| blob | 79044eb18463780756c9b8eaf2d75e0a6fd37a8c |
1 /* Declaration statement matcher
2 Copyright (C) 2002, 2004, 2005, 2006, 2007, 2008
3 Free Software Foundation, Inc.
4 Contributed by Andy Vaught
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 3, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
29 /* Macros to access allocate memory for gfc_data_variable,
30 gfc_data_value and gfc_data. */
31 #define gfc_get_data_variable() gfc_getmem (sizeof (gfc_data_variable))
32 #define gfc_get_data_value() gfc_getmem (sizeof (gfc_data_value))
33 #define gfc_get_data() gfc_getmem( sizeof (gfc_data))
36 /* This flag is set if an old-style length selector is matched
37 during a type-declaration statement. */
41 /* When variables acquire types and attributes from a declaration
42 statement, they get them from the following static variables. The
43 first part of a declaration sets these variables and the second
44 part copies these into symbol structures. */
52 /* The current binding label (if any). */
54 /* Need to know how many identifiers are on the current data declaration
55 line in case we're given the BIND(C) attribute with a NAME= specifier. */
57 /* Need to know if a NAME= specifier was found during gfc_match_bind_c so we
58 can supply a name if the curr_binding_label is nil and NAME= was not. */
61 /* Initializer of the previous enumerator. */
65 /* History of all the enumerators is maintained, so that
66 kind values of all the enumerators could be updated depending
67 upon the maximum initialized value. */
70 {
74 }
75 enumerator_history;
77 /* Header of enum history chain. */
81 /* Pointer of enum history node containing largest initializer. */
85 /* gfc_new_block points to the symbol of a newly matched block. */
92 /********************* DATA statement subroutines *********************/
96 bool
98 {
100 }
102 static void
104 {
106 }
108 /* Free a gfc_data_variable structure and everything beneath it. */
110 static void
112 {
116 {
122 }
123 }
126 /* Free a gfc_data_value structure and everything beneath it. */
128 static void
130 {
134 {
138 }
139 }
142 /* Free a list of gfc_data structures. */
144 void
146 {
150 {
155 }
156 }
159 /* Free all data in a namespace. */
161 static void
163 {
167 {
171 }
172 }
177 /* Match a list of variables terminated by an iterator and a right
178 parenthesis. */
180 static match
182 {
184 match m;
198 {
218 }
224 syntax:
227 }
230 /* Match a single element in a data variable list, which can be a
231 variable-iterator list. */
233 static match
235 {
236 match m;
252 {
256 }
269 }
272 /* Match the top-level list of data variables. */
274 static match
276 {
278 match m;
283 {
295 else
304 }
308 syntax:
312 }
315 static match
317 {
321 match m;
322 locus old_loc;
326 {
329 }
340 /* Should this be a structure component, try to match it
341 before matching a name. */
347 {
351 }
364 {
366 name);
368 }
372 /* Check to see if the value is an initialization array expression. */
374 {
382 {
388 else
389 {
392 }
393 }
394 }
398 }
401 /* Match a list of values in a DATA statement. The leading '/' has
402 already been seen at this point. */
404 static match
406 {
409 match m;
414 {
426 else
432 {
435 }
436 else
437 {
447 }
453 }
457 syntax:
461 }
464 /* Matches an old style initialization. */
466 static match
468 {
469 match m;
474 /* Set up data structure to hold initializers. */
483 /* Match initial value list. This also eats the terminal '/'. */
486 {
489 }
492 {
496 }
498 /* Mark the variable as having appeared in a data statement. */
500 {
503 }
505 /* Chain in namespace list of DATA initializers. */
510 }
513 /* Match the stuff following a DATA statement. If ERROR_FLAG is set,
514 we are matching a DATA statement and are therefore issuing an error
515 if we encounter something unexpected, if not, we're trying to match
516 an old-style initialization expression of the form INTEGER I /2/. */
518 match
520 {
522 match m;
527 {
546 }
551 {
554 }
558 cleanup:
562 }
565 /************************ Declaration statements *********************/
567 /* Match an intent specification. Since this can only happen after an
568 INTENT word, a legal intent-spec must follow. */
570 static sym_intent
572 {
583 }
586 /* Matches a character length specification, which is either a
587 specification expression or a '*'. */
589 static match
591 {
592 match m;
595 {
598 }
602 {
605 {
610 {
617 }
618 }
619 }
622 syntax:
625 }
628 /* A character length is a '*' followed by a literal integer or a
629 char_len_param_value in parenthesis. */
631 static match
633 {
635 match m;
646 {
649 }
656 {
659 }
667 {
671 }
675 syntax:
678 }
681 /* Special subroutine for finding a symbol. Check if the name is found
682 in the current name space. If not, and we're compiling a function or
683 subroutine and the parent compilation unit is an interface, then check
684 to see if the name we've been given is the name of the interface
685 (located in another namespace). */
687 static int
689 {
711 {
714 }
716 end:
718 }
721 /* Special subroutine for getting a symbol node associated with a
722 procedure name, used in SUBROUTINE and FUNCTION statements. The
723 symbol is created in the parent using with symtree node in the
724 child unit pointing to the symbol. If the current namespace has no
725 parent, then the symbol is just created in the current unit. */
727 static int
729 {
734 /* Module functions have to be left in their own namespace because
735 they have potentially (almost certainly!) already been referenced.
736 In this sense, they are rather like external functions. This is
737 fixed up in resolve.c(resolve_entries), where the symbol name-
738 space is set to point to the master function, so that the fake
739 result mechanism can work. */
741 {
742 /* Present if entry is declared to be a module procedure. */
750 /* Pick up the typespec for the entry, if declared in the function
751 body. Note that this symbol is FL_UNKNOWN because it will
752 only have appeared in a type declaration. The local symtree
753 is set to point to the module symbol and a unique symtree
754 to the local version. This latter ensures a correct clearing
755 of the symbols. */
756 {
757 /* If the ENTRY proceeds its specification, we need to ensure
758 that this does not raise a "has no IMPLICIT type" error. */
764 /* Put the symbol in the procedure namespace so that, should
765 the ENTRY preceed its specification, the specification
766 can be applied. */
773 }
774 }
775 else
785 {
786 /* Trap another encompassed procedure with the same name. All
787 these conditions are necessary to avoid picking up an entry
788 whose name clashes with that of the encompassing procedure;
789 this is handled using gsymbols to register unique,globally
790 accessible names. */
798 /* Trap a procedure with a name the same as interface in the
799 encompassing scope. */
807 /* Trap declarations of attributes in encompassing scope. The
808 signature for this is that ts.kind is set. Legitimate
809 references only set ts.type. */
819 }
824 /* Module function entries will already have a symtree in
825 the current namespace but will need one at module level. */
827 {
828 /* Present if entry is declared to be a module procedure. */
832 }
833 else
839 /* See if the procedure should be a module procedure. */
850 }
853 /* Verify that the given symbol representing a parameter is C
854 interoperable, by checking to see if it was marked as such after
855 its declaration. If the given symbol is not interoperable, a
856 warning is reported, thus removing the need to return the status to
857 the calling function. The standard does not require the user use
858 one of the iso_c_binding named constants to declare an
859 interoperable parameter, but we can't be sure if the param is C
860 interop or not if the user doesn't. For example, integer(4) may be
861 legal Fortran, but doesn't have meaning in C. It may interop with
862 a number of the C types, which causes a problem because the
863 compiler can't know which one. This code is almost certainly not
864 portable, and the user will get what they deserve if the C type
865 across platforms isn't always interoperable with integer(4). If
866 the user had used something like integer(c_int) or integer(c_long),
867 the compiler could have automatically handled the varying sizes
868 across platforms. */
870 try
872 {
876 /* We check implicitly typed variables in symbol.c:gfc_set_default_type().
877 Don't repeat the checks here. */
881 /* For subroutines or functions that are passed to a BIND(C) procedure,
882 they're interoperable if they're BIND(C) and their params are all
883 interoperable. */
885 {
887 {
893 }
894 else
895 {
897 /* We've already checked this procedure; don't check it again. */
899 else
902 }
903 }
905 /* See if we've stored a reference to a procedure that owns sym. */
907 {
909 {
910 is_c_interop =
915 {
916 /* Make personalized messages to give better feedback. */
919 " procedure '%s' but is not C interoperable "
924 else
926 "BIND(C) procedure '%s' but may not be C "
930 }
932 /* Character strings are only C interoperable if they have a
933 length of 1. */
935 {
939 {
941 "must be length 1 because "
946 }
947 }
949 /* We have to make sure that any param to a bind(c) routine does
950 not have the allocatable, pointer, or optional attributes,
951 according to J3/04-007, section 5.1. */
953 {
955 "ALLOCATABLE attribute because procedure '%s'"
959 }
962 {
964 "POINTER attribute because procedure '%s'"
968 }
971 {
973 "OPTIONAL attribute because procedure '%s'"
977 }
979 /* Make sure that if it has the dimension attribute, that it is
980 either assumed size or explicit shape. */
982 {
984 {
986 "argument to the procedure '%s' at %L because "
991 }
994 {
996 "argument to the procedure '%s' at %L because "
1001 }
1002 }
1003 }
1004 }
1007 }
1010 /* Function called by variable_decl() that adds a name to the symbol table. */
1015 {
1016 symbol_attribute attr;
1022 /* Start updating the symbol table. Add basic type attribute if present. */
1032 /* Add dimension attribute if present. */
1037 /* Add attribute to symbol. The copy is so that we can reset the
1038 dimension attribute. */
1045 /* Finish any work that may need to be done for the binding label,
1046 if it's a bind(c). The bind(c) attr is found before the symbol
1047 is made, and before the symbol name (for data decls), so the
1048 current_ts is holding the binding label, or nothing if the
1049 name= attr wasn't given. Therefore, test here if we're dealing
1050 with a bind(c) and make sure the binding label is set correctly. */
1052 {
1054 {
1055 /* Set the binding label and verify that if a NAME= was specified
1056 then only one identifier was in the entity-decl-list. */
1060 }
1061 }
1063 /* See if we know we're in a common block, and if it's a bind(c)
1064 common then we need to make sure we're an interoperable type. */
1066 {
1067 /* Test the common block object. */
1070 {
1072 "must be declared with a C interoperable "
1077 }
1078 }
1083 }
1086 /* Set character constant to the given length. The constant will be padded or
1087 truncated. */
1089 void
1091 {
1100 {
1111 /* Apply the standard by 'hand' otherwise it gets cleared for
1112 initializers. */
1122 }
1123 }
1126 /* Function to create and update the enumerator history
1127 using the information passed as arguments.
1128 Pointer "max_enum" is also updated, to point to
1129 enum history node containing largest initializer.
1131 SYM points to the symbol node of enumerator.
1132 INIT points to its enumerator value. */
1134 static void
1136 {
1147 {
1150 }
1151 else
1152 {
1159 }
1160 }
1163 /* Function to free enum kind history. */
1165 void
1167 {
1172 {
1176 }
1179 }
1182 /* Function called by variable_decl() that adds an initialization
1183 expression to a symbol. */
1187 {
1188 symbol_attribute attr;
1198 /* If this symbol is confirming an implicit parameter type,
1199 then an initialization expression is not allowed. */
1203 {
1207 }
1210 {
1211 /* An initializer is required for PARAMETER declarations. */
1213 {
1216 }
1217 }
1218 else
1219 {
1220 /* If a variable appears in a DATA block, it cannot have an
1221 initializer. */
1223 {
1227 }
1229 /* Check if the assignment can happen. This has to be put off
1230 until later for a derived type variable. */
1236 {
1237 /* Update symbol character length according initializer. */
1239 {
1241 /* If there are multiple CHARACTER variables declared on the
1242 same line, we don't want them to share the same length. */
1248 {
1250 {
1253 }
1255 {
1259 }
1263 }
1264 }
1265 /* Update initializer character length according symbol. */
1267 {
1274 {
1275 /* Build a new charlen to prevent simplification from
1276 deleting the length before it is resolved. */
1284 }
1285 }
1286 }
1288 /* Need to check if the expression we initialized this
1289 to was one of the iso_c_binding named constants. If so,
1290 and we're a parameter (constant), let it be iso_c.
1291 For example:
1292 integer(c_int), parameter :: my_int = c_int
1293 integer(my_int) :: my_int_2
1294 If we mark my_int as iso_c (since we can see it's value
1295 is equal to one of the named constants), then my_int_2
1296 will be considered C interoperable. */
1298 {
1301 /* attr bits needed for module files. */
1306 }
1308 /* Add initializer. Make sure we keep the ranks sane. */
1310 {
1311 mpz_t size;
1319 {
1325 {
1327 {
1330 }
1331 else
1332 {
1336 }
1337 }
1345 }
1347 }
1353 }
1356 }
1359 /* Function called by variable_decl() that adds a name to a structure
1360 being built. */
1365 {
1368 /* If the current symbol is of the same derived type that we're
1369 constructing, it must have the pointer attribute. */
1373 {
1376 }
1379 {
1381 {
1385 }
1386 }
1403 /* Should this ever get more complicated, combine with similar section
1404 in add_init_expr_to_sym into a separate function. */
1406 {
1413 {
1418 }
1419 }
1421 /* Check array components. */
1423 {
1425 {
1428 }
1429 else
1431 }
1434 {
1436 {
1440 }
1441 }
1443 {
1445 {
1449 }
1450 }
1451 else
1452 {
1454 {
1458 }
1459 }
1462 }
1465 /* Match a 'NULL()', and possibly take care of some side effects. */
1467 match
1469 {
1472 match m;
1478 /* The NULL symbol now has to be/become an intrinsic function. */
1480 {
1483 }
1501 }
1504 /* Match a variable name with an optional initializer. When this
1505 subroutine is called, a variable is expected to be parsed next.
1506 Depending on what is happening at the moment, updates either the
1507 symbol table or the current interface. */
1509 static match
1511 {
1517 locus var_locus;
1518 match m;
1521 locus old_locus;
1528 /* When we get here, we've just matched a list of attributes and
1529 maybe a type and a double colon. The next thing we expect to see
1530 is the name of the symbol. */
1537 /* Now we could see the optional array spec. or character length. */
1551 {
1553 {
1562 /* Non-constant lengths need to be copied after the first
1563 element. Also copy assumed lengths. */
1568 {
1573 }
1574 else
1581 }
1582 }
1584 /* If this symbol has already shown up in a Cray Pointer declaration,
1585 then we want to set the type & bail out. */
1587 {
1590 {
1599 /* Check to see if we have an array specification. */
1601 {
1603 {
1608 }
1609 else
1610 {
1614 /* Fix the array spec. */
1618 }
1619 }
1621 }
1622 else
1623 {
1625 }
1626 }
1629 /* OK, we've successfully matched the declaration. Now put the
1630 symbol in the current namespace, because it might be used in the
1631 optional initialization expression for this symbol, e.g. this is
1632 perfectly legal:
1634 integer, parameter :: i = huge(i)
1636 This is only true for parameters or variables of a basic type.
1637 For components of derived types, it is not true, so we don't
1638 create a symbol for those yet. If we fail to create the symbol,
1639 bail out. */
1642 {
1645 }
1647 /* An interface body specifies all of the procedure's
1648 characteristics and these shall be consistent with those
1649 specified in the procedure definition, except that the interface
1650 may specify a procedure that is not pure if the procedure is
1651 defined to be pure(12.3.2). */
1656 {
1663 {
1668 }
1669 }
1671 /* In functions that have a RESULT variable defined, the function
1672 name always refers to function calls. Therefore, the name is
1673 not allowed to appear in specification statements. */
1679 {
1683 }
1685 /* We allow old-style initializations of the form
1686 integer i /2/, j(4) /3*3, 1/
1687 (if no colon has been seen). These are different from data
1688 statements in that initializers are only allowed to apply to the
1689 variable immediately preceding, i.e.
1690 integer i, j /1, 2/
1691 is not allowed. Therefore we have to do some work manually, that
1692 could otherwise be left to the matchers for DATA statements. */
1695 {
1701 }
1703 /* The double colon must be present in order to have initializers.
1704 Otherwise the statement is ambiguous with an assignment statement. */
1706 {
1708 {
1710 {
1714 }
1718 {
1721 }
1724 {
1728 }
1733 }
1735 {
1737 {
1742 }
1746 {
1749 }
1752 {
1756 }
1760 }
1761 }
1765 {
1770 }
1772 /* Add the initializer. Note that it is fine if initializer is
1773 NULL here, because we sometimes also need to check if a
1774 declaration *must* have an initialization expression. */
1777 else
1778 {
1783 }
1787 cleanup:
1788 /* Free stuff up and return. */
1793 }
1796 /* Match an extended-f77 "TYPESPEC*bytesize"-style kind specification.
1797 This assumes that the byte size is equal to the kind number for
1798 non-COMPLEX types, and equal to twice the kind number for COMPLEX. */
1800 match
1802 {
1803 match m;
1815 /* Massage the kind numbers for complex types. */
1817 {
1819 {
1823 }
1825 }
1828 {
1832 }
1839 }
1842 /* Match a kind specification. Since kinds are generally optional, we
1843 usually return MATCH_NO if something goes wrong. If a "kind="
1844 string is found, then we know we have an error. */
1846 match
1848 {
1867 /* Also gobbles optional text. */
1873 kind_expr:
1877 {
1879 {
1880 /* The function kind expression might include use associated or
1881 imported parameters and try again after the specification
1882 expressions..... */
1884 {
1888 }
1893 }
1894 else
1895 {
1896 /* ....or else, the match is real. */
1901 }
1902 }
1905 {
1909 }
1914 {
1918 }
1920 /* Before throwing away the expression, let's see if we had a
1921 C interoperable kind (and store the fact). */
1923 {
1924 /* Mark this as c interoperable if being declared with one
1925 of the named constants from iso_c_binding. */
1928 }
1933 /* Ignore errors to this point, if we've gotten here. This means
1934 we ignore the m=MATCH_ERROR from above. */
1936 {
1941 }
1946 {
1949 else
1952 }
1953 else
1954 /* All tests passed. */
1960 /* Return what we know from the test(s). */
1963 no_match:
1967 }
1970 static match
1972 {
1973 locus where;
1985 {
1986 /* The expression might include use-associated or imported
1987 parameters and try again after the specification
1988 expressions. */
1992 }
2000 {
2004 }
2009 {
2013 }
2017 /* Ignore errors to this point, if we've gotten here. This means
2018 we ignore the m=MATCH_ERROR from above. */
2020 {
2023 }
2024 else
2025 /* All tests passed. */
2031 /* Return what we know from the test(s). */
2034 no_match:
2038 }
2040 /* Match the various kind/length specifications in a CHARACTER
2041 declaration. We don't return MATCH_NO. */
2043 static match
2045 {
2049 match m;
2056 /* Try the old-style specification first. */
2061 {
2066 }
2070 {
2073 }
2075 /* Try the weird case: ( KIND = <int> [ , LEN = <len-param> ] ). */
2077 {
2096 }
2098 /* Try to match "LEN = <len-param>" or "LEN = <len-param>, KIND = <int>". */
2100 {
2118 }
2120 /* Try to match ( <len-param> ) or ( <len-param> , [ KIND = ] <int> ). */
2143 rparen:
2144 /* Require a right-paren at this point. */
2149 syntax:
2155 done:
2156 /* Deal with character functions after USE and IMPORT statements. */
2158 {
2162 }
2165 {
2168 }
2170 /* Do some final massaging of the length values. */
2177 else
2183 /* We have to know if it was a c interoperable kind so we can
2184 do accurate type checking of bind(c) procs, etc. */
2186 /* Mark this as c interoperable if being declared with one
2187 of the named constants from iso_c_binding. */
2190 /* Here, we might have parsed something such as: character(c_char)
2191 In this case, the parsing code above grabs the c_char when
2192 looking for the length (line 1690, roughly). it's the last
2193 testcase for parsing the kind params of a character variable.
2194 However, it's not actually the length. this seems like it
2195 could be an error.
2196 To see if the user used a C interop kind, test the expr
2197 of the so called length, and see if it's C interoperable. */
2201 }
2204 /* Matches a type specification. If successful, sets the ts structure
2205 to the matched specification. This is necessary for FUNCTION and
2206 IMPLICIT statements.
2208 If implicit_flag is nonzero, then we don't check for the optional
2209 kind specification. Not doing so is needed for matching an IMPLICIT
2210 statement correctly. */
2212 match
2214 {
2217 match m;
2221 /* A belt and braces check that the typespec is correctly being treated
2222 as a deferred characteristic association. */
2230 /* Clear the current binding label, in case one is given. */
2234 {
2240 {
2244 }
2249 }
2252 {
2256 }
2259 {
2263 else
2265 }
2268 {
2272 }
2275 {
2279 }
2282 {
2286 }
2289 {
2297 }
2300 {
2304 }
2312 /* Defer association of the derived type until the end of the
2313 specification block. However, if the derived type can be
2314 found, add it to the typespec. */
2316 {
2322 }
2324 /* Search for the name but allow the components to be defined later. If
2325 type = -1, this typespec has been seen in a function declaration but
2326 the type could not be accessed at that point. */
2329 {
2332 }
2334 {
2338 {
2341 }
2346 }
2357 get_kind:
2358 /* For all types except double, derived and character, look for an
2359 optional kind specifier. MATCH_NO is actually OK at this point. */
2364 {
2369 }
2375 /* Defer association of the KIND expression of function results
2376 until after USE and IMPORT statements. */
2385 }
2388 /* Match an IMPLICIT NONE statement. Actually, this statement is
2389 already matched in parse.c, or we would not end up here in the
2390 first place. So the only thing we need to check, is if there is
2391 trailing garbage. If not, the match is successful. */
2393 match
2395 {
2397 }
2400 /* Match the letter range(s) of an IMPLICIT statement. */
2402 static match
2404 {
2407 locus cur_loc;
2414 {
2417 }
2421 {
2431 {
2457 }
2460 {
2464 }
2466 /* See if we can add the newly matched range to the pending
2467 implicits from this IMPLICIT statement. We do not check for
2468 conflicts with whatever earlier IMPLICIT statements may have
2469 set. This is done when we've successfully finished matching
2470 the current one. */
2473 }
2477 bad:
2482 }
2485 /* Match an IMPLICIT statement, storing the types for
2486 gfc_set_implicit() if the statement is accepted by the parser.
2487 There is a strange looking, but legal syntactic construction
2488 possible. It looks like:
2490 IMPLICIT INTEGER (a-b) (c-d)
2492 This is legal if "a-b" is a constant expression that happens to
2493 equal one of the legal kinds for integers. The real problem
2494 happens with an implicit specification that looks like:
2496 IMPLICIT INTEGER (a-b)
2498 In this case, a typespec matcher that is "greedy" (as most of the
2499 matchers are) gobbles the character range as a kindspec, leaving
2500 nothing left. We therefore have to go a bit more slowly in the
2501 matching process by inhibiting the kindspec checking during
2502 typespec matching and checking for a kind later. */
2504 match
2506 {
2507 gfc_typespec ts;
2508 locus cur_loc;
2510 match m;
2514 /* We don't allow empty implicit statements. */
2516 {
2519 }
2521 do
2522 {
2523 /* First cleanup. */
2526 /* A basic type is mandatory here. */
2537 {
2538 /* We may have <TYPE> (<RANGE>). */
2542 {
2543 /* Check for CHARACTER with no length parameter. */
2545 {
2551 }
2553 /* Record the Successful match. */
2557 }
2560 }
2562 /* Discard the (incorrectly) matched range. */
2565 /* Last chance -- check <TYPE> <SELECTOR> (<RANGE>). */
2568 else
2569 {
2572 {
2578 }
2579 }
2596 }
2601 syntax:
2604 error:
2606 }
2609 match
2611 {
2613 match m;
2619 {
2623 }
2630 {
2631 /* All host variables should be imported. */
2634 }
2637 {
2639 {
2642 }
2643 }
2646 {
2649 {
2653 {
2656 }
2661 {
2664 }
2667 {
2671 }
2674 {
2678 }
2692 }
2694 next_item:
2699 }
2703 syntax:
2706 }
2709 /* A minimal implementation of gfc_match without whitespace, escape
2710 characters or variable arguments. Returns true if the next
2711 characters match the TARGET template exactly. */
2713 static bool
2715 {
2722 }
2724 /* Matches an attribute specification including array specs. If
2725 successful, leaves the variables current_attr and current_as
2726 holding the specification. Also sets the colon_seen variable for
2727 later use by matchers associated with initializations.
2729 This subroutine is a little tricky in the sense that we don't know
2730 if we really have an attr-spec until we hit the double colon.
2731 Until that time, we can only return MATCH_NO. This forces us to
2732 check for duplicate specification at this level. */
2734 static match
2736 {
2737 /* Modifiers that can exist in a type statement. */
2745 GFC_DECL_END /* Sentinel */
2746 }
2747 decl_types;
2749 /* GFC_DECL_END is the sentinel, index starts at 0. */
2750 #define NUM_DECL GFC_DECL_END
2754 decl_types d;
2756 match m;
2765 /* See if we get all of the keywords up to the final double colon. */
2770 {
2778 {
2779 /* This is the successful exit condition for the loop. */
2782 }
2784 {
2787 {
2794 /* Try and match the bind(c). */
2814 {
2817 {
2819 {
2820 /* Matched "intent". */
2821 /* TODO: Call match_intent_spec from here. */
2828 }
2829 }
2831 {
2833 {
2834 /* Matched "intrinsic". */
2836 }
2837 }
2838 }
2849 {
2852 {
2853 /* Matched "parameter". */
2855 }
2860 {
2861 /* Matched "pointer". */
2863 }
2869 {
2871 {
2872 /* Matched "private". */
2874 }
2875 }
2877 {
2879 {
2880 /* Matched "protected". */
2882 }
2883 }
2888 {
2889 /* Matched "public". */
2891 }
2893 }
2910 {
2912 {
2913 /* Matched "value". */
2915 }
2916 }
2918 {
2920 {
2921 /* Matched "volatile". */
2923 }
2924 }
2926 }
2927 }
2929 /* No double colon and no recognizable decl_type, so assume that
2930 we've been looking at something else the whole time. */
2932 {
2935 }
2937 /* Check to make sure any parens are paired up correctly. */
2939 {
2942 }
2948 {
2952 {
2955 }
2959 }
2960 }
2962 /* Since we've seen a double colon, we have to be looking at an
2963 attr-spec. This means that we can now issue errors. */
2966 {
2968 {
3025 }
3030 }
3032 /* Now that we've dealt with duplicate attributes, add the attributes
3033 to the current attribute. */
3035 {
3043 {
3045 {
3049 {
3052 }
3053 }
3054 else
3055 {
3060 }
3061 }
3065 {
3068 else
3073 {
3078 {
3081 }
3082 }
3083 else
3084 {
3089 }
3090 }
3093 {
3136 {
3141 }
3147 else
3178 else
3187 else
3193 }
3196 {
3199 }
3200 }
3205 cleanup:
3210 }
3213 /* Set the binding label, dest_label, either with the binding label
3214 stored in the given gfc_typespec, ts, or if none was provided, it
3215 will be the symbol name in all lower case, as required by the draft
3216 (J3/04-007, section 15.4.1). If a binding label was given and
3217 there is more than one argument (num_idents), it is an error. */
3219 try
3221 {
3223 {
3227 }
3230 {
3231 /* Binding label given; store in temp holder til have sym. */
3233 }
3234 else
3235 {
3236 /* No binding label given, and the NAME= specifier did not exist,
3237 which means there was no NAME="". */
3240 }
3243 }
3246 /* Set the status of the given common block as being BIND(C) or not,
3247 depending on the given parameter, is_bind_c. */
3249 void
3251 {
3254 }
3257 /* Verify that the given gfc_typespec is for a C interoperable type. */
3259 try
3261 {
3264 /* Make sure the kind used is appropriate for the type.
3265 The f90_type is unknown if an integer constant was
3266 used (e.g., real(4), bind(c) :: myFloat). */
3268 {
3271 {
3272 /* Print an error, but continue parsing line. */
3278 }
3279 }
3281 /* Make sure the kind is C interoperable. This does not care about the
3282 possible error above. */
3289 }
3292 /* Verify that the variables of a given common block, which has been
3293 defined with the attribute specifier bind(c), to be of a C
3294 interoperable type. Errors will be reported here, if
3295 encountered. */
3297 try
3299 {
3305 /* Make sure we have at least one symbol. */
3309 /* Here we know we have a symbol, so we'll execute this loop
3310 at least once. */
3311 do
3312 {
3313 /* The second to last param, 1, says this is in a common block. */
3319 }
3322 /* Verify that a given BIND(C) symbol is C interoperable. If it is not,
3323 an appropriate error message is reported. */
3325 try
3328 {
3332 {
3334 /* Make sure it wasn't an implicitly typed result. */
3336 {
3341 /* Mark it as C interoperable to prevent duplicate warnings. */
3344 }
3345 }
3347 /* Here, we know we have the bind(c) attribute, so if we have
3348 enough type info, then verify that it's a C interop kind.
3349 The info could be in the symbol already, or possibly still in
3350 the given ts (current_ts), so look in both. */
3352 {
3355 {
3356 /* See if we're dealing with a sym in a common block or not. */
3358 {
3360 "may not be a C interoperable "
3364 }
3365 else
3366 {
3371 else
3373 "may not be a C interoperable "
3376 }
3377 }
3379 /* Variables declared w/in a common block can't be bind(c)
3380 since there's no way for C to see these variables, so there's
3381 semantically no reason for the attribute. */
3383 {
3385 "%L cannot be declared with BIND(C) "
3390 }
3392 /* Scalar variables that are bind(c) can not have the pointer
3393 or allocatable attributes. */
3395 {
3397 {
3402 }
3405 {
3410 }
3412 /* If it is a BIND(C) function, make sure the return value is a
3413 scalar value. The previous tests in this function made sure
3414 the type is interoperable. */
3419 /* BIND(C) functions can not return a character string. */
3427 }
3428 }
3430 /* See if the symbol has been marked as private. If it has, make sure
3431 there is no binding label and warn the user if there is one. */
3434 /* Use gfc_warning_now because we won't say that the symbol fails
3435 just because of this. */
3441 }
3444 /* Set the appropriate fields for a symbol that's been declared as
3445 BIND(C) (the is_bind_c flag and the binding label), and verify that
3446 the type is C interoperable. Errors are reported by the functions
3447 used to set/test these fields. */
3449 try
3451 {
3454 /* TODO: Do we need to make sure the vars aren't marked private? */
3456 /* Set the is_bind_c bit in symbol_attribute. */
3464 }
3467 /* Set the fields marking the given common block as BIND(C), including
3468 a binding label, and report any errors encountered. */
3470 try
3472 {
3475 /* destLabel, common name, typespec (which may have binding label). */
3480 /* Set the given common block (com_block) to being bind(c) (1). */
3484 }
3487 /* Retrieve the list of one or more identifiers that the given bind(c)
3488 attribute applies to. */
3490 try
3492 {
3496 match found_id;
3500 {
3503 }
3505 {
3508 }
3509 else
3510 {
3514 }
3516 /* Save the current identifier and look for more. */
3517 do
3518 {
3519 /* Increment the number of identifiers found for this spec stmt. */
3520 num_idents++;
3522 /* Make sure we have a sym or com block, and verify that it can
3523 be bind(c). Set the appropriate field(s) and look for more
3524 identifiers. */
3526 {
3528 {
3532 }
3533 else
3534 {
3538 }
3540 /* Look to see if we have another identifier. */
3547 {
3550 }
3552 {
3555 }
3556 else
3557 {
3561 }
3562 }
3563 else
3564 {
3566 }
3569 /* if we get here we were successful */
3571 }
3574 /* Try and match a BIND(C) attribute specification statement. */
3576 match
3578 {
3584 /* This may not be necessary. */
3586 /* Clear the temporary binding label holder. */
3589 /* Look for the bind(c). */
3593 {
3594 /* Look for the :: now, but it is not required. */
3597 /* Get the identifier(s) that needs to be updated. This may need to
3598 change to hand the flag(s) for the attr specified so all identifiers
3599 found can have all appropriate parts updated (assuming that the same
3600 spec stmt can have multiple attrs, such as both bind(c) and
3601 allocatable...). */
3603 /* Error message should have printed already. */
3605 }
3608 }
3611 /* Match a data declaration statement. */
3613 match
3615 {
3617 match m;
3627 {
3631 {
3634 }
3637 }
3641 {
3644 }
3648 {
3656 /* Any symbol that we find had better be a type definition
3657 which has its components defined. */
3663 /* Now we have an error, which we signal, and then fix up
3664 because the knock-on is plain and simple confusing. */
3669 }
3671 ok:
3672 /* If we have an old-style character declaration, and no new-style
3673 attribute specifications, then there a comma is optional between
3674 the type specification and the variable list. */
3678 /* Give the types/attributes to symbols that follow. Give the element
3679 a number so that repeat character length expressions can be copied. */
3682 {
3683 num_idents_on_line++;
3694 }
3702 cleanup:
3706 }
3709 /* Match a prefix associated with a function or subroutine
3710 declaration. If the typespec pointer is nonnull, then a typespec
3711 can be matched. Note that if nothing matches, MATCH_YES is
3712 returned (the null string was matched). */
3714 match
3716 {
3722 loop:
3726 {
3730 }
3733 {
3738 }
3741 {
3746 }
3749 {
3754 }
3756 /* At this point, the next item is not a prefix. */
3758 }
3761 /* Copy attributes matched by gfc_match_prefix() to attributes on a symbol. */
3765 {
3776 }
3779 /* Match a formal argument list. */
3781 match
3783 {
3787 match m;
3792 {
3796 }
3802 {
3805 else
3806 {
3813 }
3819 else
3820 {
3823 }
3827 /* We don't add the VARIABLE flavor because the name could be a
3828 dummy procedure. We don't apply these attributes to formal
3829 arguments of statement functions. */
3833 {
3836 }
3838 /* The name of a program unit can be in a different namespace,
3839 so check for it explicitly. After the statement is accepted,
3840 the name is checked for especially in gfc_get_symbol(). */
3843 {
3848 }
3855 {
3858 }
3859 }
3861 ok:
3862 /* Check for duplicate symbols in the formal argument list. */
3864 {
3866 {
3872 {
3878 }
3879 }
3880 }
3884 {
3887 }
3891 cleanup:
3894 }
3897 /* Match a RESULT specification following a function declaration or
3898 ENTRY statement. Also matches the end-of-statement. */
3900 static match
3902 {
3905 match m;
3914 /* Get the right paren, and that's it because there could be the
3915 bind(c) attribute after the result clause. */
3917 {
3918 /* TODO: should report the missing right paren here. */
3920 }
3923 {
3926 }
3938 }
3941 /* Match a function suffix, which could be a combination of a result
3942 clause and BIND(C), either one, or neither. The draft does not
3943 require them to come in a specific order. */
3945 match
3947 {
3954 /* Initialize to having found nothing. */
3959 /* Get the next char to narrow between result and bind(c). */
3963 /* C binding names are not allowed for internal procedures. */
3967 else
3971 {
3973 /* Look for result clause. */
3976 {
3977 /* Now see if there is a bind(c) after it. */
3979 /* We've found the result clause and possibly bind(c). */
3981 }
3982 else
3983 /* This should only be MATCH_ERROR. */
3987 /* Look for bind(c) first. */
3990 {
3991 /* Now see if a result clause followed it. */
3994 }
3995 else
3996 {
3997 /* Should only be a MATCH_ERROR if we get here after seeing 'b'. */
3999 }
4005 }
4008 {
4009 /* Fortran 2008 draft allows BIND(C) for internal procedures. */
4013 "at %L may not be specified for an internal "
4021 }
4024 }
4027 /* Match a PROCEDURE declaration (R1211). */
4029 static match
4031 {
4032 match m;
4042 {
4045 }
4047 /* Get the type spec. for the procedure interface. */
4058 /* Get the name of the procedure or abstract interface
4059 to inherit the interface from. */
4067 /* Various interface checks. */
4069 {
4070 /* Resolve interface if possible. That way, attr.procedure is only set
4071 if it is declared by a later procedure-declaration-stmt, which is
4072 invalid per C1212. */
4077 {
4080 }
4082 {
4086 }
4087 /* Handle intrinsic procedures. */
4093 {
4097 }
4098 }
4100 got_ts:
4102 {
4105 }
4107 /* Parse attributes. */
4112 /* Get procedure symbols. */
4114 {
4121 /* Add current_attr to the symbol attributes. */
4126 {
4127 /* Check for C1218. */
4129 {
4133 }
4134 /* Check for C1217. */
4136 {
4140 }
4142 {
4146 }
4147 /* Set binding label for BIND(C). */
4150 }
4157 /* Set interface. */
4159 {
4162 }
4164 {
4170 }
4176 }
4178 syntax:
4181 }
4184 /* Match a PROCEDURE declaration inside an interface (R1206). */
4186 static match
4188 {
4189 match m;
4195 {
4198 }
4201 {
4217 }
4221 syntax:
4224 }
4227 /* General matcher for PROCEDURE declarations. */
4229 match
4231 {
4232 match m;
4235 {
4252 }
4262 }
4265 /* Match a function declaration. */
4267 match
4269 {
4272 locus old_loc;
4273 match m;
4274 match suffix_match;
4288 {
4291 }
4294 {
4297 }
4304 {
4309 }
4315 /* According to the draft, the bind(c) and result clause can
4316 come in either order after the formal_arg_list (i.e., either
4317 can be first, both can exist together or by themselves or neither
4318 one). Therefore, the match_result can't match the end of the
4319 string, and check for the bind(c) or result clause in either order. */
4322 /* Make sure that it isn't already declared as BIND(C). If it is, it
4323 must have been marked BIND(C) with a BIND(C) attribute and that is
4324 not allowed for procedures. */
4326 {
4332 else
4335 }
4338 {
4339 /* If we haven't found the end-of-statement, look for a suffix. */
4342 /* Need to get the eos now. */
4344 else
4346 }
4350 else
4351 {
4352 /* Make changes to the symbol. */
4364 {
4368 }
4370 /* Delay matching the function characteristics until after the
4371 specification block by signalling kind=-1. */
4375 else
4379 {
4382 }
4383 else
4384 {
4387 }
4390 }
4392 cleanup:
4395 }
4398 /* This is mostly a copy of parse.c(add_global_procedure) but modified to
4399 pass the name of the entry, rather than the gfc_current_block name, and
4400 to return false upon finding an existing global entry. */
4402 static bool
4404 {
4415 else
4416 {
4421 }
4423 }
4426 /* Match an ENTRY statement. */
4428 match
4430 {
4435 gfc_compile_state state;
4436 match m;
4438 locus old_loc;
4441 match is_bind_c;
4449 {
4451 {
4496 }
4498 }
4508 {
4512 }
4514 /* Module function entries need special care in get_proc_name
4515 because previous references within the function will have
4516 created symbols attached to the current namespace. */
4519 && module_procedure
4525 /* Make sure that it isn't already declared as BIND(C). If it is, it
4526 must have been marked BIND(C) with a BIND(C) attribute and that is
4527 not allowed for procedures. */
4529 {
4535 else
4538 }
4540 /* Check what next non-whitespace character is so we can tell if there
4541 is the required parens if we have a BIND(C). */
4546 {
4547 /* An entry in a subroutine. */
4555 /* Call gfc_match_bind_c with allow_binding_name = true as ENTRY can
4556 never be an internal procedure. */
4561 {
4563 {
4566 }
4570 }
4575 }
4576 else
4577 {
4578 /* An entry in a function.
4579 We need to take special care because writing
4580 ENTRY f()
4581 as
4582 ENTRY f
4583 is allowed, whereas
4584 ENTRY f() RESULT (r)
4585 can't be written as
4586 ENTRY f RESULT (r). */
4592 {
4594 /* Match the empty argument list, and add the interface to
4595 the symbol. */
4597 }
4598 else
4607 {
4613 }
4614 else
4615 {
4623 {
4630 }
4631 else
4632 {
4637 }
4638 }
4639 }
4642 {
4645 }
4657 else
4664 }
4667 /* Match a subroutine statement, including optional prefixes. */
4669 match
4671 {
4674 match m;
4675 match is_bind_c;
4696 /* Check what next non-whitespace character is so we can tell if there
4697 is the required parens if we have a BIND(C). */
4707 /* Make sure that it isn't already declared as BIND(C). If it is, it
4708 must have been marked BIND(C) with a BIND(C) attribute and that is
4709 not allowed for procedures. */
4711 {
4717 else
4720 }
4722 /* C binding names are not allowed for internal procedures. */
4726 else
4729 /* Here, we are just checking if it has the bind(c) attribute, and if
4730 so, then we need to make sure it's all correct. If it doesn't,
4731 we still need to continue matching the rest of the subroutine line. */
4734 {
4735 /* There was an attempt at the bind(c), but it was wrong. An
4736 error message should have been printed w/in the gfc_match_bind_c
4737 so here we'll just return the MATCH_ERROR. */
4739 }
4742 {
4743 /* The following is allowed in the Fortran 2008 draft. */
4747 "at %L may not be specified for an internal "
4753 {
4756 }
4760 }
4763 {
4766 }
4772 }
4775 /* Match a BIND(C) specifier, with the optional 'name=' specifier if
4776 given, and set the binding label in either the given symbol (if not
4777 NULL), or in the current_ts. The symbol may be NULL because we may
4778 encounter the BIND(C) before the declaration itself. Return
4779 MATCH_NO if what we're looking at isn't a BIND(C) specifier,
4780 MATCH_ERROR if it is a BIND(C) clause but an error was encountered,
4781 or MATCH_YES if the specifier was correct and the binding label and
4782 bind(c) fields were set correctly for the given symbol or the
4783 current_ts. If allow_binding_name is false, no binding name may be
4784 given. */
4786 match
4788 {
4789 /* binding label, if exists */
4791 match double_quote;
4792 match single_quote;
4794 /* Initialize the flag that specifies whether we encountered a NAME=
4795 specifier or not. */
4798 /* Init the first char to nil so we can catch if we don't have
4799 the label (name attr) or the symbol name yet. */
4802 /* This much we have to be able to match, in this order, if
4803 there is a bind(c) label. */
4807 /* Now see if there is a binding label, or if we've reached the
4808 end of the bind(c) attribute without one. */
4810 {
4812 {
4815 /* should give an error message here */
4817 }
4821 /* Get the opening quote. */
4828 {
4832 }
4834 /* Grab the binding label, using functions that will not lower
4835 case the names automatically. */
4839 /* Get the closing quotation. */
4841 {
4843 {
4845 /* User started string with '"' so looked to match it. */
4847 }
4848 }
4849 else
4850 {
4852 {
4854 /* User started string with "'" char. */
4856 }
4857 }
4858 }
4860 /* Get the required right paren. */
4862 {
4865 }
4868 {
4871 }
4874 {
4878 }
4881 /* Save the binding label to the symbol. If sym is null, we're
4882 probably matching the typespec attributes of a declaration and
4883 haven't gotten the name yet, and therefore, no symbol yet. */
4885 {
4887 {
4889 }
4890 else
4892 }
4894 {
4895 /* No binding label, but if symbol isn't null, we
4896 can set the label for it here.
4897 If name="" or allow_binding_name is false, no C binding name is
4898 created. */
4901 }
4905 {
4908 }
4911 }
4914 /* Return nonzero if we're currently compiling a contained procedure. */
4916 static int
4918 {
4926 }
4928 /* Set the kind of each enumerator. The kind is selected such that it is
4929 interoperable with the corresponding C enumeration type, making
4930 sure that -fshort-enums is honored. */
4932 static void
4934 {
4946 do
4947 {
4949 }
4956 {
4959 }
4960 }
4963 /* Match any of the various end-block statements. Returns the type of
4964 END to the caller. The END INTERFACE, END IF, END DO and END
4965 SELECT statements cannot be replaced by a single END statement. */
4967 match
4969 {
4971 gfc_compile_state state;
4972 locus old_loc;
4976 match m;
4987 {
4991 }
4994 {
5080 }
5083 {
5085 {
5086 /* We would have required END [something]. */
5090 }
5093 }
5095 /* Verify that we've got the sort of end-block that we're expecting. */
5097 {
5100 }
5102 /* If we're at the end, make sure a block name wasn't required. */
5104 {
5117 }
5119 /* END INTERFACE has a special handler for its several possible endings. */
5123 /* We haven't hit the end of statement, so what is left must be an
5124 end-name. */
5138 {
5142 }
5147 syntax:
5150 cleanup:
5153 }
5157 /***************** Attribute declaration statements ****************/
5159 /* Set the attribute of a single variable. */
5161 static match
5163 {
5167 locus var_locus;
5168 match m;
5181 /* Deal with possible array specification for certain attributes. */
5186 {
5192 {
5197 }
5200 {
5205 }
5209 {
5213 }
5214 }
5216 /* Update symbol table. DIMENSION attribute is set
5217 in gfc_set_array_spec(). */
5220 {
5223 }
5226 {
5229 }
5232 {
5233 /* Fix the array spec. */
5237 }
5240 {
5243 }
5248 {
5251 }
5255 cleanup:
5258 }
5261 /* Generic attribute declaration subroutine. Used for attributes that
5262 just have a list of names. */
5264 static match
5266 {
5267 match m;
5269 /* Gobble the optional double colon, by simply ignoring the result
5270 of gfc_match(). */
5274 {
5280 {
5283 }
5286 {
5290 }
5291 }
5294 }
5297 /* This routine matches Cray Pointer declarations of the form:
5298 pointer ( <pointer>, <pointee> )
5299 or
5300 pointer ( <pointer1>, <pointee1> ), ( <pointer2>, <pointee2> ), ...
5301 The pointer, if already declared, should be an integer. Otherwise, we
5302 set it as BT_INTEGER with kind gfc_index_integer_kind. The pointee may
5303 be either a scalar, or an array declaration. No space is allocated for
5304 the pointee. For the statement
5305 pointer (ipt, ar(10))
5306 any subsequent uses of ar will be translated (in C-notation) as
5307 ar(i) => ((<type> *) ipt)(i)
5308 After gimplification, pointee variable will disappear in the code. */
5310 static match
5312 {
5313 match m;
5317 locus var_locus;
5321 {
5323 {
5326 }
5328 /* Match pointer. */
5337 {
5340 }
5348 {
5351 }
5353 {
5356 }
5363 {
5366 }
5368 /* Match Pointee. */
5377 {
5380 }
5382 /* Check for an optional array spec. */
5385 {
5388 }
5390 {
5393 }
5401 {
5404 }
5406 {
5410 }
5415 {
5416 /* Fix array spec. */
5420 }
5422 /* Point the Pointee at the Pointer. */
5426 {
5429 }
5434 }
5438 {
5441 }
5443 }
5446 match
5448 {
5454 }
5457 match
5459 {
5460 sym_intent intent;
5470 }
5473 match
5475 {
5481 }
5484 match
5486 {
5492 }
5495 match
5497 {
5500 {
5502 {
5506 }
5508 }
5509 else
5510 {
5515 }
5516 }
5519 match
5521 {
5526 }
5529 match
5531 {
5536 }
5539 match
5541 {
5546 }
5549 /* Match the list of entities being specified in a PUBLIC or PRIVATE
5550 statement. */
5552 static match
5554 {
5556 interface_type type;
5560 match m;
5566 {
5574 {
5592 {
5595 }
5596 else
5597 {
5601 }
5609 {
5612 }
5613 else
5614 {
5618 }
5621 }
5625 }
5631 syntax:
5634 done:
5636 }
5639 match
5641 {
5643 match m;
5646 {
5651 }
5658 {
5660 }
5666 {
5669 {
5681 }
5683 next_item:
5688 }
5692 syntax:
5695 }
5698 /* The PRIVATE statement is a bit weird in that it can be an attribute
5699 declaration, but also works as a standlone statement inside of a
5700 type declaration or a module. */
5702 match
5704 {
5713 {
5717 }
5720 {
5722 {
5725 }
5729 }
5732 {
5735 }
5739 }
5742 match
5744 {
5750 {
5754 }
5757 {
5760 }
5764 }
5767 /* Workhorse for gfc_match_parameter. */
5769 static match
5771 {
5774 match m;
5784 {
5787 }
5797 {
5800 }
5804 {
5807 }
5810 {
5814 }
5829 cleanup:
5832 }
5835 /* Match a parameter statement, with the weird syntax that these have. */
5837 match
5839 {
5840 match m;
5846 {
5855 {
5859 }
5860 }
5863 }
5866 /* Save statements have a special syntax. */
5868 match
5870 {
5874 match m;
5877 {
5879 {
5884 }
5888 }
5891 {
5896 }
5901 {
5904 {
5916 }
5929 next_item:
5934 }
5938 syntax:
5941 }
5944 match
5946 {
5948 match m;
5955 {
5957 }
5963 {
5966 {
5978 }
5980 next_item:
5985 }
5989 syntax:
5992 }
5995 match
5997 {
5999 match m;
6006 {
6008 }
6014 {
6015 /* VOLATILE is special because it can be added to host-associated
6016 symbols locally. */
6019 {
6031 }
6033 next_item:
6038 }
6042 syntax:
6045 }
6048 /* Match a module procedure statement. Note that we have to modify
6049 symbols in the parent's namespace because the current one was there
6050 to receive symbols that are in an interface's formal argument list. */
6052 match
6054 {
6057 match m;
6065 {
6069 }
6079 /* Store the current state of the interface. We will need it if we
6080 end up with a syntax error and need to recover. */
6084 {
6093 /* Check for syntax error before starting to add symbols to the
6094 current namespace. */
6100 /* Now we're sure the syntax is valid, we process this item
6101 further. */
6117 }
6121 syntax:
6122 /* Restore the previous state of the interface. */
6126 /* Free the new interfaces. */
6128 {
6132 }
6134 /* And issue a syntax error. */
6137 }
6140 /* Match the optional attribute specifiers for a type declaration.
6141 Return MATCH_ERROR if an error is encountered in one of the handled
6142 attributes (public, private, bind(c)), MATCH_NO if what's found is
6143 not a handled attribute, and MATCH_YES otherwise. TODO: More error
6144 checking on attribute conflicts needs to be done. */
6146 match
6148 {
6149 /* See if the derived type is marked as private. */
6151 {
6153 {
6157 }
6161 }
6163 {
6165 {
6169 }
6173 }
6175 {
6176 /* If the type is defined to be bind(c) it then needs to make
6177 sure that all fields are interoperable. This will
6178 need to be a semantic check on the finished derived type.
6179 See 15.2.3 (lines 9-12) of F2003 draft. */
6183 /* TODO: attr conflicts need to be checked, probably in symbol.c. */
6184 }
6185 else
6188 /* If we get here, something matched. */
6190 }
6193 /* Match the beginning of a derived type declaration. If a type name
6194 was the result of a function, then it is possible to have a symbol
6195 already to be known as a derived type yet have no components. */
6197 match
6199 {
6201 symbol_attribute attr;
6203 match m;
6212 do
6213 {
6222 {
6225 }
6231 /* Make sure the name is not the name of an intrinsic type. */
6233 {
6237 }
6243 {
6247 }
6249 /* The symbol may already have the derived attribute without the
6250 components. The ways this can happen is via a function
6251 definition, an INTRINSIC statement or a subtype in another
6252 derived type that is a pointer. The first part of the AND clause
6253 is true if a the symbol is not the return value of a function. */
6259 {
6263 }
6269 /* See if the derived type was labeled as bind(c). */
6276 }
6279 /* Cray Pointees can be declared as:
6280 pointer (ipt, a (n,m,...,*))
6281 By default, this is treated as an AS_ASSUMED_SIZE array. We'll
6282 cheat and set a constant bound of 1 for the last dimension, if this
6283 is the case. Since there is no bounds-checking for Cray Pointees,
6284 this will be okay. */
6286 try
6288 {
6291 {
6295 }
6297 {
6300 }
6302 }
6305 /* Match the enum definition statement, here we are trying to match
6306 the first line of enum definition statement.
6307 Returns MATCH_YES if match is found. */
6309 match
6311 {
6312 match m;
6323 }
6326 /* Match a variable name with an optional initializer. When this
6327 subroutine is called, a variable is expected to be parsed next.
6328 Depending on what is happening at the moment, updates either the
6329 symbol table or the current interface. */
6331 static match
6333 {
6338 locus var_locus;
6339 match m;
6341 locus old_locus;
6346 /* When we get here, we've just matched a list of attributes and
6347 maybe a type and a double colon. The next thing we expect to see
6348 is the name of the symbol. */
6355 /* OK, we've successfully matched the declaration. Now put the
6356 symbol in the current namespace. If we fail to create the symbol,
6357 bail out. */
6359 {
6362 }
6364 /* The double colon must be present in order to have initializers.
6365 Otherwise the statement is ambiguous with an assignment statement. */
6367 {
6369 {
6372 {
6375 }
6379 }
6380 }
6382 /* If we do not have an initializer, the initialization value of the
6383 previous enumerator (stored in last_initializer) is incremented
6384 by 1 and is used to initialize the current enumerator. */
6389 {
6395 }
6397 /* Store this current initializer, for the next enumerator variable
6398 to be parsed. add_init_expr_to_sym() zeros initializer, so we
6399 use last_initializer below. */
6403 /* Maintain enumerator history. */
6409 cleanup:
6410 /* Free stuff up and return. */
6414 }
6417 /* Match the enumerator definition statement. */
6419 match
6421 {
6422 match m;
6438 {
6442 }
6450 {
6453 }
6456 {
6467 }
6470 {
6474 }
6476 cleanup:
6481 }