinfo_hashmap_traits::equal_keys (const key_type &v,
3608                                           const key_type &candidate)
3609 {
3610   return compare_op (v->s->result, v->s, candidate->s->result, candidate->s);
3611 }
3612 
3613 
3614 /* Main entry to generate code for matching GIMPLE IL off the decision
3615    tree.  */
3616 
3617 void
gen(FILE * f,bool gimple)3618 decision_tree::gen (FILE *f, bool gimple)
3619 {
3620   sinfo_map_t si;
3621 
3622   root->analyze (si);
3623 
3624   fprintf (stderr, "%s decision tree has %u leafs, maximum depth %u and "
3625              "a total number of %u nodes\n",
3626              gimple ? "GIMPLE" : "GENERIC",
3627              root->num_leafs, root->max_level, root->total_size);
3628 
3629   /* First split out the transform part of equal leafs.  */
3630   unsigned rcnt = 0;
3631   unsigned fcnt = 1;
3632   for (sinfo_map_t::iterator iter = si.begin ();
3633        iter != si.end (); ++iter)
3634     {
3635       sinfo *s = (*iter).second;
3636       /* Do not split out single uses.  */
3637       if (s->cnt <= 1)
3638           continue;
3639 
3640       rcnt += s->cnt - 1;
3641       if (verbose >= 1)
3642           {
3643             fprintf (stderr, "found %u uses of", s->cnt);
3644             output_line_directive (stderr, s->s->s->result->location);
3645           }
3646 
3647       /* Generate a split out function with the leaf transform code.  */
3648       s->fname = xasprintf ("%s_simplify_%u", gimple ? "gimple" : "generic",
3649                                   fcnt++);
3650       if (gimple)
3651           fprintf (f, "\nstatic bool\n"
3652                      "%s (code_helper *res_code, tree *res_ops,\n"
3653                      "                 gimple_seq *seq, tree (*valueize)(tree) "
3654                      "ATTRIBUTE_UNUSED,\n"
3655                      "                 const tree ARG_UNUSED (type), tree *ARG_UNUSED "
3656                      "(captures)\n",
3657                      s->fname);
3658       else
3659           {
3660             fprintf (f, "\nstatic tree\n"
3661                        "%s (location_t ARG_UNUSED (loc), const tree ARG_UNUSED (type),\n",
3662                        (*iter).second->fname);
3663             for (unsigned i = 0;
3664                  i < as_a <expr *>(s->s->s->match)->ops.length (); ++i)
3665               fprintf (f, " tree ARG_UNUSED (op%d),", i);
3666             fprintf (f, " tree *captures\n");
3667           }
3668       for (unsigned i = 0; i < s->s->s->for_subst_vec.length (); ++i)
3669           {
3670             if (! s->s->s->for_subst_vec[i].first->used)
3671               continue;
3672             if (is_a <operator_id *> (s->s->s->for_subst_vec[i].second))
3673               fprintf (f, ", const enum tree_code ARG_UNUSED (%s)",
3674                          s->s->s->for_subst_vec[i].first->id);
3675             else if (is_a <fn_id *> (s->s->s->for_subst_vec[i].second))
3676               fprintf (f, ", const combined_fn ARG_UNUSED (%s)",
3677                          s->s->s->for_subst_vec[i].first->id);
3678           }
3679 
3680       fprintf (f, ")\n{\n");
3681       s->s->gen_1 (f, 2, gimple, s->s->s->result);
3682       if (gimple)
3683           fprintf (f, "  return false;\n");
3684       else
3685           fprintf (f, "  return NULL_TREE;\n");
3686       fprintf (f, "}\n");
3687     }
3688   fprintf (stderr, "removed %u duplicate tails\n", rcnt);
3689 
3690   for (unsigned n = 1; n <= 3; ++n)
3691     {
3692       /* First generate split-out functions.  */
3693       for (unsigned i = 0; i < root->kids.length (); i++)
3694           {
3695             dt_operand *dop = static_cast<dt_operand *>(root->kids[i]);
3696             expr *e = static_cast<expr *>(dop->op);
3697             if (e->ops.length () != n
3698                 /* Builtin simplifications are somewhat premature on
3699                      GENERIC.  The following drops patterns with outermost
3700                      calls.  It's easy to emit overloads for function code
3701                      though if necessary.  */
3702                 || (!gimple
3703                       && e->operation->kind != id_base::CODE))
3704               continue;
3705 
3706             if (gimple)
3707               fprintf (f, "\nstatic bool\n"
3708                          "gimple_simplify_%s (code_helper *res_code, tree *res_ops,\n"
3709                          "                 gimple_seq *seq, tree (*valueize)(tree) "
3710                          "ATTRIBUTE_UNUSED,\n"
3711                          "                 code_helper ARG_UNUSED (code), tree "
3712                          "ARG_UNUSED (type)\n",
3713                          e->operation->id);
3714             else
3715               fprintf (f, "\nstatic tree\n"
3716                          "generic_simplify_%s (location_t ARG_UNUSED (loc), enum "
3717                          "tree_code ARG_UNUSED (code), const tree ARG_UNUSED (type)",
3718                          e->operation->id);
3719             for (unsigned i = 0; i < n; ++i)
3720               fprintf (f, ", tree op%d", i);
3721             fprintf (f, ")\n");
3722             fprintf (f, "{\n");
3723             dop->gen_kids (f, 2, gimple);
3724             if (gimple)
3725               fprintf (f, "  return false;\n");
3726             else
3727               fprintf (f, "  return NULL_TREE;\n");
3728             fprintf (f, "}\n");
3729           }
3730 
3731       /* Then generate the main entry with the outermost switch and
3732          tail-calls to the split-out functions.  */
3733       if (gimple)
3734           fprintf (f, "\nstatic bool\n"
3735                      "gimple_simplify (code_helper *res_code, tree *res_ops,\n"
3736                      "                 gimple_seq *seq, tree (*valueize)(tree),\n"
3737                      "                 code_helper code, const tree type");
3738       else
3739           fprintf (f, "\ntree\n"
3740                      "generic_simplify (location_t loc, enum tree_code code, "
3741                      "const tree type ATTRIBUTE_UNUSED");
3742       for (unsigned i = 0; i < n; ++i)
3743           fprintf (f, ", tree op%d", i);
3744       fprintf (f, ")\n");
3745       fprintf (f, "{\n");
3746 
3747       if (gimple)
3748           fprintf (f, "  switch (code.get_rep())\n"
3749                      "    {\n");
3750       else
3751           fprintf (f, "  switch (code)\n"
3752                      "    {\n");
3753       for (unsigned i = 0; i < root->kids.length (); i++)
3754           {
3755             dt_operand *dop = static_cast<dt_operand *>(root->kids[i]);
3756             expr *e = static_cast<expr *>(dop->op);
3757             if (e->ops.length () != n
3758                 /* Builtin simplifications are somewhat premature on
3759                      GENERIC.  The following drops patterns with outermost
3760                      calls.  It's easy to emit overloads for function code
3761                      though if necessary.  */
3762                 || (!gimple
3763                       && e->operation->kind != id_base::CODE))
3764               continue;
3765 
3766             if (*e->operation == CONVERT_EXPR
3767                 || *e->operation == NOP_EXPR)
3768               fprintf (f, "    CASE_CONVERT:\n");
3769             else
3770               fprintf (f, "    case %s%s:\n",
3771                          is_a <fn_id *> (e->operation) ? "-" : "",
3772                          e->operation->id);
3773             if (gimple)
3774               fprintf (f, "      return gimple_simplify_%s (res_code, res_ops, "
3775                          "seq, valueize, code, type", e->operation->id);
3776             else
3777               fprintf (f, "      return generic_simplify_%s (loc, code, type",
3778                          e->operation->id);
3779             for (unsigned i = 0; i < n; ++i)
3780               fprintf (f, ", op%d", i);
3781             fprintf (f, ");\n");
3782           }
3783       fprintf (f,       "    default:;\n"
3784                           "    }\n");
3785 
3786       if (gimple)
3787           fprintf (f, "  return false;\n");
3788       else
3789           fprintf (f, "  return NULL_TREE;\n");
3790       fprintf (f, "}\n");
3791     }
3792 }
3793 
3794 /* Output code to implement the predicate P from the decision tree DT.  */
3795 
3796 void
write_predicate(FILE * f,predicate_id * p,decision_tree & dt,bool gimple)3797 write_predicate (FILE *f, predicate_id *p, decision_tree &dt, bool gimple)
3798 {
3799   fprintf (f, "\nbool\n"
3800              "%s%s (tree t%s%s)\n"
3801              "{\n", gimple ? "gimple_" : "tree_", p->id,
3802              p->nargs > 0 ? ", tree *res_ops" : "",
3803              gimple ? ", tree (*valueize)(tree) ATTRIBUTE_UNUSED" : "");
3804   /* Conveniently make 'type' available.  */
3805   fprintf_indent (f, 2, "const tree type = TREE_TYPE (t);\n");
3806 
3807   if (!gimple)
3808     fprintf_indent (f, 2, "if (TREE_SIDE_EFFECTS (t)) return false;\n");
3809   dt.root->gen_kids (f, 2, gimple);
3810 
3811   fprintf_indent (f, 2, "return false;\n"
3812              "}\n");
3813 }
3814 
3815 /* Write the common header for the GIMPLE/GENERIC IL matching routines.  */
3816 
3817 static void
write_header(FILE * f,const char * head)3818 write_header (FILE *f, const char *head)
3819 {
3820   fprintf (f, "/* Generated automatically by the program `genmatch' from\n");
3821   fprintf (f, "   a IL pattern matching and simplification description.  */\n");
3822 
3823   /* Include the header instead of writing it awkwardly quoted here.  */
3824   fprintf (f, "\n#include \"%s\"\n", head);
3825 }
3826 
3827 
3828 
3829 /* AST parsing.  */
3830 
3831 class parser
3832 {
3833 public:
3834   parser (cpp_reader *);
3835 
3836 private:
3837   const cpp_token *next ();
3838   const cpp_token *peek (unsigned = 1);
3839   const cpp_token *peek_ident (const char * = NULL, unsigned = 1);
3840   const cpp_token *expect (enum cpp_ttype);
3841   const cpp_token *eat_token (enum cpp_ttype);
3842   const char *get_string ();
3843   const char *get_ident ();
3844   const cpp_token *eat_ident (const char *);
3845   const char *get_number ();
3846 
3847   unsigned get_internal_capture_id ();
3848 
3849   id_base *parse_operation ();
3850   operand *parse_capture (operand *, bool);
3851   operand *parse_expr ();
3852   c_expr *parse_c_expr (cpp_ttype);
3853   operand *parse_op ();
3854 
3855   void record_operlist (source_location, user_id *);
3856 
3857   void parse_pattern ();
3858   operand *parse_result (operand *, predicate_id *);
3859   void push_simplify (simplify::simplify_kind,
3860                           vec<simplify *>&, operand *, operand *);
3861   void parse_simplify (simplify::simplify_kind,
3862                            vec<simplify *>&, predicate_id *, operand *);
3863   void parse_for (source_location);
3864   void parse_if (source_location);
3865   void parse_predicates (source_location);
3866   void parse_operator_list (source_location);
3867 
3868   void finish_match_operand (operand *);
3869 
3870   cpp_reader *r;
3871   vec<c_expr *> active_ifs;
3872   vec<vec<user_id *> > active_fors;
3873   hash_set<user_id *> *oper_lists_set;
3874   vec<user_id *> oper_lists;
3875 
3876   cid_map_t *capture_ids;
3877   unsigned last_id;
3878 
3879 public:
3880   vec<simplify *> simplifiers;
3881   vec<predicate_id *> user_predicates;
3882   bool parsing_match_operand;
3883 };
3884 
3885 /* Lexing helpers.  */
3886 
3887 /* Read the next non-whitespace token from R.  */
3888 
3889 const cpp_token *
next()3890 parser::next ()
3891 {
3892   const cpp_token *token;
3893   do
3894     {
3895       token = cpp_get_token (r);
3896     }
3897   while (token->type == CPP_PADDING);
3898   return token;
3899 }
3900 
3901 /* Peek at the next non-whitespace token from R.  */
3902 
3903 const cpp_token *
peek(unsigned num)3904 parser::peek (unsigned num)
3905 {
3906   const cpp_token *token;
3907   unsigned i = 0;
3908   do
3909     {
3910       token = cpp_peek_token (r, i++);
3911     }
3912   while (token->type == CPP_PADDING
3913            || (--num > 0));
3914   /* If we peek at EOF this is a fatal error as it leaves the
3915      cpp_reader in unusable state.  Assume we really wanted a
3916      token and thus this EOF is unexpected.  */
3917   if (token->type == CPP_EOF)
3918     fatal_at (token, "unexpected end of file");
3919   return token;
3920 }
3921 
3922 /* Peek at the next identifier token (or return NULL if the next
3923    token is not an identifier or equal to ID if supplied).  */
3924 
3925 const cpp_token *
peek_ident(const char * id,unsigned num)3926 parser::peek_ident (const char *id, unsigned num)
3927 {
3928   const cpp_token *token = peek (num);
3929   if (token->type != CPP_NAME)
3930     return 0;
3931 
3932   if (id == 0)
3933     return token;
3934 
3935   const char *t = (const char *) CPP_HASHNODE (token->val.node.node)->ident.str;
3936   if (strcmp (id, t) == 0)
3937     return token;
3938 
3939   return 0;
3940 }
3941 
3942 /* Read the next token from R and assert it is of type TK.  */
3943 
3944 const cpp_token *
expect(enum cpp_ttype tk)3945 parser::expect (enum cpp_ttype tk)
3946 {
3947   const cpp_token *token = next ();
3948   if (token->type != tk)
3949     fatal_at (token, "expected %s, got %s",
3950                 cpp_type2name (tk, 0), cpp_type2name (token->type, 0));
3951 
3952   return token;
3953 }
3954 
3955 /* Consume the next token from R and assert it is of type TK.  */
3956 
3957 const cpp_token *
eat_token(enum cpp_ttype tk)3958 parser::eat_token (enum cpp_ttype tk)
3959 {
3960   return expect (tk);
3961 }
3962 
3963 /* Read the next token from R and assert it is of type CPP_STRING and
3964    return its value.  */
3965 
3966 const char *
get_string()3967 parser::get_string ()
3968 {
3969   const cpp_token *token = expect (CPP_STRING);
3970   return (const char *)token->val.str.text;
3971 }
3972 
3973 /* Read the next token from R and assert it is of type CPP_NAME and
3974    return its value.  */
3975 
3976 const char *
get_ident()3977 parser::get_ident ()
3978 {
3979   const cpp_token *token = expect (CPP_NAME);
3980   return (const char *)CPP_HASHNODE (token->val.node.node)->ident.str;
3981 }
3982 
3983 /* Eat an identifier token with value S from R.  */
3984 
3985 const cpp_token *
eat_ident(const char * s)3986 parser::eat_ident (const char *s)
3987 {
3988   const cpp_token *token = peek ();
3989   const char *t = get_ident ();
3990   if (strcmp (s, t) != 0)
3991     fatal_at (token, "expected '%s' got '%s'\n", s, t);
3992   return token;
3993 }
3994 
3995 /* Read the next token from R and assert it is of type CPP_NUMBER and
3996    return its value.  */
3997 
3998 const char *
get_number()3999 parser::get_number ()
4000 {
4001   const cpp_token *token = expect (CPP_NUMBER);
4002   return (const char *)token->val.str.text;
4003 }
4004 
4005 /* Return a capture ID that can be used internally.  */
4006 
4007 unsigned
get_internal_capture_id()4008 parser::get_internal_capture_id ()
4009 {
4010   unsigned newid = capture_ids->elements ();
4011   /* Big enough for a 32-bit UINT_MAX plus prefix.  */
4012   char id[13];
4013   bool existed;
4014   sprintf (id, "__%u", newid);
4015   capture_ids->get_or_insert (xstrdup (id), &existed);
4016   if (existed)
4017     fatal ("reserved capture id '%s' already used", id);
4018   return newid;
4019 }
4020 
4021 /* Record an operator-list use for transparent for handling.  */
4022 
4023 void
record_operlist(source_location loc,user_id * p)4024 parser::record_operlist (source_location loc, user_id *p)
4025 {
4026   if (!oper_lists_set->add (p))
4027     {
4028       if (!oper_lists.is_empty ()
4029             && oper_lists[0]->substitutes.length () != p->substitutes.length ())
4030           fatal_at (loc, "User-defined operator list does not have the "
4031                       "same number of entries as others used in the pattern");
4032       oper_lists.safe_push (p);
4033     }
4034 }
4035 
4036 /* Parse the operator ID, special-casing convert?, convert1? and
4037    convert2?  */
4038 
4039 id_base *
parse_operation()4040 parser::parse_operation ()
4041 {
4042   const cpp_token *id_tok = peek ();
4043   const char *id = get_ident ();
4044   const cpp_token *token = peek ();
4045   if (strcmp (id, "convert0") == 0)
4046     fatal_at (id_tok, "use 'convert?' here");
4047   else if (strcmp (id, "view_convert0") == 0)
4048     fatal_at (id_tok, "use 'view_convert?' here");
4049   if (token->type == CPP_QUERY
4050       && !(token->flags & PREV_WHITE))
4051     {
4052       if (strcmp (id, "convert") == 0)
4053           id = "convert0";
4054       else if (strcmp (id, "convert1") == 0)
4055           ;
4056       else if (strcmp (id, "convert2") == 0)
4057           ;
4058       else if (strcmp (id, "view_convert") == 0)
4059           id = "view_convert0";
4060       else if (strcmp (id, "view_convert1") == 0)
4061           ;
4062       else if (strcmp (id, "view_convert2") == 0)
4063           ;
4064       else
4065           fatal_at (id_tok, "non-convert operator conditionalized");
4066 
4067       if (!parsing_match_operand)
4068           fatal_at (id_tok, "conditional convert can only be used in "
4069                       "match expression");
4070       eat_token (CPP_QUERY);
4071     }
4072   else if (strcmp (id, "convert1") == 0
4073              || strcmp (id, "convert2") == 0
4074              || strcmp (id, "view_convert1") == 0
4075              || strcmp (id, "view_convert2") == 0)
4076     fatal_at (id_tok, "expected '?' after conditional operator");
4077   id_base *op = get_operator (id);
4078   if (!op)
4079     fatal_at (id_tok, "unknown operator %s", id);
4080 
4081   user_id *p = dyn_cast<user_id *> (op);
4082   if (p && p->is_oper_list)
4083     {
4084       if (active_fors.length() == 0)
4085           record_operlist (id_tok->src_loc, p);
4086       else
4087           fatal_at (id_tok, "operator-list %s cannot be exapnded inside 'for'", id);
4088     }
4089   return op;
4090 }
4091 
4092 /* Parse a capture.
4093      capture = '@'<number>  */
4094 
4095 struct operand *
parse_capture(operand * op,bool require_existing)4096 parser::parse_capture (operand *op, bool require_existing)
4097 {
4098   source_location src_loc = eat_token (CPP_ATSIGN)->src_loc;
4099   const cpp_token *token = peek ();
4100   const char *id = NULL;
4101   bool value_match = false;
4102   /* For matches parse @@ as a value-match denoting the prevailing operand.  */
4103   if (token->type == CPP_ATSIGN
4104       && ! (token->flags & PREV_WHITE)
4105       && parsing_match_operand)
4106     {
4107       eat_token (CPP_ATSIGN);
4108       token = peek ();
4109       value_match = true;
4110     }
4111   if (token->type == CPP_NUMBER)
4112     id = get_number ();
4113   else if (token->type == CPP_NAME)
4114     id = get_ident ();
4115   else
4116     fatal_at (token, "expected number or identifier");
4117   unsigned next_id = capture_ids->elements ();
4118   bool existed;
4119   unsigned &num = capture_ids->get_or_insert (id, &existed);
4120   if (!existed)
4121     {
4122       if (require_existing)
4123           fatal_at (src_loc, "unknown capture id");
4124       num = next_id;
4125     }
4126   return new capture (src_loc, num, op, value_match);
4127 }
4128 
4129 /* Parse an expression
4130      expr = '(' <operation>[capture][flag][type] <operand>... ')'  */
4131 
4132 struct operand *
parse_expr()4133 parser::parse_expr ()
4134 {
4135   const cpp_token *token = peek ();
4136   expr *e = new expr (parse_operation (), token->src_loc);
4137   token = peek ();
4138   operand *op;
4139   bool is_commutative = false;
4140   bool force_capture = false;
4141   const char *expr_type = NULL;
4142 
4143   if (token->type == CPP_COLON
4144       && !(token->flags & PREV_WHITE))
4145     {
4146       eat_token (CPP_COLON);
4147       token = peek ();
4148       if (token->type == CPP_NAME
4149             && !(token->flags & PREV_WHITE))
4150           {
4151             const char *s = get_ident ();
4152             if (!parsing_match_operand)
4153               expr_type = s;
4154             else
4155               {
4156                 const char *sp = s;
4157                 while (*sp)
4158                     {
4159                       if (*sp == 'c')
4160                         {
4161                           if (operator_id *p
4162                                   = dyn_cast<operator_id *> (e->operation))
4163                               {
4164                                 if (!commutative_tree_code (p->code)
4165                                     && !comparison_code_p (p->code))
4166                                   fatal_at (token, "operation is not commutative");
4167                               }
4168                           else if (user_id *p = dyn_cast<user_id *> (e->operation))
4169                               for (unsigned i = 0;
4170                                    i < p->substitutes.length (); ++i)
4171                                 {
4172                                   if (operator_id *q
4173                                           = dyn_cast<operator_id *> (p->substitutes[i]))
4174                                     {
4175                                         if (!commutative_tree_code (q->code)
4176                                             && !comparison_code_p (q->code))
4177                                           fatal_at (token, "operation %s is not "
4178                                                       "commutative", q->id);
4179                                     }
4180                                 }
4181                           is_commutative = true;
4182                         }
4183                       else if (*sp == 'C')
4184                         is_commutative = true;
4185                       else if (*sp == 's')
4186                         {
4187                           e->force_single_use = true;
4188                           force_capture = true;
4189                         }
4190                       else
4191                         fatal_at (token, "flag %c not recognized", *sp);
4192                       sp++;
4193                     }
4194               }
4195             token = peek ();
4196           }
4197       else
4198           fatal_at (token, "expected flag or type specifying identifier");
4199     }
4200 
4201   if (token->type == CPP_ATSIGN
4202       && !(token->flags & PREV_WHITE))
4203     op = parse_capture (e, false);
4204   else if (force_capture)
4205     {
4206       unsigned num = get_internal_capture_id ();
4207       op = new capture (token->src_loc, num, e, false);
4208     }
4209   else
4210     op = e;
4211   do
4212     {
4213       const cpp_token *token = peek ();
4214       if (token->type == CPP_CLOSE_PAREN)
4215           {
4216             if (e->operation->nargs != -1
4217                 && e->operation->nargs != (int) e->ops.length ())
4218               fatal_at (token, "'%s' expects %u operands, not %u",
4219                           e->operation->id, e->operation->nargs, e->ops.length ());
4220             if (is_commutative)
4221               {
4222                 if (e->ops.length () == 2)
4223                     e->is_commutative = true;
4224                 else
4225                     fatal_at (token, "only binary operators or function with "
4226                                 "two arguments can be marked commutative");
4227               }
4228             e->expr_type = expr_type;
4229             return op;
4230           }
4231       else if (!(token->flags & PREV_WHITE))
4232           fatal_at (token, "expected expression operand");
4233 
4234       e->append_op (parse_op ());
4235     }
4236   while (1);
4237 }
4238 
4239 /* Lex native C code delimited by START recording the preprocessing tokens
4240    for later processing.
4241      c_expr = ('{'|'(') <pp token>... ('}'|')')  */
4242 
4243 c_expr *
parse_c_expr(cpp_ttype start)4244 parser::parse_c_expr (cpp_ttype start)
4245 {
4246   const cpp_token *token;
4247   cpp_ttype end;
4248   unsigned opencnt;
4249   vec<cpp_token> code = vNULL;
4250   unsigned nr_stmts = 0;
4251   source_location loc = eat_token (start)->src_loc;
4252   if (start == CPP_OPEN_PAREN)
4253     end = CPP_CLOSE_PAREN;
4254   else if (start == CPP_OPEN_BRACE)
4255     end = CPP_CLOSE_BRACE;
4256   else
4257     gcc_unreachable ();
4258   opencnt = 1;
4259   do
4260     {
4261       token = next ();
4262 
4263       /* Count brace pairs to find the end of the expr to match.  */
4264       if (token->type == start)
4265           opencnt++;
4266       else if (token->type == end
4267                  && --opencnt == 0)
4268           break;
4269       else if (token->type == CPP_EOF)
4270           fatal_at (token, "unexpected end of file");
4271 
4272       /* This is a lame way of counting the number of statements.  */
4273       if (token->type == CPP_SEMICOLON)
4274           nr_stmts++;
4275 
4276       /* If this is possibly a user-defined identifier mark it used.  */
4277       if (token->type == CPP_NAME)
4278           {
4279             id_base *idb = get_operator ((const char *)CPP_HASHNODE
4280                                               (token->val.node.node)->ident.str);
4281             user_id *p;
4282             if (idb && (p = dyn_cast<user_id *> (idb)) && p->is_oper_list)
4283               record_operlist (token->src_loc, p);
4284           }
4285 
4286       /* Record the token.  */
4287       code.safe_push (*token);
4288     }
4289   while (1);
4290   return new c_expr (r, loc, code, nr_stmts, vNULL, capture_ids);
4291 }
4292 
4293 /* Parse an operand which is either an expression, a predicate or
4294    a standalone capture.
4295      op = predicate | expr | c_expr | capture  */
4296 
4297 struct operand *
parse_op()4298 parser::parse_op ()
4299 {
4300   const cpp_token *token = peek ();
4301   struct operand *op = NULL;
4302   if (token->type == CPP_OPEN_PAREN)
4303     {
4304       eat_token (CPP_OPEN_PAREN);
4305       op = parse_expr ();
4306       eat_token (CPP_CLOSE_PAREN);
4307     }
4308   else if (token->type == CPP_OPEN_BRACE)
4309     {
4310       op = parse_c_expr (CPP_OPEN_BRACE);
4311     }
4312   else
4313     {
4314       /* Remaining ops are either empty or predicates  */
4315       if (token->type == CPP_NAME)
4316           {
4317             const char *id = get_ident ();
4318             id_base *opr = get_operator (id);
4319             if (!opr)
4320               fatal_at (token, "expected predicate name");
4321             if (operator_id *code = dyn_cast <operator_id *> (opr))
4322               {
4323                 if (code->nargs != 0)
4324                     fatal_at (token, "using an operator with operands as predicate");
4325                 /* Parse the zero-operand operator "predicates" as
4326                      expression.  */
4327                 op = new expr (opr, token->src_loc);
4328               }
4329             else if (user_id *code = dyn_cast <user_id *> (opr))
4330               {
4331                 if (code->nargs != 0)
4332                     fatal_at (token, "using an operator with operands as predicate");
4333                 /* Parse the zero-operand operator "predicates" as
4334                      expression.  */
4335                 op = new expr (opr, token->src_loc);
4336               }
4337             else if (predicate_id *p = dyn_cast <predicate_id *> (opr))
4338               op = new predicate (p, token->src_loc);
4339             else
4340               fatal_at (token, "using an unsupported operator as predicate");
4341             if (!parsing_match_operand)
4342               fatal_at (token, "predicates are only allowed in match expression");
4343             token = peek ();
4344             if (token->flags & PREV_WHITE)
4345               return op;
4346           }
4347       else if (token->type != CPP_COLON
4348                  && token->type != CPP_ATSIGN)
4349           fatal_at (token, "expected expression or predicate");
4350       /* optionally followed by a capture and a predicate.  */
4351       if (token->type == CPP_COLON)
4352           fatal_at (token, "not implemented: predicate on leaf operand");
4353       if (token->type == CPP_ATSIGN)
4354           op = parse_capture (op, !parsing_match_operand);
4355     }
4356 
4357   return op;
4358 }
4359 
4360 /* Create a new simplify from the current parsing state and MATCH,
4361    MATCH_LOC, RESULT and RESULT_LOC and push it to SIMPLIFIERS.  */
4362 
4363 void
push_simplify(simplify::simplify_kind kind,vec<simplify * > & simplifiers,operand * match,operand * result)4364 parser::push_simplify (simplify::simplify_kind kind,
4365                            vec<simplify *>& simplifiers,
4366                            operand *match, operand *result)
4367 {
4368   /* Build and push a temporary for operator list uses in expressions.  */
4369   if (!oper_lists.is_empty ())
4370     active_fors.safe_push (oper_lists);
4371 
4372   simplifiers.safe_push
4373     (new simplify (kind, last_id++, match, result,
4374                        active_fors.copy (), capture_ids));
4375 
4376   if (!oper_lists.is_empty ())
4377     active_fors.pop ();
4378 }
4379 
4380 /* Parse
4381      <result-op> = <op> | <if> | <with>
4382      <if> = '(' 'if' '(' <c-expr> ')' <result-op> ')'
4383      <with> = '(' 'with' '{' <c-expr> '}' <result-op> ')'
4384    and return it.  */
4385 
4386 operand *
parse_result(operand * result,predicate_id * matcher)4387 parser::parse_result (operand *result, predicate_id *matcher)
4388 {
4389   const cpp_token *token = peek ();
4390   if (token->type != CPP_OPEN_PAREN)
4391     return parse_op ();
4392 
4393   eat_token (CPP_OPEN_PAREN);
4394   if (peek_ident ("if"))
4395     {
4396       eat_ident ("if");
4397       if_expr *ife = new if_expr (token->src_loc);
4398       ife->cond = parse_c_expr (CPP_OPEN_PAREN);
4399       if (peek ()->type == CPP_OPEN_PAREN)
4400           {
4401             ife->trueexpr = parse_result (result, matcher);
4402             if (peek ()->type == CPP_OPEN_PAREN)
4403               ife->falseexpr = parse_result (result, matcher);
4404             else if (peek ()->type != CPP_CLOSE_PAREN)
4405               ife->falseexpr = parse_op ();
4406           }
4407       else if (peek ()->type != CPP_CLOSE_PAREN)
4408           {
4409             ife->trueexpr = parse_op ();
4410             if (peek ()->type == CPP_OPEN_PAREN)
4411               ife->falseexpr = parse_result (result, matcher);
4412             else if (peek ()->type != CPP_CLOSE_PAREN)
4413               ife->falseexpr = parse_op ();
4414           }
4415       /* If this if is immediately closed then it contains a
4416            manual matcher or is part of a predicate definition.  */
4417       else /* if (peek ()->type == CPP_CLOSE_PAREN) */
4418           {
4419             if (!matcher)
4420               fatal_at (peek (), "manual transform not implemented");
4421             ife->trueexpr = result;
4422           }
4423       eat_token (CPP_CLOSE_PAREN);
4424       return ife;
4425     }
4426   else if (peek_ident ("with"))
4427     {
4428       eat_ident ("with");
4429       with_expr *withe = new with_expr (token->src_loc);
4430       /* Parse (with c-expr expr) as (if-with (true) expr).  */
4431       withe->with = parse_c_expr (CPP_OPEN_BRACE);
4432       withe->with->nr_stmts = 0;
4433       withe->subexpr = parse_result (result, matcher);
4434       eat_token (CPP_CLOSE_PAREN);
4435       return withe;
4436     }
4437   else if (peek_ident ("switch"))
4438     {
4439       token = eat_ident ("switch");
4440       source_location ifloc = eat_token (CPP_OPEN_PAREN)->src_loc;
4441       eat_ident ("if");
4442       if_expr *ife = new if_expr (ifloc);
4443       operand *res = ife;
4444       ife->cond = parse_c_expr (CPP_OPEN_PAREN);
4445       if (peek ()->type == CPP_OPEN_PAREN)
4446           ife->trueexpr = parse_result (result, matcher);
4447       else
4448           ife->trueexpr = parse_op ();
4449       eat_token (CPP_CLOSE_PAREN);
4450       if (peek ()->type != CPP_OPEN_PAREN
4451             || !peek_ident ("if", 2))
4452           fatal_at (token, "switch can be implemented with a single if");
4453       while  (peek ()->type != CPP_CLOSE_PAREN)
4454           {
4455             if (peek ()->type == CPP_OPEN_PAREN)
4456               {
4457                 if (peek_ident ("if", 2))
4458                     {
4459                       ifloc = eat_token (CPP_OPEN_PAREN)->src_loc;
4460                       eat_ident ("if");
4461                       ife->falseexpr = new if_expr (ifloc);
4462                       ife = as_a <if_expr *> (ife->falseexpr);
4463                       ife->cond = parse_c_expr (CPP_OPEN_PAREN);
4464                       if (peek ()->type == CPP_OPEN_PAREN)
4465                         ife->trueexpr = parse_result (result, matcher);
4466                       else
4467                         ife->trueexpr = parse_op ();
4468                       eat_token (CPP_CLOSE_PAREN);
4469                     }
4470                 else
4471                     {
4472                       /* switch default clause */
4473                       ife->falseexpr = parse_result (result, matcher);
4474                       eat_token (CPP_CLOSE_PAREN);
4475                       return res;
4476                     }
4477               }
4478             else
4479               {
4480                 /* switch default clause */
4481                 ife->falseexpr = parse_op ();
4482                 eat_token (CPP_CLOSE_PAREN);
4483                 return res;
4484               }
4485           }
4486       eat_token (CPP_CLOSE_PAREN);
4487       return res;
4488     }
4489   else
4490     {
4491       operand *op = result;
4492       if (!matcher)
4493           op = parse_expr ();
4494       eat_token (CPP_CLOSE_PAREN);
4495       return op;
4496     }
4497 }
4498 
4499 /* Parse
4500      simplify = 'simplify' <expr> <result-op>
4501    or
4502      match = 'match' <ident> <expr> [<result-op>]
4503    and fill SIMPLIFIERS with the results.  */
4504 
4505 void
parse_simplify(simplify::simplify_kind kind,vec<simplify * > & simplifiers,predicate_id * matcher,operand * result)4506 parser::parse_simplify (simplify::simplify_kind kind,
4507                               vec<simplify *>& simplifiers, predicate_id *matcher,
4508                               operand *result)
4509 {
4510   /* Reset the capture map.  */
4511   if (!capture_ids)
4512     capture_ids = new cid_map_t;
4513   /* Reset oper_lists and set.  */
4514   hash_set <user_id *> olist;
4515   oper_lists_set = &olist;
4516   oper_lists = vNULL;
4517 
4518   const cpp_token *loc = peek ();
4519   parsing_match_operand = true;
4520   struct operand *match = parse_op ();
4521   finish_match_operand (match);
4522   parsing_match_operand = false;
4523   if (match->type == operand::OP_CAPTURE && !matcher)
4524     fatal_at (loc, "outermost expression cannot be captured");
4525   if (match->type == operand::OP_EXPR
4526       && is_a <predicate_id *> (as_a <expr *> (match)->operation))
4527     fatal_at (loc, "outermost expression cannot be a predicate");
4528 
4529   /* Splice active_ifs onto result and continue parsing the
4530      "then" expr.  */
4531   if_expr *active_if = NULL;
4532   for (int i = active_ifs.length (); i > 0; --i)
4533     {
4534       if_expr *ifc = new if_expr (active_ifs[i-1]->location);
4535       ifc->cond = active_ifs[i-1];
4536       ifc->trueexpr = active_if;
4537       active_if = ifc;
4538     }
4539   if_expr *outermost_if = active_if;
4540   while (active_if && active_if->trueexpr)
4541     active_if = as_a <if_expr *> (active_if->trueexpr);
4542 
4543   const cpp_token *token = peek ();
4544 
4545   /* If this if is immediately closed then it is part of a predicate
4546      definition.  Push it.  */
4547   if (token->type == CPP_CLOSE_PAREN)
4548     {
4549       if (!matcher)
4550           fatal_at (token, "expected transform expression");
4551       if (active_if)
4552           {
4553             active_if->trueexpr = result;
4554             result = outermost_if;
4555           }
4556       push_simplify (kind, simplifiers, match, result);
4557       return;
4558     }
4559 
4560   operand *tem = parse_result (result, matcher);
4561   if (active_if)
4562     {
4563       active_if->trueexpr = tem;
4564       result = outermost_if;
4565     }
4566   else
4567     result = tem;
4568 
4569   push_simplify (kind, simplifiers, match, result);
4570 }
4571 
4572 /* Parsing of the outer control structures.  */
4573 
4574 /* Parse a for expression
4575      for = '(' 'for' <subst>... <pattern> ')'
4576      subst = <ident> '(' <ident>... ')'  */
4577 
4578 void
parse_for(source_location)4579 parser::parse_for (source_location)
4580 {
4581   auto_vec<const cpp_token *> user_id_tokens;
4582   vec<user_id *> user_ids = vNULL;
4583   const cpp_token *token;
4584   unsigned min_n_opers = 0, max_n_opers = 0;
4585 
4586   while (1)
4587     {
4588       token = peek ();
4589       if (token->type != CPP_NAME)
4590           break;
4591 
4592       /* Insert the user defined operators into the operator hash.  */
4593       const char *id = get_ident ();
4594       if (get_operator (id, true) != NULL)
4595           fatal_at (token, "operator already defined");
4596       user_id *op = new user_id (id);
4597       id_base **slot = operators->find_slot_with_hash (op, op->hashval, INSERT);
4598       *slot = op;
4599       user_ids.safe_push (op);
4600       user_id_tokens.safe_push (token);
4601 
4602       eat_token (CPP_OPEN_PAREN);
4603 
4604       int arity = -1;
4605       while ((token = peek_ident ()) != 0)
4606           {
4607             const char *oper = get_ident ();
4608             id_base *idb = get_operator (oper, true);
4609             if (idb == NULL)
4610               fatal_at (token, "no such operator '%s'", oper);
4611             if (*idb == CONVERT0 || *idb == CONVERT1 || *idb == CONVERT2
4612                 || *idb == VIEW_CONVERT0 || *idb == VIEW_CONVERT1
4613                 || *idb == VIEW_CONVERT2)
4614               fatal_at (token, "conditional operators cannot be used inside for");
4615 
4616             if (arity == -1)
4617               arity = idb->nargs;
4618             else if (idb->nargs == -1)
4619               ;
4620             else if (idb->nargs != arity)
4621               fatal_at (token, "operator '%s' with arity %d does not match "
4622                           "others with arity %d", oper, idb->nargs, arity);
4623 
4624             user_id *p = dyn_cast<user_id *> (idb);
4625             if (p)
4626               {
4627                 if (p->is_oper_list)
4628                     op->substitutes.safe_splice (p->substitutes);
4629                 else
4630                     fatal_at (token, "iterator cannot be used as operator-list");
4631               }
4632             else
4633               op->substitutes.safe_push (idb);
4634           }
4635       op->nargs = arity;
4636       token = expect (CPP_CLOSE_PAREN);
4637 
4638       unsigned nsubstitutes = op->substitutes.length ();
4639       if (nsubstitutes == 0)
4640           fatal_at (token, "A user-defined operator must have at least "
4641                       "one substitution");
4642       if (max_n_opers == 0)
4643           {
4644             min_n_opers = nsubstitutes;
4645             max_n_opers = nsubstitutes;
4646           }
4647       else
4648           {
4649             if (nsubstitutes % min_n_opers != 0
4650                 && min_n_opers % nsubstitutes != 0)
4651               fatal_at (token, "All user-defined identifiers must have a "
4652                           "multiple number of operator substitutions of the "
4653                           "smallest number of substitutions");
4654             if (nsubstitutes < min_n_opers)
4655               min_n_opers = nsubstitutes;
4656             else if (nsubstitutes > max_n_opers)
4657               max_n_opers = nsubstitutes;
4658           }
4659     }
4660 
4661   unsigned n_ids = user_ids.length ();
4662   if (n_ids == 0)
4663     fatal_at (token, "for requires at least one user-defined identifier");
4664 
4665   token = peek ();
4666   if (token->type == CPP_CLOSE_PAREN)
4667     fatal_at (token, "no pattern defined in for");
4668 
4669   active_fors.safe_push (user_ids);
4670   while (1)
4671     {
4672       token = peek ();
4673       if (token->type == CPP_CLOSE_PAREN)
4674           break;
4675       parse_pattern ();
4676     }
4677   active_fors.pop ();
4678 
4679   /* Remove user-defined operators from the hash again.  */
4680   for (unsigned i = 0; i < user_ids.length (); ++i)
4681     {
4682       if (!user_ids[i]->used)
4683           warning_at (user_id_tokens[i],
4684                         "operator %s defined but not used", user_ids[i]->id);
4685       operators->remove_elt (user_ids[i]);
4686     }
4687 }
4688 
4689 /* Parse an identifier associated with a list of operators.
4690      oprs = '(' 'define_operator_list' <ident> <ident>... ')'  */
4691 
4692 void
parse_operator_list(source_location)4693 parser::parse_operator_list (source_location)
4694 {
4695   const cpp_token *token = peek ();
4696   const char *id = get_ident ();
4697 
4698   if (get_operator (id, true) != 0)
4699     fatal_at (token, "operator %s already defined", id);
4700 
4701   user_id *op = new user_id (id, true);
4702   int arity = -1;
4703 
4704   while ((token = peek_ident ()) != 0)
4705     {
4706       token = peek ();
4707       const char *oper = get_ident ();
4708       id_base *idb = get_operator (oper, true);
4709 
4710       if (idb == 0)
4711           fatal_at (token, "no such operator '%s'", oper);
4712 
4713       if (arity == -1)
4714           arity = idb->nargs;
4715       else if (idb->nargs == -1)
4716           ;
4717       else if (arity != idb->nargs)
4718           fatal_at (token, "operator '%s' with arity %d does not match "
4719                                "others with arity %d", oper, idb->nargs, arity);
4720 
4721       /* We allow composition of multiple operator lists.  */
4722       if (user_id *p = dyn_cast<user_id *> (idb))
4723           op->substitutes.safe_splice (p->substitutes);
4724       else
4725           op->substitutes.safe_push (idb);
4726     }
4727 
4728   // Check that there is no junk after id-list
4729   token = peek();
4730   if (token->type != CPP_CLOSE_PAREN)
4731     fatal_at (token, "expected identifier got %s", cpp_type2name (token->type, 0));
4732 
4733   if (op->substitutes.length () == 0)
4734     fatal_at (token, "operator-list cannot be empty");
4735 
4736   op->nargs = arity;
4737   id_base **slot = operators->find_slot_with_hash (op, op->hashval, INSERT);
4738   *slot = op;
4739 }
4740 
4741 /* Parse an outer if expression.
4742      if = '(' 'if' '(' <c-expr> ')' <pattern> ')'  */
4743 
4744 void
parse_if(source_location)4745 parser::parse_if (source_location)
4746 {
4747   c_expr *ifexpr = parse_c_expr (CPP_OPEN_PAREN);
4748 
4749   const cpp_token *token = peek ();
4750   if (token->type == CPP_CLOSE_PAREN)
4751     fatal_at (token, "no pattern defined in if");
4752 
4753   active_ifs.safe_push (ifexpr);
4754   while (1)
4755     {
4756       const cpp_token *token = peek ();
4757       if (token->type == CPP_CLOSE_PAREN)
4758           break;
4759 
4760       parse_pattern ();
4761     }
4762   active_ifs.pop ();
4763 }
4764 
4765 /* Parse a list of predefined predicate identifiers.
4766      preds = '(' 'define_predicates' <ident>... ')'  */
4767 
4768 void
parse_predicates(source_location)4769 parser::parse_predicates (source_location)
4770 {
4771   do
4772     {
4773       const cpp_token *token = peek ();
4774       if (token->type != CPP_NAME)
4775           break;
4776 
4777       add_predicate (get_ident ());
4778     }
4779   while (1);
4780 }
4781 
4782 /* Parse outer control structures.
4783      pattern = <preds>|<for>|<if>|<simplify>|<match>  */
4784 
4785 void
parse_pattern()4786 parser::parse_pattern ()
4787 {
4788   /* All clauses start with '('.  */
4789   eat_token (CPP_OPEN_PAREN);
4790   const cpp_token *token = peek ();
4791   const char *id = get_ident ();
4792   if (strcmp (id, "simplify") == 0)
4793     {
4794       parse_simplify (simplify::SIMPLIFY, simplifiers, NULL, NULL);
4795       capture_ids = NULL;
4796     }
4797   else if (strcmp (id, "match") == 0)
4798     {
4799       bool with_args = false;
4800       source_location e_loc = peek ()->src_loc;
4801       if (peek ()->type == CPP_OPEN_PAREN)
4802           {
4803             eat_token (CPP_OPEN_PAREN);
4804             with_args = true;
4805           }
4806       const char *name = get_ident ();
4807       id_base *id = get_operator (name);
4808       predicate_id *p;
4809       if (!id)
4810           {
4811             p = add_predicate (name);
4812             user_predicates.safe_push (p);
4813           }
4814       else if ((p = dyn_cast <predicate_id *> (id)))
4815           ;
4816       else
4817           fatal_at (token, "cannot add a match to a non-predicate ID");
4818       /* Parse (match <id> <arg>... (match-expr)) here.  */
4819       expr *e = NULL;
4820       if (with_args)
4821           {
4822             capture_ids = new cid_map_t;
4823             e = new expr (p, e_loc);
4824             while (peek ()->type == CPP_ATSIGN)
4825               e->append_op (parse_capture (NULL, false));
4826             eat_token (CPP_CLOSE_PAREN);
4827           }
4828       if (p->nargs != -1
4829             && ((e && e->ops.length () != (unsigned)p->nargs)
4830                 || (!e && p->nargs != 0)))
4831           fatal_at (token, "non-matching number of match operands");
4832       p->nargs = e ? e->ops.length () : 0;
4833       parse_simplify (simplify::MATCH, p->matchers, p, e);
4834       capture_ids = NULL;
4835     }
4836   else if (strcmp (id, "for") == 0)
4837     parse_for (token->src_loc);
4838   else if (strcmp (id, "if") == 0)
4839     parse_if (token->src_loc);
4840   else if (strcmp (id, "define_predicates") == 0)
4841     {
4842       if (active_ifs.length () > 0
4843             || active_fors.length () > 0)
4844           fatal_at (token, "define_predicates inside if or for is not supported");
4845       parse_predicates (token->src_loc);
4846     }
4847   else if (strcmp (id, "define_operator_list") == 0)
4848     {
4849       if (active_ifs.length () > 0
4850             || active_fors.length () > 0)
4851           fatal_at (token, "operator-list inside if or for is not supported");
4852       parse_operator_list (token->src_loc);
4853     }
4854   else
4855     fatal_at (token, "expected %s'simplify', 'match', 'for' or 'if'",
4856                 active_ifs.length () == 0 && active_fors.length () == 0
4857                 ? "'define_predicates', " : "");
4858 
4859   eat_token (CPP_CLOSE_PAREN);
4860 }
4861 
4862 /* Helper for finish_match_operand, collecting captures of OP in CPTS
4863    recursively.  */
4864 
4865 static void
walk_captures(operand * op,vec<vec<capture * >> cpts)4866 walk_captures (operand *op, vec<vec<capture *> > cpts)
4867 {
4868   if (! op)
4869     return;
4870 
4871   if (capture *c = dyn_cast <capture *> (op))
4872     {
4873       cpts[c->where].safe_push (c);
4874       walk_captures (c->what, cpts);
4875     }
4876   else if (expr *e = dyn_cast <expr *> (op))
4877     for (unsigned i = 0; i < e->ops.length (); ++i)
4878       walk_captures (e->ops[i], cpts);
4879 }
4880 
4881 /* Finish up OP which is a match operand.  */
4882 
4883 void
finish_match_operand(operand * op)4884 parser::finish_match_operand (operand *op)
4885 {
4886   /* Look for matching captures, diagnose mis-uses of @@ and apply
4887      early lowering and distribution of value_match.  */
4888   auto_vec<vec<capture *> > cpts;
4889   cpts.safe_grow_cleared (capture_ids->elements ());
4890   walk_captures (op, cpts);
4891   for (unsigned i = 0; i < cpts.length (); ++i)
4892     {
4893       capture *value_match = NULL;
4894       for (unsigned j = 0; j < cpts[i].length (); ++j)
4895           {
4896             if (cpts[i][j]->value_match)
4897               {
4898                 if (value_match)
4899                     fatal_at (cpts[i][j]->location, "duplicate @@");
4900                 value_match = cpts[i][j];
4901               }
4902           }
4903       if (cpts[i].length () == 1 && value_match)
4904           fatal_at (value_match->location, "@@ without a matching capture");
4905       if (value_match)
4906           {
4907             /* Duplicate prevailing capture with the existing ID, create
4908                a fake ID and rewrite all captures to use it.  This turns
4909                @@1 into @__<newid>@1 and @1 into @__<newid>.  */
4910             value_match->what = new capture (value_match->location,
4911                                                      value_match->where,
4912                                                      value_match->what, false);
4913             /* Create a fake ID and rewrite all captures to use it.  */
4914             unsigned newid = get_internal_capture_id ();
4915             for (unsigned j = 0; j < cpts[i].length (); ++j)
4916               {
4917                 cpts[i][j]->where = newid;
4918                 cpts[i][j]->value_match = true;
4919               }
4920           }
4921       cpts[i].release ();
4922     }
4923 }
4924 
4925 /* Main entry of the parser.  Repeatedly parse outer control structures.  */
4926 
parser(cpp_reader * r_)4927 parser::parser (cpp_reader *r_)
4928 {
4929   r = r_;
4930   active_ifs = vNULL;
4931   active_fors = vNULL;
4932   simplifiers = vNULL;
4933   oper_lists_set = NULL;
4934   oper_lists = vNULL;
4935   capture_ids = NULL;
4936   user_predicates = vNULL;
4937   parsing_match_operand = false;
4938   last_id = 0;
4939 
4940   const cpp_token *token = next ();
4941   while (token->type != CPP_EOF)
4942     {
4943       _cpp_backup_tokens (r, 1);
4944       parse_pattern ();
4945       token = next ();
4946     }
4947 }
4948 
4949 
4950 /* Helper for the linemap code.  */
4951 
4952 static size_t
round_alloc_size(size_t s)4953 round_alloc_size (size_t s)
4954 {
4955   return s;
4956 }
4957 
4958 
4959 /* The genmatch generator progam.  It reads from a pattern description
4960    and outputs GIMPLE or GENERIC IL matching and simplification routines.  */
4961 
4962 int
main(int argc,char ** argv)4963 main (int argc, char **argv)
4964 {
4965   cpp_reader *r;
4966 
4967   progname = "genmatch";
4968 
4969   if (argc < 2)
4970     return 1;
4971 
4972   bool gimple = true;
4973   char *input = argv[argc-1];
4974   for (int i = 1; i < argc - 1; ++i)
4975     {
4976       if (strcmp (argv[i], "--gimple") == 0)
4977           gimple = true;
4978       else if (strcmp (argv[i], "--generic") == 0)
4979           gimple = false;
4980       else if (strcmp (argv[i], "-v") == 0)
4981           verbose = 1;
4982       else if (strcmp (argv[i], "-vv") == 0)
4983           verbose = 2;
4984       else
4985           {
4986             fprintf (stderr, "Usage: genmatch "
4987                        "[--gimple] [--generic] [-v[v]] input\n");
4988             return 1;
4989           }
4990     }
4991 
4992   line_table = XCNEW (struct line_maps);
4993   linemap_init (line_table, 0);
4994   line_table->reallocator = xrealloc;
4995   line_table->round_alloc_size = round_alloc_size;
4996 
4997   r = cpp_create_reader (CLK_GNUC99, NULL, line_table);
4998   cpp_callbacks *cb = cpp_get_callbacks (r);
4999   cb->error = error_cb;
5000 
5001   /* Add the build directory to the #include "" search path.  */
5002   cpp_dir *dir = XCNEW (cpp_dir);
5003   dir->name = getpwd ();
5004   if (!dir->name)
5005     dir->name = ASTRDUP (".");
5006   cpp_set_include_chains (r, dir, NULL, false);
5007 
5008   if (!cpp_read_main_file (r, input))
5009     return 1;
5010   cpp_define (r, gimple ? "GIMPLE=1": "GENERIC=1");
5011   cpp_define (r, gimple ? "GENERIC=0": "GIMPLE=0");
5012 
5013   null_id = new id_base (id_base::NULL_ID, "null");
5014 
5015   /* Pre-seed operators.  */
5016   operators = new hash_table<id_base> (1024);
5017 #define DEFTREECODE(SYM, STRING, TYPE, NARGS) \
5018   add_operator (SYM, # SYM, # TYPE, NARGS);
5019 #define END_OF_BASE_TREE_CODES
5020 #include "tree.def"
5021 add_operator (CONVERT0, "convert0", "tcc_unary", 1);
5022 add_operator (CONVERT1, "convert1", "tcc_unary", 1);
5023 add_operator (CONVERT2, "convert2", "tcc_unary", 1);
5024 add_operator (VIEW_CONVERT0, "view_convert0", "tcc_unary", 1);
5025 add_operator (VIEW_CONVERT1, "view_convert1", "tcc_unary", 1);
5026 add_operator (VIEW_CONVERT2, "view_convert2", "tcc_unary", 1);
5027 #undef END_OF_BASE_TREE_CODES
5028 #undef DEFTREECODE
5029 
5030   /* Pre-seed builtin functions.
5031      ???  Cannot use N (name) as that is targetm.emultls.get_address
5032      for BUILT_IN_EMUTLS_GET_ADDRESS ... */
5033 #define DEF_BUILTIN(ENUM, N, C, T, LT, B, F, NA, AT, IM, COND) \
5034   add_function (ENUM, "CFN_" # ENUM);
5035 #include "builtins.def"
5036 
5037 #define DEF_INTERNAL_FN(CODE, NAME, FNSPEC) \
5038   add_function (IFN_##CODE, "CFN_" #CODE);
5039 #include "internal-fn.def"
5040 
5041   /* Parse ahead!  */
5042   parser p (r);
5043 
5044   if (gimple)
5045     write_header (stdout, "gimple-match-head.c");
5046   else
5047     write_header (stdout, "generic-match-head.c");
5048 
5049   /* Go over all predicates defined with patterns and perform
5050      lowering and code generation.  */
5051   for (unsigned i = 0; i < p.user_predicates.length (); ++i)
5052     {
5053       predicate_id *pred = p.user_predicates[i];
5054       lower (pred->matchers, gimple);
5055 
5056       if (verbose == 2)
5057           for (unsigned i = 0; i < pred->matchers.length (); ++i)
5058             print_matches (pred->matchers[i]);
5059 
5060       decision_tree dt;
5061       for (unsigned i = 0; i < pred->matchers.length (); ++i)
5062           dt.insert (pred->matchers[i], i);
5063 
5064       if (verbose == 2)
5065           dt.print (stderr);
5066 
5067       write_predicate (stdout, pred, dt, gimple);
5068     }
5069 
5070   /* Lower the main simplifiers and generate code for them.  */
5071   lower (p.simplifiers, gimple);
5072 
5073   if (verbose == 2)
5074     for (unsigned i = 0; i < p.simplifiers.length (); ++i)
5075       print_matches (p.simplifiers[i]);
5076 
5077   decision_tree dt;
5078   for (unsigned i = 0; i < p.simplifiers.length (); ++i)
5079     dt.insert (p.simplifiers[i], i);
5080 
5081   if (verbose == 2)
5082     dt.print (stderr);
5083 
5084   dt.gen (stdout, gimple);
5085 
5086   /* Finalize.  */
5087   cpp_finish (r, NULL);
5088   cpp_destroy (r);
5089 
5090   delete operators;
5091 
5092   return 0;
5093 }
5094