| blob | 0210ccfedb9b2b305194f1593699dcda62559b65 |
1 /* Statement simplification on GIMPLE.
2 Copyright (C) 2010, 2011, 2012 Free Software Foundation, Inc.
3 Split out from tree-ssa-ccp.c.
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it
8 under the terms of the GNU General Public License as published by the
9 Free Software Foundation; either version 3, or (at your option) any
10 later version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT
13 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
35 /* Return true when DECL can be referenced from current unit.
36 We can get declarations that are not possible to reference for
37 various reasons:
39 1) When analyzing C++ virtual tables.
40 C++ virtual tables do have known constructors even
41 when they are keyed to other compilation unit.
42 Those tables can contain pointers to methods and vars
43 in other units. Those methods have both STATIC and EXTERNAL
44 set.
45 2) In WHOPR mode devirtualization might lead to reference
46 to method that was partitioned elsehwere.
47 In this case we have static VAR_DECL or FUNCTION_DECL
48 that has no corresponding callgraph/varpool node
49 declaring the body.
50 3) COMDAT functions referred by external vtables that
51 we devirtualize only during final copmilation stage.
52 At this time we already decided that we will not output
53 the function body and thus we can't reference the symbol
54 directly. */
56 static bool
58 {
64 /* External flag is set, so we deal with C++ reference
65 to static object from other file. */
68 {
69 /* Just be sure it is not big in frontend setting
70 flags incorrectly. Those variables should never
71 be finalized. */
75 }
76 /* When function is public, we always can introduce new reference.
77 Exception are the COMDAT functions where introducing a direct
78 reference imply need to include function body in the curren tunit. */
81 /* We are not at ltrans stage; so don't worry about WHOPR.
82 Also when still gimplifying all referred comdat functions will be
83 produced.
84 ??? as observed in PR20991 for already optimized out comdat virtual functions
85 we may not neccesarily give up because the copy will be output elsewhere when
86 corresponding vtable is output. */
89 /* If we already output the function body, we are safe. */
93 {
95 /* Check that we still have function body and that we didn't took
96 the decision to eliminate offline copy of the function yet.
97 The second is important when devirtualization happens during final
98 compilation stage when making a new reference no longer makes callee
99 to be compiled. */
102 }
104 {
108 }
110 }
112 /* CVAL is value taken from DECL_INITIAL of variable. Try to transform it into
113 acceptable form for is_gimple_min_invariant. */
115 tree
117 {
122 {
128 ptr,
131 }
133 {
142 {
146 }
147 /* Fixup types in global initializers. */
154 }
156 }
158 /* If SYM is a constant variable with known value, return the value.
159 NULL_TREE is returned otherwise. */
161 tree
163 {
165 {
168 {
172 else
174 }
175 /* Variables declared 'const' without an initializer
176 have zero as the initializer if they may not be
177 overridden at link or run time. */
182 }
185 }
189 /* Subroutine of fold_stmt. We perform several simplifications of the
190 memory reference tree EXPR and make sure to re-gimplify them properly
191 after propagation of constant addresses. IS_LHS is true if the
192 reference is supposed to be an lvalue. */
194 static tree
196 {
198 tree result;
220 /* Canonicalize MEM_REFs invariant address operand. Do this first
221 to avoid feeding non-canonical MEM_REFs elsewhere. */
224 {
230 {
237 }
238 }
245 /* Fold back MEM_REFs to reference trees. */
254 /* We have to look out here to not drop a required conversion
255 from the rhs to the lhs if is_lhs, but we don't have the
256 rhs here to verify that. Thus require strict type
257 compatibility. */
261 {
262 tree tem;
268 }
270 {
273 {
279 }
280 }
283 }
286 /* Attempt to fold an assignment statement pointed-to by SI. Returns a
287 replacement rhs for the statement or NULL_TREE if no simplification
288 could be made. It is assumed that the operands have been previously
289 folded. */
291 static tree
293 {
301 {
303 {
310 {
323 }
329 {
330 /* Fold a constant vector CONSTRUCTOR to VECTOR_CST. */
332 tree val;
342 }
347 /* If we couldn't fold the RHS, hand over to the generic
348 fold routines. */
352 /* Strip away useless type conversions. Both the NON_LVALUE_EXPR
353 that may have been added by fold, and "useless" type
354 conversions that might now be apparent due to propagation. */
361 }
365 {
370 {
371 /* If the operation was a conversion do _not_ mark a
372 resulting constant with TREE_OVERFLOW if the original
373 constant was not. These conversions have implementation
374 defined behavior and retaining the TREE_OVERFLOW flag
375 here would confuse later passes such as VRP. */
384 }
385 }
389 /* Try to canonicalize for boolean-typed X the comparisons
390 X == 0, X == 1, X != 0, and X != 1. */
393 {
399 /* Check whether the comparison operands are of the same boolean
400 type as the result type is.
401 Check that second operand is an integer-constant with value
402 one or zero. */
406 {
410 /* X == 0 and X != 1 is a logical-not.of X
411 X == 1 and X != 0 is X */
418 /* Only for one-bit precision typed X the transformation
419 !X -> ~X is valied. */
423 /* Otherwise we use !X -> X ^ 1. */
424 else
428 }
429 }
438 {
442 }
446 /* Try to fold a conditional expression. */
448 {
450 tree tem;
455 {
461 /* This is actually a conditional expression, not a GIMPLE
462 conditional statement, however, the valid_gimple_rhs_p
463 test still applies. */
467 }
469 {
472 }
473 else
481 }
491 {
495 }
500 }
503 }
505 /* Attempt to fold a conditional statement. Return true if any changes were
506 made. We only attempt to fold the condition expression, and do not perform
507 any transformation that would require alteration of the cfg. It is
508 assumed that the operands have been previously folded. */
510 static bool
512 {
515 boolean_type_node,
520 {
523 {
526 }
527 }
530 }
532 /* Convert EXPR into a GIMPLE value suitable for substitution on the
533 RHS of an assignment. Insert the necessary statements before
534 iterator *SI_P. The statement at *SI_P, which must be a GIMPLE_CALL
535 is replaced. If the call is expected to produces a result, then it
536 is replaced by an assignment of the new RHS to the result variable.
537 If the result is to be ignored, then the call is replaced by a
538 GIMPLE_NOP. A proper VDEF chain is retained by making the first
539 VUSE and the last VDEF of the whole sequence be the same as the replaced
540 statement and using new SSA names for stores in between. */
542 void
544 {
545 tree lhs;
547 gimple_stmt_iterator i;
550 gimple last;
551 gimple laststore;
552 tree reaching_vuse;
563 {
565 /* We can end up with folding a memcpy of an empty class assignment
566 which gets optimized away by C++ gimplification. */
568 {
571 {
574 }
577 }
578 }
579 else
580 {
585 GSI_CONTINUE_LINKING);
586 }
593 /* First iterate over the replacement statements backward, assigning
594 virtual operands to their defining statements. */
597 {
604 {
605 tree vdef;
608 else
614 }
615 }
617 /* Second iterate over the statements forward, assigning virtual
618 operands to their uses. */
622 {
623 /* Do not insert the last stmt in this loop but remember it
624 for replacing the original statement. */
626 {
629 }
631 /* The replacement can expose previously unreferenced variables. */
634 /* If the new statement possibly has a VUSE, update it with exact SSA
635 name we know will reach this one. */
642 }
644 /* If the new sequence does not do a store release the virtual
645 definition of the original statement. */
648 {
652 {
655 }
656 }
658 /* Finally replace rhe original statement with the last. */
660 }
662 /* Return the string length, maximum string length or maximum value of
663 ARG in LENGTH.
664 If ARG is an SSA name variable, follow its use-def chains. If LENGTH
665 is not NULL and, for TYPE == 0, its value is not equal to the length
666 we determine or if we are unable to determine the length or value,
667 return false. VISITED is a bitmap of visited variables.
668 TYPE is 0 if string length should be returned, 1 for maximum string
669 length and 2 for maximum value ARG can have. */
671 static bool
673 {
675 gimple def_stmt;
678 {
679 /* We can end up with &(*iftmp_1)[0] here as well, so handle it. */
683 {
689 }
692 {
697 }
698 else
704 {
706 {
714 }
717 }
721 }
723 /* If we were already here, break the infinite cycle. */
731 {
733 /* The RHS of the statement defining VAR must either have a
734 constant length or come from another SSA_NAME with a constant
735 length. */
738 {
741 }
743 {
748 }
752 {
753 /* All the arguments of the PHI node must have the same constant
754 length. */
758 {
761 /* If this PHI has itself as an argument, we cannot
762 determine the string length of this argument. However,
763 if we can find a constant string length for the other
764 PHI args then we can still be sure that this is a
765 constant string length. So be optimistic and just
766 continue with the next argument. */
772 }
773 }
778 }
779 }
782 /* Fold builtin call in statement STMT. Returns a simplified tree.
783 We may return a non-constant expression, including another call
784 to a different function and with different arguments, e.g.,
785 substituting memcpy for strcpy when the string length is known.
786 Note that some builtins expand into inline code that may not
787 be valid in GIMPLE. Callers must take care. */
789 tree
791 {
795 bitmap visited;
804 /* First try the generic builtin folder. If that succeeds, return the
805 result directly. */
808 {
812 }
814 /* Ignore MD builtins. */
819 /* Give up for always_inline inline builtins until they are
820 inlined. */
824 /* If the builtin could not be folded, and it has no argument list,
825 we're done. */
830 /* Limit the work only for builtins we know how to simplify. */
832 {
865 }
870 /* Try to use the dataflow information gathered by the CCP process. */
883 {
886 {
887 tree new_val =
890 /* If the result is not a valid gimple value, or not a cast
891 of a valid gimple value, then we cannot use the result. */
896 }
975 }
980 }
982 /* Generate code adjusting the first parameter of a call statement determined
983 by GSI by DELTA. */
985 void
987 {
990 gimple new_stmt;
1004 }
1006 /* Return a binfo to be used for devirtualization of calls based on an object
1007 represented by a declaration (i.e. a global or automatically allocated one)
1008 or NULL if it cannot be found or is not safe. CST is expected to be an
1009 ADDR_EXPR of such object or the function will return NULL. Currently it is
1010 safe to use such binfo only if it has no base binfo (i.e. no ancestors). */
1012 tree
1014 {
1034 /* Find the sub-object the constant actually refers to and mark whether it is
1035 an artificial one (as opposed to a user-defined one). */
1037 {
1039 tree fld;
1047 {
1055 }
1062 }
1063 /* Artifical sub-objects are ancestors, we do not want to use them for
1064 devirtualization, at least not here. */
1070 else
1072 }
1074 /* Attempt to fold a call statement referenced by the statement iterator GSI.
1075 The statement may be replaced by another statement, e.g., if the call
1076 simplifies to a constant value. Return true if any changes were made.
1077 It is assumed that the operands have been previously folded. */
1079 static bool
1081 {
1083 tree callee;
1087 /* Fold *& in call arguments. */
1090 {
1093 {
1096 }
1097 }
1099 /* Check for virtual calls that became direct calls. */
1102 {
1104 {
1107 }
1108 else
1109 {
1113 {
1114 HOST_WIDE_INT token
1118 {
1121 }
1122 }
1123 }
1124 }
1129 /* Check for builtins that CCP can handle using information not
1130 available in the generic fold routines. */
1133 {
1136 {
1140 }
1141 }
1144 }
1146 /* Worker for both fold_stmt and fold_stmt_inplace. The INPLACE argument
1147 distinguishes both cases. */
1149 static bool
1151 {
1156 gimple next_stmt;
1161 /* Fold the main computation performed by the statement. */
1163 {
1165 {
1169 tree new_rhs;
1170 /* First canonicalize operand order. This avoids building new
1171 trees if this is the only thing fold would later do. */
1176 {
1181 }
1188 && (!inplace
1190 {
1193 }
1195 }
1206 /* Fold *& in asm operands. */
1207 {
1217 {
1224 {
1227 }
1228 }
1230 {
1233 constraint
1240 {
1243 }
1244 }
1245 }
1250 {
1254 {
1257 {
1260 }
1261 }
1264 {
1268 {
1272 }
1273 }
1274 }
1278 }
1280 /* If stmt folds into nothing and it was the last stmt in a bb,
1281 don't call gsi_stmt. */
1283 {
1286 }
1290 /* Fold *& on the lhs. Don't do this if stmt folded into nothing,
1291 as we'd changing the next stmt. */
1293 {
1296 {
1299 {
1302 }
1303 }
1304 }
1307 }
1309 /* Fold the statement pointed to by GSI. In some cases, this function may
1310 replace the whole statement with a new one. Returns true iff folding
1311 makes any changes.
1312 The statement pointed to by GSI should be in valid gimple form but may
1313 be in unfolded state as resulting from for example constant propagation
1314 which can produce *&x = 0. */
1316 bool
1318 {
1320 }
1322 /* Perform the minimal folding on statement *GSI. Only operations like
1323 *&x created by constant propagation are handled. The statement cannot
1324 be replaced with a new one. Return true if the statement was
1325 changed, false otherwise.
1326 The statement *GSI should be in valid gimple form but may
1327 be in unfolded state as resulting from for example constant propagation
1328 which can produce *&x = 0. */
1330 bool
1332 {
1337 }
1339 /* Canonicalize and possibly invert the boolean EXPR; return NULL_TREE
1340 if EXPR is null or we don't know how.
1341 If non-null, the result always has boolean type. */
1343 static tree
1345 {
1349 {
1359 boolean_type_node,
1362 else
1364 }
1365 else
1366 {
1378 boolean_type_node,
1381 else
1383 }
1384 }
1386 /* Check to see if a boolean expression EXPR is logically equivalent to the
1387 comparison (OP1 CODE OP2). Check for various identities involving
1388 SSA_NAMEs. */
1390 static bool
1393 {
1394 gimple s;
1396 /* The obvious case. */
1402 /* Check for comparing (name, name != 0) and the case where expr
1403 is an SSA_NAME with a definition matching the comparison. */
1406 {
1416 }
1418 /* If op1 is of the form (name != 0) or (name == 0), and the definition
1419 of name is a comparison, recurse. */
1422 {
1426 {
1439 }
1440 }
1442 }
1444 /* Check to see if two boolean expressions OP1 and OP2 are logically
1445 equivalent. */
1447 static bool
1449 {
1450 /* Simple cases first. */
1454 /* Check the cases where at least one of the operands is a comparison.
1455 These are a bit smarter than operand_equal_p in that they apply some
1456 identifies on SSA_NAMEs. */
1468 /* Default case. */
1470 }
1472 /* Forward declarations for some mutually recursive functions. */
1474 static tree
1477 static tree
1480 static tree
1483 static tree
1486 static tree
1489 static tree
1493 /* Helper function for and_comparisons_1: try to simplify the AND of the
1494 ssa variable VAR with the comparison specified by (OP2A CODE2 OP2B).
1495 If INVERT is true, invert the value of the VAR before doing the AND.
1496 Return NULL_EXPR if we can't simplify this to a single expression. */
1498 static tree
1501 {
1502 tree t;
1505 /* We can only deal with variables whose definitions are assignments. */
1509 /* If we have an inverted comparison, apply DeMorgan's law and rewrite
1510 !var AND (op2a code2 op2b) => !(var OR !(op2a code2 op2b))
1511 Then we only have to consider the simpler non-inverted cases. */
1516 else
1519 }
1521 /* Try to simplify the AND of the ssa variable defined by the assignment
1522 STMT with the comparison specified by (OP2A CODE2 OP2B).
1523 Return NULL_EXPR if we can't simplify this to a single expression. */
1525 static tree
1528 {
1534 /* Check for identities like (var AND (var == 0)) => false. */
1537 {
1540 {
1544 }
1547 {
1551 }
1552 }
1554 /* If the definition is a comparison, recurse on it. */
1556 {
1560 code2,
1561 op2a,
1562 op2b);
1565 }
1567 /* If the definition is an AND or OR expression, we may be able to
1568 simplify by reassociating. */
1571 {
1574 gimple s;
1575 tree t;
1579 /* Check for boolean identities that don't require recursive examination
1580 of inner1/inner2:
1581 inner1 AND (inner1 AND inner2) => inner1 AND inner2 => var
1582 inner1 AND (inner1 OR inner2) => inner1
1583 !inner1 AND (inner1 AND inner2) => false
1584 !inner1 AND (inner1 OR inner2) => !inner1 AND inner2
1585 Likewise for similar cases involving inner2. */
1592 ? boolean_false_node
1596 ? boolean_false_node
1599 /* Next, redistribute/reassociate the AND across the inner tests.
1600 Compute the first partial result, (inner1 AND (op2a code op2b)) */
1608 {
1609 /* Handle the AND case, where we are reassociating:
1610 (inner1 AND inner2) AND (op2a code2 op2b)
1611 => (t AND inner2)
1612 If the partial result t is a constant, we win. Otherwise
1613 continue on to try reassociating with the other inner test. */
1615 {
1620 }
1622 /* Handle the OR case, where we are redistributing:
1623 (inner1 OR inner2) AND (op2a code2 op2b)
1624 => (t OR (inner2 AND (op2a code2 op2b))) */
1628 /* Save partial result for later. */
1630 }
1632 /* Compute the second partial result, (inner2 AND (op2a code op2b)) */
1640 {
1641 /* Handle the AND case, where we are reassociating:
1642 (inner1 AND inner2) AND (op2a code2 op2b)
1643 => (inner1 AND t) */
1645 {
1650 /* If both are the same, we can apply the identity
1651 (x AND x) == x. */
1654 }
1656 /* Handle the OR case. where we are redistributing:
1657 (inner1 OR inner2) AND (op2a code2 op2b)
1658 => (t OR (inner1 AND (op2a code2 op2b)))
1659 => (t OR partial) */
1660 else
1661 {
1665 {
1666 /* We already got a simplification for the other
1667 operand to the redistributed OR expression. The
1668 interesting case is when at least one is false.
1669 Or, if both are the same, we can apply the identity
1670 (x OR x) == x. */
1677 }
1678 }
1679 }
1680 }
1682 }
1684 /* Try to simplify the AND of two comparisons defined by
1685 (OP1A CODE1 OP1B) and (OP2A CODE2 OP2B), respectively.
1686 If this can be done without constructing an intermediate value,
1687 return the resulting tree; otherwise NULL_TREE is returned.
1688 This function is deliberately asymmetric as it recurses on SSA_DEFs
1689 in the first comparison but not the second. */
1691 static tree
1694 {
1695 /* First check for ((x CODE1 y) AND (x CODE2 y)). */
1698 {
1699 /* Result will be either NULL_TREE, or a combined comparison. */
1705 }
1707 /* Likewise the swapped case of the above. */
1710 {
1711 /* Result will be either NULL_TREE, or a combined comparison. */
1718 }
1720 /* If both comparisons are of the same value against constants, we might
1721 be able to merge them. */
1725 {
1728 /* If we have (op1a == op1b), we should either be able to
1729 return that or FALSE, depending on whether the constant op1b
1730 also satisfies the other comparison against op2b. */
1732 {
1736 {
1744 }
1746 {
1749 else
1751 }
1752 }
1753 /* Likewise if the second comparison is an == comparison. */
1755 {
1759 {
1767 }
1769 {
1772 else
1774 }
1775 }
1777 /* Same business with inequality tests. */
1779 {
1782 {
1791 }
1794 }
1796 {
1799 {
1808 }
1811 }
1813 /* Chose the more restrictive of two < or <= comparisons. */
1816 {
1819 else
1821 }
1823 /* Likewise chose the more restrictive of two > or >= comparisons. */
1826 {
1829 else
1831 }
1833 /* Check for singleton ranges. */
1839 /* Check for disjoint ranges. */
1848 }
1850 /* Perhaps the first comparison is (NAME != 0) or (NAME == 1) where
1851 NAME's definition is a truth value. See if there are any simplifications
1852 that can be done against the NAME's definition. */
1856 {
1861 {
1863 /* Try to simplify by copy-propagating the definition. */
1867 /* If every argument to the PHI produces the same result when
1868 ANDed with the second comparison, we win.
1869 Do not do this unless the type is bool since we need a bool
1870 result here anyway. */
1872 {
1876 {
1879 /* If this PHI has itself as an argument, ignore it.
1880 If all the other args produce the same result,
1881 we're still OK. */
1885 {
1887 {
1892 }
1899 }
1902 {
1903 tree temp;
1905 /* In simple cases we can look through PHI nodes,
1906 but we have to be careful with loops.
1907 See PR49073. */
1922 }
1923 else
1925 }
1927 }
1931 }
1932 }
1934 }
1936 /* Try to simplify the AND of two comparisons, specified by
1937 (OP1A CODE1 OP1B) and (OP2B CODE2 OP2B), respectively.
1938 If this can be simplified to a single expression (without requiring
1939 introducing more SSA variables to hold intermediate values),
1940 return the resulting tree. Otherwise return NULL_TREE.
1941 If the result expression is non-null, it has boolean type. */
1943 tree
1946 {
1950 else
1952 }
1954 /* Helper function for or_comparisons_1: try to simplify the OR of the
1955 ssa variable VAR with the comparison specified by (OP2A CODE2 OP2B).
1956 If INVERT is true, invert the value of VAR before doing the OR.
1957 Return NULL_EXPR if we can't simplify this to a single expression. */
1959 static tree
1962 {
1963 tree t;
1966 /* We can only deal with variables whose definitions are assignments. */
1970 /* If we have an inverted comparison, apply DeMorgan's law and rewrite
1971 !var OR (op2a code2 op2b) => !(var AND !(op2a code2 op2b))
1972 Then we only have to consider the simpler non-inverted cases. */
1977 else
1980 }
1982 /* Try to simplify the OR of the ssa variable defined by the assignment
1983 STMT with the comparison specified by (OP2A CODE2 OP2B).
1984 Return NULL_EXPR if we can't simplify this to a single expression. */
1986 static tree
1989 {
1995 /* Check for identities like (var OR (var != 0)) => true . */
1998 {
2001 {
2005 }
2008 {
2012 }
2013 }
2015 /* If the definition is a comparison, recurse on it. */
2017 {
2021 code2,
2022 op2a,
2023 op2b);
2026 }
2028 /* If the definition is an AND or OR expression, we may be able to
2029 simplify by reassociating. */
2032 {
2035 gimple s;
2036 tree t;
2040 /* Check for boolean identities that don't require recursive examination
2041 of inner1/inner2:
2042 inner1 OR (inner1 OR inner2) => inner1 OR inner2 => var
2043 inner1 OR (inner1 AND inner2) => inner1
2044 !inner1 OR (inner1 OR inner2) => true
2045 !inner1 OR (inner1 AND inner2) => !inner1 OR inner2
2046 */
2053 ? boolean_true_node
2057 ? boolean_true_node
2060 /* Next, redistribute/reassociate the OR across the inner tests.
2061 Compute the first partial result, (inner1 OR (op2a code op2b)) */
2069 {
2070 /* Handle the OR case, where we are reassociating:
2071 (inner1 OR inner2) OR (op2a code2 op2b)
2072 => (t OR inner2)
2073 If the partial result t is a constant, we win. Otherwise
2074 continue on to try reassociating with the other inner test. */
2076 {
2081 }
2083 /* Handle the AND case, where we are redistributing:
2084 (inner1 AND inner2) OR (op2a code2 op2b)
2085 => (t AND (inner2 OR (op2a code op2b))) */
2089 /* Save partial result for later. */
2091 }
2093 /* Compute the second partial result, (inner2 OR (op2a code op2b)) */
2101 {
2102 /* Handle the OR case, where we are reassociating:
2103 (inner1 OR inner2) OR (op2a code2 op2b)
2104 => (inner1 OR t)
2105 => (t OR partial) */
2107 {
2112 /* If both are the same, we can apply the identity
2113 (x OR x) == x. */
2116 }
2118 /* Handle the AND case, where we are redistributing:
2119 (inner1 AND inner2) OR (op2a code2 op2b)
2120 => (t AND (inner1 OR (op2a code2 op2b)))
2121 => (t AND partial) */
2122 else
2123 {
2127 {
2128 /* We already got a simplification for the other
2129 operand to the redistributed AND expression. The
2130 interesting case is when at least one is true.
2131 Or, if both are the same, we can apply the identity
2132 (x AND x) == x. */
2139 }
2140 }
2141 }
2142 }
2144 }
2146 /* Try to simplify the OR of two comparisons defined by
2147 (OP1A CODE1 OP1B) and (OP2A CODE2 OP2B), respectively.
2148 If this can be done without constructing an intermediate value,
2149 return the resulting tree; otherwise NULL_TREE is returned.
2150 This function is deliberately asymmetric as it recurses on SSA_DEFs
2151 in the first comparison but not the second. */
2153 static tree
2156 {
2157 /* First check for ((x CODE1 y) OR (x CODE2 y)). */
2160 {
2161 /* Result will be either NULL_TREE, or a combined comparison. */
2167 }
2169 /* Likewise the swapped case of the above. */
2172 {
2173 /* Result will be either NULL_TREE, or a combined comparison. */
2180 }
2182 /* If both comparisons are of the same value against constants, we might
2183 be able to merge them. */
2187 {
2190 /* If we have (op1a != op1b), we should either be able to
2191 return that or TRUE, depending on whether the constant op1b
2192 also satisfies the other comparison against op2b. */
2194 {
2198 {
2206 }
2208 {
2211 else
2213 }
2214 }
2215 /* Likewise if the second comparison is a != comparison. */
2217 {
2221 {
2229 }
2231 {
2234 else
2236 }
2237 }
2239 /* See if an equality test is redundant with the other comparison. */
2241 {
2244 {
2253 }
2256 }
2258 {
2261 {
2270 }
2273 }
2275 /* Chose the less restrictive of two < or <= comparisons. */
2278 {
2281 else
2283 }
2285 /* Likewise chose the less restrictive of two > or >= comparisons. */
2288 {
2291 else
2293 }
2295 /* Check for singleton ranges. */
2301 /* Check for less/greater pairs that don't restrict the range at all. */
2310 }
2312 /* Perhaps the first comparison is (NAME != 0) or (NAME == 1) where
2313 NAME's definition is a truth value. See if there are any simplifications
2314 that can be done against the NAME's definition. */
2318 {
2323 {
2325 /* Try to simplify by copy-propagating the definition. */
2329 /* If every argument to the PHI produces the same result when
2330 ORed with the second comparison, we win.
2331 Do not do this unless the type is bool since we need a bool
2332 result here anyway. */
2334 {
2338 {
2341 /* If this PHI has itself as an argument, ignore it.
2342 If all the other args produce the same result,
2343 we're still OK. */
2347 {
2349 {
2354 }
2361 }
2364 {
2365 tree temp;
2367 /* In simple cases we can look through PHI nodes,
2368 but we have to be careful with loops.
2369 See PR49073. */
2384 }
2385 else
2387 }
2389 }
2393 }
2394 }
2396 }
2398 /* Try to simplify the OR of two comparisons, specified by
2399 (OP1A CODE1 OP1B) and (OP2B CODE2 OP2B), respectively.
2400 If this can be simplified to a single expression (without requiring
2401 introducing more SSA variables to hold intermediate values),
2402 return the resulting tree. Otherwise return NULL_TREE.
2403 If the result expression is non-null, it has boolean type. */
2405 tree
2408 {
2412 else
2414 }
2417 /* Fold STMT to a constant using VALUEIZE to valueize SSA names.
2419 Either NULL_TREE, a simplified but non-constant or a constant
2420 is returned.
2422 ??? This should go into a gimple-fold-inline.h file to be eventually
2423 privatized with the single valueize function used in the various TUs
2424 to avoid the indirect function call overhead. */
2426 tree
2428 {
2431 {
2433 {
2437 {
2439 {
2444 {
2445 /* If the RHS is an SSA_NAME, return its known constant value,
2446 if any. */
2448 }
2449 /* Handle propagating invariant addresses into address
2450 operations. */
2453 {
2454 HOST_WIDE_INT offset;
2455 tree base;
2458 valueize);
2464 }
2469 {
2475 {
2481 else
2483 }
2486 }
2489 {
2494 {
2499 }
2502 {
2509 }
2512 {
2516 {
2522 }
2523 }
2525 }
2529 }
2532 {
2533 /* Handle unary operators that can appear in GIMPLE form.
2534 Note that we know the single operand must be a constant,
2535 so this should almost always return a simplified RHS. */
2539 /* Conversions are useless for CCP purposes if they are
2540 value-preserving. Thus the restrictions that
2541 useless_type_conversion_p places for restrict qualification
2542 of pointer types should not apply here.
2543 Substitution later will only substitute to allowed places. */
2553 return
2556 }
2559 {
2560 /* Handle binary operators that can appear in GIMPLE form. */
2564 /* Translate &x + CST into an invariant form suitable for
2565 further propagation. */
2569 {
2571 return build_fold_addr_expr_loc
2576 }
2580 }
2583 {
2584 /* Handle ternary operators that can appear in GIMPLE form. */
2589 /* Fold embedded expressions in ternary codes. */
2593 {
2600 }
2604 }
2608 }
2609 }
2612 {
2613 tree fn;
2616 /* No folding yet for these functions. */
2623 {
2634 /* fold_call_expr wraps the result inside a NOP_EXPR. */
2637 }
2639 }
2643 }
2644 }
2646 /* Fold STMT to a constant using VALUEIZE to valueize SSA names.
2647 Returns NULL_TREE if folding to a constant is not possible, otherwise
2648 returns a constant according to is_gimple_min_invariant. */
2650 tree
2652 {
2657 }
2660 /* The following set of functions are supposed to fold references using
2661 their constant initializers. */
2667 /* See if we can find constructor defining value of BASE.
2668 When we know the consructor with constant offset (such as
2669 base is array[40] and we do know constructor of array), then
2670 BIT_OFFSET is adjusted accordingly.
2672 As a special case, return error_mark_node when constructor
2673 is not explicitly available, but it is known to be zero
2674 such as 'static const int a;'. */
2675 static tree
2678 {
2681 {
2683 {
2688 }
2696 }
2698 /* Get a CONSTRUCTOR. If BASE is a VAR_DECL, get its
2699 DECL_INITIAL. If BASE is a nested reference into another
2700 ARRAY_REF or COMPONENT_REF, make a recursive call to resolve
2701 the inner reference. */
2703 {
2708 /* Fallthru. */
2713 /* Do not return an error_mark_node DECL_INITIAL. LTO uses this
2714 as special marker (_not_ zero ...) for its own purposes. */
2733 }
2734 }
2736 /* CTOR is STRING_CST. Fold reference of type TYPE and size SIZE
2737 to the memory at bit OFFSET.
2739 We do only simple job of folding byte accesses. */
2741 static tree
2745 {
2754 {
2759 /* Folding
2760 const char a[20]="hello";
2761 return a[10];
2763 might lead to offset greater than string length. In this case we
2764 know value is either initialized to 0 or out of bounds. Return 0
2765 in both cases. */
2767 }
2769 }
2771 /* CTOR is CONSTRUCTOR of an array type. Fold reference of type TYPE and size
2772 SIZE to the memory at bit OFFSET. */
2774 static tree
2778 {
2783 double_int access_index;
2785 HOST_WIDE_INT inner_offset;
2787 /* Compute low bound and elt size. */
2791 {
2792 /* Static constructors for variably sized objects makes no sense. */
2795 }
2796 else
2798 /* Static constructors for variably sized objects makes no sense. */
2801 elt_size =
2805 /* We can handle only constantly sized accesses that are known to not
2806 be larger than size of array element. */
2813 /* Compute the array index we look for. */
2818 /* And offset within the access. */
2821 /* See if the array field is large enough to span whole access. We do not
2822 care to fold accesses spanning multiple array indexes. */
2828 {
2829 /* Array constructor might explicitely set index, or specify range
2830 or leave index NULL meaning that it is next index after previous
2831 one. */
2833 {
2836 else
2837 {
2841 }
2842 }
2843 else
2846 /* Do we have match? */
2850 }
2851 /* When memory is not explicitely mentioned in constructor,
2852 it is 0 (or out of range). */
2854 }
2856 /* CTOR is CONSTRUCTOR of an aggregate or vector.
2857 Fold reference of type TYPE and size SIZE to the memory at bit OFFSET. */
2859 static tree
2863 {
2868 cval)
2869 {
2873 double_int bitoffset;
2878 /* Variable sized objects in static constructors makes no sense,
2879 but field_size can be NULL for flexible array members. */
2886 /* Compute bit offset of the field. */
2889 bits_per_unit_cst));
2890 /* Compute bit offset where the field ends. */
2894 else
2900 /* Is there any overlap between [OFFSET, OFFSET+SIZE) and
2901 [BITOFFSET, BITOFFSET_END)? */
2906 {
2908 bitoffset);
2909 /* We do have overlap. Now see if field is large enough to
2910 cover the access. Give up for accesses spanning multiple
2911 fields. */
2918 }
2919 }
2920 /* When memory is not explicitely mentioned in constructor, it is 0. */
2922 }
2924 /* CTOR is value initializing memory, fold reference of type TYPE and size SIZE
2925 to the memory at bit OFFSET. */
2927 static tree
2930 {
2931 tree ret;
2933 /* We found the field with exact match. */
2938 /* We are at the end of walk, see if we can view convert the
2939 result. */
2941 /* VIEW_CONVERT_EXPR is defined only for matching sizes. */
2944 {
2950 }
2954 {
2959 else
2961 }
2964 }
2966 /* Return the tree representing the element referenced by T if T is an
2967 ARRAY_REF or COMPONENT_REF into constant aggregates valuezing SSA
2968 names using VALUEIZE. Return NULL_TREE otherwise. */
2970 tree
2972 {
2975 tree tem;
2988 {
2991 /* Constant indexes are handled well by get_base_constructor.
2992 Only special case variable offsets.
2993 FIXME: This code can't handle nested references with variable indexes
2994 (they will be handled only by iteration of ccp). Perhaps we can bring
2995 get_ref_base_and_extent here and make it use a valueize callback. */
2997 && valueize
3000 {
3003 /* If the resulting bit-offset is constant, track it. */
3008 {
3016 /* Empty constructor. Always fold to 0. */
3019 /* Out of bound array access. Value is undefined,
3020 but don't fold. */
3023 /* We can not determine ctor. */
3029 }
3030 }
3031 /* Fallthru. */
3040 /* Empty constructor. Always fold to 0. */
3043 /* We do not know precise address. */
3046 /* We can not determine ctor. */
3050 /* Out of bound array access. Value is undefined, but don't fold. */
3058 {
3064 }
3068 }
3071 }
3073 tree
3075 {
3077 }
3079 /* Return a declaration of a function which an OBJ_TYPE_REF references. TOKEN
3080 is integer form of OBJ_TYPE_REF_TOKEN of the reference expression.
3081 KNOWN_BINFO carries the binfo describing the true type of
3082 OBJ_TYPE_REF_OBJECT(REF). */
3084 tree
3086 {
3091 /* If there is no virtual methods table, leave the OBJ_TYPE_REF alone. */
3096 {
3099 }
3100 else
3124 /* When cgraph node is missing and function is not public, we cannot
3125 devirtualize. This can happen in WHOPR when the actual method
3126 ends up in other partition, because we found devirtualization
3127 possibility too late. */
3132 }
3134 /* Return true iff VAL is a gimple expression that is known to be
3135 non-negative. Restricted to floating-point inputs. */
3137 bool
3139 {
3140 gimple def_stmt;
3144 /* Use existing logic for non-gimple trees. */
3151 /* Currently we look only at the immediately defining statement
3152 to make this determination, since recursion on defining
3153 statements of operands can lead to quadratic behavior in the
3154 worst case. This is expected to catch almost all occurrences
3155 in practice. It would be possible to implement limited-depth
3156 recursion if important cases are lost. Alternatively, passes
3157 that need this information (such as the pow/powi lowering code
3158 in the cse_sincos pass) could be revised to provide it through
3159 dataflow propagation. */
3164 {
3167 /* See fold-const.c:tree_expr_nonnegative_p for additional
3168 cases that could be handled with recursion. */
3171 {
3173 /* Always true for floating-point operands. */
3177 /* True if the two operands are identical (since we are
3178 restricted to floating-point inputs). */
3188 }
3189 }
3191 {
3195 {
3196 tree arg1;
3199 {
3215 /* sqrt(-0.0) is -0.0, and sqrt is not defined over other
3216 nonnegative inputs. */
3223 /* True if the second argument is an even integer. */
3233 /* True if the second argument is an even integer-valued
3234 real. */
3238 {
3239 REAL_VALUE_TYPE c;
3240 HOST_WIDE_INT n;
3246 {
3247 REAL_VALUE_TYPE cint;
3251 }
3252 }
3258 }
3259 }
3260 }
3263 }