| blob | 1eae4ea849c84bacaa97cda080e357c33acac5ae |
1 /* Build expressions with type checking for C compiler.
2 Copyright (C) 1987-2018 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
21 /* This file is part of the C front end.
22 It contains routines to build C expressions given their operands,
23 including computing the types of the result, C-specific error checks,
24 and some optimization. */
56 /* Possible cases of implicit bad conversions. Used to select
57 diagnostic messages in convert_for_assignment. */
59 ic_argpass,
60 ic_assign,
61 ic_init,
62 ic_return
63 };
65 /* The level of nesting inside "__alignof__". */
68 /* The level of nesting inside "sizeof". */
71 /* The level of nesting inside "typeof". */
74 /* The argument of last parsed sizeof expression, only to be tested
75 if expr.original_code == SIZEOF_EXPR. */
76 tree c_last_sizeof_arg;
77 location_t c_last_sizeof_loc;
79 /* Nonzero if we might need to print a "missing braces around
80 initializer" message within this initializer. */
97 tree);
122 \f
123 /* Return true if EXP is a null pointer constant, false otherwise. */
125 static bool
127 {
128 /* This should really operate on c_expr structures, but they aren't
129 yet available everywhere required. */
138 }
140 /* EXPR may appear in an unevaluated part of an integer constant
141 expression, but not in an evaluated part. Wrap it in a
142 C_MAYBE_CONST_EXPR, or mark it with TREE_OVERFLOW if it is just an
143 INTEGER_CST and we cannot create a C_MAYBE_CONST_EXPR. */
145 static tree
147 {
148 tree ret;
150 {
153 }
154 else
155 {
158 }
160 }
162 /* Having checked whether EXPR may appear in an unevaluated part of an
163 integer constant expression and found that it may, remove any
164 C_MAYBE_CONST_EXPR noting this fact and return the resulting
165 expression. */
169 {
172 else
174 }
180 const_tree t1;
181 const_tree t2;
182 /* The return value of tagged_types_tu_compatible_p if we had seen
183 these two types already. */
185 };
190 /* Do `exp = require_complete_type (loc, exp);' to make sure exp
191 does not have an incomplete type. (That includes void types.)
192 LOC is the location of the use. */
194 tree
196 {
202 /* First, detect a valid value with a complete type. */
208 }
210 /* Print an error message for invalid use of an incomplete type.
211 VALUE is the expression that was used (or 0 if that isn't known)
212 and TYPE is the type that was invalid. LOC is the location for
213 the error. */
215 void
217 {
218 /* Avoid duplicate error message. */
224 else
225 {
226 retry:
227 /* We must print an error message. Be clever about what it says. */
230 {
242 {
244 {
247 }
250 }
256 }
260 else
261 /* If this type has a typedef-name, the TYPE_NAME is a TYPE_DECL. */
263 }
264 }
266 /* Given a type, apply default promotions wrt unnamed function
267 arguments and return the new type. */
269 tree
271 {
277 {
278 /* Preserve unsignedness if not really getting any wider. */
282 else
284 }
292 }
294 /* Return true if between two named address spaces, whether there is a superset
295 named address space that encompasses both address spaces. If there is a
296 superset, return which address space is the superset. */
298 static bool
300 {
302 {
305 }
307 {
310 }
312 {
315 }
316 else
318 }
320 /* Return a variant of TYPE which has all the type qualifiers of LIKE
321 as well as those of TYPE. */
323 static tree
325 {
328 addr_space_t as_common;
330 /* If the two named address spaces are different, determine the common
331 superset address space. If there isn't one, raise an error. */
333 {
337 }
343 }
345 /* Return true iff the given tree T is a variable length array. */
347 bool
349 {
354 }
355 \f
356 /* Return the composite type of two compatible types.
358 We assume that comptypes has already been done and returned
359 nonzero; if that isn't so, this may crash. In particular, we
360 assume that qualifiers match. */
362 tree
364 {
367 tree attributes;
369 /* Save time if the two types are the same. */
373 /* If one type is nonsense, use the other. */
382 /* Merge the attributes. */
385 /* If one is an enumerated type and the other is the compatible
386 integer type, the composite type might be either of the two
387 (DR#013 question 3). For consistency, use the enumerated type as
388 the composite type. */
398 {
400 /* For two pointers, do this recursively on the target type. */
401 {
408 }
411 {
414 tree unqual_elt;
421 /* We should not have any type quals on arrays at all. */
431 d1_variable = (!d1_zero
434 d2_variable = (!d2_zero
440 /* Save space: see if the result is identical to one of the args. */
453 /* Merge the element types, and have a size if either arg has
454 one. We may have qualifiers on the element types. To set
455 up TYPE_MAIN_VARIANT correctly, we need to form the
456 composite of the unqualified types and add the qualifiers
457 back at the end. */
462 && (d2_variable
463 || d2_zero
465 ? t1
467 /* Ensure a composite type involving a zero-length array type
468 is a zero-length type not an incomplete type. */
472 {
475 }
478 }
484 {
485 /* Try harder not to create a new aggregate type. */
490 }
494 /* Function types: prefer the one that specified arg types.
495 If both do, merge the arg types. Also merge the return types. */
496 {
504 /* Save space: see if the result is identical to one of the args. */
510 /* Simple way if one arg fails to specify argument types. */
512 {
516 }
518 {
522 }
524 /* If both args specify argument types, we must merge the two
525 lists, argument by argument. */
530 ;
539 {
540 /* A null type means arg type is not specified.
541 Take whatever the other function type has. */
543 {
546 }
548 {
551 }
553 /* Given wait (union {union wait *u; int *i} *)
554 and wait (union wait *),
555 prefer union wait * as type of parm. */
558 {
559 tree memb;
566 {
572 {
578 }
579 }
580 }
583 {
584 tree memb;
591 {
597 {
603 }
604 }
605 }
607 parm_done: ;
608 }
612 }
613 /* FALLTHRU */
617 }
619 }
621 /* Return the type of a conditional expression between pointers to
622 possibly differently qualified versions of compatible types.
624 We assume that comp_target_types has already been done and returned
625 nonzero; if that isn't so, this may crash. */
627 static tree
629 {
630 tree attributes;
633 tree target;
638 /* Save time if the two types are the same. */
642 /* If one type is nonsense, use the other. */
651 /* Merge the attributes. */
654 /* Find the composite type of the target types, and combine the
655 qualifiers of the two types' targets. Do not lose qualifiers on
656 array element types by taking the TYPE_MAIN_VARIANT. */
665 /* Strip array types to get correct qualifier for pointers to arrays */
669 /* For function types do not merge const qualifiers, but drop them
670 if used inconsistently. The middle-end uses these to mark const
671 and noreturn functions. */
674 else
677 /* If the two named address spaces are different, determine the common
678 superset address space. This is guaranteed to exist due to the
679 assumption that comp_target_type returned non-zero. */
689 }
691 /* Return the common type for two arithmetic types under the usual
692 arithmetic conversions. The default conversions have already been
693 applied, and enumerated types converted to their compatible integer
694 types. The resulting type is unqualified and has no attributes.
696 This is the type for the result of most arithmetic operations
697 if the operands have the given two types. */
699 static tree
701 {
705 /* If one type is nonsense, use the other. */
723 /* Save time if the two types are the same. */
737 /* When one operand is a decimal float type, the other operand cannot be
738 a generic float type or a complex type. We also disallow vector types
739 here. */
742 {
744 {
747 }
749 {
752 }
754 {
757 }
758 }
760 /* If one type is a vector type, return that type. (How the usual
761 arithmetic conversions apply to the vector types extension is not
762 precisely specified.) */
769 /* If one type is complex, form the common type of the non-complex
770 components, then make that complex. Use T1 or T2 if it is the
771 required type. */
773 {
782 else
784 }
786 /* If only one is real, use it as the result. */
794 /* If both are real and either are decimal floating point types, use
795 the decimal floating point type with the greater precision. */
798 {
808 }
810 /* Deal with fixed-point types. */
812 {
820 /* If one input type is saturating, the result type is saturating. */
824 /* If both fixed-point types are unsigned, the result type is unsigned.
825 When mixing fixed-point and integer types, follow the sign of the
826 fixed-point type.
827 Otherwise, the result type is signed. */
836 /* The result type is signed. */
838 {
839 /* If the input type is unsigned, we need to convert to the
840 signed type. */
842 {
848 else
852 }
854 {
860 else
864 }
865 }
868 {
871 }
872 else
873 {
875 /* Signed integers need to subtract one sign bit. */
877 }
880 {
883 }
884 else
885 {
887 /* Signed integers need to subtract one sign bit. */
889 }
894 satp);
895 }
897 /* Both real or both integers; use the one with greater precision. */
904 /* Same precision. Prefer long longs to longs to ints when the
905 same precision, following the C99 rules on integer type rank
906 (which are equivalent to the C90 rules for C90 types). */
914 {
917 else
919 }
927 {
928 /* But preserve unsignedness from the other type,
929 since long cannot hold all the values of an unsigned int. */
932 else
934 }
936 /* For floating types of the same TYPE_PRECISION (which we here
937 assume means either the same set of values, or sets of values
938 neither a subset of the other, with behavior being undefined in
939 the latter case), follow the rules from TS 18661-3: prefer
940 interchange types _FloatN, then standard types long double,
941 double, float, then extended types _FloatNx. For extended types,
942 check them starting with _Float128x as that seems most consistent
943 in spirit with preferring long double to double; for interchange
944 types, also check in that order for consistency although it's not
945 possible for more than one of them to have the same
946 precision. */
954 /* Likewise, prefer long double to double even if same size. */
958 /* Likewise, prefer double to float even if same size.
959 We got a couple of embedded targets with 32 bit doubles, and the
960 pdp11 might have 64 bit floats. */
971 /* Otherwise prefer the unsigned one. */
975 else
977 }
978 \f
979 /* Wrapper around c_common_type that is used by c-common.c and other
980 front end optimizations that remove promotions. ENUMERAL_TYPEs
981 are allowed here and are converted to their compatible integer types.
982 BOOLEAN_TYPEs are allowed here and return either boolean_type_node or
983 preferably a non-Boolean type as the common type. */
984 tree
986 {
992 /* If both types are BOOLEAN_TYPE, then return boolean_type_node. */
997 /* If either type is BOOLEAN_TYPE, then return the other. */
1004 }
1006 /* Return 1 if TYPE1 and TYPE2 are compatible types for assignment
1007 or various other operations. Return 2 if they are compatible
1008 but a warning may be needed if you use them together. */
1010 int
1012 {
1020 }
1022 /* Like comptypes, but if it returns non-zero because enum and int are
1023 compatible, it sets *ENUM_AND_INT_P to true. */
1025 static int
1027 {
1035 }
1037 /* Like comptypes, but if it returns nonzero for different types, it
1038 sets *DIFFERENT_TYPES_P to true. */
1040 int
1043 {
1051 }
1052 \f
1053 /* Return 1 if TYPE1 and TYPE2 are compatible types for assignment
1054 or various other operations. Return 2 if they are compatible
1055 but a warning may be needed if you use them together. If
1056 ENUM_AND_INT_P is not NULL, and one type is an enum and the other a
1057 compatible integer type, then this sets *ENUM_AND_INT_P to true;
1058 *ENUM_AND_INT_P is never set to false. If DIFFERENT_TYPES_P is not
1059 NULL, and the types are compatible but different enough not to be
1060 permitted in C11 typedef redeclarations, then this sets
1061 *DIFFERENT_TYPES_P to true; *DIFFERENT_TYPES_P is never set to
1062 false, but may or may not be set if the types are incompatible.
1063 This differs from comptypes, in that we don't free the seen
1064 types. */
1066 static int
1069 {
1074 /* Suppress errors caused by previously reported errors. */
1080 /* Enumerated types are compatible with integer types, but this is
1081 not transitive: two enumerated types in the same translation unit
1082 are compatible with each other only if they are the same type. */
1085 {
1088 {
1093 }
1094 }
1096 {
1099 {
1104 }
1105 }
1110 /* Different classes of types can't be compatible. */
1115 /* Qualifiers must match. C99 6.7.3p9 */
1120 /* Allow for two different type nodes which have essentially the same
1121 definition. Note that we already checked for equality of the type
1122 qualifiers (just above). */
1128 /* 1 if no need for warning yet, 2 if warning cause has been seen. */
1132 /* 1 if no need for warning yet, 2 if warning cause has been seen. */
1136 {
1140 /* With these nodes, we can't determine type equivalence by
1141 looking at what is stored in the nodes themselves, because
1142 two nodes might have different TYPE_MAIN_VARIANTs but still
1143 represent the same type. For example, wchar_t and int could
1144 have the same properties (TYPE_PRECISION, TYPE_MIN_VALUE,
1145 TYPE_MAX_VALUE, etc.), but have different TYPE_MAIN_VARIANTs
1146 and are distinct types. On the other hand, int and the
1147 following typedef
1149 typedef int INT __attribute((may_alias));
1151 have identical properties, different TYPE_MAIN_VARIANTs, but
1152 represent the same type. The canonical type system keeps
1153 track of equivalence in this case, so we fall back on it. */
1157 /* Do not remove mode information. */
1167 different_types_p);
1171 {
1178 /* Target types must match incl. qualifiers. */
1181 enum_and_int_p,
1188 /* Sizes must match unless one is missing or variable. */
1195 d1_variable = (!d1_zero
1198 d2_variable = (!d2_zero
1217 }
1223 {
1233 different_types_p);
1235 different_types_p);
1236 }
1247 }
1249 }
1251 /* Return 1 if TTL and TTR are pointers to types that are equivalent, ignoring
1252 their qualifiers, except for named address spaces. If the pointers point to
1253 different named addresses, then we must determine if one address space is a
1254 subset of the other. */
1256 static int
1258 {
1265 addr_space_t as_common;
1268 /* Fail if pointers point to incompatible address spaces. */
1272 /* For pedantic record result of comptypes on arrays before losing
1273 qualifiers on the element type below. */
1280 /* Qualifiers on element types of array types that are
1281 pointer targets are lost by taking their TYPE_MAIN_VARIANT. */
1306 }
1307 \f
1308 /* Subroutines of `comptypes'. */
1310 /* Determine whether two trees derive from the same translation unit.
1311 If the CONTEXT chain ends in a null, that tree's context is still
1312 being parsed, so if two trees have context chains ending in null,
1313 they're in the same translation unit. */
1315 bool
1317 {
1320 {
1328 }
1332 {
1340 }
1343 }
1345 /* Allocate the seen two types, assuming that they are compatible. */
1349 {
1357 /* The C standard says that two structures in different translation
1358 units are compatible with each other only if the types of their
1359 fields are compatible (among other things). We assume that they
1360 are compatible until proven otherwise when building the cache.
1361 An example where this can occur is:
1362 struct a
1363 {
1364 struct a *next;
1365 };
1366 If we are comparing this against a similar struct in another TU,
1367 and did not assume they were compatible, we end up with an infinite
1368 loop. */
1371 }
1373 /* Free the seen types until we get to TU_TIL. */
1375 static void
1377 {
1380 {
1385 }
1387 }
1389 /* Return 1 if two 'struct', 'union', or 'enum' types T1 and T2 are
1390 compatible. If the two types are not the same (which has been
1391 checked earlier), this can only happen when multiple translation
1392 units are being compiled. See C99 6.2.7 paragraph 1 for the exact
1393 rules. ENUM_AND_INT_P and DIFFERENT_TYPES_P are as in
1394 comptypes_internal. */
1396 static int
1399 {
1403 /* We have to verify that the tags of the types are the same. This
1404 is harder than it looks because this may be a typedef, so we have
1405 to go look at the original type. It may even be a typedef of a
1406 typedef...
1407 In the case of compiler-created builtin structs the TYPE_DECL
1408 may be a dummy, with no DECL_ORIGINAL_TYPE. Don't fault. */
1419 /* C90 didn't have the requirement that the two tags be the same. */
1423 /* C90 didn't say what happened if one or both of the types were
1424 incomplete; we choose to follow C99 rules here, which is that they
1425 are compatible. */
1430 {
1435 }
1438 {
1440 {
1442 /* Speed up the case where the type values are in the same order. */
1447 {
1449 }
1452 {
1456 {
1459 }
1460 }
1463 {
1465 }
1467 {
1470 }
1473 {
1476 }
1479 {
1483 {
1486 }
1487 }
1489 }
1492 {
1495 {
1498 }
1500 /* Speed up the common case where the fields are in the same order. */
1503 {
1514 {
1517 }
1524 {
1527 }
1528 }
1530 {
1533 }
1536 {
1541 {
1545 enum_and_int_p,
1546 different_types_p);
1551 {
1554 }
1565 }
1567 {
1570 }
1571 }
1574 }
1577 {
1583 {
1599 }
1602 else
1605 }
1609 }
1610 }
1612 /* Return 1 if two function types F1 and F2 are compatible.
1613 If either type specifies no argument types,
1614 the other must specify a fixed number of self-promoting arg types.
1615 Otherwise, if one type specifies only the number of arguments,
1616 the other must specify that number of self-promoting arg types.
1617 Otherwise, the argument types must match.
1618 ENUM_AND_INT_P and DIFFERENT_TYPES_P are as in comptypes_internal. */
1620 static int
1623 {
1625 /* 1 if no need for warning yet, 2 if warning cause has been seen. */
1633 /* 'volatile' qualifiers on a function's return type used to mean
1634 the function is noreturn. */
1654 /* An unspecified parmlist matches any specified parmlist
1655 whose argument types don't need default promotions. */
1658 {
1661 /* If one of these types comes from a non-prototype fn definition,
1662 compare that with the other type's arglist.
1663 If they don't match, ask for a warning (but no error). */
1669 }
1671 {
1679 }
1681 /* Both types have argument lists: compare them and propagate results. */
1683 different_types_p);
1685 }
1687 /* Check two lists of types for compatibility, returning 0 for
1688 incompatible, 1 for compatible, or 2 for compatible with
1689 warning. ENUM_AND_INT_P and DIFFERENT_TYPES_P are as in
1690 comptypes_internal. */
1692 static int
1695 {
1696 /* 1 if no need for warning yet, 2 if warning cause has been seen. */
1701 {
1705 /* If one list is shorter than the other,
1706 they fail to match. */
1714 TYPE_QUAL_ATOMIC)
1719 TYPE_QUAL_ATOMIC)
1721 /* A null pointer instead of a type
1722 means there is supposed to be an argument
1723 but nothing is specified about what type it has.
1724 So match anything that self-promotes. */
1729 {
1732 }
1734 {
1737 }
1738 /* If one of the lists has an error marker, ignore this arg. */
1741 ;
1743 different_types_p)))
1744 {
1747 /* Allow wait (union {union wait *u; int *i} *)
1748 and wait (union wait *) to be compatible. */
1755 {
1756 tree memb;
1759 {
1765 TYPE_QUAL_ATOMIC)
1768 different_types_p))
1770 }
1773 }
1780 {
1781 tree memb;
1784 {
1790 TYPE_QUAL_ATOMIC)
1793 different_types_p))
1795 }
1798 }
1799 else
1801 }
1803 /* comptypes said ok, but record if it said to warn. */
1809 }
1810 }
1811 \f
1812 /* Compute the size to increment a pointer by. When a function type or void
1813 type or incomplete type is passed, size_one_node is returned.
1814 This function does not emit any diagnostics; the caller is responsible
1815 for that. */
1817 static tree
1819 {
1826 /* Convert in case a char is more than one unit. */
1830 }
1831 \f
1832 /* Return either DECL or its known constant value (if it has one). */
1834 tree
1836 {
1843 /* This is invalid if initial value is not constant.
1844 If it has either a function call, a memory reference,
1845 or a variable, then re-evaluating it could give different results. */
1847 /* Check for cases where this is sub-optimal, even though valid. */
1851 }
1853 /* Return either DECL or its known constant value (if it has one).
1854 Like the above, but always return decl outside of functions. */
1856 tree
1858 {
1859 /* Don't change a variable array bound or initial value to a constant
1860 in a place where a variable is invalid. */
1862 }
1864 /* Convert the array expression EXP to a pointer. */
1865 static tree
1867 {
1870 tree adr;
1872 tree ptrtype;
1886 /* In C++ array compound literals are temporary objects unless they are
1887 const or appear in namespace scope, so they are destroyed too soon
1888 to use them for much of anything (c++/53220). */
1890 {
1894 "converting an array compound literal to a pointer "
1896 }
1900 }
1902 /* Convert the function expression EXP to a pointer. */
1903 static tree
1905 {
1916 }
1918 /* Mark EXP as read, not just set, for set but not used -Wunused
1919 warning purposes. */
1921 void
1923 {
1925 {
1935 CASE_CONVERT:
1946 }
1947 }
1949 /* Perform the default conversion of arrays and functions to pointers.
1950 Return the result of converting EXP. For any other expression, just
1951 return EXP.
1953 LOC is the location of the expression. */
1955 struct c_expr
1957 {
1963 {
1965 {
1972 {
1976 }
1983 {
1984 /* Before C99, non-lvalue arrays do not decay to pointers.
1985 Normally, using such an array would be invalid; but it can
1986 be used correctly inside sizeof or as a statement expression.
1987 Thus, do not give an error here; an error will result later. */
1989 }
1992 }
1999 }
2002 }
2004 struct c_expr
2006 {
2009 }
2011 /* Return whether EXPR should be treated as an atomic lvalue for the
2012 purposes of load and store handling. */
2014 static bool
2016 {
2024 /* Ignore _Atomic on register variables, since their addresses can't
2025 be taken so (a) atomicity is irrelevant and (b) the normal atomic
2026 sequences wouldn't work. Ignore _Atomic on structures containing
2027 bit-fields, since accessing elements of atomic structures or
2028 unions is undefined behavior (C11 6.5.2.3#5), but it's unclear if
2029 it's undefined at translation time or execution time, and the
2030 normal atomic sequences again wouldn't work. */
2032 {
2037 }
2041 }
2043 /* Convert expression EXP (location LOC) from lvalue to rvalue,
2044 including converting functions and arrays to pointers if CONVERT_P.
2045 If READ_P, also mark the expression as having been read. */
2047 struct c_expr
2050 {
2056 {
2065 /* Expansion of a generic atomic load may require an addition
2066 element, so allocate enough to prevent a resize. */
2069 /* Remove the qualifiers for the rest of the expressions and
2070 create the VAL temp variable to hold the RHS. */
2077 /* Issue __atomic_load (&expr, &tmp, SEQ_CST); */
2084 /* EXPR is always read. */
2087 /* Return tmp which contains the value loaded. */
2090 }
2092 }
2094 /* EXP is an expression of integer type. Apply the integer promotions
2095 to it and return the promoted value. */
2097 tree
2099 {
2105 /* Normally convert enums to int,
2106 but convert wide enums to something wider. */
2108 {
2116 }
2118 /* ??? This should no longer be needed now bit-fields have their
2119 proper types. */
2122 /* If it's thinner than an int, promote it like a
2123 c_promoting_integer_type_p, otherwise leave it alone. */
2129 {
2130 /* Preserve unsignedness if not really getting any wider. */
2136 }
2139 }
2142 /* Perform default promotions for C data used in expressions.
2143 Enumeral types or short or char are converted to int.
2144 In addition, manifest constants symbols are replaced by their values. */
2146 tree
2148 {
2149 tree orig_exp;
2152 tree promoted_type;
2156 /* Functions and arrays have been converted during parsing. */
2161 /* Constants can be used directly unless they're not loadable. */
2165 /* Strip no-op conversions. */
2173 {
2177 }
2191 }
2192 \f
2193 /* Look up COMPONENT in a structure or union TYPE.
2195 If the component name is not found, returns NULL_TREE. Otherwise,
2196 the return value is a TREE_LIST, with each TREE_VALUE a FIELD_DECL
2197 stepping down the chain to the component, which is in the last
2198 TREE_VALUE of the list. Normally the list is of length one, but if
2199 the component is embedded within (nested) anonymous structures or
2200 unions, the list steps down the chain to the component. */
2202 static tree
2204 {
2205 tree field;
2207 /* If TYPE_LANG_SPECIFIC is set, then it is a sorted array of pointers
2208 to the field elements. Use a binary search on this array to quickly
2209 find the element. Otherwise, do a linear search. TYPE_LANG_SPECIFIC
2210 will always be set for structures which have many elements. */
2213 {
2221 {
2226 {
2227 /* Step through all anon unions in linear fashion. */
2229 {
2232 {
2238 /* The Plan 9 compiler permits referring
2239 directly to an anonymous struct/union field
2240 using a typedef name. */
2248 }
2249 }
2251 /* Entire record is only anon unions. */
2255 /* Restart the binary search, with new lower bound. */
2257 }
2263 else
2265 }
2271 }
2272 else
2273 {
2275 {
2278 {
2284 /* The Plan 9 compiler permits referring directly to an
2285 anonymous struct/union field using a typedef
2286 name. */
2293 }
2297 }
2301 }
2304 }
2306 /* Recursively append candidate IDENTIFIER_NODEs to CANDIDATES. */
2308 static void
2311 {
2312 tree field;
2314 {
2318 candidates);
2322 }
2323 }
2325 /* Like "lookup_field", but find the closest matching IDENTIFIER_NODE,
2326 rather than returning a TREE_LIST for an exact match. */
2328 static tree
2330 {
2333 /* First, gather a list of candidates. */
2340 }
2342 /* Support function for build_component_ref's error-handling.
2344 Given DATUM_TYPE, and "DATUM.COMPONENT", where DATUM is *not* a
2345 struct or union, should we suggest "DATUM->COMPONENT" as a hint? */
2347 static bool
2349 {
2350 /* We don't do it for Objective-C, since Objective-C 2.0 dot-syntax
2351 allows "." for ptrs; we could be handling a failed attempt
2352 to access a property. */
2356 /* Only suggest it for pointers... */
2360 /* ...to structs/unions. */
2365 else
2367 }
2369 /* Make an expression to refer to the COMPONENT field of structure or
2370 union value DATUM. COMPONENT is an IDENTIFIER_NODE. LOC is the
2371 location of the COMPONENT_REF. COMPONENT_LOC is the location
2372 of COMPONENT. */
2374 tree
2376 location_t component_loc)
2377 {
2381 tree ref;
2387 /* Detect Objective-C property syntax object.property. */
2392 /* See if there is a field or component with name COMPONENT. */
2395 {
2397 {
2400 }
2405 {
2408 {
2409 /* Attempt to provide a fixit replacement hint, if
2410 we have a valid range for the component. */
2411 location_t reported_loc
2419 }
2420 else
2423 }
2425 /* Accessing elements of atomic structures or unions is undefined
2426 behavior (C11 6.5.2.3#5). */
2428 {
2432 else
2435 }
2437 /* Chain the COMPONENT_REFs if necessary down to the FIELD.
2438 This might be better solved in future the way the C++ front
2439 end does it - by giving the anonymous entities each a
2440 separate name and type, and then have build_component_ref
2441 recursively call itself. We can't do that here. */
2442 do
2443 {
2446 tree subtype;
2452 /* If this is an rvalue, it does not have qualifiers in C
2453 standard terms and we must avoid propagating such
2454 qualifiers down to a non-lvalue array that is then
2455 converted to a pointer. */
2456 use_datum_quals = (datum_lvalue
2465 NULL_TREE);
2480 }
2484 }
2486 {
2487 /* Special-case the error message for "ptr.field" for the case
2488 where the user has confused "." vs "->". */
2490 /* "loc" should be the "." token. */
2494 datum);
2496 }
2500 component);
2503 }
2504 \f
2505 /* Given an expression PTR for a pointer, return an expression
2506 for the value pointed to.
2507 ERRORSTRING is the name of the operator to appear in error messages.
2509 LOC is the location to use for the generated tree. */
2511 tree
2513 {
2516 tree ref;
2519 {
2522 {
2523 /* If a warning is issued, mark it to avoid duplicates from
2524 the backend. This only needs to be done at
2525 warn_strict_aliasing > 2. */
2530 }
2535 {
2539 }
2540 else
2541 {
2547 {
2549 {
2553 }
2555 }
2559 /* We *must* set TREE_READONLY when dereferencing a pointer to const,
2560 so that we get the proper error message if the result is used
2561 to assign to. Also, &* is supposed to be a no-op.
2562 And ANSI C seems to specify that the type of the result
2563 should be the const type. */
2564 /* A de-reference of a pointer to const is not a const. It is valid
2565 to change it via some other pointer. */
2572 }
2573 }
2578 }
2580 /* This handles expressions of the form "a[i]", which denotes
2581 an array reference.
2583 This is logically equivalent in C to *(a+i), but we may do it differently.
2584 If A is a variable or a member, we generate a primitive ARRAY_REF.
2585 This avoids forcing the array out of registers, and can work on
2586 arrays that are not lvalues (for example, members of structures returned
2587 by functions).
2589 For vector types, allow vector[i] but not i[vector], and create
2590 *(((type*)&vectortype) + i) for the expression.
2592 LOC is the location to use for the returned expression. */
2594 tree
2596 {
2597 tree ret;
2605 /* Allow vector[index] but not index[vector]. */
2607 {
2610 {
2615 }
2618 }
2621 {
2624 }
2627 {
2630 }
2632 /* ??? Existing practice has been to warn only when the char
2633 index is syntactically the index, not for char[array]. */
2637 /* Apply default promotions *after* noticing character types. */
2648 {
2651 /* An array that is indexed by a non-constant
2652 cannot be stored in a register; we must be able to do
2653 address arithmetic on its address.
2654 Likewise an array of elements of variable size. */
2658 {
2661 }
2662 /* An array that is indexed by a constant value which is not within
2663 the array bounds cannot be stored in a register either; because we
2664 would get a crash in store_bit_field/extract_bit_field when trying
2665 to access a non-existent part of the register. */
2669 {
2672 }
2676 {
2685 "ISO C90 forbids subscripting non-lvalue "
2687 }
2691 /* Array ref is const/volatile if the array elements are
2692 or if the array is. */
2701 /* This was added by rms on 16 Nov 91.
2702 It fixes vol struct foo *a; a->elts[1]
2703 in an inline function.
2704 Hope it doesn't break something else. */
2711 }
2712 else
2713 {
2724 RO_ARRAY_INDEXING);
2728 }
2729 }
2730 \f
2731 /* Build an external reference to identifier ID. FUN indicates
2732 whether this will be used for a function call. LOC is the source
2733 location of the identifier. This sets *TYPE to the type of the
2734 identifier, which is not the same as the type of the returned value
2735 for CONST_DECLs defined as enum constants. If the type of the
2736 identifier is not available, *TYPE is set to NULL. */
2737 tree
2739 {
2740 tree ref;
2743 /* In Objective-C, an instance variable (ivar) may be preferred to
2744 whatever lookup_name() found. */
2749 {
2752 }
2754 /* Implicit function declaration. */
2757 /* Don't complain about something that's already been
2758 complained about. */
2760 else
2761 {
2764 }
2772 /* Recursive call does not count as usage. */
2774 {
2776 }
2779 {
2786 }
2789 {
2795 {
2800 }
2804 }
2809 {
2814 }
2815 /* C99 6.7.4p3: An inline definition of a function with external
2816 linkage ... shall not contain a reference to an identifier with
2817 internal linkage. */
2826 csi_internal);
2829 }
2831 /* Record details of decls possibly used inside sizeof or typeof. */
2832 struct maybe_used_decl
2833 {
2834 /* The decl. */
2835 tree decl;
2836 /* The level seen at (in_sizeof + in_typeof). */
2838 /* The next one at this level or above, or NULL. */
2840 };
2844 /* Record that DECL, an undefined static function reference seen
2845 inside sizeof or typeof, might be used if the operand of sizeof is
2846 a VLA type or the operand of typeof is a variably modified
2847 type. */
2849 static void
2851 {
2857 }
2859 /* Pop the stack of decls possibly used inside sizeof or typeof. If
2860 USED is false, just discard them. If it is true, mark them used
2861 (if no longer inside sizeof or typeof) or move them to the next
2862 level up (if still inside sizeof or typeof). */
2864 void
2866 {
2870 {
2872 {
2875 else
2877 }
2879 }
2882 }
2884 /* Return the result of sizeof applied to EXPR. */
2886 struct c_expr
2888 {
2891 {
2896 }
2897 else
2898 {
2903 {
2905 "%<sizeof%> on array function parameter %qE will "
2909 }
2918 {
2919 /* sizeof is evaluated when given a vla (C99 6.5.3.4p2). */
2924 }
2926 }
2928 }
2930 /* Return the result of sizeof applied to T, a structure for the type
2931 name passed to sizeof (rather than the type itself). LOC is the
2932 location of the original expression. */
2934 struct c_expr
2936 {
2937 tree type;
2949 {
2950 /* If the type is a [*] array, it is a VLA but is represented as
2951 having a size of zero. In such a case we must ensure that
2952 the result of sizeof does not get folded to a constant by
2953 c_fully_fold, because if the size is evaluated the result is
2954 not constant and so constraints on zero or negative size
2955 arrays must not be applied when this sizeof call is inside
2956 another array declarator. */
2962 }
2966 }
2968 /* Build a function call to function FUNCTION with parameters PARAMS.
2969 The function call is at LOC.
2970 PARAMS is a list--a chain of TREE_LIST nodes--in which the
2971 TREE_VALUE of each node is a parameter-expression.
2972 FUNCTION's data type may be a function type or a pointer-to-function. */
2974 tree
2976 {
2978 tree ret;
2986 }
2988 /* Give a note about the location of the declaration of DECL. */
2990 static void
2992 {
2995 }
2997 /* Build a function call to function FUNCTION with parameters PARAMS.
2998 ORIGTYPES, if not NULL, is a vector of types; each element is
2999 either NULL or the original type of the corresponding element in
3000 PARAMS. The original type may differ from TREE_TYPE of the
3001 parameter for enums. FUNCTION's data type may be a function type
3002 or pointer-to-function. This function changes the elements of
3003 PARAMS. */
3005 tree
3009 {
3012 tree tem;
3017 /* Strip NON_LVALUE_EXPRs, etc., since we aren't using as an lvalue. */
3020 /* Convert anything with function type to a pointer-to-function. */
3022 {
3028 /* Atomic functions have type checking/casting already done. They are
3029 often rewritten and don't match the original parameter list. */
3032 }
3036 /* For Objective-C, convert any calls via a cast to OBJC_TYPE_REF
3037 expressions, like those used for ObjC messenger dispatches. */
3050 {
3054 function);
3056 {
3059 function);
3061 }
3062 else
3066 }
3071 /* fntype now gets the type of function pointed to. */
3074 /* Convert the parameters to the types declared in the
3075 function prototype, or apply default promotions. */
3082 /* Check that the function is called through a compatible prototype.
3083 If it is not, warn. */
3088 {
3091 /* This situation leads to run-time undefined behavior. We can't,
3092 therefore, simply error unless we can prove that all possible
3093 executions of the program must execute the code. */
3100 }
3104 /* Check that arguments to builtin functions match the expectations. */
3109 argarray))
3112 /* Check that the arguments to the function are valid. */
3118 {
3120 result
3123 else
3129 }
3130 else
3133 /* If -Wnonnull warning has been diagnosed, avoid diagnosing it again
3134 later. */
3138 /* In this improbable scenario, a nested function returns a VM type.
3139 Create a TARGET_EXPR so that the call always has a LHS, much as
3140 what the C++ FE does for functions returning non-PODs. */
3142 {
3146 }
3149 {
3154 }
3156 }
3158 /* Like build_function_call_vec, but call also resolve_overloaded_builtin. */
3160 tree
3164 {
3165 /* Strip NON_LVALUE_EXPRs, etc., since we aren't using as an lvalue. */
3168 /* Convert anything with function type to a pointer-to-function. */
3170 {
3171 /* Implement type-directed function overloading for builtins.
3172 resolve_overloaded_builtin and targetm.resolve_overloaded_builtin
3173 handle all the type checking. The result is a complete expression
3174 that implements this function call. */
3178 }
3180 }
3181 \f
3182 /* Convert the argument expressions in the vector VALUES
3183 to the types in the list TYPELIST.
3185 If TYPELIST is exhausted, or when an element has NULL as its type,
3186 perform the default conversions.
3188 ORIGTYPES is the original types of the expressions in VALUES. This
3189 holds the type of enum values which have been converted to integral
3190 types. It may be NULL.
3192 FUNCTION is a tree for the called function. It is used only for
3193 error messages, where it is formatted with %qE.
3195 This is also where warnings about wrong number of args are generated.
3197 ARG_LOC are locations of function arguments (if any).
3199 Returns the actual number of arguments processed (which may be less
3200 than the length of VALUES in some error situations), or -1 on
3201 failure. */
3203 static int
3207 {
3215 tree selector;
3217 /* Change pointer to function to the function itself for
3218 diagnostics. */
3223 /* Handle an ObjC selector specially for diagnostics. */
3226 /* For type-generic built-in functions, determine whether excess
3227 precision should be removed (classification) or not
3228 (comparison). */
3232 {
3234 {
3247 /* The last argument of these type-generic builtins
3248 should not be promoted. */
3254 }
3255 }
3257 /* Scan the given expressions and types, producing individual
3258 converted arguments. */
3263 {
3271 tree parmval;
3272 /* Some __atomic_* builtins have additional hidden argument at
3273 position 0. */
3274 location_t ploc
3280 {
3283 else
3287 }
3290 {
3293 }
3297 /* If there is excess precision and a prototype, convert once to
3298 the required type rather than converting via the semantic
3299 type. Likewise without a prototype a float value represented
3300 as long double should be converted once to double. But for
3301 type-generic classification functions excess precision must
3302 be removed here. */
3305 {
3308 }
3314 /* Some floating-point arguments must be promoted to double when
3315 no type is specified by a prototype. This applies to
3316 arguments of type float, and to architecture-specific types
3317 (ARM __fp16), but not to _FloatN or _FloatNx types. */
3326 {
3327 /* Promote this argument, unless it has a _FloatN or
3328 _FloatNx type. */
3332 {
3335 }
3336 }
3339 {
3340 /* Formal parm type is specified by a function prototype. */
3343 {
3347 }
3348 else
3349 {
3350 tree origtype;
3352 /* Optionally warn about conversions that
3353 differ from the default conversions. */
3355 {
3361 "passing argument %d of %qE as integer rather "
3367 "passing argument %d of %qE as integer rather "
3373 "passing argument %d of %qE as complex rather "
3379 "passing argument %d of %qE as floating rather "
3385 "passing argument %d of %qE as complex rather "
3391 "passing argument %d of %qE as floating rather "
3394 /* ??? At some point, messages should be written about
3395 conversions between complex types, but that's too messy
3396 to do now. */
3399 {
3400 /* Warn if any argument is passed as `float',
3401 since without a prototype it would be `double'. */
3405 "passing argument %d of %qE as %<float%> "
3409 /* Warn if mismatch between argument and prototype
3410 for decimal float types. Warn of conversions with
3411 binary float types and of precision narrowing due to
3412 prototype. */
3420 && (formal_prec
3423 && (valtype
3424 != dfloat64_type_node
3425 && (valtype
3428 && (valtype
3431 "passing argument %d of %qE as %qT "
3435 }
3436 /* Detect integer changing in width or signedness.
3437 These warnings are only activated with
3438 -Wtraditional-conversion, not with -Wtraditional. */
3442 {
3451 /* No warning if function asks for enum
3452 and the actual arg is that enum type. */
3453 ;
3456 "passing argument %d of %qE "
3460 ;
3461 /* Don't complain if the formal parameter type
3462 is an enum, because we can't tell now whether
3463 the value was an enum--even the same enum. */
3465 ;
3468 /* Change in signedness doesn't matter
3469 if a constant value is unaffected. */
3470 ;
3471 /* If the value is extended from a narrower
3472 unsigned type, it doesn't matter whether we
3473 pass it as signed or unsigned; the value
3474 certainly is the same either way. */
3477 ;
3480 "passing argument %d of %qE "
3483 else
3485 "passing argument %d of %qE "
3488 }
3489 }
3491 /* Possibly restore an EXCESS_PRECISION_EXPR for the
3492 sake of better warnings from convert_and_check. */
3505 }
3506 }
3508 {
3511 else
3512 {
3513 /* Convert `float' to `double'. */
3516 "implicit conversion from %qT to %qT when passing "
3520 }
3521 }
3524 /* A "double" argument with excess precision being passed
3525 without a prototype or in variable arguments.
3526 The last argument of __builtin_*_overflow_p should not be
3527 promoted. */
3531 {
3534 }
3536 {
3538 }
3539 else
3540 /* Convert `short' and `char' to full-size `int'. */
3549 }
3554 {
3558 }
3561 }
3562 \f
3563 /* This is the entry point used by the parser to build unary operators
3564 in the input. CODE, a tree_code, specifies the unary operator, and
3565 ARG is the operand. For unary plus, the C parser currently uses
3566 CONVERT_EXPR for code.
3568 LOC is the location to use for the tree generated.
3569 */
3571 struct c_expr
3573 {
3580 {
3582 }
3583 else
3584 {
3589 }
3591 /* We are typically called when parsing a prefix token at LOC acting on
3592 ARG. Reflect this by updating the source range of the result to
3593 start at LOC and end at the end of ARG. */
3598 }
3600 /* Returns true if TYPE is a character type, *not* including wchar_t. */
3602 static bool
3604 {
3610 }
3612 /* This is the entry point used by the parser to build binary operators
3613 in the input. CODE, a tree_code, specifies the binary operator, and
3614 ARG1 and ARG2 are the operands. In addition to constructing the
3615 expression, we check for operands that were written with other binary
3616 operators in a way that is likely to confuse the user.
3618 LOCATION is the location of the binary operator. */
3620 struct c_expr
3623 {
3641 {
3646 }
3655 /* Check for cases such as x+y<<z which users are likely
3656 to misinterpret. */
3666 {
3670 {
3674 else
3676 }
3678 {
3682 else
3684 }
3687 }
3693 /* Avoid warning for !!x == y. */
3696 {
3697 /* Avoid warning for !b == y where b has _Bool type. */
3702 {
3704 do
3705 {
3712 else
3714 }
3716 }
3719 }
3721 /* Warn about comparisons against string literals, with the exception
3722 of testing for equality or inequality of a string literal with NULL. */
3724 {
3731 /* Warn for ptr == '\0', it's likely that it should've been ptr[0]. */
3736 "comparison between pointer and zero character "
3743 "comparison between pointer and zero character "
3746 }
3757 /* Warn about comparisons of different enum types. */
3768 }
3769 \f
3770 /* Return a tree for the difference of pointers OP0 and OP1.
3771 The resulting tree has type ptrdiff_t. If POINTER_SUBTRACT sanitization is
3772 enabled, assign to INSTRUMENT_EXPR call to libsanitizer. */
3774 static tree
3776 {
3785 /* If the operands point into different address spaces, we need to
3786 explicitly convert them to pointers into the common address space
3787 before we can subtract the numerical address values. */
3789 {
3790 addr_space_t as_common;
3791 tree common_type;
3793 /* Determine the common superset address space. This is guaranteed
3794 to exist because the caller verified that comp_target_types
3795 returned non-zero. */
3802 }
3804 /* Determine integer type result of the subtraction. This will usually
3805 be the same as the result type (ptrdiff_t), but may need to be a wider
3806 type if pointers for the address space are wider than ptrdiff_t. */
3809 else
3820 {
3828 }
3830 /* First do the subtraction, then build the divide operator
3831 and only convert at the very end.
3832 Do not do default conversions in case restype is a short type. */
3834 /* POINTER_DIFF_EXPR requires a signed integer type of the same size as
3835 pointers. If some platform cannot provide that, or has a larger
3836 ptrdiff_type to support differences larger than half the address
3837 space, cast the pointers to some larger integer type and do the
3838 computations in that type. */
3842 else
3845 /* This generates an error if op1 is pointer to incomplete type. */
3854 /* Divide by the size, in easiest possible way. */
3858 /* Convert to final result type if necessary. */
3860 }
3861 \f
3862 /* Expand atomic compound assignments into an appropriate sequence as
3863 specified by the C11 standard section 6.5.16.2.
3865 _Atomic T1 E1
3866 T2 E2
3867 E1 op= E2
3869 This sequence is used for all types for which these operations are
3870 supported.
3872 In addition, built-in versions of the 'fe' prefixed routines may
3873 need to be invoked for floating point (real, complex or vector) when
3874 floating-point exceptions are supported. See 6.5.16.2 footnote 113.
3876 T1 newval;
3877 T1 old;
3878 T1 *addr
3879 T2 val
3880 fenv_t fenv
3882 addr = &E1;
3883 val = (E2);
3884 __atomic_load (addr, &old, SEQ_CST);
3885 feholdexcept (&fenv);
3886 loop:
3887 newval = old op val;
3888 if (__atomic_compare_exchange_strong (addr, &old, &newval, SEQ_CST,
3889 SEQ_CST))
3890 goto done;
3891 feclearexcept (FE_ALL_EXCEPT);
3892 goto loop:
3893 done:
3894 feupdateenv (&fenv);
3896 The compiler will issue the __atomic_fetch_* built-in when possible,
3897 otherwise it will generate the generic form of the atomic operations.
3898 This requires temp(s) and has their address taken. The atomic processing
3899 is smart enough to figure out when the size of an object can utilize
3900 a lock-free version, and convert the built-in call to the appropriate
3901 lock-free routine. The optimizers will then dispose of any temps that
3902 are no longer required, and lock-free implementations are utilized as
3903 long as there is target support for the required size.
3905 If the operator is NOP_EXPR, then this is a simple assignment, and
3906 an __atomic_store is issued to perform the assignment rather than
3907 the above loop. */
3909 /* Build an atomic assignment at LOC, expanding into the proper
3910 sequence to store LHS MODIFYCODE= RHS. Return a value representing
3911 the result of the operation, unless RETURN_OLD_P, in which case
3912 return the old value of LHS (this is only for postincrement and
3913 postdecrement). */
3915 static tree
3918 {
3923 tree compound_stmt;
3931 tree nonatomic_rhs_semantic_type;
3932 tree rhs_type;
3939 /* Allocate enough vector items for a compare_exchange. */
3942 /* Create a compound statement to hold the sequence of statements
3943 with a loop. */
3946 /* Remove any excess precision (which is only present here in the
3947 case of compound assignments). */
3949 {
3952 }
3955 /* Fold the RHS if it hasn't already been folded. */
3959 /* Remove the qualifiers for the rest of the expressions and create
3960 the VAL temp variable to hold the RHS. */
3964 TYPE_UNQUALIFIED);
3969 NULL_TREE);
3973 /* NOP_EXPR indicates it's a straight store of the RHS. Simply issue
3974 an atomic_store. */
3976 {
3977 /* Build __atomic_store (&lhs, &val, SEQ_CST) */
3986 /* Finish the compound statement. */
3989 /* VAL is the value which was stored, return a COMPOUND_STMT of
3990 the statement and that value. */
3992 }
3994 /* Attempt to implement the atomic operation as an __atomic_fetch_* or
3995 __atomic_*_fetch built-in rather than a CAS loop. atomic_bool type
3996 isn't applicable for such builtins. ??? Do we want to handle enums? */
3999 {
4000 built_in_function fncode;
4002 {
4005 fncode = (return_old_p
4006 ? BUILT_IN_ATOMIC_FETCH_ADD_N
4010 fncode = (return_old_p
4011 ? BUILT_IN_ATOMIC_FETCH_SUB_N
4015 fncode = (return_old_p
4016 ? BUILT_IN_ATOMIC_FETCH_AND_N
4020 fncode = (return_old_p
4021 ? BUILT_IN_ATOMIC_FETCH_OR_N
4025 fncode = (return_old_p
4026 ? BUILT_IN_ATOMIC_FETCH_XOR_N
4031 }
4033 /* We can only use "_1" through "_16" variants of the atomic fetch
4034 built-ins. */
4039 /* If this is a pointer type, we need to multiply by the size of
4040 the pointer target type. */
4042 {
4044 /* ??? This would introduce -Wdiscarded-qualifiers
4045 warning: __atomic_fetch_* expect volatile void *
4046 type as the first argument. (Assignments between
4047 atomic and non-atomic objects are OK.) */
4054 }
4056 /* Build __atomic_fetch_* (&lhs, &val, SEQ_CST), or
4057 __atomic_*_fetch (&lhs, &val, SEQ_CST). */
4072 /* Finish the compound statement. */
4075 /* NEWVAL is the value which was stored, return a COMPOUND_STMT of
4076 the statement and that value. */
4078 }
4080 cas_loop:
4081 /* Create the variables and labels required for the op= form. */
4098 /* __atomic_load (addr, &old, SEQ_CST). */
4105 NULL_TREE);
4109 /* Create the expressions for floating-point environment
4110 manipulation, if required. */
4120 /* loop: */
4123 /* newval = old + val; */
4128 {
4132 }
4133 else
4139 {
4141 NULL_TREE);
4144 }
4146 /* if (__atomic_compare_exchange (addr, &old, &new, false, SEQ_CST, SEQ_CST))
4147 goto done; */
4167 /* goto loop; */
4172 /* done: */
4178 /* Finish the compound statement. */
4181 /* NEWVAL is the value that was successfully stored, return a
4182 COMPOUND_EXPR of the statement and the appropriate value. */
4185 }
4187 /* Construct and perhaps optimize a tree representation
4188 for a unary operation. CODE, a tree_code, specifies the operation
4189 and XARG is the operand.
4190 For any CODE other than ADDR_EXPR, NOCONVERT suppresses the default
4191 promotions (such as from short to int).
4192 For ADDR_EXPR, the default promotions are not applied; NOCONVERT allows
4193 non-lvalues; this is only used to handle conversion of non-lvalue arrays
4194 to pointers in C99.
4196 LOCATION is the location of the operator. */
4198 tree
4201 {
4202 /* No default_conversion here. It causes trouble for ADDR_EXPR. */
4206 tree val;
4227 {
4230 }
4233 {
4236 }
4239 {
4241 /* This is used for unary plus, because a CONVERT_EXPR
4242 is enough to prevent anybody from looking inside for
4243 associativity, but won't generate any code. */
4247 {
4250 }
4260 {
4263 }
4269 /* ~ works on integer types and non float vectors. */
4273 {
4276 /* Warn if the expression has boolean value. */
4284 {
4288 }
4291 }
4293 {
4299 }
4300 else
4301 {
4304 }
4309 {
4312 }
4318 /* Conjugating a real value is a no-op, but allow it anyway. */
4321 {
4324 }
4333 {
4337 }
4339 {
4342 }
4343 else
4346 /* If the TRUTH_NOT_EXPR has been folded, reset the location. */
4366 {
4369 noconvert);
4377 }
4379 /* Complain about anything that is not a true lvalue. In
4380 Objective-C, skip this check for property_refs. */
4385 ? lv_increment
4390 {
4394 else
4397 }
4400 {
4404 else
4407 }
4409 /* Ensure the argument is fully folded inside any SAVE_EXPR. */
4415 /* Increment or decrement the real part of the value,
4416 and don't change the imaginary part. */
4418 {
4425 {
4437 }
4438 }
4440 /* Report invalid types. */
4445 {
4448 else
4452 }
4454 {
4455 tree inc;
4459 /* Compute the increment. */
4462 {
4463 /* If pointer target is an incomplete type,
4464 we just cannot know how to do the arithmetic. */
4466 {
4471 else
4475 }
4478 {
4482 else
4485 }
4489 }
4491 {
4492 /* For signed fract types, we invert ++ to -- or
4493 -- to ++, and change inc from 1 to -1, because
4494 it is not possible to represent 1 in signed fract constants.
4495 For unsigned fract types, the result always overflows and
4496 we get an undefined (original) or the maximum value. */
4508 }
4509 else
4510 {
4515 }
4517 /* If 'arg' is an Objective-C PROPERTY_REF expression, then we
4518 need to ask Objective-C to build the increment or decrement
4519 expression for it. */
4524 /* Report a read-only lvalue. */
4526 {
4532 }
4539 /* If the argument is atomic, use the special code sequences for
4540 atomic compound assignment. */
4542 {
4547 ? PLUS_EXPR
4550 ? inc
4555 }
4559 else
4566 }
4569 /* Note that this operation never does default_conversion. */
4571 /* The operand of unary '&' must be an lvalue (which excludes
4572 expressions of type void), or, in C99, the result of a [] or
4573 unary '*' operator. */
4579 /* Let &* cancel out to simplify resulting code. */
4581 {
4582 /* Don't let this be an lvalue. */
4587 }
4589 /* Anything not already handled and not a true memory reference
4590 or a non-lvalue array is an error. */
4595 /* Move address operations inside C_MAYBE_CONST_EXPR to simplify
4596 folding later. */
4598 {
4601 noconvert);
4608 }
4610 /* Ordinary case; arg is a COMPONENT_REF or a decl. */
4613 /* If the lvalue is const or volatile, merge that into the type
4614 to which the address will point. This is only needed
4615 for function types. */
4619 {
4629 }
4632 {
4635 {
4639 }
4641 /* fall through */
4645 {
4648 {
4652 }
4657 "address of array with reverse scalar storage "
4659 }
4663 }
4673 /* ??? Cope with user tricks that amount to offsetof. Delete this
4674 when we have proper support for integer constant expressions. */
4678 {
4681 }
4690 }
4695 ret = (require_constant_value
4698 else
4700 return_build_unary_op:
4711 }
4713 /* Return nonzero if REF is an lvalue valid for this language.
4714 Lvalues can be assigned, unless their type has TYPE_READONLY.
4715 Lvalues can have their address taken, unless they have C_DECL_REGISTER. */
4717 bool
4719 {
4723 {
4750 }
4751 }
4752 \f
4753 /* Give a warning for storing in something that is read-only in GCC
4754 terms but not const in ISO C terms. */
4756 static void
4758 {
4760 {
4772 }
4774 }
4777 /* Return nonzero if REF is an lvalue valid for this language;
4778 otherwise, print an error message and return zero. USE says
4779 how the lvalue is being used and so selects the error message.
4780 LOCATION is the location at which any error should be reported. */
4782 static int
4784 {
4791 }
4792 \f
4793 /* Mark EXP saying that we need to be able to take the
4794 address of it; it should not be allocated in a register.
4795 Returns true if successful. ARRAY_REF_P is true if this
4796 is for ARRAY_REF construction - in that case we don't want
4797 to look through VIEW_CONVERT_EXPR from VECTOR_TYPE to ARRAY_TYPE,
4798 it is fine to use ARRAY_REFs for vector subscripts on vector
4799 register variables. */
4801 bool
4803 {
4808 {
4814 /* FALLTHRU */
4834 {
4836 {
4837 error
4840 }
4842 }
4844 {
4847 else
4850 }
4852 /* FALLTHRU */
4855 /* FALLTHRU */
4858 }
4859 }
4860 \f
4861 /* Convert EXPR to TYPE, warning about conversion problems with
4862 constants. SEMANTIC_TYPE is the type this conversion would use
4863 without excess precision. If SEMANTIC_TYPE is NULL, this function
4864 is equivalent to convert_and_check. This function is a wrapper that
4865 handles conversions that may be different than
4866 the usual ones because of excess precision. */
4868 static tree
4870 tree semantic_type)
4871 {
4875 /* For C11, integer conversions may have results with excess
4876 precision. */
4882 {
4883 /* For integers, we need to check the real conversion, not
4884 the conversion to the excess precision type. */
4886 }
4887 /* Result type is the excess precision type, which should be
4888 large enough, so do not check. */
4890 }
4892 /* Build and return a conditional expression IFEXP ? OP1 : OP2. If
4893 IFEXP_BCP then the condition is a call to __builtin_constant_p, and
4894 if folded to an integer constant then the unselected half may
4895 contain arbitrary operations not normally permitted in constant
4896 expressions. Set the location of the expression to LOC. */
4898 tree
4902 {
4903 tree type1;
4904 tree type2;
4912 tree ret;
4924 /* Promote both alternatives. */
4947 /* C90 does not permit non-lvalue arrays in conditional expressions.
4948 In C99 they will be pointers by now. */
4950 {
4953 }
4961 {
4964 {
4968 }
4970 {
4974 }
4975 }
4978 {
4989 }
4991 /* Quickly detect the usual case where op1 and op2 have the same type
4992 after promotion. */
4994 {
4997 else
4999 }
5004 {
5005 /* In C11, a conditional expression between a floating-point
5006 type and an integer type should convert the integer type to
5007 the evaluation format of the floating-point type, with
5008 possible excess precision. */
5012 {
5013 tree eptype;
5016 {
5020 }
5023 {
5027 }
5028 }
5033 "implicit conversion from %qT to %qT to "
5035 colon_loc);
5037 /* If -Wsign-compare, warn here if type1 and type2 have
5038 different signedness. We'll promote the signed to unsigned
5039 and later code won't know it used to be different.
5040 Do this check on the original types, so that explicit casts
5041 will be considered, but default promotions won't. */
5043 {
5048 {
5051 /* Do not warn if the result type is signed, since the
5052 signed type will only be chosen if it can represent
5053 all the values of the unsigned type. */
5056 else
5057 {
5061 /* Do not warn if the signed quantity is an
5062 unsuffixed integer literal (or some static
5063 constant expression involving such literals) and
5064 it is non-negative. This warning requires the
5065 operands to be folded for best results, so do
5066 that folding in this case even without
5067 warn_sign_compare to avoid warning options
5068 possibly affecting code generation. */
5069 c_inhibit_evaluation_warnings
5073 c_inhibit_evaluation_warnings
5076 c_inhibit_evaluation_warnings
5080 c_inhibit_evaluation_warnings
5084 {
5087 || (unsigned_op1
5092 "operand of ?: changes signedness from "
5093 "%qT to %qT due to unsignedness of other "
5096 else
5098 "operand of ?: changes signedness from "
5099 "%qT to %qT due to unsignedness of other "
5102 }
5107 }
5108 }
5109 }
5110 }
5112 {
5117 }
5119 {
5122 addr_space_t as_common;
5131 {
5135 }
5138 {
5143 "pointer to array loses qualifier "
5148 "ISO C forbids conditional expr between "
5152 }
5155 {
5160 "pointer to array loses qualifier "
5165 "ISO C forbids conditional expr between "
5169 }
5170 /* Objective-C pointer comparisons are a bit more lenient. */
5173 else
5174 {
5179 result_type = build_pointer_type
5181 }
5182 }
5184 {
5188 else
5189 {
5191 }
5193 }
5195 {
5199 else
5200 {
5202 }
5204 }
5207 {
5210 else
5211 {
5214 }
5215 }
5217 /* Merge const and volatile flags of the incoming types. */
5218 result_type
5224 semantic_result_type);
5226 semantic_result_type);
5229 {
5232 }
5234 {
5237 }
5239 && op1_int_operands
5242 {
5249 }
5251 /* Need to convert condition operand into a vector mask. */
5253 {
5260 }
5264 else
5265 {
5267 {
5268 /* Use c_fully_fold here, since C_MAYBE_CONST_EXPR might be
5269 nested inside of the expression. */
5272 }
5276 }
5282 /* If the OP1 and OP2 are the same and don't have side-effects,
5283 warn here, because the COND_EXPR will be turned into OP1. */
5291 }
5292 \f
5293 /* Return a compound expression that performs two expressions and
5294 returns the value of the second of them.
5296 LOC is the location of the COMPOUND_EXPR. */
5298 tree
5300 {
5303 tree ret;
5315 {
5318 }
5321 {
5322 /* The left-hand operand of a comma expression is like an expression
5323 statement: with -Wunused, we should warn if it doesn't have
5324 any side-effects, unless it was explicitly cast to (void). */
5326 {
5334 else
5337 }
5338 }
5341 {
5345 {
5349 }
5355 }
5357 /* With -Wunused, we should also warn if the left-hand operand does have
5358 side-effects, but computes a value which is not used. For example, in
5359 `foo() + bar(), baz()' the result of the `+' operator is not used,
5360 so we should issue a warning. */
5370 && expr1_int_operands
5379 }
5381 /* Issue -Wcast-qual warnings when appropriate. TYPE is the type to
5382 which we are casting. OTYPE is the type of the expression being
5383 cast. Both TYPE and OTYPE are pointer types. LOC is the location
5384 of the cast. -Wcast-qual appeared on the command line. Named
5385 address space qualifiers are not handled here, because they result
5386 in different warnings. */
5388 static void
5390 {
5397 /* Check that the qualifiers on IN_TYPE are a superset of the
5398 qualifiers of IN_OTYPE. The outermost level of POINTER_TYPE
5399 nodes is uninteresting and we stop as soon as we hit a
5400 non-POINTER_TYPE node on either type. */
5401 do
5402 {
5406 /* GNU C allows cv-qualified function types. 'const' means the
5407 function is very pure, 'volatile' means it can't return. We
5408 need to warn when such qualifiers are added, not when they're
5409 taken away. */
5414 else
5417 }
5426 /* There are qualifiers present in IN_OTYPE that are not present
5427 in IN_TYPE. */
5430 discarded);
5435 /* A cast from **T to const **T is unsafe, because it can cause a
5436 const value to be changed with no additional warning. We only
5437 issue this warning if T is the same on both sides, and we only
5438 issue the warning if there are the same number of pointers on
5439 both sides, as otherwise the cast is clearly unsafe anyhow. A
5440 cast is unsafe when a qualifier is added at one level and const
5441 is not present at all outer levels.
5443 To issue this warning, we check at each level whether the cast
5444 adds new qualifiers not already seen. We don't need to special
5445 case function types, as they won't have the same
5446 TYPE_MAIN_VARIANT. */
5456 do
5457 {
5462 {
5464 "to be safe all intermediate pointers in cast from "
5468 }
5471 }
5473 }
5475 /* Heuristic check if two parameter types can be considered ABI-equivalent. */
5477 static bool
5479 {
5487 /* The signedness of the parameter matters only when an integral
5488 type smaller than int is promoted to int, otherwise only the
5489 precision of the parameter matters.
5490 This check should make sure that the callee does not see
5491 undefined values in argument registers. */
5501 }
5503 /* Check if a type cast between two function types can be considered safe. */
5505 static bool
5507 {
5526 }
5528 /* Build an expression representing a cast to type TYPE of expression EXPR.
5529 LOC is the location of the cast-- typically the open paren of the cast. */
5531 tree
5533 {
5534 tree value;
5544 /* The ObjC front-end uses TYPE_MAIN_VARIANT to tie together types differing
5545 only in <protocol> qualifications. But when constructing cast expressions,
5546 the protocols do matter and must be kept around. */
5553 {
5556 }
5559 {
5562 }
5565 {
5569 }
5572 {
5577 /* Convert to remove any qualifiers from VALUE's type. */
5579 }
5581 {
5582 tree field;
5591 {
5592 tree t;
5604 }
5607 }
5608 else
5609 {
5613 {
5617 }
5621 /* Optionally warn about potentially worrisome casts. */
5627 /* Warn about conversions between pointers to disjoint
5628 address spaces. */
5632 {
5635 addr_space_t as_common;
5638 {
5649 else
5654 }
5655 }
5657 /* Warn about possible alignment problems. */
5663 /* Don't warn about opaque types, where the actual alignment
5664 restriction is unknown. */
5675 /* Unlike conversion of integers to pointers, where the
5676 warning is disabled for converting constants because
5677 of cases such as SIG_*, warn about converting constant
5678 pointers to integers. In some cases it may cause unwanted
5679 sign extension, and a warning is appropriate. */
5686 "cast from function call of type %qT "
5692 /* Don't warn about converting any constant. */
5701 /* If pedantic, warn for conversions between function and object
5702 pointer types, except for converting a null pointer constant
5703 to function pointer type. */
5728 "cast between incompatible function types"
5734 /* Ignore any integer overflow caused by the cast. */
5736 {
5738 {
5740 {
5741 /* Avoid clobbering a shared constant. */
5744 }
5745 }
5747 /* Reset VALUE's overflow flags, ensuring constant sharing. */
5749 }
5750 }
5752 /* Don't let a cast be an lvalue. */
5756 /* Don't allow the results of casting to floating-point or complex
5757 types be confused with actual constants, or casts involving
5758 integer and pointer types other than direct integer-to-integer
5759 and integer-to-pointer be confused with integer constant
5760 expressions and null pointer constants. */
5772 }
5774 /* Interpret a cast of expression EXPR to type TYPE. LOC is the
5775 location of the open paren of the cast, or the position of the cast
5776 expr. */
5777 tree
5779 {
5780 tree type;
5783 tree ret;
5786 /* This avoids warnings about unprototyped casts on
5787 integers. E.g. "#define SIG_DFL (void(*)())0". */
5799 {
5806 }
5811 /* C++ does not permits types to be defined in a cast, but it
5812 allows references to incomplete types. */
5818 }
5819 \f
5820 /* Build an assignment expression of lvalue LHS from value RHS.
5821 If LHS_ORIGTYPE is not NULL, it is the original type of LHS, which
5822 may differ from TREE_TYPE (LHS) for an enum bitfield.
5823 MODIFYCODE is the code for a binary operator that we use
5824 to combine the old value of LHS with RHS to get the new value.
5825 Or else MODIFYCODE is NOP_EXPR meaning do a simple assignment.
5826 If RHS_ORIGTYPE is not NULL_TREE, it is the original type of RHS,
5827 which may differ from TREE_TYPE (RHS) for an enum value.
5829 LOCATION is the location of the MODIFYCODE operator.
5830 RHS_LOC is the location of the RHS. */
5832 tree
5836 {
5837 tree result;
5838 tree newrhs;
5845 /* Types that aren't fully specified cannot be used in assignments. */
5848 /* Avoid duplicate error messages from operands that had errors. */
5852 /* Ensure an error for assigning a non-lvalue array to an array in
5853 C90. */
5855 {
5858 }
5860 /* For ObjC properties, defer this check. */
5869 {
5872 rhs_origtype);
5881 }
5883 /* If a binary op has been requested, combine the old LHS value with the RHS
5884 producing the value we should actually store into the LHS. */
5887 {
5891 /* Construct the RHS for any non-atomic compound assignemnt. */
5893 {
5894 /* If in LHS op= RHS the RHS has side-effects, ensure they
5895 are preevaluated before the rest of the assignment expression's
5896 side-effects, because RHS could contain e.g. function calls
5897 that modify LHS. */
5899 {
5902 else
5907 newrhs);
5908 }
5912 /* The original type of the right hand side is no longer
5913 meaningful. */
5915 }
5916 }
5919 {
5920 /* Check if we are modifying an Objective-C property reference;
5921 if so, we need to generate setter calls. */
5924 else
5929 /* Else, do the check that we postponed for Objective-C. */
5932 }
5934 /* Give an error for storing in something that is 'const'. */
5939 {
5942 }
5946 /* If storing into a structure or union member,
5947 it has probably been given type `int'.
5948 Compute the type that would go with
5949 the actual amount of storage the member occupies. */
5958 /* If storing in a field that is in actuality a short or narrower than one,
5959 we must store in the field in its actual type. */
5962 {
5965 }
5967 /* Issue -Wc++-compat warnings about an assignment to an enum type
5968 when LHS does not have its original type. This happens for,
5969 e.g., an enum bitfield in a struct. */
5974 {
5976 ? rhs_origtype
5983 }
5985 /* If the lhs is atomic, remove that qualifier. */
5987 {
5994 }
5996 /* Convert new value to destination type. Fold it first, then
5997 restore any excess precision information, for the sake of
5998 conversion warnings. */
6001 {
6004 {
6007 }
6017 }
6019 /* Emit ObjC write barrier, if necessary. */
6021 {
6024 {
6027 }
6028 }
6030 /* Scan operands. */
6034 else
6035 {
6039 }
6041 /* If we got the LHS in a different type for storing in,
6042 convert the result back to the nominal type of LHS
6043 so that the value we return always has the same type
6044 as the LHS argument. */
6054 return_result:
6058 }
6059 \f
6060 /* Return whether STRUCT_TYPE has an anonymous field with type TYPE.
6061 This is used to implement -fplan9-extensions. */
6063 static bool
6065 {
6066 tree field;
6074 {
6077 TYPE_QUAL_ATOMIC)
6081 {
6085 }
6089 {
6093 }
6094 }
6096 }
6098 /* RHS is an expression whose type is pointer to struct. If there is
6099 an anonymous field in RHS with type TYPE, then return a pointer to
6100 that field in RHS. This is used with -fplan9-extensions. This
6101 returns NULL if no conversion could be found. */
6103 static tree
6105 {
6109 tree ret;
6118 TYPE_QUAL_ATOMIC)
6126 {
6132 TYPE_QUAL_ATOMIC)
6135 {
6139 }
6141 lhs_main_type))
6142 {
6147 }
6148 }
6155 NULL_TREE);
6159 {
6162 }
6165 }
6167 /* Issue an error message for a bad initializer component.
6168 GMSGID identifies the message.
6169 The component name is taken from the spelling stack. */
6171 static void
6173 {
6176 /* The gmsgid may be a format string with %< and %>. */
6181 }
6183 /* Issue a pedantic warning for a bad initializer component. OPT is
6184 the option OPT_* (from options.h) controlling this warning or 0 if
6185 it is unconditionally given. GMSGID identifies the message. The
6186 component name is taken from the spelling stack. */
6190 {
6191 /* Use the location where a macro was expanded rather than where
6192 it was defined to make sure macros defined in system headers
6193 but used incorrectly elsewhere are diagnosed. */
6203 }
6205 /* Issue a warning for a bad initializer component.
6207 OPT is the OPT_W* value corresponding to the warning option that
6208 controls this warning. GMSGID identifies the message. The
6209 component name is taken from the spelling stack. */
6211 static void
6213 {
6217 /* Use the location where a macro was expanded rather than where
6218 it was defined to make sure macros defined in system headers
6219 but used incorrectly elsewhere are diagnosed. */
6222 /* The gmsgid may be a format string with %< and %>. */
6227 }
6228 \f
6229 /* If TYPE is an array type and EXPR is a parenthesized string
6230 constant, warn if pedantic that EXPR is being used to initialize an
6231 object of type TYPE. */
6233 void
6235 {
6242 }
6244 /* Attempt to locate the parameter with the given index within FNDECL,
6245 returning DECL_SOURCE_LOCATION (FNDECL) if it can't be found. */
6247 static location_t
6249 {
6251 tree param;
6253 /* Locate param by index within DECL_ARGUMENTS (fndecl). */
6257 ;
6259 /* If something went wrong (e.g. if we have a builtin and thus no arguments),
6260 return DECL_SOURCE_LOCATION (FNDECL). */
6265 }
6267 /* Issue a note about a mismatching argument for parameter PARMNUM
6268 to FUNDECL, for types EXPECTED_TYPE and ACTUAL_TYPE.
6269 Attempt to issue the note at the pertinent parameter of the decl;
6270 failing that issue it at the location of FUNDECL; failing that
6271 issue it at PLOC. */
6273 static void
6276 {
6277 location_t loc;
6280 else
6286 }
6288 /* Convert value RHS to type TYPE as preparation for an assignment to
6289 an lvalue of type TYPE. If ORIGTYPE is not NULL_TREE, it is the
6290 original type of RHS; this differs from TREE_TYPE (RHS) for enum
6291 types. NULL_POINTER_CONSTANT says whether RHS was a null pointer
6292 constant before any folding.
6293 The real work of conversion is done by `convert'.
6294 The purpose of this function is to generate error messages
6295 for assignments that are not allowed in C.
6296 ERRTYPE says whether it is argument passing, assignment,
6297 initialization or return.
6299 In the following example, '~' denotes where EXPR_LOC and '^' where
6300 LOCATION point to:
6302 f (var); [ic_argpass]
6303 ^ ~~~
6304 x = var; [ic_assign]
6305 ^ ~~~;
6306 int x = var; [ic_init]
6307 ^^^
6308 return x; [ic_return]
6309 ^
6311 FUNCTION is a tree for the function being called.
6312 PARMNUM is the number of the argument, for printing in error messages. */
6314 static tree
6319 {
6322 tree rhstype;
6327 /* Use the expansion point location to handle cases such as user's
6328 function returning a wrong-type macro defined in a system header. */
6332 {
6333 tree selector;
6334 /* Change pointer to function to the function itself for
6335 diagnostics. */
6340 /* Handle an ObjC selector specially for diagnostics. */
6344 {
6347 }
6348 }
6350 /* This macro is used to emit diagnostics to ensure that all format
6351 strings are complete sentences, visible to gettext and checked at
6352 compile time. */
6353 #define PEDWARN_FOR_ASSIGNMENT(LOCATION, PLOC, OPT, AR, AS, IN, RE) \
6354 do { \
6355 switch (errtype) \
6356 { \
6357 case ic_argpass: \
6358 if (pedwarn (PLOC, OPT, AR, parmnum, rname)) \
6359 inform_for_arg (fundecl, (PLOC), parmnum, type, rhstype); \
6360 break; \
6361 case ic_assign: \
6362 pedwarn (LOCATION, OPT, AS); \
6363 break; \
6364 case ic_init: \
6365 pedwarn_init (LOCATION, OPT, IN); \
6366 break; \
6367 case ic_return: \
6368 pedwarn (LOCATION, OPT, RE); \
6369 break; \
6370 default: \
6371 gcc_unreachable (); \
6372 } \
6373 } while (0)
6375 /* This macro is used to emit diagnostics to ensure that all format
6376 strings are complete sentences, visible to gettext and checked at
6377 compile time. It is the same as PEDWARN_FOR_ASSIGNMENT but with an
6378 extra parameter to enumerate qualifiers. */
6379 #define PEDWARN_FOR_QUALIFIERS(LOCATION, PLOC, OPT, AR, AS, IN, RE, QUALS) \
6380 do { \
6381 switch (errtype) \
6382 { \
6383 case ic_argpass: \
6384 if (pedwarn (PLOC, OPT, AR, parmnum, rname, QUALS)) \
6385 inform_for_arg (fundecl, (PLOC), parmnum, type, rhstype); \
6386 break; \
6387 case ic_assign: \
6388 pedwarn (LOCATION, OPT, AS, QUALS); \
6389 break; \
6390 case ic_init: \
6391 pedwarn (LOCATION, OPT, IN, QUALS); \
6392 break; \
6393 case ic_return: \
6394 pedwarn (LOCATION, OPT, RE, QUALS); \
6395 break; \
6396 default: \
6397 gcc_unreachable (); \
6398 } \
6399 } while (0)
6401 /* This macro is used to emit diagnostics to ensure that all format
6402 strings are complete sentences, visible to gettext and checked at
6403 compile time. It is the same as PEDWARN_FOR_QUALIFIERS but uses
6404 warning_at instead of pedwarn. */
6405 #define WARNING_FOR_QUALIFIERS(LOCATION, PLOC, OPT, AR, AS, IN, RE, QUALS) \
6406 do { \
6407 switch (errtype) \
6408 { \
6409 case ic_argpass: \
6410 if (warning_at (PLOC, OPT, AR, parmnum, rname, QUALS)) \
6411 inform_for_arg (fundecl, (PLOC), parmnum, type, rhstype); \
6412 break; \
6413 case ic_assign: \
6414 warning_at (LOCATION, OPT, AS, QUALS); \
6415 break; \
6416 case ic_init: \
6417 warning_at (LOCATION, OPT, IN, QUALS); \
6418 break; \
6419 case ic_return: \
6420 warning_at (LOCATION, OPT, RE, QUALS); \
6421 break; \
6422 default: \
6423 gcc_unreachable (); \
6424 } \
6425 } while (0)
6437 {
6441 {
6457 }
6460 }
6463 {
6469 {
6494 }
6495 }
6501 {
6502 /* Except for passing an argument to an unprototyped function,
6503 this is a constraint violation. When passing an argument to
6504 an unprototyped function, it is compile-time undefined;
6505 making it a constraint in that case was rejected in
6506 DR#252. */
6509 }
6517 /* A non-reference type can convert to a reference. This handles
6518 va_start, va_copy and possibly port built-ins. */
6520 {
6522 {
6525 }
6535 parmnum);
6542 }
6543 /* Some types can interconvert without explicit casts. */
6547 /* Arithmetic types all interconvert, and enum is treated like int. */
6556 {
6557 tree ret;
6568 }
6570 /* Aggregates in different TUs might need conversion. */
6577 /* Conversion to a transparent union or record from its member types.
6578 This applies only to function arguments. */
6582 {
6586 {
6597 {
6601 /* Any non-function converts to a [const][volatile] void *
6602 and vice versa; otherwise, targets must be the same.
6603 Meanwhile, the lhs target must have all the qualifiers of
6604 the rhs. */
6608 {
6611 /* If this type won't generate any warnings, use it. */
6619 /* Keep looking for a better type, but remember this one. */
6622 }
6623 }
6625 /* Can convert integer zero to any pointer type. */
6627 {
6630 }
6631 }
6634 {
6636 {
6637 /* We have only a marginally acceptable member type;
6638 it needs a warning. */
6642 /* Const and volatile mean something different for function
6643 types, so the usual warnings are not appropriate. */
6646 {
6647 /* Because const and volatile on functions are
6648 restrictions that say the function will not do
6649 certain things, it is okay to use a const or volatile
6650 function where an ordinary one is wanted, but not
6651 vice-versa. */
6655 OPT_Wdiscarded_qualifiers,
6657 "makes %q#v qualified function "
6660 "function pointer from "
6663 "function pointer from "
6668 }
6672 OPT_Wdiscarded_qualifiers,
6684 }
6692 }
6693 }
6695 /* Conversions among pointers */
6698 {
6705 addr_space_t asl;
6706 addr_space_t asr;
6711 TYPE_QUAL_ATOMIC)
6716 TYPE_QUAL_ATOMIC)
6718 /* Opaque pointers are treated like void pointers. */
6721 /* The Plan 9 compiler permits a pointer to a struct to be
6722 automatically converted into a pointer to an anonymous field
6723 within the struct. */
6728 {
6731 {
6737 }
6738 }
6740 /* C++ does not allow the implicit conversion void* -> T*. However,
6741 for the purpose of reducing the number of false positives, we
6742 tolerate the special case of
6744 int *p = NULL;
6746 where NULL is typically defined in C to be '(void *) 0'. */
6749 OPT_Wc___compat,
6750 "request for implicit conversion "
6753 /* See if the pointers point to incompatible address spaces. */
6758 {
6760 {
6779 }
6781 }
6783 /* Check if the right-hand side has a format attribute but the
6784 left-hand side doesn't. */
6787 {
6789 {
6792 "argument %d of %qE might be "
6798 "assignment left-hand side might be "
6803 "initialization left-hand side might be "
6808 "return type might be "
6813 }
6814 }
6816 /* Any non-function converts to a [const][volatile] void *
6817 and vice versa; otherwise, targets must be the same.
6818 Meanwhile, the lhs target must have all the qualifiers of the rhs. */
6822 || is_opaque_pointer
6828 {
6829 /* Warn about loss of qualifers from pointers to arrays with
6830 qualifiers on the element type. */
6832 {
6839 OPT_Wdiscarded_array_qualifiers,
6849 }
6852 ||
6854 && !null_pointer_constant
6858 "%qE between function pointer "
6866 /* Const and volatile mean something different for function types,
6867 so the usual warnings are not appropriate. */
6870 {
6871 /* Don't warn about loss of qualifier for conversions from
6872 qualified void* to pointers to arrays with corresponding
6873 qualifier on the element type. */
6877 /* Assignments between atomic and non-atomic objects are OK. */
6880 {
6882 OPT_Wdiscarded_qualifiers,
6892 }
6893 /* If this is not a case of ignoring a mismatch in signedness,
6894 no warning. */
6897 ;
6898 /* If there is a mismatch, do warn. */
6901 {
6904 "pointer targets in passing argument %d of "
6913 "pointer targets in assignment from %qT to %qT "
6918 "pointer targets in initialization of %qT "
6920 rhstype);
6924 "returning %qT from a function with return type "
6929 }
6930 }
6933 {
6934 /* Because const and volatile on functions are restrictions
6935 that say the function will not do certain things,
6936 it is okay to use a const or volatile function
6937 where an ordinary one is wanted, but not vice-versa. */
6941 OPT_Wdiscarded_qualifiers,
6943 "%q#v qualified function pointer "
6952 }
6953 }
6954 /* Avoid warning about the volatile ObjC EH puts on decls. */
6956 {
6958 {
6961 "passing argument %d of %qE from incompatible "
6972 "initialization of %qT from incompatible pointer "
6977 "returning %qT from a function with incompatible "
6982 }
6983 }
6986 }
6988 {
6989 /* ??? This should not be an error when inlining calls to
6990 unprototyped functions. */
6993 }
6995 {
6996 /* An explicit constant 0 can convert to a pointer,
6997 or one that results from arithmetic, even including
6998 a cast to integer type. */
7001 {
7004 "passing argument %d of %qE makes pointer from "
7010 "assignment to %qT from %qT makes pointer from integer "
7015 "initialization of %qT from %qT makes pointer from "
7020 "function with return type %qT makes pointer from "
7025 }
7028 }
7030 {
7032 {
7035 "passing argument %d of %qE makes integer from "
7041 "assignment to %qT from %qT makes integer from pointer "
7046 "initialization of %qT from %qT makes integer from "
7051 "function with return type %qT makes integer from "
7056 }
7059 }
7061 {
7062 tree ret;
7068 }
7071 {
7074 rname);
7088 "incompatible types when returning type %qT but %qT was "
7093 }
7096 }
7097 \f
7098 /* If VALUE is a compound expr all of whose expressions are constant, then
7099 return its value. Otherwise, return error_mark_node.
7101 This is for handling COMPOUND_EXPRs as initializer elements
7102 which is allowed with a warning when -pedantic is specified. */
7104 static tree
7106 {
7108 {
7113 endtype);
7114 }
7117 else
7119 }
7120 \f
7121 /* Perform appropriate conversions on the initial value of a variable,
7122 store it in the declaration DECL,
7123 and print any error messages that are appropriate.
7124 If ORIGTYPE is not NULL_TREE, it is the original type of INIT.
7125 If the init is invalid, store an ERROR_MARK.
7127 INIT_LOC is the location of the initial value. */
7129 void
7131 {
7135 /* If variable's type was invalidly declared, just ignore it. */
7141 /* Digest the specified initializer into an expression. */
7148 /* Store the expression if valid; else report error. */
7158 /* ANSI wants warnings about out-of-range constant initializers. */
7163 /* Check if we need to set array size from compound literal size. */
7167 {
7174 {
7178 {
7179 /* For int foo[] = (int [3]){1}; we need to set array size
7180 now since later on array initializer will be just the
7181 brace enclosed list of the compound literal. */
7189 }
7190 }
7191 }
7192 }
7193 \f
7194 /* Methods for storing and printing names for error messages. */
7196 /* Implement a spelling stack that allows components of a name to be pushed
7197 and popped. Each element on the stack is this structure. */
7199 struct spelling
7200 {
7202 union
7203 {
7207 };
7209 #define SPELLING_STRING 1
7210 #define SPELLING_MEMBER 2
7211 #define SPELLING_BOUNDS 3
7217 /* Macros to save and restore the spelling stack around push_... functions.
7218 Alternative to SAVE_SPELLING_STACK. */
7220 #define SPELLING_DEPTH() (spelling - spelling_base)
7221 #define RESTORE_SPELLING_DEPTH(DEPTH) (spelling = spelling_base + (DEPTH))
7223 /* Push an element on the spelling stack with type KIND and assign VALUE
7224 to MEMBER. */
7226 #define PUSH_SPELLING(KIND, VALUE, MEMBER) \
7227 { \
7228 int depth = SPELLING_DEPTH (); \
7229 \
7230 if (depth >= spelling_size) \
7231 { \
7232 spelling_size += 10; \
7233 spelling_base = XRESIZEVEC (struct spelling, spelling_base, \
7234 spelling_size); \
7235 RESTORE_SPELLING_DEPTH (depth); \
7236 } \
7237 \
7238 spelling->kind = (KIND); \
7239 spelling->MEMBER = (VALUE); \
7240 spelling++; \
7241 }
7243 /* Push STRING on the stack. Printed literally. */
7245 static void
7247 {
7249 }
7251 /* Push a member name on the stack. Printed as '.' STRING. */
7253 static void
7255 {
7261 }
7263 /* Push an array bounds on the stack. Printed as [BOUNDS]. */
7265 static void
7267 {
7269 }
7271 /* Compute the maximum size in bytes of the printed spelling. */
7273 static int
7275 {
7280 {
7283 else
7285 }
7288 }
7290 /* Print the spelling to BUFFER and return it. */
7294 {
7300 {
7303 }
7304 else
7305 {
7310 ;
7311 }
7314 }
7316 /* Digest the parser output INIT as an initializer for type TYPE.
7317 Return a C expression of type TYPE to represent the initial value.
7319 If ORIGTYPE is not NULL_TREE, it is the original type of INIT.
7321 NULL_POINTER_CONSTANT is true if INIT is a null pointer constant.
7323 If INIT is a string constant, STRICT_STRING is true if it is
7324 unparenthesized or we should not warn here for it being parenthesized.
7325 For other types of INIT, STRICT_STRING is not used.
7327 INIT_LOC is the location of the INIT.
7329 REQUIRE_CONSTANT requests an error if non-constant initializers or
7330 elements are seen. */
7332 static tree
7336 {
7343 || !init
7350 {
7353 }
7356 /* Initialization of an array of chars from a string constant
7357 optionally enclosed in braces. */
7361 {
7362 tree typ1
7365 TYPE_QUAL_ATOMIC)
7367 /* Note that an array could be both an array of character type
7368 and an array of wchar_t if wchar_t is signed char or unsigned
7369 char. */
7378 {
7395 {
7397 {
7401 }
7402 }
7403 else
7404 {
7406 {
7410 }
7412 {
7416 }
7417 }
7423 {
7426 /* Subtract the size of a single (possibly wide) character
7427 because it's ok to ignore the terminating null char
7428 that is counted in the length of the constant. */
7440 }
7443 }
7445 {
7449 }
7450 }
7452 /* Build a VECTOR_CST from a *constant* vector constructor. If the
7453 vector constructor is not constant (e.g. {1,2,3,foo()}) then punt
7454 below and handle as a constructor. */
7459 {
7466 {
7468 tree value;
7471 /* Iterate through elements and check if all constructor
7472 elements are *_CSTs. */
7475 {
7478 }
7483 }
7484 }
7489 /* Any type can be initialized
7490 from an expression of the same type, optionally with braces. */
7503 {
7505 {
7507 {
7510 inside_init = array_to_pointer_conversion
7512 else
7513 {
7516 }
7517 }
7518 }
7521 /* Although the types are compatible, we may require a
7522 conversion. */
7527 {
7528 /* As an extension, allow initializing objects with static storage
7529 duration with compound literals (which are then treated just as
7530 the brace enclosed list they contain). Also allow this for
7531 vectors, as we can only assign them with compound literals. */
7537 }
7541 {
7545 }
7547 /* Compound expressions can only occur here if -Wpedantic or
7548 -pedantic-errors is specified. In the later case, we always want
7549 an error. In the former case, we simply want a warning. */
7552 {
7553 inside_init
7558 else
7563 }
7567 {
7570 }
7575 /* Added to enable additional -Wsuggest-attribute=format warnings. */
7582 }
7584 /* Handle scalar types, including conversions. */
7589 {
7596 inside_init);
7597 inside_init
7603 /* Check to see if we have already given an error message. */
7605 ;
7607 {
7610 }
7614 {
7618 }
7624 }
7626 /* Come here only for records and arrays. */
7629 {
7632 }
7636 }
7637 \f
7638 /* Handle initializers that use braces. */
7640 /* Type of object we are accumulating a constructor for.
7641 This type is always a RECORD_TYPE, UNION_TYPE or ARRAY_TYPE. */
7644 /* For a RECORD_TYPE or UNION_TYPE, this is the chain of fields
7645 left to fill. */
7648 /* For an ARRAY_TYPE, this is the specified index
7649 at which to store the next element we get. */
7652 /* For an ARRAY_TYPE, this is the maximum index. */
7655 /* For a RECORD_TYPE, this is the first field not yet written out. */
7658 /* For an ARRAY_TYPE, this is the index of the first element
7659 not yet written out. */
7662 /* In a RECORD_TYPE, the byte index of the next consecutive field.
7663 This is so we can generate gaps between fields, when appropriate. */
7666 /* If we are saving up the elements rather than allocating them,
7667 this is the list of elements so far (in reverse order,
7668 most recent first). */
7671 /* 1 if constructor should be incrementally stored into a constructor chain,
7672 0 if all the elements should be kept in AVL tree. */
7675 /* 1 if so far this constructor's elements are all compile-time constants. */
7678 /* 1 if so far this constructor's elements are all valid address constants. */
7681 /* 1 if this constructor has an element that cannot be part of a
7682 constant expression. */
7685 /* 1 if this constructor is erroneous so far. */
7688 /* 1 if this constructor is the universal zero initializer { 0 }. */
7691 /* Structure for managing pending initializer elements, organized as an
7692 AVL tree. */
7694 struct init_node
7695 {
7699 tree purpose;
7700 tree value;
7701 tree origtype;
7702 };
7704 /* Tree of pending elements at this constructor level.
7705 These are elements encountered out of order
7706 which belong at places we haven't reached yet in actually
7707 writing the output.
7708 Will never hold tree nodes across GC runs. */
7711 /* The SPELLING_DEPTH of this constructor. */
7714 /* DECL node for which an initializer is being read.
7715 0 means we are reading a constructor expression
7716 such as (struct foo) {...}. */
7719 /* Nonzero if this is an initializer for a top-level decl. */
7722 /* Nonzero if there were any member designators in this initializer. */
7725 /* Nesting depth of designator list. */
7728 /* Nonzero if there were diagnosed errors in this designator list. */
7731 \f
7732 /* This stack has a level for each implicit or explicit level of
7733 structuring in the initializer, including the outermost one. It
7734 saves the values of most of the variables above. */
7738 struct constructor_stack
7739 {
7741 tree type;
7742 tree fields;
7743 tree index;
7744 tree max_index;
7745 tree unfilled_index;
7746 tree unfilled_fields;
7747 tree bit_index;
7752 /* If value nonzero, this value should replace the entire
7753 constructor at this level. */
7765 };
7769 /* This stack represents designators from some range designator up to
7770 the last designator in the list. */
7772 struct constructor_range_stack
7773 {
7776 tree range_start;
7777 tree index;
7778 tree range_end;
7779 tree fields;
7780 };
7784 /* This stack records separate initializers that are nested.
7785 Nested initializers can't happen in ANSI C, but GNU C allows them
7786 in cases like { ... (struct foo) { ... } ... }. */
7788 struct initializer_stack
7789 {
7791 tree decl;
7802 };
7805 \f
7806 /* Prepare to parse and output the initializer for variable DECL. */
7808 void
7811 {
7834 {
7836 require_constant_elements
7838 /* For a scalar, you can always use any value to initialize,
7839 even within braces. */
7842 }
7843 else
7844 {
7848 }
7861 }
7863 void
7865 {
7868 /* Free the whole constructor stack of this initializer. */
7870 {
7874 }
7878 /* Pop back to the data of the outer initializer (if any). */
7893 }
7894 \f
7895 /* Call here when we see the initializer is surrounded by braces.
7896 This is instead of a call to push_init_level;
7897 it is matched by a call to pop_init_level.
7899 TYPE is the type to initialize, for a constructor expression.
7900 For an initializer for a decl, TYPE is zero. */
7902 void
7904 {
7954 {
7956 /* Skip any nameless bit fields at the beginning. */
7963 }
7965 {
7967 {
7968 constructor_max_index
7971 /* Detect non-empty initializations of zero-length arrays. */
7976 /* constructor_max_index needs to be an INTEGER_CST. Attempts
7977 to initialize VLAs will cause a proper error; avoid tree
7978 checking errors as well by setting a safe value. */
7983 constructor_index
7986 }
7987 else
7988 {
7991 }
7994 }
7996 {
7997 /* Vectors are like simple fixed-size arrays. */
7998 constructor_max_index =
8002 }
8003 else
8004 {
8005 /* Handle the case of int x = {5}; */
8008 }
8009 }
8010 \f
8013 /* Called when we see an open brace for a nested initializer. Finish
8014 off any pending levels with implicit braces. */
8015 void
8017 {
8019 {
8024 last_init_list_comma),
8027 && constructor_max_index
8029 constructor_index))
8032 last_init_list_comma),
8034 else
8036 }
8037 }
8039 /* Push down into a subobject, for initialization.
8040 If this is for an explicit set of braces, IMPLICIT is 0.
8041 If it is because the next element belongs at a lower level,
8042 IMPLICIT is 1 (or 2 if the push is because of designator list). */
8044 void
8047 {
8051 /* Unless this is an explicit brace, we need to preserve previous
8052 content if any. */
8054 {
8059 }
8097 {
8102 }
8104 /* Don't die if an entire brace-pair level is superfluous
8105 in the containing level. */
8107 ;
8109 {
8110 /* Don't die if there are extra init elts at the end. */
8113 else
8114 {
8117 constructor_depth++;
8118 }
8119 /* If upper initializer is designated, then mark this as
8120 designated too to prevent bogus warnings. */
8122 }
8124 {
8127 constructor_depth++;
8128 }
8131 {
8136 }
8139 {
8148 }
8151 {
8156 }
8159 {
8161 /* Skip any nameless bit fields at the beginning. */
8168 }
8170 {
8171 /* Vectors are like simple fixed-size arrays. */
8172 constructor_max_index =
8176 }
8178 {
8180 {
8181 constructor_max_index
8184 /* Detect non-empty initializations of zero-length arrays. */
8189 /* constructor_max_index needs to be an INTEGER_CST. Attempts
8190 to initialize VLAs will cause a proper error; avoid tree
8191 checking errors as well by setting a safe value. */
8196 constructor_index
8199 }
8200 else
8205 {
8206 /* We need to split the char/wchar array into individual
8207 characters, so that we don't have to special case it
8208 everywhere. */
8210 }
8211 }
8212 else
8213 {
8218 }
8219 }
8221 /* At the end of an implicit or explicit brace level,
8222 finish up that level of constructor. If a single expression
8223 with redundant braces initialized that level, return the
8224 c_expr structure for that expression. Otherwise, the original_code
8225 element is set to ERROR_MARK.
8226 If we were outputting the elements as they are read, return 0 as the value
8227 from inner levels (process_init_element ignores that),
8228 but return error_mark_node as the value from the outermost level
8229 (that's what we want to put in DECL_INITIAL).
8230 Otherwise, return a CONSTRUCTOR expression as the value. */
8232 struct c_expr
8235 location_t insert_before)
8236 {
8244 {
8245 /* When we come to an explicit close brace,
8246 pop any inner levels that didn't have explicit braces. */
8250 insert_before),
8253 }
8254 else
8259 /* Now output all pending elements. */
8265 /* Error for initializing a flexible array member, or a zero-length
8266 array member in an inappropriate context. */
8271 {
8272 /* Silently discard empty initializations. The parser will
8273 already have pedwarned for empty brackets. */
8276 else
8277 {
8282 else
8286 /* We have already issued an error message for the existence
8287 of a flexible array member not at the end of the structure.
8288 Discard the initializer so that we do not die later. */
8291 }
8292 }
8295 {
8297 /* Initialization with { } counts as zeroinit. */
8301 /* This might be zeroinit as well. */
8306 /* If the constructor has more than one element, it can't be { 0 }. */
8309 }
8311 /* Warn when some structs are initialized with direct aggregation. */
8314 {
8317 OPT_Wmissing_braces,
8319 }
8321 /* Warn when some struct elements are implicitly initialized to zero. */
8323 && constructor_type
8326 {
8327 /* Do not warn for flexible array members or zero-length arrays. */
8334 /* Do not warn if this level of the initializer uses member
8335 designators; it is likely to be deliberate. */
8336 && !constructor_designated
8337 /* Do not warn about initializing with { 0 } or with { }. */
8339 {
8342 constructor_unfilled_fields,
8343 constructor_type))
8346 }
8347 }
8349 /* Pad out the end of the structure. */
8351 /* If this closes a superfluous brace pair,
8352 just pass out the element between them. */
8355 ;
8359 {
8360 /* A nonincremental scalar initializer--just return
8361 the element, after verifying there is just one. */
8363 {
8367 }
8369 {
8372 }
8373 else
8375 }
8376 else
8377 {
8380 else
8381 {
8383 constructor_elements);
8390 }
8391 }
8394 {
8399 }
8428 }
8430 /* Common handling for both array range and field name designators.
8431 ARRAY argument is nonzero for array ranges. Returns false for success. */
8433 static bool
8436 {
8437 tree subtype;
8440 /* Don't die if an entire brace-pair level is superfluous
8441 in the containing level. */
8445 /* If there were errors in this designator list already, bail out
8446 silently. */
8451 {
8454 /* Designator list starts at the level of closest explicit
8455 braces. */
8459 last_init_list_comma),
8463 }
8466 {
8478 }
8482 {
8485 }
8487 {
8490 }
8496 }
8498 /* If there are range designators in designator list, push a new designator
8499 to constructor_range_stack. RANGE_END is end of such stack range or
8500 NULL_TREE if there is no range designator at this level. */
8502 static void
8504 {
8520 }
8522 /* Within an array initializer, specify the next index to be initialized.
8523 FIRST is that index. If LAST is nonzero, then initialize a range
8524 of indices, running from FIRST through LAST. */
8526 void
8529 {
8537 {
8540 }
8543 {
8547 "array index in initializer is not "
8549 }
8552 {
8556 "array index in initializer is not "
8558 }
8571 else
8572 {
8578 {
8581 }
8584 {
8588 {
8591 }
8592 else
8593 {
8597 {
8601 }
8602 }
8603 }
8605 designator_depth++;
8609 }
8610 }
8612 /* Within a struct initializer, specify the next field to be initialized. */
8614 void
8617 {
8618 tree field;
8626 {
8629 }
8634 {
8637 {
8643 }
8644 else
8647 }
8648 else
8649 do
8650 {
8652 designator_depth++;
8658 {
8661 }
8662 }
8664 }
8665 \f
8666 /* Add a new initializer to the tree of pending initializers. PURPOSE
8667 identifies the initializer, either array index or field in a structure.
8668 VALUE is the value of that index or field. If ORIGTYPE is not
8669 NULL_TREE, it is the original type of VALUE.
8671 IMPLICIT is true if value comes from pop_init_level (1),
8672 the new initializer has been merged with the existing one
8673 and thus no warnings should be emitted about overriding an
8674 existing initializer. */
8676 static void
8679 {
8686 {
8688 {
8694 else
8695 {
8697 {
8700 "initialized field with side-effects "
8705 }
8709 }
8710 }
8711 }
8712 else
8713 {
8714 tree bitpos;
8718 {
8724 else
8725 {
8727 {
8730 "initialized field with side-effects "
8735 }
8739 }
8740 }
8741 }
8756 {
8760 {
8764 {
8766 {
8767 /* L rotation. */
8780 {
8783 else
8785 }
8786 else
8788 }
8789 else
8790 {
8791 /* LR rotation. */
8813 {
8816 else
8818 }
8819 else
8821 }
8823 }
8824 else
8825 {
8826 /* p->balance == +1; growth of left side balances the node. */
8829 }
8830 }
8832 {
8834 /* Growth propagation from right side. */
8837 {
8839 {
8840 /* R rotation. */
8853 {
8856 else
8858 }
8859 else
8861 }
8863 {
8864 /* RL rotation */
8886 {
8889 else
8891 }
8892 else
8894 }
8896 }
8897 else
8898 {
8899 /* p->balance == -1; growth of right side balances the node. */
8902 }
8903 }
8907 }
8908 }
8910 /* Build AVL tree from a sorted chain. */
8912 static void
8914 {
8924 braced_init_obstack);
8927 {
8929 /* Skip any nameless bit fields at the beginning. */
8934 }
8936 {
8938 constructor_unfilled_index
8941 else
8943 }
8945 }
8947 /* Build AVL tree from a string constant. */
8949 static void
8952 {
8969 p < end
8970 && !(constructor_max_index
8973 {
8975 {
8978 }
8979 else
8980 {
8984 {
8987 else
8992 }
8993 }
8996 {
8999 {
9001 {
9004 }
9005 }
9007 {
9010 }
9014 }
9020 braced_init_obstack);
9021 }
9024 }
9026 /* Return value of FIELD in pending initializer or NULL_TREE if the field was
9027 not initialized yet. */
9029 static tree
9031 {
9035 {
9042 {
9047 else
9049 }
9050 }
9052 {
9056 && (!constructor_unfilled_fields
9063 {
9068 else
9070 }
9071 }
9073 {
9077 }
9079 }
9081 /* "Output" the next constructor element.
9082 At top level, really output it to assembler code now.
9083 Otherwise, collect it in a list from which we will make a CONSTRUCTOR.
9084 If ORIGTYPE is not NULL_TREE, it is the original type of VALUE.
9085 TYPE is the data type that the containing data type wants here.
9086 FIELD is the field (a FIELD_DECL) or the index that this element fills.
9087 If VALUE is a string constant, STRICT_STRING is true if it is
9088 unparenthesized or we should not warn here for it being parenthesized.
9089 For other types of VALUE, STRICT_STRING is not used.
9091 PENDING if true means output pending elements that belong
9092 right after this element. (PENDING is normally true;
9093 it is false while outputting pending elements, to avoid recursion.)
9095 IMPLICIT is true if value comes from pop_init_level (1),
9096 the new initializer has been merged with the existing one
9097 and thus no warnings should be emitted about overriding an
9098 existing initializer. */
9100 static void
9104 {
9110 {
9113 }
9126 {
9127 /* As an extension, allow initializing objects with static storage
9128 duration with compound literals (which are then treated just as
9129 the brace enclosed list they contain). */
9135 }
9139 {
9142 }
9152 && TYPE_REVERSE_STORAGE_ORDER
9161 /* Digest the initializer and issue any errors about incompatible
9162 types before issuing errors about non-constant initializers. */
9167 require_constant_value);
9169 {
9172 }
9176 /* Proceed to check the constness of the original initializer. */
9178 {
9180 {
9183 }
9187 }
9193 /* Issue -Wc++-compat warnings about initializing a bitfield with
9194 enum type. */
9202 {
9209 }
9211 /* If this field is empty (and not at the end of structure),
9212 don't do anything other than checking the initializer. */
9221 /* Finally, set VALUE to the initializer value digested above. */
9224 /* If this element doesn't come next in sequence,
9225 put it on constructor_pending_elts. */
9227 && (!constructor_incremental
9229 {
9235 braced_init_obstack);
9237 }
9239 && (!constructor_incremental
9241 {
9242 /* We do this for records but not for unions. In a union,
9243 no matter which field is specified, it can be initialized
9244 right away since it starts at the beginning of the union. */
9246 {
9249 else
9250 {
9258 }
9259 }
9262 braced_init_obstack);
9264 }
9267 {
9269 {
9276 }
9278 /* We can have just one union field set. */
9280 }
9282 /* Otherwise, output this element either to
9283 constructor_elements or to the assembler file. */
9288 /* Advance the variable that indicates sequential elements output. */
9290 constructor_unfilled_index
9292 bitsize_one_node);
9294 {
9295 constructor_unfilled_fields
9298 /* Skip any nameless bit fields. */
9301 constructor_unfilled_fields =
9303 }
9307 /* Now output any pending elements which have become next. */
9310 }
9312 /* Output any pending elements which have become next.
9313 As we output elements, constructor_unfilled_{fields,index}
9314 advances, which may cause other elements to become next;
9315 if so, they too are output.
9317 If ALL is 0, we return when there are
9318 no more pending elements to output now.
9320 If ALL is 1, we output space as necessary so that
9321 we can output all the pending elements. */
9322 static void
9324 {
9326 tree next;
9328 retry:
9330 /* Look through the whole pending tree.
9331 If we find an element that should be output now,
9332 output it. Otherwise, set NEXT to the element
9333 that comes first among those still pending. */
9337 {
9339 {
9341 constructor_unfilled_index))
9345 braced_init_obstack);
9348 {
9349 /* Advance to the next smaller node. */
9352 else
9353 {
9354 /* We have reached the smallest node bigger than the
9355 current unfilled index. Fill the space first. */
9358 }
9359 }
9360 else
9361 {
9362 /* Advance to the next bigger node. */
9365 else
9366 {
9367 /* We have reached the biggest node in a subtree. Find
9368 the parent of it, which is the next bigger node. */
9374 {
9377 }
9378 }
9379 }
9380 }
9382 {
9385 /* If the current record is complete we are done. */
9391 /* We can't compare fields here because there might be empty
9392 fields in between. */
9394 {
9399 braced_init_obstack);
9400 }
9402 {
9403 /* Advance to the next smaller node. */
9406 else
9407 {
9408 /* We have reached the smallest node bigger than the
9409 current unfilled field. Fill the space first. */
9412 }
9413 }
9414 else
9415 {
9416 /* Advance to the next bigger node. */
9419 else
9420 {
9421 /* We have reached the biggest node in a subtree. Find
9422 the parent of it, which is the next bigger node. */
9429 {
9432 }
9433 }
9434 }
9435 }
9436 }
9438 /* Ordinarily return, but not if we want to output all
9439 and there are elements left. */
9443 /* If it's not incremental, just skip over the gap, so that after
9444 jumping to retry we will output the next successive element. */
9450 /* ELT now points to the node in the pending tree with the next
9451 initializer to output. */
9453 }
9454 \f
9455 /* Add one non-braced element to the current constructor level.
9456 This adjusts the current position within the constructor's type.
9457 This may also start or terminate implicit levels
9458 to handle a partly-braced initializer.
9460 Once this has found the correct level for the new element,
9461 it calls output_init_element.
9463 IMPLICIT is true if value comes from pop_init_level (1),
9464 the new initializer has been merged with the existing one
9465 and thus no warnings should be emitted about overriding an
9466 existing initializer. */
9468 void
9471 {
9473 int string_flag
9484 /* Handle superfluous braces around string cst as in
9485 char x[] = {"foo"}; */
9487 && constructor_type
9488 && !was_designated
9492 {
9497 }
9500 {
9503 }
9505 /* Ignore elements of a brace group if it is entirely superfluous
9506 and has already been diagnosed. */
9515 OPT_Wdesignated_init,
9516 "positional initialization of field "
9519 /* If we've exhausted any levels that didn't have braces,
9520 pop them now. */
9522 {
9527 last_init_list_comma),
9531 && constructor_max_index
9533 constructor_index))
9536 last_init_list_comma),
9538 else
9540 }
9542 /* In the case of [LO ... HI] = VALUE, only evaluate VALUE once. */
9544 {
9545 /* If value is a compound literal and we'll be just using its
9546 content, don't put it into a SAVE_EXPR. */
9549 {
9552 {
9555 }
9560 }
9561 }
9564 {
9566 {
9567 tree fieldtype;
9571 {
9574 }
9581 /* Error for non-static initialization of a flexible array member. */
9583 && !require_constant_value
9586 {
9590 }
9592 /* Error for initialization of a flexible array member with
9593 a string constant if the structure is in an array. E.g.:
9594 struct S { int x; char y[]; };
9595 struct S s[] = { { 1, "foo" } };
9596 is invalid. */
9602 {
9607 {
9610 }
9612 {
9616 }
9617 }
9619 /* Accept a string constant to initialize a subarray. */
9625 /* Otherwise, if we have come to a subaggregate,
9626 and we don't have an element of its type, push into it. */
9632 {
9635 }
9638 {
9643 braced_init_obstack);
9645 }
9646 else
9647 /* Do the bookkeeping for an element that was
9648 directly output as a constructor. */
9649 {
9650 /* For a record, keep track of end position of last field. */
9652 constructor_bit_index
9657 /* If the current field was the first one not yet written out,
9658 it isn't now, so update. */
9660 {
9662 /* Skip any nameless bit fields. */
9664 && (DECL_UNNAMED_BIT_FIELD
9666 constructor_unfilled_fields =
9668 }
9669 }
9672 /* Skip any nameless bit fields at the beginning. */
9676 }
9678 {
9679 tree fieldtype;
9683 {
9687 }
9694 /* Warn that traditional C rejects initialization of unions.
9695 We skip the warning if the value is zero. This is done
9696 under the assumption that the zero initializer in user
9697 code appears conditioned on e.g. __STDC__ to avoid
9698 "missing initializer" warnings and relies on default
9699 initialization to zero in the traditional C case.
9700 We also skip the warning if the initializer is designated,
9701 again on the assumption that this must be conditional on
9702 __STDC__ anyway (and we've already complained about the
9703 member-designator already). */
9710 /* Accept a string constant to initialize a subarray. */
9716 /* Otherwise, if we have come to a subaggregate,
9717 and we don't have an element of its type, push into it. */
9723 {
9726 }
9729 {
9734 braced_init_obstack);
9736 }
9737 else
9738 /* Do the bookkeeping for an element that was
9739 directly output as a constructor. */
9740 {
9743 }
9746 }
9748 {
9752 /* Accept a string constant to initialize a subarray. */
9758 /* Otherwise, if we have come to a subaggregate,
9759 and we don't have an element of its type, push into it. */
9765 {
9768 }
9773 {
9777 }
9779 /* Now output the actual element. */
9781 {
9786 braced_init_obstack);
9788 }
9790 constructor_index
9795 /* If we are doing the bookkeeping for an element that was
9796 directly output as a constructor, we must update
9797 constructor_unfilled_index. */
9799 }
9801 {
9804 /* Do a basic check of initializer size. Note that vectors
9805 always have a fixed size derived from their type. */
9807 {
9811 }
9813 /* Now output the actual element. */
9815 {
9821 braced_init_obstack);
9822 }
9824 constructor_index
9829 /* If we are doing the bookkeeping for an element that was
9830 directly output as a constructor, we must update
9831 constructor_unfilled_index. */
9833 }
9835 /* Handle the sole element allowed in a braced initializer
9836 for a scalar variable. */
9839 {
9843 }
9844 else
9845 {
9850 braced_init_obstack);
9852 }
9854 /* Handle range initializers either at this level or anywhere higher
9855 in the designator stack. */
9857 {
9864 {
9868 braced_init_obstack,
9869 last_init_list_comma),
9871 }
9875 {
9879 braced_init_obstack,
9880 last_init_list_comma),
9882 }
9890 {
9894 {
9897 }
9906 }
9911 }
9914 }
9917 }
9918 \f
9919 /* Build a complete asm-statement, whose components are a CV_QUALIFIER
9920 (guaranteed to be 'volatile' or null) and ARGS (represented using
9921 an ASM_EXPR node). */
9922 tree
9924 {
9928 }
9930 /* Build an asm-expr, whose components are a STRING, some OUTPUTS,
9931 some INPUTS, and some CLOBBERS. The latter three may be NULL.
9932 SIMPLE indicates whether there was anything at all after the
9933 string in the asm expression -- asm("blah") and asm("blah" : )
9934 are subtly different. We use a ASM_EXPR node to represent this. */
9935 tree
9938 {
9939 tree tail;
9940 tree args;
9953 /* Remove output conversions that change the type but not the mode. */
9955 {
9960 /* ??? Really, this should not be here. Users should be using a
9961 proper lvalue, dammit. But there's a long history of using casts
9962 in the output operands. In cases like longlong.h, this becomes a
9963 primitive form of typechecking -- if the cast can be removed, then
9964 the output operand had a type of the proper width; otherwise we'll
9965 get an error. Gross, but ... */
9983 {
9984 /* If the operand is going to end up in memory,
9985 mark it addressable. */
9991 {
9994 }
9995 }
9996 else
10000 }
10003 {
10004 tree input;
10011 {
10012 /* If the operand is going to end up in memory,
10013 mark it addressable. */
10015 {
10018 /* Strip the nops as we allow this case. FIXME, this really
10019 should be rejected or made deprecated. */
10023 }
10024 else
10025 {
10033 {
10036 }
10037 }
10038 }
10039 else
10043 }
10045 /* ASMs with labels cannot have outputs. This should have been
10046 enforced by the parser. */
10051 /* asm statements without outputs, including simple ones, are treated
10052 as volatile. */
10057 }
10058 \f
10059 /* Generate a goto statement to LABEL. LOC is the location of the
10060 GOTO. */
10062 tree
10064 {
10069 {
10074 }
10075 }
10077 /* Generate a computed goto statement to EXPR. LOC is the location of
10078 the GOTO. */
10080 tree
10082 {
10083 tree t;
10090 }
10092 /* Generate a C `return' statement. RETVAL is the expression for what
10093 to return, or a null pointer for `return;' with no value. LOC is
10094 the location of the return statement, or the location of the expression,
10095 if the statement has any. If ORIGTYPE is not NULL_TREE, it
10096 is the original type of RETVAL. */
10098 tree
10100 {
10105 /* Use the expansion point to handle cases such as returning NULL
10106 in a function returning void. */
10114 {
10118 {
10121 }
10125 }
10128 {
10132 {
10135 warned_here = pedwarn
10138 else
10139 warned_here = warning_at
10146 }
10147 }
10149 {
10153 warned_here = pedwarn
10156 else
10157 warned_here = pedwarn
10163 }
10164 else
10165 {
10170 tree inner;
10188 /* Strip any conversions, additions, and subtractions, and see if
10189 we are returning the address of a local variable. Warn if so. */
10191 {
10193 {
10194 CASE_CONVERT:
10202 /* If the second operand of the MINUS_EXPR has a pointer
10203 type (or is converted from it), this may be valid, so
10204 don't give a warning. */
10205 {
10218 }
10231 {
10235 else
10236 {
10241 }
10242 }
10247 }
10250 }
10257 }
10262 }
10263 \f
10265 /* The SWITCH_EXPR being built. */
10266 tree switch_expr;
10268 /* The original type of the testing expression, i.e. before the
10269 default conversion is applied. */
10270 tree orig_type;
10272 /* A splay-tree mapping the low element of a case range to the high
10273 element, or NULL_TREE if there is no high element. Used to
10274 determine whether or not a new case label duplicates an old case
10275 label. We need a tree, rather than simply a hash table, because
10276 of the GNU case range extension. */
10277 splay_tree cases;
10279 /* The bindings at the point of the switch. This is used for
10280 warnings crossing decls when branching to a case label. */
10283 /* The next node on the stack. */
10286 /* Remember whether the controlling expression had boolean type
10287 before integer promotions for the sake of -Wswitch-bool. */
10290 /* Remember whether there was a case value that is outside the
10291 range of the ORIG_TYPE. */
10293 };
10295 /* A stack of the currently active switch statements. The innermost
10296 switch statement is on the top of the stack. There is no need to
10297 mark the stack for garbage collection because it is only active
10298 during the processing of the body of a function, and we never
10299 collect at that point. */
10303 /* Start a C switch statement, testing expression EXP. Return the new
10304 SWITCH_EXPR. SWITCH_LOC is the location of the `switch'.
10305 SWITCH_COND_LOC is the location of the switch's condition.
10306 EXPLICIT_CAST_P is true if the expression EXP has an explicit cast. */
10308 tree
10310 location_t switch_cond_loc,
10312 {
10318 {
10322 {
10324 {
10327 }
10329 }
10330 else
10331 {
10335 /* Warn if the condition has boolean value. */
10341 /* Explicit cast to int suppresses this warning. */
10358 }
10359 }
10361 /* Add this new SWITCH_EXPR to the stack. */
10374 }
10376 /* Process a case label at location LOC. */
10378 tree
10380 {
10384 {
10389 }
10392 {
10397 }
10400 {
10403 else
10406 }
10410 loc))
10421 }
10423 /* Finish the switch statement. TYPE is the original type of the
10424 controlling expression of the switch, or NULL_TREE. */
10426 void
10428 {
10430 location_t switch_location;
10434 /* Emit warnings as needed. */
10443 /* Pop the stack. */
10448 }
10449 \f
10450 /* Emit an if statement. IF_LOCUS is the location of the 'if'. COND,
10451 THEN_BLOCK and ELSE_BLOCK are expressions to be used; ELSE_BLOCK
10452 may be null. */
10454 void
10456 tree else_block)
10457 {
10458 tree stmt;
10463 }
10465 /* Emit a general-purpose loop construct. START_LOCUS is the location of
10466 the beginning of the loop. COND is the loop condition. COND_IS_FIRST
10467 is false for DO loops. INCR is the FOR increment expression. BODY is
10468 the statement controlled by the loop. BLAB is the break label. CLAB is
10469 the continue label. Everything is allowed to be NULL. */
10471 void
10474 {
10477 /* If the condition is zero don't generate a loop construct. */
10479 {
10481 {
10485 }
10486 }
10487 else
10488 {
10491 /* If we have an exit condition, then we build an IF with gotos either
10492 out of the loop, or to the top of it. If there's no exit condition,
10493 then we just build a jump back to the top. */
10497 {
10498 /* Canonicalize the loop condition to the end. This means
10499 generating a branch to the loop condition. Reuse the
10500 continue label, if possible. */
10502 {
10504 {
10507 }
10508 else
10512 }
10518 else
10521 }
10522 else
10523 {
10524 /* For the backward-goto's location of an unconditional loop
10525 use the beginning of the body, or, if there is none, the
10526 top of the loop. */
10531 }
10534 }
10548 }
10550 tree
10552 {
10556 /* In switch statements break is sometimes stylistically used after
10557 a return statement. This can lead to spurious warnings about
10558 control reaching the end of a non-void function when it is
10559 inlined. Note that we are calling block_may_fallthru with
10560 language specific tree nodes; this works because
10561 block_may_fallthru returns true when given something it does not
10562 understand. */
10566 {
10569 }
10571 ;
10573 {
10577 else
10589 else
10595 }
10604 }
10606 /* A helper routine for c_process_expr_stmt and c_finish_stmt_expr. */
10608 static void
10610 {
10612 ;
10614 {
10617 }
10619 {
10623 {
10627 }
10635 }
10636 else
10638 }
10640 /* Process an expression as if it were a complete statement. Emit
10641 diagnostics, but do not call ADD_STMT. LOC is the location of the
10642 statement. */
10644 tree
10646 {
10647 tree exprv;
10662 /* If we're not processing a statement expression, warn about unused values.
10663 Warnings for statement expressions will be emitted later, once we figure
10664 out which is the result. */
10679 /* If the expression is not of a type to which we cannot assign a line
10680 number, wrap the thing in a no-op NOP_EXPR. */
10682 {
10685 }
10688 }
10690 /* Emit an expression as a statement. LOC is the location of the
10691 expression. */
10693 tree
10695 {
10698 else
10700 }
10702 /* Do the opposite and emit a statement as an expression. To begin,
10703 create a new binding level and return it. */
10705 tree
10707 {
10708 tree ret;
10710 /* We must force a BLOCK for this level so that, if it is not expanded
10711 later, there is a way to turn off the entire subtree of blocks that
10712 are contained in it. */
10717 ? NULL
10720 /* Mark the current statement list as belonging to a statement list. */
10724 }
10726 /* LOC is the location of the compound statement to which this body
10727 belongs. */
10729 tree
10731 {
10738 ? NULL
10741 /* Locate the last statement in BODY. See c_end_compound_stmt
10742 about always returning a BIND_EXPR. */
10746 continue_searching:
10748 {
10754 /* This can happen with degenerate cases like ({ }). No value. */
10758 /* If we're supposed to generate side effects warnings, process
10759 all of the statements except the last. */
10761 {
10764 {
10765 location_t tloc;
10770 }
10771 }
10774 }
10776 /* If the end of the list is exception related, then the list was split
10777 by a call to push_cleanup. Continue searching. */
10780 {
10784 }
10789 /* In the case that the BIND_EXPR is not necessary, return the
10790 expression out from inside it. */
10792 /* Skip nested debug stmts. */
10795 {
10796 /* Even if this looks constant, do not allow it in a constant
10797 expression. */
10799 /* Do not warn if the return value of a statement expression is
10800 unused. */
10803 }
10805 /* Extract the type of said expression. */
10808 /* If we're not returning a value at all, then the BIND_EXPR that
10809 we already have is a fine expression to return. */
10813 /* Now that we've located the expression containing the value, it seems
10814 silly to make voidify_wrapper_expr repeat the process. Create a
10815 temporary of the appropriate type and stick it in a TARGET_EXPR. */
10818 /* Unwrap a no-op NOP_EXPR as added by c_finish_expr_stmt. This avoids
10819 tree_expr_nonnegative_p giving up immediately. */
10828 {
10832 }
10833 }
10834 \f
10835 /* Begin and end compound statements. This is as simple as pushing
10836 and popping new statement lists from the tree. */
10838 tree
10840 {
10845 }
10847 /* End a compound statement. STMT is the statement. LOC is the
10848 location of the compound statement-- this is usually the location
10849 of the opening brace. */
10851 tree
10853 {
10857 {
10861 }
10866 /* If this compound statement is nested immediately inside a statement
10867 expression, then force a BIND_EXPR to be created. Otherwise we'll
10868 do the wrong thing for ({ { 1; } }) or ({ 1; { } }). In particular,
10869 STATEMENT_LISTs merge, and thus we can lose track of what statement
10870 was really last. */
10874 {
10878 }
10881 }
10883 /* Queue a cleanup. CLEANUP is an expression/statement to be executed
10884 when the current scope is exited. EH_ONLY is true when this is not
10885 meant to apply to normal control flow transfer. */
10887 void
10889 {
10901 }
10902 \f
10903 /* Build a vector comparison of ARG0 and ARG1 using CODE opcode
10904 into a value of TYPE type. Comparison is done via VEC_COND_EXPR. */
10906 static tree
10909 {
10915 }
10917 /* Build a binary-operation expression without default conversions.
10918 CODE is the kind of expression to build.
10919 LOCATION is the operator's location.
10920 This function differs from `build' in several ways:
10921 the data type of the result is computed and recorded in it,
10922 warnings are generated if arg data types are invalid,
10923 special handling for addition and subtraction of pointers is known,
10924 and some optimization is done (operations on narrow ints
10925 are done in the narrower type when that gives the same result).
10926 Constant folding is also done before the result is returned.
10928 Note that the operands will never have enumeral types, or function
10929 or array types, because either they will have the default conversions
10930 performed or they have both just been converted to some other type in which
10931 the arithmetic is to be done. */
10933 tree
10936 {
10938 tree eptype;
10946 /* Expression code to give to the expression when it is built.
10947 Normally this is CODE, which is what the caller asked for,
10948 but in some special cases we change it. */
10951 /* Data type in which the computation is to be performed.
10952 In the simplest cases this is the common type of the arguments. */
10955 /* When the computation is in excess precision, the type of the
10956 final EXCESS_PRECISION_EXPR. */
10959 /* Nonzero means operands have already been type-converted
10960 in whatever way is necessary.
10961 Zero means they need to be converted to RESULT_TYPE. */
10964 /* Nonzero means create the expression with this type, rather than
10965 RESULT_TYPE. */
10968 /* Nonzero means after finally constructing the expression
10969 convert it to this type. */
10972 /* Nonzero if this is an operation like MIN or MAX which can
10973 safely be computed in short if both args are promoted shorts.
10974 Also implies COMMON.
10975 -1 indicates a bitwise operation; this makes a difference
10976 in the exact conditions for when it is safe to do the operation
10977 in a narrower mode. */
10980 /* Nonzero if this is a comparison operation;
10981 if both args are promoted shorts, compare the original shorts.
10982 Also implies COMMON. */
10985 /* Nonzero if this is a right-shift operation, which can be computed on the
10986 original short and then promoted if the operand is a promoted short. */
10989 /* Nonzero means set RESULT_TYPE to the common type of the args. */
10992 /* True means types are compatible as far as ObjC is concerned. */
10995 /* True means this is an arithmetic operation that may need excess
10996 precision. */
10999 /* True means this is a boolean operation that converts both its
11000 operands to truth-values. */
11003 /* Remember whether we're doing / or %. */
11006 /* Remember whether we're doing << or >>. */
11009 /* Tree holding instrumentation expression. */
11026 {
11029 int_const = (int_const_or_overflow
11032 }
11033 else
11036 /* Do not apply default conversion in mixed vector/scalar expression. */
11039 {
11042 }
11048 /* The expression codes of the data types of the arguments tell us
11049 whether the arguments are integers, floating, pointers, etc. */
11053 /* Strip NON_LVALUE_EXPRs, etc., since we aren't using as an lvalue. */
11057 /* If an error was already reported for one of the arguments,
11058 avoid reporting another error. */
11073 {
11076 }
11079 {
11093 }
11095 {
11098 }
11101 {
11104 }
11106 {
11109 }
11112 {
11115 }
11119 /* In case when one of the operands of the binary operation is
11120 a vector and another is a scalar -- convert scalar to vector. */
11122 {
11127 {
11131 {
11133 tree sc;
11144 }
11146 {
11148 tree sc;
11159 }
11162 }
11163 }
11166 {
11168 /* Handle the pointer + int case. */
11170 {
11173 }
11175 {
11178 }
11179 else
11184 /* Subtraction of two similar pointers.
11185 We must subtract them as integers, then divide by object size. */
11188 {
11191 }
11192 /* Handle pointer minus int. Just like pointer plus int. */
11194 {
11197 }
11198 else
11220 {
11231 else
11232 /* Although it would be tempting to shorten always here, that
11233 loses on some targets, since the modulo instruction is
11234 undefined if the quotient can't be represented in the
11235 computation mode. We shorten only if unsigned or if
11236 dividing by something we know != -1. */
11241 }
11249 /* Allow vector types which are not floating point types. */
11267 {
11268 /* Although it would be tempting to shorten always here, that loses
11269 on some targets, since the modulo instruction is undefined if the
11270 quotient can't be represented in the computation mode. We shorten
11271 only if unsigned or if dividing by something we know != -1. */
11276 }
11290 {
11291 /* Result of these operations is always an int,
11292 but that does not mean the operands should be
11293 converted to ints! */
11296 {
11299 }
11300 else
11303 {
11306 }
11307 else
11311 }
11313 {
11314 int_const_or_overflow = (int_operands
11318 int_const = (int_const_or_overflow
11322 }
11324 {
11325 int_const_or_overflow = (int_operands
11329 int_const = (int_const_or_overflow
11333 }
11336 /* Shift operations: result has same type as first operand;
11337 always convert second operand to int.
11338 Also set SHORT_SHIFT if shifting rightward. */
11346 {
11349 }
11353 {
11356 {
11358 {
11363 }
11365 {
11369 {
11374 }
11375 }
11376 else
11377 {
11382 {
11387 }
11388 }
11389 }
11391 /* Use the type of the value to be shifted. */
11393 /* Avoid converting op1 to result_type later. */
11395 }
11404 {
11407 }
11411 {
11415 {
11416 /* Don't reject a left shift of a negative value in a context
11417 where a constant expression is needed in C90. */
11423 }
11425 {
11427 {
11432 }
11434 {
11438 {
11443 }
11444 }
11446 {
11451 }
11456 }
11458 /* Use the type of the value to be shifted. */
11460 /* Avoid converting op1 to result_type later. */
11462 }
11468 {
11469 tree intt;
11471 {
11475 }
11479 {
11483 }
11485 /* It's not precisely specified how the usual arithmetic
11486 conversions apply to the vector types. Here, we use
11487 the unsigned type if one of the operands is signed and
11488 the other one is unsigned. */
11490 {
11493 else
11497 }
11499 /* Always construct signed integer vector type. */
11501 (SCALAR_TYPE_MODE
11508 }
11511 OPT_Wfloat_equal,
11513 /* Result of comparison is always int,
11514 but don't convert the args to int! */
11522 {
11526 {
11529 OPT_Waddress,
11530 "the comparison will always evaluate as %<false%> "
11533 else
11535 OPT_Waddress,
11536 "the comparison will always evaluate as %<true%> "
11539 }
11541 }
11543 {
11547 {
11550 OPT_Waddress,
11551 "the comparison will always evaluate as %<false%> "
11554 else
11556 OPT_Waddress,
11557 "the comparison will always evaluate as %<true%> "
11560 }
11562 }
11564 {
11571 /* Anything compares with void *. void * compares with anything.
11572 Otherwise, the targets must be compatible
11573 and both must be object or both incomplete. */
11577 {
11581 }
11583 {
11587 }
11589 {
11593 }
11594 else
11595 /* Avoid warning about the volatile ObjC EH puts on decls. */
11601 {
11603 result_type = build_pointer_type
11605 }
11606 }
11608 {
11611 }
11613 {
11616 }
11629 {
11630 tree intt;
11632 {
11636 }
11640 {
11644 }
11646 /* It's not precisely specified how the usual arithmetic
11647 conversions apply to the vector types. Here, we use
11648 the unsigned type if one of the operands is signed and
11649 the other one is unsigned. */
11651 {
11654 else
11658 }
11660 /* Always construct signed integer vector type. */
11662 (SCALAR_TYPE_MODE
11669 }
11677 {
11680 addr_space_t as_common;
11683 {
11697 }
11699 {
11703 }
11704 else
11705 {
11707 result_type = build_pointer_type
11711 }
11712 }
11714 {
11722 }
11724 {
11732 }
11734 {
11737 }
11739 {
11742 }
11746 {
11752 }
11763 }
11771 {
11777 }
11781 &&
11784 {
11790 {
11793 "implicit conversion from %qT to %qT "
11794 "to match other operand of binary "
11796 location);
11799 }
11808 {
11809 /* An operation on mixed real/complex operands must be
11810 handled specially, but the language-independent code can
11811 more easily optimize the plain complex arithmetic if
11812 -fno-signed-zeros. */
11816 {
11819 }
11821 {
11826 }
11827 else
11828 {
11833 }
11837 {
11844 {
11849 /* Fall through. */
11856 }
11857 }
11858 else
11859 {
11866 {
11870 /* Fall through. */
11880 }
11881 }
11884 }
11886 /* For certain operations (which identify themselves by shorten != 0)
11887 if both args were extended from the same smaller type,
11888 do the arithmetic in that type and then extend.
11890 shorten !=0 and !=1 indicates a bitwise operation.
11891 For them, this optimization is safe only if
11892 both args are zero-extended or both are sign-extended.
11893 Otherwise, we might change the result.
11894 Eg, (short)-1 | (unsigned short)-1 is (int)-1
11895 but calculated in (unsigned short) it would be (unsigned short)-1. */
11898 {
11902 }
11904 /* Shifts can be shortened if shifting right. */
11907 {
11918 /* We can shorten only if the shift count is less than the
11919 number of bits in the smaller type size. */
11921 /* We cannot drop an unsigned shift after sign-extension. */
11923 {
11924 /* Do an unsigned shift if the operand was zero-extended. */
11925 result_type
11928 /* Convert value-to-be-shifted to that type. */
11932 }
11933 }
11935 /* Comparison operations are shortened too but differently.
11936 They identify themselves by setting short_compare = 1. */
11939 {
11940 /* Don't write &op0, etc., because that would prevent op0
11941 from being kept in a register.
11942 Instead, make copies of the our local variables and
11943 pass the copies by reference, then copy them back afterward. */
11946 tree val
11951 {
11954 }
11961 {
11967 {
11970 }
11971 else
11972 {
11973 /* Fold for the sake of possible warnings, as in
11974 build_conditional_expr. This requires the
11975 "original" values to be folded, not just op0 and
11976 op1. */
11977 c_inhibit_evaluation_warnings++;
11982 c_inhibit_evaluation_warnings--;
11984 require_constant_value,
11985 NULL);
11987 require_constant_value,
11988 NULL);
11989 }
11996 {
12001 }
12002 }
12003 }
12004 }
12006 /* At this point, RESULT_TYPE must be nonzero to avoid an error message.
12007 If CONVERTED is zero, both args will be converted to type RESULT_TYPE.
12008 Then the expression will be built.
12009 It will be given type FINAL_TYPE if that is nonzero;
12010 otherwise, it will be given type RESULT_TYPE. */
12013 {
12019 }
12022 {
12026 {
12029 }
12030 }
12033 {
12035 semantic_result_type);
12037 semantic_result_type);
12039 /* This can happen if one operand has a vector type, and the other
12040 has a different type. */
12043 }
12050 {
12051 /* OP0 and/or OP1 might have side-effects. */
12061 }
12063 /* Treat expressions in initializers specially as they can't trap. */
12065 ret = (require_constant_value
12069 else
12074 return_build_binary_op:
12077 ret = (int_operands
12094 }
12097 /* Convert EXPR to be a truth-value, validating its type for this
12098 purpose. LOCATION is the source location for the expression. */
12100 tree
12102 {
12106 {
12108 error_at (location, "used array that cannot be converted to pointer where scalar is required");
12137 }
12142 {
12147 }
12148 else
12149 /* ??? Should we also give an error for vectors rather than leaving
12150 those to give errors later? */
12154 {
12157 else
12159 }
12163 }
12164 \f
12166 /* Convert EXPR to a contained DECL, updating *TC, *TI and *SE as
12167 required. */
12169 tree
12171 {
12173 {
12175 /* Executing a compound literal inside a function reinitializes
12176 it. */
12180 }
12181 else
12183 }
12184 \f
12185 /* Generate OMP construct CODE, with BODY and CLAUSES as its compound
12186 statement. LOC is the location of the construct. */
12188 tree
12190 tree clauses)
12191 {
12201 }
12203 /* Generate OACC_DATA, with CLAUSES and BLOCK as its compound
12204 statement. LOC is the location of the OACC_DATA. */
12206 tree
12208 {
12209 tree stmt;
12220 }
12222 /* Generate OACC_HOST_DATA, with CLAUSES and BLOCK as its compound
12223 statement. LOC is the location of the OACC_HOST_DATA. */
12225 tree
12227 {
12228 tree stmt;
12239 }
12241 /* Like c_begin_compound_stmt, except force the retention of the BLOCK. */
12243 tree
12245 {
12246 tree block;
12252 }
12254 /* Generate OMP_PARALLEL, with CLAUSES and BLOCK as its compound
12255 statement. LOC is the location of the OMP_PARALLEL. */
12257 tree
12259 {
12260 tree stmt;
12271 }
12273 /* Like c_begin_compound_stmt, except force the retention of the BLOCK. */
12275 tree
12277 {
12278 tree block;
12284 }
12286 /* Generate OMP_TASK, with CLAUSES and BLOCK as its compound
12287 statement. LOC is the location of the #pragma. */
12289 tree
12291 {
12292 tree stmt;
12303 }
12305 /* Generate GOMP_cancel call for #pragma omp cancel. */
12307 void
12309 {
12320 else
12321 {
12323 "%<parallel%>, %<for%>, %<sections%> or %<taskgroup%> "
12326 }
12329 {
12334 }
12335 else
12339 ifc);
12341 }
12343 /* Generate GOMP_cancellation_point call for
12344 #pragma omp cancellation point. */
12346 void
12348 {
12359 else
12360 {
12362 "%<parallel%>, %<for%>, %<sections%> or %<taskgroup%> "
12365 }
12369 }
12371 /* Helper function for handle_omp_array_sections. Called recursively
12372 to handle multiple array-section-subscripts. C is the clause,
12373 T current expression (initially OMP_CLAUSE_DECL), which is either
12374 a TREE_LIST for array-section-subscript (TREE_PURPOSE is low-bound
12375 expression if specified, TREE_VALUE length expression if specified,
12376 TREE_CHAIN is what it has been specified after, or some decl.
12377 TYPES vector is populated with array section types, MAYBE_ZERO_LEN
12378 set to true if any of the array-section-subscript could have length
12379 of zero (explicit or implicit), FIRST_NON_ONE is the index of the
12380 first array-section-subscript which is known not to have length
12381 of one. Given say:
12382 map(a[:b][2:1][:c][:2][:d][e:f][2:5])
12383 FIRST_NON_ONE will be 3, array-section-subscript [:b], [2:1] and [:c]
12384 all are or may have length of 1, array-section-subscript [:2] is the
12385 first one known not to have length 1. For array-section-subscript
12386 <= FIRST_NON_ONE we diagnose non-contiguous arrays if low bound isn't
12387 0 or length isn't the array domain max + 1, for > FIRST_NON_ONE we
12388 can if MAYBE_ZERO_LEN is false. MAYBE_ZERO_LEN will be true in the above
12389 case though, as some lengths could be zero. */
12391 static tree
12395 {
12398 {
12404 {
12408 }
12414 {
12416 {
12421 }
12423 {
12425 {
12429 }
12431 }
12432 }
12434 {
12439 else
12444 }
12447 {
12451 }
12455 {
12460 }
12464 {
12465 /* If the array section is pointer based and the pointer
12466 itself is _Atomic qualified, we need to atomically load
12467 the pointer. */
12468 c_expr expr;
12474 }
12476 }
12491 {
12494 low_bound);
12496 }
12498 {
12501 length);
12503 }
12518 {
12520 {
12523 {
12525 {
12530 }
12531 }
12532 else
12534 }
12537 first_non_one++;
12538 }
12540 {
12544 {
12546 "for unknown bound array type length expression must "
12549 }
12552 {
12557 }
12561 {
12566 }
12571 {
12572 tree size
12576 {
12578 {
12580 "low bound %qE above array section size "
12584 }
12586 {
12589 {
12594 }
12596 }
12599 && tree_int_cst_equal
12601 low_bound))
12602 first_non_one++;
12603 }
12605 {
12610 first_non_one++;
12611 }
12613 {
12615 {
12617 "length %qE above array section size "
12621 }
12623 {
12624 tree lbpluslen
12630 {
12632 "high bound %qE above array section size "
12636 }
12637 }
12638 }
12639 }
12641 {
12646 first_non_one++;
12647 }
12649 /* For [lb:] we will need to evaluate lb more than once. */
12651 {
12654 {
12657 }
12658 }
12659 }
12661 {
12663 {
12667 }
12671 {
12676 }
12677 /* If there is a pointer type anywhere but in the very first
12678 array-section-subscript, the array section can't be contiguous. */
12681 {
12686 }
12687 }
12688 else
12689 {
12693 }
12696 /* We will need to evaluate lb more than once. */
12699 {
12702 }
12705 }
12707 /* Handle array sections for clause C. */
12709 static bool
12711 {
12717 ort);
12723 {
12726 /* Need to evaluate side effects in the length expressions
12727 if any. */
12729 {
12731 {
12734 else
12737 }
12739 }
12744 }
12745 else
12746 {
12756 {
12760 i--;
12774 {
12783 {
12784 tree size;
12787 size_one_node);
12789 {
12790 do_warn_noncontiguous:
12792 "array section is not contiguous in %qs "
12796 }
12797 }
12800 {
12803 else
12807 }
12808 }
12809 else
12810 {
12811 tree l;
12819 else
12820 {
12823 size_one_node);
12826 }
12828 {
12830 size_zero_node);
12833 else
12836 }
12838 {
12844 {
12847 {
12852 }
12855 }
12860 }
12861 else
12863 }
12864 }
12868 {
12890 else
12891 {
12896 }
12899 }
12912 {
12930 }
12936 else
12955 }
12957 }
12959 /* Helper function of finish_omp_clauses. Clone STMT as if we were making
12960 an inline call. But, remap
12961 the OMP_DECL1 VAR_DECL (omp_out resp. omp_orig) to PLACEHOLDER
12962 and OMP_DECL2 VAR_DECL (omp_in resp. omp_priv) to DECL. */
12964 static tree
12967 {
12968 copy_body_data id;
12987 }
12989 /* Helper function of c_finish_omp_clauses, called via walk_tree.
12990 Find OMP_CLAUSE_PLACEHOLDER (passed in DATA) in *TP. */
12992 static tree
12994 {
12998 }
13000 /* For all elements of CLAUSES, validate them against their constraints.
13001 Remove any elements from the list that are invalid. */
13003 tree
13005 {
13030 {
13033 }
13036 {
13042 {
13056 {
13058 {
13061 }
13064 }
13067 {
13070 }
13077 {
13083 {
13086 t);
13089 }
13093 {
13096 t);
13099 }
13108 }
13110 {
13115 }
13119 {
13124 {
13156 }
13158 {
13164 }
13165 }
13167 {
13172 }
13174 {
13184 {
13190 }
13200 decl_placeholder ? decl_placeholder
13208 {
13220 decl_placeholder ? decl_placeholder
13223 {
13228 }
13230 c_find_omp_placeholder_r,
13233 }
13234 else
13235 {
13236 tree init;
13240 else
13244 }
13250 }
13252 {
13256 {
13261 }
13267 }
13273 {
13275 "%<nowait%> clause must not be used together "
13279 }
13285 {
13290 }
13299 {
13301 "modifier should not be specified in %<linear%> "
13304 }
13307 {
13309 "linear clause applied to non-integral non-pointer "
13313 }
13315 {
13320 }
13322 {
13325 {
13327 /* map_head bitmap is used as uniform_head if
13328 declare_simd. */
13332 }
13334 {
13336 "%<linear%> clause step %qE is neither constant "
13340 }
13341 }
13343 {
13349 fold_convert
13354 }
13355 else
13360 check_dup_generic:
13362 check_dup_generic_t:
13364 {
13369 }
13372 {
13374 {
13377 }
13378 else
13380 }
13384 {
13388 }
13391 {
13394 else
13397 }
13398 else
13407 {
13411 }
13414 {
13418 }
13420 {
13423 else
13426 }
13427 else
13436 {
13440 }
13443 {
13447 }
13448 else
13455 {
13459 }
13462 {
13464 "%qE in %<aligned%> clause is neither a pointer nor "
13467 }
13469 {
13474 }
13476 {
13479 t);
13481 }
13482 else
13489 {
13493 }
13495 {
13498 {
13501 {
13509 sizetype,
13513 {
13516 }
13518 }
13519 }
13521 }
13523 {
13527 }
13531 {
13535 }
13546 {
13549 else
13550 {
13553 {
13555 "array section does not have mappable type "
13559 }
13561 {
13566 }
13571 {
13577 {
13584 else
13588 }
13589 else
13590 {
13593 }
13594 }
13595 }
13597 }
13599 {
13602 }
13606 {
13608 {
13613 }
13615 {
13620 }
13622 {
13627 }
13629 {
13632 {
13637 }
13639 }
13643 {
13646 }
13647 }
13649 {
13654 }
13656 {
13661 }
13675 {
13680 }
13684 {
13689 }
13692 {
13695 {
13698 }
13700 {
13703 else
13706 }
13707 else
13709 }
13711 {
13716 else
13719 }
13722 {
13725 else
13728 }
13729 else
13730 {
13735 }
13743 ;
13745 {
13748 "%qE is neither a variable nor a function name in "
13751 else
13756 }
13758 {
13763 }
13765 {
13770 }
13774 {
13776 "%qE appears more than once on the same "
13779 }
13780 else
13787 {
13791 else
13796 }
13797 /* map_head bitmap is used as uniform_head if declare_simd. */
13806 {
13811 }
13816 {
13818 "%<nowait%> clause must not be used together "
13822 }
13868 {
13871 {
13878 }
13880 {
13882 "%<nonmonotonic%> modifier specified for %qs "
13888 }
13889 }
13911 {
13913 "%<inbranch%> clause is incompatible with "
13917 }
13924 }
13927 {
13931 {
13935 }
13938 {
13944 {
13948 /* const vars may be specified in firstprivate clause. */
13959 }
13961 {
13967 }
13968 }
13969 }
13973 else
13975 }
13978 && safelen
13981 {
13983 "%<simdlen%> clause value is bigger than "
13987 }
13990 && schedule_clause
13993 {
13995 "%<nonmonotonic%> schedule modifier specified together "
14001 }
14005 {
14011 {
14013 "%<linear%> clause step is a parameter %qD not "
14017 }
14021 else
14023 }
14027 }
14029 /* Return code to initialize DST with a copy constructor from SRC.
14030 C doesn't have copy constructors nor assignment operators, only for
14031 _Atomic vars we need to perform __atomic_load from src into a temporary
14032 followed by __atomic_store of the temporary to dst. */
14034 tree
14036 {
14051 /* Expansion of a generic atomic load may require an addition
14052 element, so allocate enough to prevent a resize. */
14055 /* Build __atomic_load (&src, &tmp, SEQ_CST); */
14064 /* Build __atomic_store (&dst, &tmp, SEQ_CST); */
14071 }
14073 /* Create a transaction node. */
14075 tree
14077 {
14084 }
14086 /* Make a variant type in the proper way for C/C++, propagating qualifiers
14087 down to the element type of an array. If ORIG_QUAL_TYPE is not
14088 NULL, then it should be used as the qualified type
14089 ORIG_QUAL_INDIRECT levels down in array type derivation (to
14090 preserve information about the typedef name from which an array
14091 type was derived). */
14093 tree
14096 {
14101 {
14102 tree t;
14107 /* See if we already have an identically qualified type. */
14110 else
14112 {
14119 }
14121 {
14132 {
14133 tree unqualified_canon
14138 {
14139 unqualified_canon
14142 }
14145 }
14146 else
14148 }
14150 }
14152 /* A restrict-qualified pointer type must be a pointer to object or
14153 incomplete type. Note that the use of POINTER_TYPE_P also allows
14154 REFERENCE_TYPEs, which is appropriate for C++. */
14158 {
14161 }
14164 ? orig_qual_type
14166 /* A variant type does not inherit the list of incomplete vars from the
14167 type main variant. */
14172 }
14174 /* Build a VA_ARG_EXPR for the C parser. */
14176 tree
14178 {
14181 /* VA_ARG_EXPR cannot be used for a scalar va_list with reverse storage
14182 order because it takes the address of the expression. */
14185 {
14188 }
14190 {
14194 }
14199 }
14201 /* Return truthvalue of whether T1 is the same tree structure as T2.
14202 Return 1 if they are the same. Return false if they are different. */
14204 bool
14206 {
14225 /* They might have become equal now. */
14233 {
14257 /* We need to do this when determining whether or not two
14258 non-type pointer to member function template arguments
14259 are the same. */
14263 {
14267 {
14272 }
14273 }
14287 {
14302 }
14305 {
14309 /* Special case: if either target is an unallocated VAR_DECL,
14310 it means that it's going to be unified with whatever the
14311 TARGET_EXPR is really supposed to initialize, so treat it
14312 as being equivalent to anything. */
14323 }
14340 {
14349 }
14353 }
14356 {
14364 {
14368 {
14380 }
14391 }
14397 }
14398 /* We can get here with --disable-checking. */
14400 }
14402 /* Returns true when the function declaration FNDECL is implicit,
14403 introduced as a result of a call to an otherwise undeclared
14404 function, and false otherwise. */
14406 bool
14408 {
14410 }