1 /* Handle modules, which amounts to loading and saving symbols and
2 their attendant structures.
3 Copyright (C) 2000-2017 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
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
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/>. */
22 /* The syntax of gfortran modules resembles that of lisp lists, i.e. a
23 sequence of atoms, which can be left or right parenthesis, names,
24 integers or strings. Parenthesis are always matched which allows
25 us to skip over sections at high speed without having to know
26 anything about the internal structure of the lists. A "name" is
27 usually a fortran 95 identifier, but can also start with '@' in
28 order to reference a hidden symbol.
30 The first line of a module is an informational message about what
31 created the module, the file it came from and when it was created.
32 The second line is a warning for people not to edit the module.
33 The rest of the module looks like:
35 ( ( <Interface info for UPLUS> )
36 ( <Interface info for UMINUS> )
39 ( ( <name of operator interface> <module of op interface> <i/f1> ... )
42 ( ( <name of generic interface> <module of generic interface> <i/f1> ... )
45 ( ( <common name> <symbol> <saved flag>)
51 ( <Symbol Number (in no particular order)>
53 <Module name of symbol>
54 ( <symbol information> )
63 In general, symbols refer to other symbols by their symbol number,
64 which are zero based. Symbols are written to the module in no
69 #include "coretypes.h"
73 #include "stringpool.h"
76 #include "parse.h" /* FIXME */
77 #include "constructor.h"
82 #define MODULE_EXTENSION ".mod"
83 #define SUBMODULE_EXTENSION ".smod"
85 /* Don't put any single quote (') in MOD_VERSION, if you want it to be
87 #define MOD_VERSION "14"
90 /* Structure that describes a position within a module file. */
99 /* Structure for list of symbols of intrinsic modules. */
112 P_UNKNOWN
= 0, P_OTHER
, P_NAMESPACE
, P_COMPONENT
, P_SYMBOL
116 /* The fixup structure lists pointers to pointers that have to
117 be updated when a pointer value becomes known. */
119 typedef struct fixup_t
122 struct fixup_t
*next
;
127 /* Structure for holding extra info needed for pointers being read. */
143 typedef struct pointer_info
145 BBT_HEADER (pointer_info
);
149 /* The first component of each member of the union is the pointer
156 void *pointer
; /* Member for doing pointer searches. */
161 char *true_name
, *module
, *binding_label
;
163 gfc_symtree
*symtree
;
164 enum gfc_rsym_state state
;
165 int ns
, referenced
, renamed
;
173 enum gfc_wsym_state state
;
182 #define gfc_get_pointer_info() XCNEW (pointer_info)
185 /* Local variables */
187 /* The gzFile for the module we're reading or writing. */
188 static gzFile module_fp
;
191 /* The name of the module we're reading (USE'ing) or writing. */
192 static const char *module_name
;
193 /* The name of the .smod file that the submodule will write to. */
194 static const char *submodule_name
;
196 /* Suppress the output of a .smod file by module, if no module
197 procedures have been seen. */
198 static bool no_module_procedures
;
200 static gfc_use_list
*module_list
;
202 /* If we're reading an intrinsic module, this is its ID. */
203 static intmod_id current_intmod
;
205 /* Content of module. */
206 static char* module_content
;
208 static long module_pos
;
209 static int module_line
, module_column
, only_flag
;
210 static int prev_module_line
, prev_module_column
;
213 { IO_INPUT
, IO_OUTPUT
}
216 static gfc_use_rename
*gfc_rename_list
;
217 static pointer_info
*pi_root
;
218 static int symbol_number
; /* Counter for assigning symbol numbers */
220 /* Tells mio_expr_ref to make symbols for unused equivalence members. */
221 static bool in_load_equiv
;
225 /*****************************************************************/
227 /* Pointer/integer conversion. Pointers between structures are stored
228 as integers in the module file. The next couple of subroutines
229 handle this translation for reading and writing. */
231 /* Recursively free the tree of pointer structures. */
234 free_pi_tree (pointer_info
*p
)
239 if (p
->fixup
!= NULL
)
240 gfc_internal_error ("free_pi_tree(): Unresolved fixup");
242 free_pi_tree (p
->left
);
243 free_pi_tree (p
->right
);
245 if (iomode
== IO_INPUT
)
247 XDELETEVEC (p
->u
.rsym
.true_name
);
248 XDELETEVEC (p
->u
.rsym
.module
);
249 XDELETEVEC (p
->u
.rsym
.binding_label
);
256 /* Compare pointers when searching by pointer. Used when writing a
260 compare_pointers (void *_sn1
, void *_sn2
)
262 pointer_info
*sn1
, *sn2
;
264 sn1
= (pointer_info
*) _sn1
;
265 sn2
= (pointer_info
*) _sn2
;
267 if (sn1
->u
.pointer
< sn2
->u
.pointer
)
269 if (sn1
->u
.pointer
> sn2
->u
.pointer
)
276 /* Compare integers when searching by integer. Used when reading a
280 compare_integers (void *_sn1
, void *_sn2
)
282 pointer_info
*sn1
, *sn2
;
284 sn1
= (pointer_info
*) _sn1
;
285 sn2
= (pointer_info
*) _sn2
;
287 if (sn1
->integer
< sn2
->integer
)
289 if (sn1
->integer
> sn2
->integer
)
296 /* Initialize the pointer_info tree. */
305 compare
= (iomode
== IO_INPUT
) ? compare_integers
: compare_pointers
;
307 /* Pointer 0 is the NULL pointer. */
308 p
= gfc_get_pointer_info ();
313 gfc_insert_bbt (&pi_root
, p
, compare
);
315 /* Pointer 1 is the current namespace. */
316 p
= gfc_get_pointer_info ();
317 p
->u
.pointer
= gfc_current_ns
;
319 p
->type
= P_NAMESPACE
;
321 gfc_insert_bbt (&pi_root
, p
, compare
);
327 /* During module writing, call here with a pointer to something,
328 returning the pointer_info node. */
330 static pointer_info
*
331 find_pointer (void *gp
)
338 if (p
->u
.pointer
== gp
)
340 p
= (gp
< p
->u
.pointer
) ? p
->left
: p
->right
;
347 /* Given a pointer while writing, returns the pointer_info tree node,
348 creating it if it doesn't exist. */
350 static pointer_info
*
351 get_pointer (void *gp
)
355 p
= find_pointer (gp
);
359 /* Pointer doesn't have an integer. Give it one. */
360 p
= gfc_get_pointer_info ();
363 p
->integer
= symbol_number
++;
365 gfc_insert_bbt (&pi_root
, p
, compare_pointers
);
371 /* Given an integer during reading, find it in the pointer_info tree,
372 creating the node if not found. */
374 static pointer_info
*
375 get_integer (int integer
)
385 c
= compare_integers (&t
, p
);
389 p
= (c
< 0) ? p
->left
: p
->right
;
395 p
= gfc_get_pointer_info ();
396 p
->integer
= integer
;
399 gfc_insert_bbt (&pi_root
, p
, compare_integers
);
405 /* Resolve any fixups using a known pointer. */
408 resolve_fixups (fixup_t
*f
, void *gp
)
421 /* Convert a string such that it starts with a lower-case character. Used
422 to convert the symtree name of a derived-type to the symbol name or to
423 the name of the associated generic function. */
426 gfc_dt_lower_string (const char *name
)
428 if (name
[0] != (char) TOLOWER ((unsigned char) name
[0]))
429 return gfc_get_string ("%c%s", (char) TOLOWER ((unsigned char) name
[0]),
431 return gfc_get_string (name
);
435 /* Convert a string such that it starts with an upper-case character. Used to
436 return the symtree-name for a derived type; the symbol name itself and the
437 symtree/symbol name of the associated generic function start with a lower-
441 gfc_dt_upper_string (const char *name
)
443 if (name
[0] != (char) TOUPPER ((unsigned char) name
[0]))
444 return gfc_get_string ("%c%s", (char) TOUPPER ((unsigned char) name
[0]),
446 return gfc_get_string (name
);
449 /* Call here during module reading when we know what pointer to
450 associate with an integer. Any fixups that exist are resolved at
454 associate_integer_pointer (pointer_info
*p
, void *gp
)
456 if (p
->u
.pointer
!= NULL
)
457 gfc_internal_error ("associate_integer_pointer(): Already associated");
461 resolve_fixups (p
->fixup
, gp
);
467 /* During module reading, given an integer and a pointer to a pointer,
468 either store the pointer from an already-known value or create a
469 fixup structure in order to store things later. Returns zero if
470 the reference has been actually stored, or nonzero if the reference
471 must be fixed later (i.e., associate_integer_pointer must be called
472 sometime later. Returns the pointer_info structure. */
474 static pointer_info
*
475 add_fixup (int integer
, void *gp
)
481 p
= get_integer (integer
);
483 if (p
->integer
== 0 || p
->u
.pointer
!= NULL
)
486 *cp
= (char *) p
->u
.pointer
;
495 f
->pointer
= (void **) gp
;
502 /*****************************************************************/
504 /* Parser related subroutines */
506 /* Free the rename list left behind by a USE statement. */
509 free_rename (gfc_use_rename
*list
)
511 gfc_use_rename
*next
;
513 for (; list
; list
= next
)
521 /* Match a USE statement. */
526 char name
[GFC_MAX_SYMBOL_LEN
+ 1], module_nature
[GFC_MAX_SYMBOL_LEN
+ 1];
527 gfc_use_rename
*tail
= NULL
, *new_use
;
528 interface_type type
, type2
;
531 gfc_use_list
*use_list
;
533 use_list
= gfc_get_use_list ();
535 if (gfc_match (" , ") == MATCH_YES
)
537 if ((m
= gfc_match (" %n ::", module_nature
)) == MATCH_YES
)
539 if (!gfc_notify_std (GFC_STD_F2003
, "module "
540 "nature in USE statement at %C"))
543 if (strcmp (module_nature
, "intrinsic") == 0)
544 use_list
->intrinsic
= true;
547 if (strcmp (module_nature
, "non_intrinsic") == 0)
548 use_list
->non_intrinsic
= true;
551 gfc_error ("Module nature in USE statement at %C shall "
552 "be either INTRINSIC or NON_INTRINSIC");
559 /* Help output a better error message than "Unclassifiable
561 gfc_match (" %n", module_nature
);
562 if (strcmp (module_nature
, "intrinsic") == 0
563 || strcmp (module_nature
, "non_intrinsic") == 0)
564 gfc_error ("\"::\" was expected after module nature at %C "
565 "but was not found");
572 m
= gfc_match (" ::");
573 if (m
== MATCH_YES
&&
574 !gfc_notify_std(GFC_STD_F2003
, "\"USE :: module\" at %C"))
579 m
= gfc_match ("% ");
588 use_list
->where
= gfc_current_locus
;
590 m
= gfc_match_name (name
);
597 use_list
->module_name
= gfc_get_string (name
);
599 if (gfc_match_eos () == MATCH_YES
)
602 if (gfc_match_char (',') != MATCH_YES
)
605 if (gfc_match (" only :") == MATCH_YES
)
606 use_list
->only_flag
= true;
608 if (gfc_match_eos () == MATCH_YES
)
613 /* Get a new rename struct and add it to the rename list. */
614 new_use
= gfc_get_use_rename ();
615 new_use
->where
= gfc_current_locus
;
618 if (use_list
->rename
== NULL
)
619 use_list
->rename
= new_use
;
621 tail
->next
= new_use
;
624 /* See what kind of interface we're dealing with. Assume it is
626 new_use
->op
= INTRINSIC_NONE
;
627 if (gfc_match_generic_spec (&type
, name
, &op
) == MATCH_ERROR
)
632 case INTERFACE_NAMELESS
:
633 gfc_error ("Missing generic specification in USE statement at %C");
636 case INTERFACE_USER_OP
:
637 case INTERFACE_GENERIC
:
638 m
= gfc_match (" =>");
640 if (type
== INTERFACE_USER_OP
&& m
== MATCH_YES
641 && (!gfc_notify_std(GFC_STD_F2003
, "Renaming "
642 "operators in USE statements at %C")))
645 if (type
== INTERFACE_USER_OP
)
646 new_use
->op
= INTRINSIC_USER
;
648 if (use_list
->only_flag
)
651 strcpy (new_use
->use_name
, name
);
654 strcpy (new_use
->local_name
, name
);
655 m
= gfc_match_generic_spec (&type2
, new_use
->use_name
, &op
);
660 if (m
== MATCH_ERROR
)
668 strcpy (new_use
->local_name
, name
);
670 m
= gfc_match_generic_spec (&type2
, new_use
->use_name
, &op
);
675 if (m
== MATCH_ERROR
)
679 if (strcmp (new_use
->use_name
, use_list
->module_name
) == 0
680 || strcmp (new_use
->local_name
, use_list
->module_name
) == 0)
682 gfc_error ("The name %qs at %C has already been used as "
683 "an external module name.", use_list
->module_name
);
688 case INTERFACE_INTRINSIC_OP
:
696 if (gfc_match_eos () == MATCH_YES
)
698 if (gfc_match_char (',') != MATCH_YES
)
705 gfc_use_list
*last
= module_list
;
708 last
->next
= use_list
;
711 module_list
= use_list
;
716 gfc_syntax_error (ST_USE
);
719 free_rename (use_list
->rename
);
725 /* Match a SUBMODULE statement.
727 According to F2008:11.2.3.2, "The submodule identifier is the
728 ordered pair whose first element is the ancestor module name and
729 whose second element is the submodule name. 'Submodule_name' is
730 used for the submodule filename and uses '@' as a separator, whilst
731 the name of the symbol for the module uses '.' as a a separator.
732 The reasons for these choices are:
733 (i) To follow another leading brand in the submodule filenames;
734 (ii) Since '.' is not particularly visible in the filenames; and
735 (iii) The linker does not permit '@' in mnemonics. */
738 gfc_match_submodule (void)
741 char name
[GFC_MAX_SYMBOL_LEN
+ 1];
742 gfc_use_list
*use_list
;
743 bool seen_colon
= false;
745 if (!gfc_notify_std (GFC_STD_F2008
, "SUBMODULE declaration at %C"))
748 gfc_new_block
= NULL
;
749 gcc_assert (module_list
== NULL
);
751 if (gfc_match_char ('(') != MATCH_YES
)
756 m
= gfc_match (" %n", name
);
760 use_list
= gfc_get_use_list ();
761 use_list
->where
= gfc_current_locus
;
765 gfc_use_list
*last
= module_list
;
768 last
->next
= use_list
;
769 use_list
->module_name
770 = gfc_get_string ("%s.%s", module_list
->module_name
, name
);
771 use_list
->submodule_name
772 = gfc_get_string ("%s@%s", module_list
->module_name
, name
);
776 module_list
= use_list
;
777 use_list
->module_name
= gfc_get_string (name
);
778 use_list
->submodule_name
= use_list
->module_name
;
781 if (gfc_match_char (')') == MATCH_YES
)
784 if (gfc_match_char (':') != MATCH_YES
791 m
= gfc_match (" %s%t", &gfc_new_block
);
795 submodule_name
= gfc_get_string ("%s@%s", module_list
->module_name
,
796 gfc_new_block
->name
);
798 gfc_new_block
->name
= gfc_get_string ("%s.%s",
799 module_list
->module_name
,
800 gfc_new_block
->name
);
802 if (!gfc_add_flavor (&gfc_new_block
->attr
, FL_MODULE
,
803 gfc_new_block
->name
, NULL
))
806 /* Just retain the ultimate .(s)mod file for reading, since it
807 contains all the information in its ancestors. */
808 use_list
= module_list
;
809 for (; module_list
->next
; use_list
= module_list
)
811 module_list
= use_list
->next
;
818 gfc_error ("Syntax error in SUBMODULE statement at %C");
823 /* Given a name and a number, inst, return the inst name
824 under which to load this symbol. Returns NULL if this
825 symbol shouldn't be loaded. If inst is zero, returns
826 the number of instances of this name. If interface is
827 true, a user-defined operator is sought, otherwise only
828 non-operators are sought. */
831 find_use_name_n (const char *name
, int *inst
, bool interface
)
834 const char *low_name
= NULL
;
837 /* For derived types. */
838 if (name
[0] != (char) TOLOWER ((unsigned char) name
[0]))
839 low_name
= gfc_dt_lower_string (name
);
842 for (u
= gfc_rename_list
; u
; u
= u
->next
)
844 if ((!low_name
&& strcmp (u
->use_name
, name
) != 0)
845 || (low_name
&& strcmp (u
->use_name
, low_name
) != 0)
846 || (u
->op
== INTRINSIC_USER
&& !interface
)
847 || (u
->op
!= INTRINSIC_USER
&& interface
))
860 return only_flag
? NULL
: name
;
866 if (u
->local_name
[0] == '\0')
868 return gfc_dt_upper_string (u
->local_name
);
871 return (u
->local_name
[0] != '\0') ? u
->local_name
: name
;
875 /* Given a name, return the name under which to load this symbol.
876 Returns NULL if this symbol shouldn't be loaded. */
879 find_use_name (const char *name
, bool interface
)
882 return find_use_name_n (name
, &i
, interface
);
886 /* Given a real name, return the number of use names associated with it. */
889 number_use_names (const char *name
, bool interface
)
892 find_use_name_n (name
, &i
, interface
);
897 /* Try to find the operator in the current list. */
899 static gfc_use_rename
*
900 find_use_operator (gfc_intrinsic_op op
)
904 for (u
= gfc_rename_list
; u
; u
= u
->next
)
912 /*****************************************************************/
914 /* The next couple of subroutines maintain a tree used to avoid a
915 brute-force search for a combination of true name and module name.
916 While symtree names, the name that a particular symbol is known by
917 can changed with USE statements, we still have to keep track of the
918 true names to generate the correct reference, and also avoid
919 loading the same real symbol twice in a program unit.
921 When we start reading, the true name tree is built and maintained
922 as symbols are read. The tree is searched as we load new symbols
923 to see if it already exists someplace in the namespace. */
925 typedef struct true_name
927 BBT_HEADER (true_name
);
933 static true_name
*true_name_root
;
936 /* Compare two true_name structures. */
939 compare_true_names (void *_t1
, void *_t2
)
944 t1
= (true_name
*) _t1
;
945 t2
= (true_name
*) _t2
;
947 c
= ((t1
->sym
->module
> t2
->sym
->module
)
948 - (t1
->sym
->module
< t2
->sym
->module
));
952 return strcmp (t1
->name
, t2
->name
);
956 /* Given a true name, search the true name tree to see if it exists
957 within the main namespace. */
960 find_true_name (const char *name
, const char *module
)
966 t
.name
= gfc_get_string (name
);
968 sym
.module
= gfc_get_string (module
);
976 c
= compare_true_names ((void *) (&t
), (void *) p
);
980 p
= (c
< 0) ? p
->left
: p
->right
;
987 /* Given a gfc_symbol pointer that is not in the true name tree, add it. */
990 add_true_name (gfc_symbol
*sym
)
994 t
= XCNEW (true_name
);
996 if (gfc_fl_struct (sym
->attr
.flavor
))
997 t
->name
= gfc_dt_upper_string (sym
->name
);
1001 gfc_insert_bbt (&true_name_root
, t
, compare_true_names
);
1005 /* Recursive function to build the initial true name tree by
1006 recursively traversing the current namespace. */
1009 build_tnt (gfc_symtree
*st
)
1015 build_tnt (st
->left
);
1016 build_tnt (st
->right
);
1018 if (gfc_fl_struct (st
->n
.sym
->attr
.flavor
))
1019 name
= gfc_dt_upper_string (st
->n
.sym
->name
);
1021 name
= st
->n
.sym
->name
;
1023 if (find_true_name (name
, st
->n
.sym
->module
) != NULL
)
1026 add_true_name (st
->n
.sym
);
1030 /* Initialize the true name tree with the current namespace. */
1033 init_true_name_tree (void)
1035 true_name_root
= NULL
;
1036 build_tnt (gfc_current_ns
->sym_root
);
1040 /* Recursively free a true name tree node. */
1043 free_true_name (true_name
*t
)
1047 free_true_name (t
->left
);
1048 free_true_name (t
->right
);
1054 /*****************************************************************/
1056 /* Module reading and writing. */
1058 /* The following are versions similar to the ones in scanner.c, but
1059 for dealing with compressed module files. */
1062 gzopen_included_file_1 (const char *name
, gfc_directorylist
*list
,
1063 bool module
, bool system
)
1066 gfc_directorylist
*p
;
1069 for (p
= list
; p
; p
= p
->next
)
1071 if (module
&& !p
->use_for_modules
)
1074 fullname
= (char *) alloca(strlen (p
->path
) + strlen (name
) + 1);
1075 strcpy (fullname
, p
->path
);
1076 strcat (fullname
, name
);
1078 f
= gzopen (fullname
, "r");
1081 if (gfc_cpp_makedep ())
1082 gfc_cpp_add_dep (fullname
, system
);
1092 gzopen_included_file (const char *name
, bool include_cwd
, bool module
)
1096 if (IS_ABSOLUTE_PATH (name
) || include_cwd
)
1098 f
= gzopen (name
, "r");
1099 if (f
&& gfc_cpp_makedep ())
1100 gfc_cpp_add_dep (name
, false);
1104 f
= gzopen_included_file_1 (name
, include_dirs
, module
, false);
1110 gzopen_intrinsic_module (const char* name
)
1114 if (IS_ABSOLUTE_PATH (name
))
1116 f
= gzopen (name
, "r");
1117 if (f
&& gfc_cpp_makedep ())
1118 gfc_cpp_add_dep (name
, true);
1122 f
= gzopen_included_file_1 (name
, intrinsic_modules_dirs
, true, true);
1130 ATOM_NAME
, ATOM_LPAREN
, ATOM_RPAREN
, ATOM_INTEGER
, ATOM_STRING
1133 static atom_type last_atom
;
1136 /* The name buffer must be at least as long as a symbol name. Right
1137 now it's not clear how we're going to store numeric constants--
1138 probably as a hexadecimal string, since this will allow the exact
1139 number to be preserved (this can't be done by a decimal
1140 representation). Worry about that later. TODO! */
1142 #define MAX_ATOM_SIZE 100
1144 static int atom_int
;
1145 static char *atom_string
, atom_name
[MAX_ATOM_SIZE
];
1148 /* Report problems with a module. Error reporting is not very
1149 elaborate, since this sorts of errors shouldn't really happen.
1150 This subroutine never returns. */
1152 static void bad_module (const char *) ATTRIBUTE_NORETURN
;
1155 bad_module (const char *msgid
)
1157 XDELETEVEC (module_content
);
1158 module_content
= NULL
;
1163 gfc_fatal_error ("Reading module %qs at line %d column %d: %s",
1164 module_name
, module_line
, module_column
, msgid
);
1167 gfc_fatal_error ("Writing module %qs at line %d column %d: %s",
1168 module_name
, module_line
, module_column
, msgid
);
1171 gfc_fatal_error ("Module %qs at line %d column %d: %s",
1172 module_name
, module_line
, module_column
, msgid
);
1178 /* Set the module's input pointer. */
1181 set_module_locus (module_locus
*m
)
1183 module_column
= m
->column
;
1184 module_line
= m
->line
;
1185 module_pos
= m
->pos
;
1189 /* Get the module's input pointer so that we can restore it later. */
1192 get_module_locus (module_locus
*m
)
1194 m
->column
= module_column
;
1195 m
->line
= module_line
;
1196 m
->pos
= module_pos
;
1200 /* Get the next character in the module, updating our reckoning of
1206 const char c
= module_content
[module_pos
++];
1208 bad_module ("Unexpected EOF");
1210 prev_module_line
= module_line
;
1211 prev_module_column
= module_column
;
1223 /* Unget a character while remembering the line and column. Works for
1224 a single character only. */
1227 module_unget_char (void)
1229 module_line
= prev_module_line
;
1230 module_column
= prev_module_column
;
1234 /* Parse a string constant. The delimiter is guaranteed to be a
1244 atom_string
= XNEWVEC (char, cursz
);
1252 int c2
= module_char ();
1255 module_unget_char ();
1263 atom_string
= XRESIZEVEC (char, atom_string
, cursz
);
1265 atom_string
[len
] = c
;
1269 atom_string
= XRESIZEVEC (char, atom_string
, len
+ 1);
1270 atom_string
[len
] = '\0'; /* C-style string for debug purposes. */
1274 /* Parse a small integer. */
1277 parse_integer (int c
)
1286 module_unget_char ();
1290 atom_int
= 10 * atom_int
+ c
- '0';
1291 if (atom_int
> 99999999)
1292 bad_module ("Integer overflow");
1314 if (!ISALNUM (c
) && c
!= '_' && c
!= '-')
1316 module_unget_char ();
1321 if (++len
> GFC_MAX_SYMBOL_LEN
)
1322 bad_module ("Name too long");
1330 /* Read the next atom in the module's input stream. */
1341 while (c
== ' ' || c
== '\r' || c
== '\n');
1366 return ATOM_INTEGER
;
1424 bad_module ("Bad name");
1431 /* Peek at the next atom on the input. */
1442 while (c
== ' ' || c
== '\r' || c
== '\n');
1447 module_unget_char ();
1451 module_unget_char ();
1455 module_unget_char ();
1468 module_unget_char ();
1469 return ATOM_INTEGER
;
1523 module_unget_char ();
1527 bad_module ("Bad name");
1532 /* Read the next atom from the input, requiring that it be a
1536 require_atom (atom_type type
)
1542 column
= module_column
;
1551 p
= _("Expected name");
1554 p
= _("Expected left parenthesis");
1557 p
= _("Expected right parenthesis");
1560 p
= _("Expected integer");
1563 p
= _("Expected string");
1566 gfc_internal_error ("require_atom(): bad atom type required");
1569 module_column
= column
;
1576 /* Given a pointer to an mstring array, require that the current input
1577 be one of the strings in the array. We return the enum value. */
1580 find_enum (const mstring
*m
)
1584 i
= gfc_string2code (m
, atom_name
);
1588 bad_module ("find_enum(): Enum not found");
1594 /* Read a string. The caller is responsible for freeing. */
1600 require_atom (ATOM_STRING
);
1607 /**************** Module output subroutines ***************************/
1609 /* Output a character to a module file. */
1612 write_char (char out
)
1614 if (gzputc (module_fp
, out
) == EOF
)
1615 gfc_fatal_error ("Error writing modules file: %s", xstrerror (errno
));
1627 /* Write an atom to a module. The line wrapping isn't perfect, but it
1628 should work most of the time. This isn't that big of a deal, since
1629 the file really isn't meant to be read by people anyway. */
1632 write_atom (atom_type atom
, const void *v
)
1636 /* Workaround -Wmaybe-uninitialized false positive during
1637 profiledbootstrap by initializing them. */
1645 p
= (const char *) v
;
1657 i
= *((const int *) v
);
1659 gfc_internal_error ("write_atom(): Writing negative integer");
1661 sprintf (buffer
, "%d", i
);
1666 gfc_internal_error ("write_atom(): Trying to write dab atom");
1670 if(p
== NULL
|| *p
== '\0')
1675 if (atom
!= ATOM_RPAREN
)
1677 if (module_column
+ len
> 72)
1682 if (last_atom
!= ATOM_LPAREN
&& module_column
!= 1)
1687 if (atom
== ATOM_STRING
)
1690 while (p
!= NULL
&& *p
)
1692 if (atom
== ATOM_STRING
&& *p
== '\'')
1697 if (atom
== ATOM_STRING
)
1705 /***************** Mid-level I/O subroutines *****************/
1707 /* These subroutines let their caller read or write atoms without
1708 caring about which of the two is actually happening. This lets a
1709 subroutine concentrate on the actual format of the data being
1712 static void mio_expr (gfc_expr
**);
1713 pointer_info
*mio_symbol_ref (gfc_symbol
**);
1714 pointer_info
*mio_interface_rest (gfc_interface
**);
1715 static void mio_symtree_ref (gfc_symtree
**);
1717 /* Read or write an enumerated value. On writing, we return the input
1718 value for the convenience of callers. We avoid using an integer
1719 pointer because enums are sometimes inside bitfields. */
1722 mio_name (int t
, const mstring
*m
)
1724 if (iomode
== IO_OUTPUT
)
1725 write_atom (ATOM_NAME
, gfc_code2string (m
, t
));
1728 require_atom (ATOM_NAME
);
1735 /* Specialization of mio_name. */
1737 #define DECL_MIO_NAME(TYPE) \
1738 static inline TYPE \
1739 MIO_NAME(TYPE) (TYPE t, const mstring *m) \
1741 return (TYPE) mio_name ((int) t, m); \
1743 #define MIO_NAME(TYPE) mio_name_##TYPE
1748 if (iomode
== IO_OUTPUT
)
1749 write_atom (ATOM_LPAREN
, NULL
);
1751 require_atom (ATOM_LPAREN
);
1758 if (iomode
== IO_OUTPUT
)
1759 write_atom (ATOM_RPAREN
, NULL
);
1761 require_atom (ATOM_RPAREN
);
1766 mio_integer (int *ip
)
1768 if (iomode
== IO_OUTPUT
)
1769 write_atom (ATOM_INTEGER
, ip
);
1772 require_atom (ATOM_INTEGER
);
1778 /* Read or write a gfc_intrinsic_op value. */
1781 mio_intrinsic_op (gfc_intrinsic_op
* op
)
1783 /* FIXME: Would be nicer to do this via the operators symbolic name. */
1784 if (iomode
== IO_OUTPUT
)
1786 int converted
= (int) *op
;
1787 write_atom (ATOM_INTEGER
, &converted
);
1791 require_atom (ATOM_INTEGER
);
1792 *op
= (gfc_intrinsic_op
) atom_int
;
1797 /* Read or write a character pointer that points to a string on the heap. */
1800 mio_allocated_string (const char *s
)
1802 if (iomode
== IO_OUTPUT
)
1804 write_atom (ATOM_STRING
, s
);
1809 require_atom (ATOM_STRING
);
1815 /* Functions for quoting and unquoting strings. */
1818 quote_string (const gfc_char_t
*s
, const size_t slength
)
1820 const gfc_char_t
*p
;
1824 /* Calculate the length we'll need: a backslash takes two ("\\"),
1825 non-printable characters take 10 ("\Uxxxxxxxx") and others take 1. */
1826 for (p
= s
, i
= 0; i
< slength
; p
++, i
++)
1830 else if (!gfc_wide_is_printable (*p
))
1836 q
= res
= XCNEWVEC (char, len
+ 1);
1837 for (p
= s
, i
= 0; i
< slength
; p
++, i
++)
1840 *q
++ = '\\', *q
++ = '\\';
1841 else if (!gfc_wide_is_printable (*p
))
1843 sprintf (q
, "\\U%08" HOST_WIDE_INT_PRINT
"x",
1844 (unsigned HOST_WIDE_INT
) *p
);
1848 *q
++ = (unsigned char) *p
;
1856 unquote_string (const char *s
)
1862 for (p
= s
, len
= 0; *p
; p
++, len
++)
1869 else if (p
[1] == 'U')
1870 p
+= 9; /* That is a "\U????????". */
1872 gfc_internal_error ("unquote_string(): got bad string");
1875 res
= gfc_get_wide_string (len
+ 1);
1876 for (i
= 0, p
= s
; i
< len
; i
++, p
++)
1881 res
[i
] = (unsigned char) *p
;
1882 else if (p
[1] == '\\')
1884 res
[i
] = (unsigned char) '\\';
1889 /* We read the 8-digits hexadecimal constant that follows. */
1894 gcc_assert (p
[1] == 'U');
1895 for (j
= 0; j
< 8; j
++)
1898 gcc_assert (sscanf (&p
[j
+2], "%01x", &n
) == 1);
1912 /* Read or write a character pointer that points to a wide string on the
1913 heap, performing quoting/unquoting of nonprintable characters using the
1914 form \U???????? (where each ? is a hexadecimal digit).
1915 Length is the length of the string, only known and used in output mode. */
1917 static const gfc_char_t
*
1918 mio_allocated_wide_string (const gfc_char_t
*s
, const size_t length
)
1920 if (iomode
== IO_OUTPUT
)
1922 char *quoted
= quote_string (s
, length
);
1923 write_atom (ATOM_STRING
, quoted
);
1929 gfc_char_t
*unquoted
;
1931 require_atom (ATOM_STRING
);
1932 unquoted
= unquote_string (atom_string
);
1939 /* Read or write a string that is in static memory. */
1942 mio_pool_string (const char **stringp
)
1944 /* TODO: one could write the string only once, and refer to it via a
1947 /* As a special case we have to deal with a NULL string. This
1948 happens for the 'module' member of 'gfc_symbol's that are not in a
1949 module. We read / write these as the empty string. */
1950 if (iomode
== IO_OUTPUT
)
1952 const char *p
= *stringp
== NULL
? "" : *stringp
;
1953 write_atom (ATOM_STRING
, p
);
1957 require_atom (ATOM_STRING
);
1958 *stringp
= atom_string
[0] == '\0' ? NULL
: gfc_get_string (atom_string
);
1964 /* Read or write a string that is inside of some already-allocated
1968 mio_internal_string (char *string
)
1970 if (iomode
== IO_OUTPUT
)
1971 write_atom (ATOM_STRING
, string
);
1974 require_atom (ATOM_STRING
);
1975 strcpy (string
, atom_string
);
1982 { AB_ALLOCATABLE
, AB_DIMENSION
, AB_EXTERNAL
, AB_INTRINSIC
, AB_OPTIONAL
,
1983 AB_POINTER
, AB_TARGET
, AB_DUMMY
, AB_RESULT
, AB_DATA
,
1984 AB_IN_NAMELIST
, AB_IN_COMMON
, AB_FUNCTION
, AB_SUBROUTINE
, AB_SEQUENCE
,
1985 AB_ELEMENTAL
, AB_PURE
, AB_RECURSIVE
, AB_GENERIC
, AB_ALWAYS_EXPLICIT
,
1986 AB_CRAY_POINTER
, AB_CRAY_POINTEE
, AB_THREADPRIVATE
,
1987 AB_ALLOC_COMP
, AB_POINTER_COMP
, AB_PROC_POINTER_COMP
, AB_PRIVATE_COMP
,
1988 AB_VALUE
, AB_VOLATILE
, AB_PROTECTED
, AB_LOCK_COMP
, AB_EVENT_COMP
,
1989 AB_IS_BIND_C
, AB_IS_C_INTEROP
, AB_IS_ISO_C
, AB_ABSTRACT
, AB_ZERO_COMP
,
1990 AB_IS_CLASS
, AB_PROCEDURE
, AB_PROC_POINTER
, AB_ASYNCHRONOUS
, AB_CODIMENSION
,
1991 AB_COARRAY_COMP
, AB_VTYPE
, AB_VTAB
, AB_CONTIGUOUS
, AB_CLASS_POINTER
,
1992 AB_IMPLICIT_PURE
, AB_ARTIFICIAL
, AB_UNLIMITED_POLY
, AB_OMP_DECLARE_TARGET
,
1993 AB_ARRAY_OUTER_DEPENDENCY
, AB_MODULE_PROCEDURE
, AB_OACC_DECLARE_CREATE
,
1994 AB_OACC_DECLARE_COPYIN
, AB_OACC_DECLARE_DEVICEPTR
,
1995 AB_OACC_DECLARE_DEVICE_RESIDENT
, AB_OACC_DECLARE_LINK
,
1996 AB_OMP_DECLARE_TARGET_LINK
1999 static const mstring attr_bits
[] =
2001 minit ("ALLOCATABLE", AB_ALLOCATABLE
),
2002 minit ("ARTIFICIAL", AB_ARTIFICIAL
),
2003 minit ("ASYNCHRONOUS", AB_ASYNCHRONOUS
),
2004 minit ("DIMENSION", AB_DIMENSION
),
2005 minit ("CODIMENSION", AB_CODIMENSION
),
2006 minit ("CONTIGUOUS", AB_CONTIGUOUS
),
2007 minit ("EXTERNAL", AB_EXTERNAL
),
2008 minit ("INTRINSIC", AB_INTRINSIC
),
2009 minit ("OPTIONAL", AB_OPTIONAL
),
2010 minit ("POINTER", AB_POINTER
),
2011 minit ("VOLATILE", AB_VOLATILE
),
2012 minit ("TARGET", AB_TARGET
),
2013 minit ("THREADPRIVATE", AB_THREADPRIVATE
),
2014 minit ("DUMMY", AB_DUMMY
),
2015 minit ("RESULT", AB_RESULT
),
2016 minit ("DATA", AB_DATA
),
2017 minit ("IN_NAMELIST", AB_IN_NAMELIST
),
2018 minit ("IN_COMMON", AB_IN_COMMON
),
2019 minit ("FUNCTION", AB_FUNCTION
),
2020 minit ("SUBROUTINE", AB_SUBROUTINE
),
2021 minit ("SEQUENCE", AB_SEQUENCE
),
2022 minit ("ELEMENTAL", AB_ELEMENTAL
),
2023 minit ("PURE", AB_PURE
),
2024 minit ("RECURSIVE", AB_RECURSIVE
),
2025 minit ("GENERIC", AB_GENERIC
),
2026 minit ("ALWAYS_EXPLICIT", AB_ALWAYS_EXPLICIT
),
2027 minit ("CRAY_POINTER", AB_CRAY_POINTER
),
2028 minit ("CRAY_POINTEE", AB_CRAY_POINTEE
),
2029 minit ("IS_BIND_C", AB_IS_BIND_C
),
2030 minit ("IS_C_INTEROP", AB_IS_C_INTEROP
),
2031 minit ("IS_ISO_C", AB_IS_ISO_C
),
2032 minit ("VALUE", AB_VALUE
),
2033 minit ("ALLOC_COMP", AB_ALLOC_COMP
),
2034 minit ("COARRAY_COMP", AB_COARRAY_COMP
),
2035 minit ("LOCK_COMP", AB_LOCK_COMP
),
2036 minit ("EVENT_COMP", AB_EVENT_COMP
),
2037 minit ("POINTER_COMP", AB_POINTER_COMP
),
2038 minit ("PROC_POINTER_COMP", AB_PROC_POINTER_COMP
),
2039 minit ("PRIVATE_COMP", AB_PRIVATE_COMP
),
2040 minit ("ZERO_COMP", AB_ZERO_COMP
),
2041 minit ("PROTECTED", AB_PROTECTED
),
2042 minit ("ABSTRACT", AB_ABSTRACT
),
2043 minit ("IS_CLASS", AB_IS_CLASS
),
2044 minit ("PROCEDURE", AB_PROCEDURE
),
2045 minit ("PROC_POINTER", AB_PROC_POINTER
),
2046 minit ("VTYPE", AB_VTYPE
),
2047 minit ("VTAB", AB_VTAB
),
2048 minit ("CLASS_POINTER", AB_CLASS_POINTER
),
2049 minit ("IMPLICIT_PURE", AB_IMPLICIT_PURE
),
2050 minit ("UNLIMITED_POLY", AB_UNLIMITED_POLY
),
2051 minit ("OMP_DECLARE_TARGET", AB_OMP_DECLARE_TARGET
),
2052 minit ("ARRAY_OUTER_DEPENDENCY", AB_ARRAY_OUTER_DEPENDENCY
),
2053 minit ("MODULE_PROCEDURE", AB_MODULE_PROCEDURE
),
2054 minit ("OACC_DECLARE_CREATE", AB_OACC_DECLARE_CREATE
),
2055 minit ("OACC_DECLARE_COPYIN", AB_OACC_DECLARE_COPYIN
),
2056 minit ("OACC_DECLARE_DEVICEPTR", AB_OACC_DECLARE_DEVICEPTR
),
2057 minit ("OACC_DECLARE_DEVICE_RESIDENT", AB_OACC_DECLARE_DEVICE_RESIDENT
),
2058 minit ("OACC_DECLARE_LINK", AB_OACC_DECLARE_LINK
),
2059 minit ("OMP_DECLARE_TARGET_LINK", AB_OMP_DECLARE_TARGET_LINK
),
2063 /* For binding attributes. */
2064 static const mstring binding_passing
[] =
2067 minit ("NOPASS", 1),
2070 static const mstring binding_overriding
[] =
2072 minit ("OVERRIDABLE", 0),
2073 minit ("NON_OVERRIDABLE", 1),
2074 minit ("DEFERRED", 2),
2077 static const mstring binding_generic
[] =
2079 minit ("SPECIFIC", 0),
2080 minit ("GENERIC", 1),
2083 static const mstring binding_ppc
[] =
2085 minit ("NO_PPC", 0),
2090 /* Specialization of mio_name. */
2091 DECL_MIO_NAME (ab_attribute
)
2092 DECL_MIO_NAME (ar_type
)
2093 DECL_MIO_NAME (array_type
)
2095 DECL_MIO_NAME (expr_t
)
2096 DECL_MIO_NAME (gfc_access
)
2097 DECL_MIO_NAME (gfc_intrinsic_op
)
2098 DECL_MIO_NAME (ifsrc
)
2099 DECL_MIO_NAME (save_state
)
2100 DECL_MIO_NAME (procedure_type
)
2101 DECL_MIO_NAME (ref_type
)
2102 DECL_MIO_NAME (sym_flavor
)
2103 DECL_MIO_NAME (sym_intent
)
2104 #undef DECL_MIO_NAME
2106 /* Symbol attributes are stored in list with the first three elements
2107 being the enumerated fields, while the remaining elements (if any)
2108 indicate the individual attribute bits. The access field is not
2109 saved-- it controls what symbols are exported when a module is
2113 mio_symbol_attribute (symbol_attribute
*attr
)
2116 unsigned ext_attr
,extension_level
;
2120 attr
->flavor
= MIO_NAME (sym_flavor
) (attr
->flavor
, flavors
);
2121 attr
->intent
= MIO_NAME (sym_intent
) (attr
->intent
, intents
);
2122 attr
->proc
= MIO_NAME (procedure_type
) (attr
->proc
, procedures
);
2123 attr
->if_source
= MIO_NAME (ifsrc
) (attr
->if_source
, ifsrc_types
);
2124 attr
->save
= MIO_NAME (save_state
) (attr
->save
, save_status
);
2126 ext_attr
= attr
->ext_attr
;
2127 mio_integer ((int *) &ext_attr
);
2128 attr
->ext_attr
= ext_attr
;
2130 extension_level
= attr
->extension
;
2131 mio_integer ((int *) &extension_level
);
2132 attr
->extension
= extension_level
;
2134 if (iomode
== IO_OUTPUT
)
2136 if (attr
->allocatable
)
2137 MIO_NAME (ab_attribute
) (AB_ALLOCATABLE
, attr_bits
);
2138 if (attr
->artificial
)
2139 MIO_NAME (ab_attribute
) (AB_ARTIFICIAL
, attr_bits
);
2140 if (attr
->asynchronous
)
2141 MIO_NAME (ab_attribute
) (AB_ASYNCHRONOUS
, attr_bits
);
2142 if (attr
->dimension
)
2143 MIO_NAME (ab_attribute
) (AB_DIMENSION
, attr_bits
);
2144 if (attr
->codimension
)
2145 MIO_NAME (ab_attribute
) (AB_CODIMENSION
, attr_bits
);
2146 if (attr
->contiguous
)
2147 MIO_NAME (ab_attribute
) (AB_CONTIGUOUS
, attr_bits
);
2149 MIO_NAME (ab_attribute
) (AB_EXTERNAL
, attr_bits
);
2150 if (attr
->intrinsic
)
2151 MIO_NAME (ab_attribute
) (AB_INTRINSIC
, attr_bits
);
2153 MIO_NAME (ab_attribute
) (AB_OPTIONAL
, attr_bits
);
2155 MIO_NAME (ab_attribute
) (AB_POINTER
, attr_bits
);
2156 if (attr
->class_pointer
)
2157 MIO_NAME (ab_attribute
) (AB_CLASS_POINTER
, attr_bits
);
2158 if (attr
->is_protected
)
2159 MIO_NAME (ab_attribute
) (AB_PROTECTED
, attr_bits
);
2161 MIO_NAME (ab_attribute
) (AB_VALUE
, attr_bits
);
2162 if (attr
->volatile_
)
2163 MIO_NAME (ab_attribute
) (AB_VOLATILE
, attr_bits
);
2165 MIO_NAME (ab_attribute
) (AB_TARGET
, attr_bits
);
2166 if (attr
->threadprivate
)
2167 MIO_NAME (ab_attribute
) (AB_THREADPRIVATE
, attr_bits
);
2169 MIO_NAME (ab_attribute
) (AB_DUMMY
, attr_bits
);
2171 MIO_NAME (ab_attribute
) (AB_RESULT
, attr_bits
);
2172 /* We deliberately don't preserve the "entry" flag. */
2175 MIO_NAME (ab_attribute
) (AB_DATA
, attr_bits
);
2176 if (attr
->in_namelist
)
2177 MIO_NAME (ab_attribute
) (AB_IN_NAMELIST
, attr_bits
);
2178 if (attr
->in_common
)
2179 MIO_NAME (ab_attribute
) (AB_IN_COMMON
, attr_bits
);
2182 MIO_NAME (ab_attribute
) (AB_FUNCTION
, attr_bits
);
2183 if (attr
->subroutine
)
2184 MIO_NAME (ab_attribute
) (AB_SUBROUTINE
, attr_bits
);
2186 MIO_NAME (ab_attribute
) (AB_GENERIC
, attr_bits
);
2188 MIO_NAME (ab_attribute
) (AB_ABSTRACT
, attr_bits
);
2191 MIO_NAME (ab_attribute
) (AB_SEQUENCE
, attr_bits
);
2192 if (attr
->elemental
)
2193 MIO_NAME (ab_attribute
) (AB_ELEMENTAL
, attr_bits
);
2195 MIO_NAME (ab_attribute
) (AB_PURE
, attr_bits
);
2196 if (attr
->implicit_pure
)
2197 MIO_NAME (ab_attribute
) (AB_IMPLICIT_PURE
, attr_bits
);
2198 if (attr
->unlimited_polymorphic
)
2199 MIO_NAME (ab_attribute
) (AB_UNLIMITED_POLY
, attr_bits
);
2200 if (attr
->recursive
)
2201 MIO_NAME (ab_attribute
) (AB_RECURSIVE
, attr_bits
);
2202 if (attr
->always_explicit
)
2203 MIO_NAME (ab_attribute
) (AB_ALWAYS_EXPLICIT
, attr_bits
);
2204 if (attr
->cray_pointer
)
2205 MIO_NAME (ab_attribute
) (AB_CRAY_POINTER
, attr_bits
);
2206 if (attr
->cray_pointee
)
2207 MIO_NAME (ab_attribute
) (AB_CRAY_POINTEE
, attr_bits
);
2208 if (attr
->is_bind_c
)
2209 MIO_NAME(ab_attribute
) (AB_IS_BIND_C
, attr_bits
);
2210 if (attr
->is_c_interop
)
2211 MIO_NAME(ab_attribute
) (AB_IS_C_INTEROP
, attr_bits
);
2213 MIO_NAME(ab_attribute
) (AB_IS_ISO_C
, attr_bits
);
2214 if (attr
->alloc_comp
)
2215 MIO_NAME (ab_attribute
) (AB_ALLOC_COMP
, attr_bits
);
2216 if (attr
->pointer_comp
)
2217 MIO_NAME (ab_attribute
) (AB_POINTER_COMP
, attr_bits
);
2218 if (attr
->proc_pointer_comp
)
2219 MIO_NAME (ab_attribute
) (AB_PROC_POINTER_COMP
, attr_bits
);
2220 if (attr
->private_comp
)
2221 MIO_NAME (ab_attribute
) (AB_PRIVATE_COMP
, attr_bits
);
2222 if (attr
->coarray_comp
)
2223 MIO_NAME (ab_attribute
) (AB_COARRAY_COMP
, attr_bits
);
2224 if (attr
->lock_comp
)
2225 MIO_NAME (ab_attribute
) (AB_LOCK_COMP
, attr_bits
);
2226 if (attr
->event_comp
)
2227 MIO_NAME (ab_attribute
) (AB_EVENT_COMP
, attr_bits
);
2228 if (attr
->zero_comp
)
2229 MIO_NAME (ab_attribute
) (AB_ZERO_COMP
, attr_bits
);
2231 MIO_NAME (ab_attribute
) (AB_IS_CLASS
, attr_bits
);
2232 if (attr
->procedure
)
2233 MIO_NAME (ab_attribute
) (AB_PROCEDURE
, attr_bits
);
2234 if (attr
->proc_pointer
)
2235 MIO_NAME (ab_attribute
) (AB_PROC_POINTER
, attr_bits
);
2237 MIO_NAME (ab_attribute
) (AB_VTYPE
, attr_bits
);
2239 MIO_NAME (ab_attribute
) (AB_VTAB
, attr_bits
);
2240 if (attr
->omp_declare_target
)
2241 MIO_NAME (ab_attribute
) (AB_OMP_DECLARE_TARGET
, attr_bits
);
2242 if (attr
->array_outer_dependency
)
2243 MIO_NAME (ab_attribute
) (AB_ARRAY_OUTER_DEPENDENCY
, attr_bits
);
2244 if (attr
->module_procedure
)
2246 MIO_NAME (ab_attribute
) (AB_MODULE_PROCEDURE
, attr_bits
);
2247 no_module_procedures
= false;
2249 if (attr
->oacc_declare_create
)
2250 MIO_NAME (ab_attribute
) (AB_OACC_DECLARE_CREATE
, attr_bits
);
2251 if (attr
->oacc_declare_copyin
)
2252 MIO_NAME (ab_attribute
) (AB_OACC_DECLARE_COPYIN
, attr_bits
);
2253 if (attr
->oacc_declare_deviceptr
)
2254 MIO_NAME (ab_attribute
) (AB_OACC_DECLARE_DEVICEPTR
, attr_bits
);
2255 if (attr
->oacc_declare_device_resident
)
2256 MIO_NAME (ab_attribute
) (AB_OACC_DECLARE_DEVICE_RESIDENT
, attr_bits
);
2257 if (attr
->oacc_declare_link
)
2258 MIO_NAME (ab_attribute
) (AB_OACC_DECLARE_LINK
, attr_bits
);
2259 if (attr
->omp_declare_target_link
)
2260 MIO_NAME (ab_attribute
) (AB_OMP_DECLARE_TARGET_LINK
, attr_bits
);
2270 if (t
== ATOM_RPAREN
)
2273 bad_module ("Expected attribute bit name");
2275 switch ((ab_attribute
) find_enum (attr_bits
))
2277 case AB_ALLOCATABLE
:
2278 attr
->allocatable
= 1;
2281 attr
->artificial
= 1;
2283 case AB_ASYNCHRONOUS
:
2284 attr
->asynchronous
= 1;
2287 attr
->dimension
= 1;
2289 case AB_CODIMENSION
:
2290 attr
->codimension
= 1;
2293 attr
->contiguous
= 1;
2299 attr
->intrinsic
= 1;
2307 case AB_CLASS_POINTER
:
2308 attr
->class_pointer
= 1;
2311 attr
->is_protected
= 1;
2317 attr
->volatile_
= 1;
2322 case AB_THREADPRIVATE
:
2323 attr
->threadprivate
= 1;
2334 case AB_IN_NAMELIST
:
2335 attr
->in_namelist
= 1;
2338 attr
->in_common
= 1;
2344 attr
->subroutine
= 1;
2356 attr
->elemental
= 1;
2361 case AB_IMPLICIT_PURE
:
2362 attr
->implicit_pure
= 1;
2364 case AB_UNLIMITED_POLY
:
2365 attr
->unlimited_polymorphic
= 1;
2368 attr
->recursive
= 1;
2370 case AB_ALWAYS_EXPLICIT
:
2371 attr
->always_explicit
= 1;
2373 case AB_CRAY_POINTER
:
2374 attr
->cray_pointer
= 1;
2376 case AB_CRAY_POINTEE
:
2377 attr
->cray_pointee
= 1;
2380 attr
->is_bind_c
= 1;
2382 case AB_IS_C_INTEROP
:
2383 attr
->is_c_interop
= 1;
2389 attr
->alloc_comp
= 1;
2391 case AB_COARRAY_COMP
:
2392 attr
->coarray_comp
= 1;
2395 attr
->lock_comp
= 1;
2398 attr
->event_comp
= 1;
2400 case AB_POINTER_COMP
:
2401 attr
->pointer_comp
= 1;
2403 case AB_PROC_POINTER_COMP
:
2404 attr
->proc_pointer_comp
= 1;
2406 case AB_PRIVATE_COMP
:
2407 attr
->private_comp
= 1;
2410 attr
->zero_comp
= 1;
2416 attr
->procedure
= 1;
2418 case AB_PROC_POINTER
:
2419 attr
->proc_pointer
= 1;
2427 case AB_OMP_DECLARE_TARGET
:
2428 attr
->omp_declare_target
= 1;
2430 case AB_OMP_DECLARE_TARGET_LINK
:
2431 attr
->omp_declare_target_link
= 1;
2433 case AB_ARRAY_OUTER_DEPENDENCY
:
2434 attr
->array_outer_dependency
=1;
2436 case AB_MODULE_PROCEDURE
:
2437 attr
->module_procedure
=1;
2439 case AB_OACC_DECLARE_CREATE
:
2440 attr
->oacc_declare_create
= 1;
2442 case AB_OACC_DECLARE_COPYIN
:
2443 attr
->oacc_declare_copyin
= 1;
2445 case AB_OACC_DECLARE_DEVICEPTR
:
2446 attr
->oacc_declare_deviceptr
= 1;
2448 case AB_OACC_DECLARE_DEVICE_RESIDENT
:
2449 attr
->oacc_declare_device_resident
= 1;
2451 case AB_OACC_DECLARE_LINK
:
2452 attr
->oacc_declare_link
= 1;
2460 static const mstring bt_types
[] = {
2461 minit ("INTEGER", BT_INTEGER
),
2462 minit ("REAL", BT_REAL
),
2463 minit ("COMPLEX", BT_COMPLEX
),
2464 minit ("LOGICAL", BT_LOGICAL
),
2465 minit ("CHARACTER", BT_CHARACTER
),
2466 minit ("UNION", BT_UNION
),
2467 minit ("DERIVED", BT_DERIVED
),
2468 minit ("CLASS", BT_CLASS
),
2469 minit ("PROCEDURE", BT_PROCEDURE
),
2470 minit ("UNKNOWN", BT_UNKNOWN
),
2471 minit ("VOID", BT_VOID
),
2472 minit ("ASSUMED", BT_ASSUMED
),
2478 mio_charlen (gfc_charlen
**clp
)
2484 if (iomode
== IO_OUTPUT
)
2488 mio_expr (&cl
->length
);
2492 if (peek_atom () != ATOM_RPAREN
)
2494 cl
= gfc_new_charlen (gfc_current_ns
, NULL
);
2495 mio_expr (&cl
->length
);
2504 /* See if a name is a generated name. */
2507 check_unique_name (const char *name
)
2509 return *name
== '@';
2514 mio_typespec (gfc_typespec
*ts
)
2518 ts
->type
= MIO_NAME (bt
) (ts
->type
, bt_types
);
2520 if (!gfc_bt_struct (ts
->type
) && ts
->type
!= BT_CLASS
)
2521 mio_integer (&ts
->kind
);
2523 mio_symbol_ref (&ts
->u
.derived
);
2525 mio_symbol_ref (&ts
->interface
);
2527 /* Add info for C interop and is_iso_c. */
2528 mio_integer (&ts
->is_c_interop
);
2529 mio_integer (&ts
->is_iso_c
);
2531 /* If the typespec is for an identifier either from iso_c_binding, or
2532 a constant that was initialized to an identifier from it, use the
2533 f90_type. Otherwise, use the ts->type, since it shouldn't matter. */
2535 ts
->f90_type
= MIO_NAME (bt
) (ts
->f90_type
, bt_types
);
2537 ts
->f90_type
= MIO_NAME (bt
) (ts
->type
, bt_types
);
2539 if (ts
->type
!= BT_CHARACTER
)
2541 /* ts->u.cl is only valid for BT_CHARACTER. */
2546 mio_charlen (&ts
->u
.cl
);
2548 /* So as not to disturb the existing API, use an ATOM_NAME to
2549 transmit deferred characteristic for characters (F2003). */
2550 if (iomode
== IO_OUTPUT
)
2552 if (ts
->type
== BT_CHARACTER
&& ts
->deferred
)
2553 write_atom (ATOM_NAME
, "DEFERRED_CL");
2555 else if (peek_atom () != ATOM_RPAREN
)
2557 if (parse_atom () != ATOM_NAME
)
2558 bad_module ("Expected string");
2566 static const mstring array_spec_types
[] = {
2567 minit ("EXPLICIT", AS_EXPLICIT
),
2568 minit ("ASSUMED_RANK", AS_ASSUMED_RANK
),
2569 minit ("ASSUMED_SHAPE", AS_ASSUMED_SHAPE
),
2570 minit ("DEFERRED", AS_DEFERRED
),
2571 minit ("ASSUMED_SIZE", AS_ASSUMED_SIZE
),
2577 mio_array_spec (gfc_array_spec
**asp
)
2584 if (iomode
== IO_OUTPUT
)
2592 /* mio_integer expects nonnegative values. */
2593 rank
= as
->rank
> 0 ? as
->rank
: 0;
2594 mio_integer (&rank
);
2598 if (peek_atom () == ATOM_RPAREN
)
2604 *asp
= as
= gfc_get_array_spec ();
2605 mio_integer (&as
->rank
);
2608 mio_integer (&as
->corank
);
2609 as
->type
= MIO_NAME (array_type
) (as
->type
, array_spec_types
);
2611 if (iomode
== IO_INPUT
&& as
->type
== AS_ASSUMED_RANK
)
2613 if (iomode
== IO_INPUT
&& as
->corank
)
2614 as
->cotype
= (as
->type
== AS_DEFERRED
) ? AS_DEFERRED
: AS_EXPLICIT
;
2616 if (as
->rank
+ as
->corank
> 0)
2617 for (i
= 0; i
< as
->rank
+ as
->corank
; i
++)
2619 mio_expr (&as
->lower
[i
]);
2620 mio_expr (&as
->upper
[i
]);
2628 /* Given a pointer to an array reference structure (which lives in a
2629 gfc_ref structure), find the corresponding array specification
2630 structure. Storing the pointer in the ref structure doesn't quite
2631 work when loading from a module. Generating code for an array
2632 reference also needs more information than just the array spec. */
2634 static const mstring array_ref_types
[] = {
2635 minit ("FULL", AR_FULL
),
2636 minit ("ELEMENT", AR_ELEMENT
),
2637 minit ("SECTION", AR_SECTION
),
2643 mio_array_ref (gfc_array_ref
*ar
)
2648 ar
->type
= MIO_NAME (ar_type
) (ar
->type
, array_ref_types
);
2649 mio_integer (&ar
->dimen
);
2657 for (i
= 0; i
< ar
->dimen
; i
++)
2658 mio_expr (&ar
->start
[i
]);
2663 for (i
= 0; i
< ar
->dimen
; i
++)
2665 mio_expr (&ar
->start
[i
]);
2666 mio_expr (&ar
->end
[i
]);
2667 mio_expr (&ar
->stride
[i
]);
2673 gfc_internal_error ("mio_array_ref(): Unknown array ref");
2676 /* Unfortunately, ar->dimen_type is an anonymous enumerated type so
2677 we can't call mio_integer directly. Instead loop over each element
2678 and cast it to/from an integer. */
2679 if (iomode
== IO_OUTPUT
)
2681 for (i
= 0; i
< ar
->dimen
; i
++)
2683 int tmp
= (int)ar
->dimen_type
[i
];
2684 write_atom (ATOM_INTEGER
, &tmp
);
2689 for (i
= 0; i
< ar
->dimen
; i
++)
2691 require_atom (ATOM_INTEGER
);
2692 ar
->dimen_type
[i
] = (enum gfc_array_ref_dimen_type
) atom_int
;
2696 if (iomode
== IO_INPUT
)
2698 ar
->where
= gfc_current_locus
;
2700 for (i
= 0; i
< ar
->dimen
; i
++)
2701 ar
->c_where
[i
] = gfc_current_locus
;
2708 /* Saves or restores a pointer. The pointer is converted back and
2709 forth from an integer. We return the pointer_info pointer so that
2710 the caller can take additional action based on the pointer type. */
2712 static pointer_info
*
2713 mio_pointer_ref (void *gp
)
2717 if (iomode
== IO_OUTPUT
)
2719 p
= get_pointer (*((char **) gp
));
2720 write_atom (ATOM_INTEGER
, &p
->integer
);
2724 require_atom (ATOM_INTEGER
);
2725 p
= add_fixup (atom_int
, gp
);
2732 /* Save and load references to components that occur within
2733 expressions. We have to describe these references by a number and
2734 by name. The number is necessary for forward references during
2735 reading, and the name is necessary if the symbol already exists in
2736 the namespace and is not loaded again. */
2739 mio_component_ref (gfc_component
**cp
)
2743 p
= mio_pointer_ref (cp
);
2744 if (p
->type
== P_UNKNOWN
)
2745 p
->type
= P_COMPONENT
;
2749 static void mio_namespace_ref (gfc_namespace
**nsp
);
2750 static void mio_formal_arglist (gfc_formal_arglist
**formal
);
2751 static void mio_typebound_proc (gfc_typebound_proc
** proc
);
2754 mio_component (gfc_component
*c
, int vtype
)
2761 if (iomode
== IO_OUTPUT
)
2763 p
= get_pointer (c
);
2764 mio_integer (&p
->integer
);
2769 p
= get_integer (n
);
2770 associate_integer_pointer (p
, c
);
2773 if (p
->type
== P_UNKNOWN
)
2774 p
->type
= P_COMPONENT
;
2776 mio_pool_string (&c
->name
);
2777 mio_typespec (&c
->ts
);
2778 mio_array_spec (&c
->as
);
2780 mio_symbol_attribute (&c
->attr
);
2781 if (c
->ts
.type
== BT_CLASS
)
2782 c
->attr
.class_ok
= 1;
2783 c
->attr
.access
= MIO_NAME (gfc_access
) (c
->attr
.access
, access_types
);
2785 if (!vtype
|| strcmp (c
->name
, "_final") == 0
2786 || strcmp (c
->name
, "_hash") == 0)
2787 mio_expr (&c
->initializer
);
2789 if (c
->attr
.proc_pointer
)
2790 mio_typebound_proc (&c
->tb
);
2797 mio_component_list (gfc_component
**cp
, int vtype
)
2799 gfc_component
*c
, *tail
;
2803 if (iomode
== IO_OUTPUT
)
2805 for (c
= *cp
; c
; c
= c
->next
)
2806 mio_component (c
, vtype
);
2815 if (peek_atom () == ATOM_RPAREN
)
2818 c
= gfc_get_component ();
2819 mio_component (c
, vtype
);
2835 mio_actual_arg (gfc_actual_arglist
*a
)
2838 mio_pool_string (&a
->name
);
2839 mio_expr (&a
->expr
);
2845 mio_actual_arglist (gfc_actual_arglist
**ap
)
2847 gfc_actual_arglist
*a
, *tail
;
2851 if (iomode
== IO_OUTPUT
)
2853 for (a
= *ap
; a
; a
= a
->next
)
2863 if (peek_atom () != ATOM_LPAREN
)
2866 a
= gfc_get_actual_arglist ();
2882 /* Read and write formal argument lists. */
2885 mio_formal_arglist (gfc_formal_arglist
**formal
)
2887 gfc_formal_arglist
*f
, *tail
;
2891 if (iomode
== IO_OUTPUT
)
2893 for (f
= *formal
; f
; f
= f
->next
)
2894 mio_symbol_ref (&f
->sym
);
2898 *formal
= tail
= NULL
;
2900 while (peek_atom () != ATOM_RPAREN
)
2902 f
= gfc_get_formal_arglist ();
2903 mio_symbol_ref (&f
->sym
);
2905 if (*formal
== NULL
)
2918 /* Save or restore a reference to a symbol node. */
2921 mio_symbol_ref (gfc_symbol
**symp
)
2925 p
= mio_pointer_ref (symp
);
2926 if (p
->type
== P_UNKNOWN
)
2929 if (iomode
== IO_OUTPUT
)
2931 if (p
->u
.wsym
.state
== UNREFERENCED
)
2932 p
->u
.wsym
.state
= NEEDS_WRITE
;
2936 if (p
->u
.rsym
.state
== UNUSED
)
2937 p
->u
.rsym
.state
= NEEDED
;
2943 /* Save or restore a reference to a symtree node. */
2946 mio_symtree_ref (gfc_symtree
**stp
)
2951 if (iomode
== IO_OUTPUT
)
2952 mio_symbol_ref (&(*stp
)->n
.sym
);
2955 require_atom (ATOM_INTEGER
);
2956 p
= get_integer (atom_int
);
2958 /* An unused equivalence member; make a symbol and a symtree
2960 if (in_load_equiv
&& p
->u
.rsym
.symtree
== NULL
)
2962 /* Since this is not used, it must have a unique name. */
2963 p
->u
.rsym
.symtree
= gfc_get_unique_symtree (gfc_current_ns
);
2965 /* Make the symbol. */
2966 if (p
->u
.rsym
.sym
== NULL
)
2968 p
->u
.rsym
.sym
= gfc_new_symbol (p
->u
.rsym
.true_name
,
2970 p
->u
.rsym
.sym
->module
= gfc_get_string (p
->u
.rsym
.module
);
2973 p
->u
.rsym
.symtree
->n
.sym
= p
->u
.rsym
.sym
;
2974 p
->u
.rsym
.symtree
->n
.sym
->refs
++;
2975 p
->u
.rsym
.referenced
= 1;
2977 /* If the symbol is PRIVATE and in COMMON, load_commons will
2978 generate a fixup symbol, which must be associated. */
2980 resolve_fixups (p
->fixup
, p
->u
.rsym
.sym
);
2984 if (p
->type
== P_UNKNOWN
)
2987 if (p
->u
.rsym
.state
== UNUSED
)
2988 p
->u
.rsym
.state
= NEEDED
;
2990 if (p
->u
.rsym
.symtree
!= NULL
)
2992 *stp
= p
->u
.rsym
.symtree
;
2996 f
= XCNEW (fixup_t
);
2998 f
->next
= p
->u
.rsym
.stfixup
;
2999 p
->u
.rsym
.stfixup
= f
;
3001 f
->pointer
= (void **) stp
;
3008 mio_iterator (gfc_iterator
**ip
)
3014 if (iomode
== IO_OUTPUT
)
3021 if (peek_atom () == ATOM_RPAREN
)
3027 *ip
= gfc_get_iterator ();
3032 mio_expr (&iter
->var
);
3033 mio_expr (&iter
->start
);
3034 mio_expr (&iter
->end
);
3035 mio_expr (&iter
->step
);
3043 mio_constructor (gfc_constructor_base
*cp
)
3049 if (iomode
== IO_OUTPUT
)
3051 for (c
= gfc_constructor_first (*cp
); c
; c
= gfc_constructor_next (c
))
3054 mio_expr (&c
->expr
);
3055 mio_iterator (&c
->iterator
);
3061 while (peek_atom () != ATOM_RPAREN
)
3063 c
= gfc_constructor_append_expr (cp
, NULL
, NULL
);
3066 mio_expr (&c
->expr
);
3067 mio_iterator (&c
->iterator
);
3076 static const mstring ref_types
[] = {
3077 minit ("ARRAY", REF_ARRAY
),
3078 minit ("COMPONENT", REF_COMPONENT
),
3079 minit ("SUBSTRING", REF_SUBSTRING
),
3085 mio_ref (gfc_ref
**rp
)
3092 r
->type
= MIO_NAME (ref_type
) (r
->type
, ref_types
);
3097 mio_array_ref (&r
->u
.ar
);
3101 mio_symbol_ref (&r
->u
.c
.sym
);
3102 mio_component_ref (&r
->u
.c
.component
);
3106 mio_expr (&r
->u
.ss
.start
);
3107 mio_expr (&r
->u
.ss
.end
);
3108 mio_charlen (&r
->u
.ss
.length
);
3117 mio_ref_list (gfc_ref
**rp
)
3119 gfc_ref
*ref
, *head
, *tail
;
3123 if (iomode
== IO_OUTPUT
)
3125 for (ref
= *rp
; ref
; ref
= ref
->next
)
3132 while (peek_atom () != ATOM_RPAREN
)
3135 head
= tail
= gfc_get_ref ();
3138 tail
->next
= gfc_get_ref ();
3152 /* Read and write an integer value. */
3155 mio_gmp_integer (mpz_t
*integer
)
3159 if (iomode
== IO_INPUT
)
3161 if (parse_atom () != ATOM_STRING
)
3162 bad_module ("Expected integer string");
3164 mpz_init (*integer
);
3165 if (mpz_set_str (*integer
, atom_string
, 10))
3166 bad_module ("Error converting integer");
3172 p
= mpz_get_str (NULL
, 10, *integer
);
3173 write_atom (ATOM_STRING
, p
);
3180 mio_gmp_real (mpfr_t
*real
)
3185 if (iomode
== IO_INPUT
)
3187 if (parse_atom () != ATOM_STRING
)
3188 bad_module ("Expected real string");
3191 mpfr_set_str (*real
, atom_string
, 16, GFC_RND_MODE
);
3196 p
= mpfr_get_str (NULL
, &exponent
, 16, 0, *real
, GFC_RND_MODE
);
3198 if (mpfr_nan_p (*real
) || mpfr_inf_p (*real
))
3200 write_atom (ATOM_STRING
, p
);
3205 atom_string
= XCNEWVEC (char, strlen (p
) + 20);
3207 sprintf (atom_string
, "0.%s@%ld", p
, exponent
);
3209 /* Fix negative numbers. */
3210 if (atom_string
[2] == '-')
3212 atom_string
[0] = '-';
3213 atom_string
[1] = '0';
3214 atom_string
[2] = '.';
3217 write_atom (ATOM_STRING
, atom_string
);
3225 /* Save and restore the shape of an array constructor. */
3228 mio_shape (mpz_t
**pshape
, int rank
)
3234 /* A NULL shape is represented by (). */
3237 if (iomode
== IO_OUTPUT
)
3249 if (t
== ATOM_RPAREN
)
3256 shape
= gfc_get_shape (rank
);
3260 for (n
= 0; n
< rank
; n
++)
3261 mio_gmp_integer (&shape
[n
]);
3267 static const mstring expr_types
[] = {
3268 minit ("OP", EXPR_OP
),
3269 minit ("FUNCTION", EXPR_FUNCTION
),
3270 minit ("CONSTANT", EXPR_CONSTANT
),
3271 minit ("VARIABLE", EXPR_VARIABLE
),
3272 minit ("SUBSTRING", EXPR_SUBSTRING
),
3273 minit ("STRUCTURE", EXPR_STRUCTURE
),
3274 minit ("ARRAY", EXPR_ARRAY
),
3275 minit ("NULL", EXPR_NULL
),
3276 minit ("COMPCALL", EXPR_COMPCALL
),
3280 /* INTRINSIC_ASSIGN is missing because it is used as an index for
3281 generic operators, not in expressions. INTRINSIC_USER is also
3282 replaced by the correct function name by the time we see it. */
3284 static const mstring intrinsics
[] =
3286 minit ("UPLUS", INTRINSIC_UPLUS
),
3287 minit ("UMINUS", INTRINSIC_UMINUS
),
3288 minit ("PLUS", INTRINSIC_PLUS
),
3289 minit ("MINUS", INTRINSIC_MINUS
),
3290 minit ("TIMES", INTRINSIC_TIMES
),
3291 minit ("DIVIDE", INTRINSIC_DIVIDE
),
3292 minit ("POWER", INTRINSIC_POWER
),
3293 minit ("CONCAT", INTRINSIC_CONCAT
),
3294 minit ("AND", INTRINSIC_AND
),
3295 minit ("OR", INTRINSIC_OR
),
3296 minit ("EQV", INTRINSIC_EQV
),
3297 minit ("NEQV", INTRINSIC_NEQV
),
3298 minit ("EQ_SIGN", INTRINSIC_EQ
),
3299 minit ("EQ", INTRINSIC_EQ_OS
),
3300 minit ("NE_SIGN", INTRINSIC_NE
),
3301 minit ("NE", INTRINSIC_NE_OS
),
3302 minit ("GT_SIGN", INTRINSIC_GT
),
3303 minit ("GT", INTRINSIC_GT_OS
),
3304 minit ("GE_SIGN", INTRINSIC_GE
),
3305 minit ("GE", INTRINSIC_GE_OS
),
3306 minit ("LT_SIGN", INTRINSIC_LT
),
3307 minit ("LT", INTRINSIC_LT_OS
),
3308 minit ("LE_SIGN", INTRINSIC_LE
),
3309 minit ("LE", INTRINSIC_LE_OS
),
3310 minit ("NOT", INTRINSIC_NOT
),
3311 minit ("PARENTHESES", INTRINSIC_PARENTHESES
),
3312 minit ("USER", INTRINSIC_USER
),
3317 /* Remedy a couple of situations where the gfc_expr's can be defective. */
3320 fix_mio_expr (gfc_expr
*e
)
3322 gfc_symtree
*ns_st
= NULL
;
3325 if (iomode
!= IO_OUTPUT
)
3330 /* If this is a symtree for a symbol that came from a contained module
3331 namespace, it has a unique name and we should look in the current
3332 namespace to see if the required, non-contained symbol is available
3333 yet. If so, the latter should be written. */
3334 if (e
->symtree
->n
.sym
&& check_unique_name (e
->symtree
->name
))
3336 const char *name
= e
->symtree
->n
.sym
->name
;
3337 if (gfc_fl_struct (e
->symtree
->n
.sym
->attr
.flavor
))
3338 name
= gfc_dt_upper_string (name
);
3339 ns_st
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
3342 /* On the other hand, if the existing symbol is the module name or the
3343 new symbol is a dummy argument, do not do the promotion. */
3344 if (ns_st
&& ns_st
->n
.sym
3345 && ns_st
->n
.sym
->attr
.flavor
!= FL_MODULE
3346 && !e
->symtree
->n
.sym
->attr
.dummy
)
3349 else if (e
->expr_type
== EXPR_FUNCTION
3350 && (e
->value
.function
.name
|| e
->value
.function
.isym
))
3354 /* In some circumstances, a function used in an initialization
3355 expression, in one use associated module, can fail to be
3356 coupled to its symtree when used in a specification
3357 expression in another module. */
3358 fname
= e
->value
.function
.esym
? e
->value
.function
.esym
->name
3359 : e
->value
.function
.isym
->name
;
3360 e
->symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, fname
);
3365 /* This is probably a reference to a private procedure from another
3366 module. To prevent a segfault, make a generic with no specific
3367 instances. If this module is used, without the required
3368 specific coming from somewhere, the appropriate error message
3370 gfc_get_symbol (fname
, gfc_current_ns
, &sym
);
3371 sym
->attr
.flavor
= FL_PROCEDURE
;
3372 sym
->attr
.generic
= 1;
3373 e
->symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, fname
);
3374 gfc_commit_symbol (sym
);
3379 /* Read and write expressions. The form "()" is allowed to indicate a
3383 mio_expr (gfc_expr
**ep
)
3391 if (iomode
== IO_OUTPUT
)
3400 MIO_NAME (expr_t
) (e
->expr_type
, expr_types
);
3405 if (t
== ATOM_RPAREN
)
3412 bad_module ("Expected expression type");
3414 e
= *ep
= gfc_get_expr ();
3415 e
->where
= gfc_current_locus
;
3416 e
->expr_type
= (expr_t
) find_enum (expr_types
);
3419 mio_typespec (&e
->ts
);
3420 mio_integer (&e
->rank
);
3424 switch (e
->expr_type
)
3428 = MIO_NAME (gfc_intrinsic_op
) (e
->value
.op
.op
, intrinsics
);
3430 switch (e
->value
.op
.op
)
3432 case INTRINSIC_UPLUS
:
3433 case INTRINSIC_UMINUS
:
3435 case INTRINSIC_PARENTHESES
:
3436 mio_expr (&e
->value
.op
.op1
);
3439 case INTRINSIC_PLUS
:
3440 case INTRINSIC_MINUS
:
3441 case INTRINSIC_TIMES
:
3442 case INTRINSIC_DIVIDE
:
3443 case INTRINSIC_POWER
:
3444 case INTRINSIC_CONCAT
:
3448 case INTRINSIC_NEQV
:
3450 case INTRINSIC_EQ_OS
:
3452 case INTRINSIC_NE_OS
:
3454 case INTRINSIC_GT_OS
:
3456 case INTRINSIC_GE_OS
:
3458 case INTRINSIC_LT_OS
:
3460 case INTRINSIC_LE_OS
:
3461 mio_expr (&e
->value
.op
.op1
);
3462 mio_expr (&e
->value
.op
.op2
);
3465 case INTRINSIC_USER
:
3466 /* INTRINSIC_USER should not appear in resolved expressions,
3467 though for UDRs we need to stream unresolved ones. */
3468 if (iomode
== IO_OUTPUT
)
3469 write_atom (ATOM_STRING
, e
->value
.op
.uop
->name
);
3472 char *name
= read_string ();
3473 const char *uop_name
= find_use_name (name
, true);
3474 if (uop_name
== NULL
)
3476 size_t len
= strlen (name
);
3477 char *name2
= XCNEWVEC (char, len
+ 2);
3478 memcpy (name2
, name
, len
);
3480 name2
[len
+ 1] = '\0';
3482 uop_name
= name
= name2
;
3484 e
->value
.op
.uop
= gfc_get_uop (uop_name
);
3487 mio_expr (&e
->value
.op
.op1
);
3488 mio_expr (&e
->value
.op
.op2
);
3492 bad_module ("Bad operator");
3498 mio_symtree_ref (&e
->symtree
);
3499 mio_actual_arglist (&e
->value
.function
.actual
);
3501 if (iomode
== IO_OUTPUT
)
3503 e
->value
.function
.name
3504 = mio_allocated_string (e
->value
.function
.name
);
3505 if (e
->value
.function
.esym
)
3509 else if (e
->value
.function
.isym
== NULL
)
3513 mio_integer (&flag
);
3517 mio_symbol_ref (&e
->value
.function
.esym
);
3520 mio_ref_list (&e
->ref
);
3525 write_atom (ATOM_STRING
, e
->value
.function
.isym
->name
);
3530 require_atom (ATOM_STRING
);
3531 if (atom_string
[0] == '\0')
3532 e
->value
.function
.name
= NULL
;
3534 e
->value
.function
.name
= gfc_get_string (atom_string
);
3537 mio_integer (&flag
);
3541 mio_symbol_ref (&e
->value
.function
.esym
);
3544 mio_ref_list (&e
->ref
);
3549 require_atom (ATOM_STRING
);
3550 e
->value
.function
.isym
= gfc_find_function (atom_string
);
3558 mio_symtree_ref (&e
->symtree
);
3559 mio_ref_list (&e
->ref
);
3562 case EXPR_SUBSTRING
:
3563 e
->value
.character
.string
3564 = CONST_CAST (gfc_char_t
*,
3565 mio_allocated_wide_string (e
->value
.character
.string
,
3566 e
->value
.character
.length
));
3567 mio_ref_list (&e
->ref
);
3570 case EXPR_STRUCTURE
:
3572 mio_constructor (&e
->value
.constructor
);
3573 mio_shape (&e
->shape
, e
->rank
);
3580 mio_gmp_integer (&e
->value
.integer
);
3584 gfc_set_model_kind (e
->ts
.kind
);
3585 mio_gmp_real (&e
->value
.real
);
3589 gfc_set_model_kind (e
->ts
.kind
);
3590 mio_gmp_real (&mpc_realref (e
->value
.complex));
3591 mio_gmp_real (&mpc_imagref (e
->value
.complex));
3595 mio_integer (&e
->value
.logical
);
3599 mio_integer (&e
->value
.character
.length
);
3600 e
->value
.character
.string
3601 = CONST_CAST (gfc_char_t
*,
3602 mio_allocated_wide_string (e
->value
.character
.string
,
3603 e
->value
.character
.length
));
3607 bad_module ("Bad type in constant expression");
3625 /* Read and write namelists. */
3628 mio_namelist (gfc_symbol
*sym
)
3630 gfc_namelist
*n
, *m
;
3631 const char *check_name
;
3635 if (iomode
== IO_OUTPUT
)
3637 for (n
= sym
->namelist
; n
; n
= n
->next
)
3638 mio_symbol_ref (&n
->sym
);
3642 /* This departure from the standard is flagged as an error.
3643 It does, in fact, work correctly. TODO: Allow it
3645 if (sym
->attr
.flavor
== FL_NAMELIST
)
3647 check_name
= find_use_name (sym
->name
, false);
3648 if (check_name
&& strcmp (check_name
, sym
->name
) != 0)
3649 gfc_error ("Namelist %s cannot be renamed by USE "
3650 "association to %s", sym
->name
, check_name
);
3654 while (peek_atom () != ATOM_RPAREN
)
3656 n
= gfc_get_namelist ();
3657 mio_symbol_ref (&n
->sym
);
3659 if (sym
->namelist
== NULL
)
3666 sym
->namelist_tail
= m
;
3673 /* Save/restore lists of gfc_interface structures. When loading an
3674 interface, we are really appending to the existing list of
3675 interfaces. Checking for duplicate and ambiguous interfaces has to
3676 be done later when all symbols have been loaded. */
3679 mio_interface_rest (gfc_interface
**ip
)
3681 gfc_interface
*tail
, *p
;
3682 pointer_info
*pi
= NULL
;
3684 if (iomode
== IO_OUTPUT
)
3687 for (p
= *ip
; p
; p
= p
->next
)
3688 mio_symbol_ref (&p
->sym
);
3703 if (peek_atom () == ATOM_RPAREN
)
3706 p
= gfc_get_interface ();
3707 p
->where
= gfc_current_locus
;
3708 pi
= mio_symbol_ref (&p
->sym
);
3724 /* Save/restore a nameless operator interface. */
3727 mio_interface (gfc_interface
**ip
)
3730 mio_interface_rest (ip
);
3734 /* Save/restore a named operator interface. */
3737 mio_symbol_interface (const char **name
, const char **module
,
3741 mio_pool_string (name
);
3742 mio_pool_string (module
);
3743 mio_interface_rest (ip
);
3748 mio_namespace_ref (gfc_namespace
**nsp
)
3753 p
= mio_pointer_ref (nsp
);
3755 if (p
->type
== P_UNKNOWN
)
3756 p
->type
= P_NAMESPACE
;
3758 if (iomode
== IO_INPUT
&& p
->integer
!= 0)
3760 ns
= (gfc_namespace
*) p
->u
.pointer
;
3763 ns
= gfc_get_namespace (NULL
, 0);
3764 associate_integer_pointer (p
, ns
);
3772 /* Save/restore the f2k_derived namespace of a derived-type symbol. */
3774 static gfc_namespace
* current_f2k_derived
;
3777 mio_typebound_proc (gfc_typebound_proc
** proc
)
3780 int overriding_flag
;
3782 if (iomode
== IO_INPUT
)
3784 *proc
= gfc_get_typebound_proc (NULL
);
3785 (*proc
)->where
= gfc_current_locus
;
3791 (*proc
)->access
= MIO_NAME (gfc_access
) ((*proc
)->access
, access_types
);
3793 /* IO the NON_OVERRIDABLE/DEFERRED combination. */
3794 gcc_assert (!((*proc
)->deferred
&& (*proc
)->non_overridable
));
3795 overriding_flag
= ((*proc
)->deferred
<< 1) | (*proc
)->non_overridable
;
3796 overriding_flag
= mio_name (overriding_flag
, binding_overriding
);
3797 (*proc
)->deferred
= ((overriding_flag
& 2) != 0);
3798 (*proc
)->non_overridable
= ((overriding_flag
& 1) != 0);
3799 gcc_assert (!((*proc
)->deferred
&& (*proc
)->non_overridable
));
3801 (*proc
)->nopass
= mio_name ((*proc
)->nopass
, binding_passing
);
3802 (*proc
)->is_generic
= mio_name ((*proc
)->is_generic
, binding_generic
);
3803 (*proc
)->ppc
= mio_name((*proc
)->ppc
, binding_ppc
);
3805 mio_pool_string (&((*proc
)->pass_arg
));
3807 flag
= (int) (*proc
)->pass_arg_num
;
3808 mio_integer (&flag
);
3809 (*proc
)->pass_arg_num
= (unsigned) flag
;
3811 if ((*proc
)->is_generic
)
3818 if (iomode
== IO_OUTPUT
)
3819 for (g
= (*proc
)->u
.generic
; g
; g
= g
->next
)
3821 iop
= (int) g
->is_operator
;
3823 mio_allocated_string (g
->specific_st
->name
);
3827 (*proc
)->u
.generic
= NULL
;
3828 while (peek_atom () != ATOM_RPAREN
)
3830 gfc_symtree
** sym_root
;
3832 g
= gfc_get_tbp_generic ();
3836 g
->is_operator
= (bool) iop
;
3838 require_atom (ATOM_STRING
);
3839 sym_root
= ¤t_f2k_derived
->tb_sym_root
;
3840 g
->specific_st
= gfc_get_tbp_symtree (sym_root
, atom_string
);
3843 g
->next
= (*proc
)->u
.generic
;
3844 (*proc
)->u
.generic
= g
;
3850 else if (!(*proc
)->ppc
)
3851 mio_symtree_ref (&(*proc
)->u
.specific
);
3856 /* Walker-callback function for this purpose. */
3858 mio_typebound_symtree (gfc_symtree
* st
)
3860 if (iomode
== IO_OUTPUT
&& !st
->n
.tb
)
3863 if (iomode
== IO_OUTPUT
)
3866 mio_allocated_string (st
->name
);
3868 /* For IO_INPUT, the above is done in mio_f2k_derived. */
3870 mio_typebound_proc (&st
->n
.tb
);
3874 /* IO a full symtree (in all depth). */
3876 mio_full_typebound_tree (gfc_symtree
** root
)
3880 if (iomode
== IO_OUTPUT
)
3881 gfc_traverse_symtree (*root
, &mio_typebound_symtree
);
3884 while (peek_atom () == ATOM_LPAREN
)
3890 require_atom (ATOM_STRING
);
3891 st
= gfc_get_tbp_symtree (root
, atom_string
);
3894 mio_typebound_symtree (st
);
3902 mio_finalizer (gfc_finalizer
**f
)
3904 if (iomode
== IO_OUTPUT
)
3907 gcc_assert ((*f
)->proc_tree
); /* Should already be resolved. */
3908 mio_symtree_ref (&(*f
)->proc_tree
);
3912 *f
= gfc_get_finalizer ();
3913 (*f
)->where
= gfc_current_locus
; /* Value should not matter. */
3916 mio_symtree_ref (&(*f
)->proc_tree
);
3917 (*f
)->proc_sym
= NULL
;
3922 mio_f2k_derived (gfc_namespace
*f2k
)
3924 current_f2k_derived
= f2k
;
3926 /* Handle the list of finalizer procedures. */
3928 if (iomode
== IO_OUTPUT
)
3931 for (f
= f2k
->finalizers
; f
; f
= f
->next
)
3936 f2k
->finalizers
= NULL
;
3937 while (peek_atom () != ATOM_RPAREN
)
3939 gfc_finalizer
*cur
= NULL
;
3940 mio_finalizer (&cur
);
3941 cur
->next
= f2k
->finalizers
;
3942 f2k
->finalizers
= cur
;
3947 /* Handle type-bound procedures. */
3948 mio_full_typebound_tree (&f2k
->tb_sym_root
);
3950 /* Type-bound user operators. */
3951 mio_full_typebound_tree (&f2k
->tb_uop_root
);
3953 /* Type-bound intrinsic operators. */
3955 if (iomode
== IO_OUTPUT
)
3958 for (op
= GFC_INTRINSIC_BEGIN
; op
!= GFC_INTRINSIC_END
; ++op
)
3960 gfc_intrinsic_op realop
;
3962 if (op
== INTRINSIC_USER
|| !f2k
->tb_op
[op
])
3966 realop
= (gfc_intrinsic_op
) op
;
3967 mio_intrinsic_op (&realop
);
3968 mio_typebound_proc (&f2k
->tb_op
[op
]);
3973 while (peek_atom () != ATOM_RPAREN
)
3975 gfc_intrinsic_op op
= GFC_INTRINSIC_BEGIN
; /* Silence GCC. */
3978 mio_intrinsic_op (&op
);
3979 mio_typebound_proc (&f2k
->tb_op
[op
]);
3986 mio_full_f2k_derived (gfc_symbol
*sym
)
3990 if (iomode
== IO_OUTPUT
)
3992 if (sym
->f2k_derived
)
3993 mio_f2k_derived (sym
->f2k_derived
);
3997 if (peek_atom () != ATOM_RPAREN
)
3999 sym
->f2k_derived
= gfc_get_namespace (NULL
, 0);
4000 mio_f2k_derived (sym
->f2k_derived
);
4003 gcc_assert (!sym
->f2k_derived
);
4009 static const mstring omp_declare_simd_clauses
[] =
4011 minit ("INBRANCH", 0),
4012 minit ("NOTINBRANCH", 1),
4013 minit ("SIMDLEN", 2),
4014 minit ("UNIFORM", 3),
4015 minit ("LINEAR", 4),
4016 minit ("ALIGNED", 5),
4020 /* Handle !$omp declare simd. */
4023 mio_omp_declare_simd (gfc_namespace
*ns
, gfc_omp_declare_simd
**odsp
)
4025 if (iomode
== IO_OUTPUT
)
4030 else if (peek_atom () != ATOM_LPAREN
)
4033 gfc_omp_declare_simd
*ods
= *odsp
;
4036 if (iomode
== IO_OUTPUT
)
4038 write_atom (ATOM_NAME
, "OMP_DECLARE_SIMD");
4041 gfc_omp_namelist
*n
;
4043 if (ods
->clauses
->inbranch
)
4044 mio_name (0, omp_declare_simd_clauses
);
4045 if (ods
->clauses
->notinbranch
)
4046 mio_name (1, omp_declare_simd_clauses
);
4047 if (ods
->clauses
->simdlen_expr
)
4049 mio_name (2, omp_declare_simd_clauses
);
4050 mio_expr (&ods
->clauses
->simdlen_expr
);
4052 for (n
= ods
->clauses
->lists
[OMP_LIST_UNIFORM
]; n
; n
= n
->next
)
4054 mio_name (3, omp_declare_simd_clauses
);
4055 mio_symbol_ref (&n
->sym
);
4057 for (n
= ods
->clauses
->lists
[OMP_LIST_LINEAR
]; n
; n
= n
->next
)
4059 mio_name (4, omp_declare_simd_clauses
);
4060 mio_symbol_ref (&n
->sym
);
4061 mio_expr (&n
->expr
);
4063 for (n
= ods
->clauses
->lists
[OMP_LIST_ALIGNED
]; n
; n
= n
->next
)
4065 mio_name (5, omp_declare_simd_clauses
);
4066 mio_symbol_ref (&n
->sym
);
4067 mio_expr (&n
->expr
);
4073 gfc_omp_namelist
**ptrs
[3] = { NULL
, NULL
, NULL
};
4075 require_atom (ATOM_NAME
);
4076 *odsp
= ods
= gfc_get_omp_declare_simd ();
4077 ods
->where
= gfc_current_locus
;
4078 ods
->proc_name
= ns
->proc_name
;
4079 if (peek_atom () == ATOM_NAME
)
4081 ods
->clauses
= gfc_get_omp_clauses ();
4082 ptrs
[0] = &ods
->clauses
->lists
[OMP_LIST_UNIFORM
];
4083 ptrs
[1] = &ods
->clauses
->lists
[OMP_LIST_LINEAR
];
4084 ptrs
[2] = &ods
->clauses
->lists
[OMP_LIST_ALIGNED
];
4086 while (peek_atom () == ATOM_NAME
)
4088 gfc_omp_namelist
*n
;
4089 int t
= mio_name (0, omp_declare_simd_clauses
);
4093 case 0: ods
->clauses
->inbranch
= true; break;
4094 case 1: ods
->clauses
->notinbranch
= true; break;
4095 case 2: mio_expr (&ods
->clauses
->simdlen_expr
); break;
4099 *ptrs
[t
- 3] = n
= gfc_get_omp_namelist ();
4100 ptrs
[t
- 3] = &n
->next
;
4101 mio_symbol_ref (&n
->sym
);
4103 mio_expr (&n
->expr
);
4109 mio_omp_declare_simd (ns
, &ods
->next
);
4115 static const mstring omp_declare_reduction_stmt
[] =
4117 minit ("ASSIGN", 0),
4124 mio_omp_udr_expr (gfc_omp_udr
*udr
, gfc_symbol
**sym1
, gfc_symbol
**sym2
,
4125 gfc_namespace
*ns
, bool is_initializer
)
4127 if (iomode
== IO_OUTPUT
)
4129 if ((*sym1
)->module
== NULL
)
4131 (*sym1
)->module
= module_name
;
4132 (*sym2
)->module
= module_name
;
4134 mio_symbol_ref (sym1
);
4135 mio_symbol_ref (sym2
);
4136 if (ns
->code
->op
== EXEC_ASSIGN
)
4138 mio_name (0, omp_declare_reduction_stmt
);
4139 mio_expr (&ns
->code
->expr1
);
4140 mio_expr (&ns
->code
->expr2
);
4145 mio_name (1, omp_declare_reduction_stmt
);
4146 mio_symtree_ref (&ns
->code
->symtree
);
4147 mio_actual_arglist (&ns
->code
->ext
.actual
);
4149 flag
= ns
->code
->resolved_isym
!= NULL
;
4150 mio_integer (&flag
);
4152 write_atom (ATOM_STRING
, ns
->code
->resolved_isym
->name
);
4154 mio_symbol_ref (&ns
->code
->resolved_sym
);
4159 pointer_info
*p1
= mio_symbol_ref (sym1
);
4160 pointer_info
*p2
= mio_symbol_ref (sym2
);
4162 gcc_assert (p1
->u
.rsym
.ns
== p2
->u
.rsym
.ns
);
4163 gcc_assert (p1
->u
.rsym
.sym
== NULL
);
4164 /* Add hidden symbols to the symtree. */
4165 pointer_info
*q
= get_integer (p1
->u
.rsym
.ns
);
4166 q
->u
.pointer
= (void *) ns
;
4167 sym
= gfc_new_symbol (is_initializer
? "omp_priv" : "omp_out", ns
);
4169 sym
->module
= gfc_get_string (p1
->u
.rsym
.module
);
4170 associate_integer_pointer (p1
, sym
);
4171 sym
->attr
.omp_udr_artificial_var
= 1;
4172 gcc_assert (p2
->u
.rsym
.sym
== NULL
);
4173 sym
= gfc_new_symbol (is_initializer
? "omp_orig" : "omp_in", ns
);
4175 sym
->module
= gfc_get_string (p2
->u
.rsym
.module
);
4176 associate_integer_pointer (p2
, sym
);
4177 sym
->attr
.omp_udr_artificial_var
= 1;
4178 if (mio_name (0, omp_declare_reduction_stmt
) == 0)
4180 ns
->code
= gfc_get_code (EXEC_ASSIGN
);
4181 mio_expr (&ns
->code
->expr1
);
4182 mio_expr (&ns
->code
->expr2
);
4187 ns
->code
= gfc_get_code (EXEC_CALL
);
4188 mio_symtree_ref (&ns
->code
->symtree
);
4189 mio_actual_arglist (&ns
->code
->ext
.actual
);
4191 mio_integer (&flag
);
4194 require_atom (ATOM_STRING
);
4195 ns
->code
->resolved_isym
= gfc_find_subroutine (atom_string
);
4199 mio_symbol_ref (&ns
->code
->resolved_sym
);
4201 ns
->code
->loc
= gfc_current_locus
;
4207 /* Unlike most other routines, the address of the symbol node is already
4208 fixed on input and the name/module has already been filled in.
4209 If you update the symbol format here, don't forget to update read_module
4210 as well (look for "seek to the symbol's component list"). */
4213 mio_symbol (gfc_symbol
*sym
)
4215 int intmod
= INTMOD_NONE
;
4219 mio_symbol_attribute (&sym
->attr
);
4221 /* Note that components are always saved, even if they are supposed
4222 to be private. Component access is checked during searching. */
4223 mio_component_list (&sym
->components
, sym
->attr
.vtype
);
4224 if (sym
->components
!= NULL
)
4225 sym
->component_access
4226 = MIO_NAME (gfc_access
) (sym
->component_access
, access_types
);
4228 mio_typespec (&sym
->ts
);
4229 if (sym
->ts
.type
== BT_CLASS
)
4230 sym
->attr
.class_ok
= 1;
4232 if (iomode
== IO_OUTPUT
)
4233 mio_namespace_ref (&sym
->formal_ns
);
4236 mio_namespace_ref (&sym
->formal_ns
);
4238 sym
->formal_ns
->proc_name
= sym
;
4241 /* Save/restore common block links. */
4242 mio_symbol_ref (&sym
->common_next
);
4244 mio_formal_arglist (&sym
->formal
);
4246 if (sym
->attr
.flavor
== FL_PARAMETER
)
4247 mio_expr (&sym
->value
);
4249 mio_array_spec (&sym
->as
);
4251 mio_symbol_ref (&sym
->result
);
4253 if (sym
->attr
.cray_pointee
)
4254 mio_symbol_ref (&sym
->cp_pointer
);
4256 /* Load/save the f2k_derived namespace of a derived-type symbol. */
4257 mio_full_f2k_derived (sym
);
4261 /* Add the fields that say whether this is from an intrinsic module,
4262 and if so, what symbol it is within the module. */
4263 /* mio_integer (&(sym->from_intmod)); */
4264 if (iomode
== IO_OUTPUT
)
4266 intmod
= sym
->from_intmod
;
4267 mio_integer (&intmod
);
4271 mio_integer (&intmod
);
4273 sym
->from_intmod
= current_intmod
;
4275 sym
->from_intmod
= (intmod_id
) intmod
;
4278 mio_integer (&(sym
->intmod_sym_id
));
4280 if (gfc_fl_struct (sym
->attr
.flavor
))
4281 mio_integer (&(sym
->hash_value
));
4284 && sym
->formal_ns
->proc_name
== sym
4285 && sym
->formal_ns
->entries
== NULL
)
4286 mio_omp_declare_simd (sym
->formal_ns
, &sym
->formal_ns
->omp_declare_simd
);
4292 /************************* Top level subroutines *************************/
4294 /* Given a root symtree node and a symbol, try to find a symtree that
4295 references the symbol that is not a unique name. */
4297 static gfc_symtree
*
4298 find_symtree_for_symbol (gfc_symtree
*st
, gfc_symbol
*sym
)
4300 gfc_symtree
*s
= NULL
;
4305 s
= find_symtree_for_symbol (st
->right
, sym
);
4308 s
= find_symtree_for_symbol (st
->left
, sym
);
4312 if (st
->n
.sym
== sym
&& !check_unique_name (st
->name
))
4319 /* A recursive function to look for a specific symbol by name and by
4320 module. Whilst several symtrees might point to one symbol, its
4321 is sufficient for the purposes here than one exist. Note that
4322 generic interfaces are distinguished as are symbols that have been
4323 renamed in another module. */
4324 static gfc_symtree
*
4325 find_symbol (gfc_symtree
*st
, const char *name
,
4326 const char *module
, int generic
)
4329 gfc_symtree
*retval
, *s
;
4331 if (st
== NULL
|| st
->n
.sym
== NULL
)
4334 c
= strcmp (name
, st
->n
.sym
->name
);
4335 if (c
== 0 && st
->n
.sym
->module
4336 && strcmp (module
, st
->n
.sym
->module
) == 0
4337 && !check_unique_name (st
->name
))
4339 s
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
4341 /* Detect symbols that are renamed by use association in another
4342 module by the absence of a symtree and null attr.use_rename,
4343 since the latter is not transmitted in the module file. */
4344 if (((!generic
&& !st
->n
.sym
->attr
.generic
)
4345 || (generic
&& st
->n
.sym
->attr
.generic
))
4346 && !(s
== NULL
&& !st
->n
.sym
->attr
.use_rename
))
4350 retval
= find_symbol (st
->left
, name
, module
, generic
);
4353 retval
= find_symbol (st
->right
, name
, module
, generic
);
4359 /* Skip a list between balanced left and right parens.
4360 By setting NEST_LEVEL one assumes that a number of NEST_LEVEL opening parens
4361 have been already parsed by hand, and the remaining of the content is to be
4362 skipped here. The default value is 0 (balanced parens). */
4365 skip_list (int nest_level
= 0)
4372 switch (parse_atom ())
4395 /* Load operator interfaces from the module. Interfaces are unusual
4396 in that they attach themselves to existing symbols. */
4399 load_operator_interfaces (void)
4402 char name
[GFC_MAX_SYMBOL_LEN
+ 1], module
[GFC_MAX_SYMBOL_LEN
+ 1];
4404 pointer_info
*pi
= NULL
;
4409 while (peek_atom () != ATOM_RPAREN
)
4413 mio_internal_string (name
);
4414 mio_internal_string (module
);
4416 n
= number_use_names (name
, true);
4419 for (i
= 1; i
<= n
; i
++)
4421 /* Decide if we need to load this one or not. */
4422 p
= find_use_name_n (name
, &i
, true);
4426 while (parse_atom () != ATOM_RPAREN
);
4432 uop
= gfc_get_uop (p
);
4433 pi
= mio_interface_rest (&uop
->op
);
4437 if (gfc_find_uop (p
, NULL
))
4439 uop
= gfc_get_uop (p
);
4440 uop
->op
= gfc_get_interface ();
4441 uop
->op
->where
= gfc_current_locus
;
4442 add_fixup (pi
->integer
, &uop
->op
->sym
);
4451 /* Load interfaces from the module. Interfaces are unusual in that
4452 they attach themselves to existing symbols. */
4455 load_generic_interfaces (void)
4458 char name
[GFC_MAX_SYMBOL_LEN
+ 1], module
[GFC_MAX_SYMBOL_LEN
+ 1];
4460 gfc_interface
*generic
= NULL
, *gen
= NULL
;
4462 bool ambiguous_set
= false;
4466 while (peek_atom () != ATOM_RPAREN
)
4470 mio_internal_string (name
);
4471 mio_internal_string (module
);
4473 n
= number_use_names (name
, false);
4474 renamed
= n
? 1 : 0;
4477 for (i
= 1; i
<= n
; i
++)
4480 /* Decide if we need to load this one or not. */
4481 p
= find_use_name_n (name
, &i
, false);
4483 st
= find_symbol (gfc_current_ns
->sym_root
,
4484 name
, module_name
, 1);
4486 if (!p
|| gfc_find_symbol (p
, NULL
, 0, &sym
))
4488 /* Skip the specific names for these cases. */
4489 while (i
== 1 && parse_atom () != ATOM_RPAREN
);
4494 /* If the symbol exists already and is being USEd without being
4495 in an ONLY clause, do not load a new symtree(11.3.2). */
4496 if (!only_flag
&& st
)
4504 if (strcmp (st
->name
, p
) != 0)
4506 st
= gfc_new_symtree (&gfc_current_ns
->sym_root
, p
);
4512 /* Since we haven't found a valid generic interface, we had
4516 gfc_get_symbol (p
, NULL
, &sym
);
4517 sym
->name
= gfc_get_string (name
);
4518 sym
->module
= module_name
;
4519 sym
->attr
.flavor
= FL_PROCEDURE
;
4520 sym
->attr
.generic
= 1;
4521 sym
->attr
.use_assoc
= 1;
4526 /* Unless sym is a generic interface, this reference
4529 st
= gfc_find_symtree (gfc_current_ns
->sym_root
, p
);
4533 if (st
&& !sym
->attr
.generic
4536 && strcmp (module
, sym
->module
))
4538 ambiguous_set
= true;
4543 sym
->attr
.use_only
= only_flag
;
4544 sym
->attr
.use_rename
= renamed
;
4548 mio_interface_rest (&sym
->generic
);
4549 generic
= sym
->generic
;
4551 else if (!sym
->generic
)
4553 sym
->generic
= generic
;
4554 sym
->attr
.generic_copy
= 1;
4557 /* If a procedure that is not generic has generic interfaces
4558 that include itself, it is generic! We need to take care
4559 to retain symbols ambiguous that were already so. */
4560 if (sym
->attr
.use_assoc
4561 && !sym
->attr
.generic
4562 && sym
->attr
.flavor
== FL_PROCEDURE
)
4564 for (gen
= generic
; gen
; gen
= gen
->next
)
4566 if (gen
->sym
== sym
)
4568 sym
->attr
.generic
= 1;
4583 /* Load common blocks. */
4588 char name
[GFC_MAX_SYMBOL_LEN
+ 1];
4593 while (peek_atom () != ATOM_RPAREN
)
4598 mio_internal_string (name
);
4600 p
= gfc_get_common (name
, 1);
4602 mio_symbol_ref (&p
->head
);
4603 mio_integer (&flags
);
4607 p
->threadprivate
= 1;
4610 /* Get whether this was a bind(c) common or not. */
4611 mio_integer (&p
->is_bind_c
);
4612 /* Get the binding label. */
4613 label
= read_string ();
4615 p
->binding_label
= IDENTIFIER_POINTER (get_identifier (label
));
4625 /* Load equivalences. The flag in_load_equiv informs mio_expr_ref of this
4626 so that unused variables are not loaded and so that the expression can
4632 gfc_equiv
*head
, *tail
, *end
, *eq
, *equiv
;
4636 in_load_equiv
= true;
4638 end
= gfc_current_ns
->equiv
;
4639 while (end
!= NULL
&& end
->next
!= NULL
)
4642 while (peek_atom () != ATOM_RPAREN
) {
4646 while(peek_atom () != ATOM_RPAREN
)
4649 head
= tail
= gfc_get_equiv ();
4652 tail
->eq
= gfc_get_equiv ();
4656 mio_pool_string (&tail
->module
);
4657 mio_expr (&tail
->expr
);
4660 /* Check for duplicate equivalences being loaded from different modules */
4662 for (equiv
= gfc_current_ns
->equiv
; equiv
; equiv
= equiv
->next
)
4664 if (equiv
->module
&& head
->module
4665 && strcmp (equiv
->module
, head
->module
) == 0)
4674 for (eq
= head
; eq
; eq
= head
)
4677 gfc_free_expr (eq
->expr
);
4683 gfc_current_ns
->equiv
= head
;
4694 in_load_equiv
= false;
4698 /* This function loads OpenMP user defined reductions. */
4700 load_omp_udrs (void)
4703 while (peek_atom () != ATOM_RPAREN
)
4705 const char *name
, *newname
;
4709 gfc_omp_reduction_op rop
= OMP_REDUCTION_USER
;
4712 mio_pool_string (&name
);
4715 if (strncmp (name
, "operator ", sizeof ("operator ") - 1) == 0)
4717 const char *p
= name
+ sizeof ("operator ") - 1;
4718 if (strcmp (p
, "+") == 0)
4719 rop
= OMP_REDUCTION_PLUS
;
4720 else if (strcmp (p
, "*") == 0)
4721 rop
= OMP_REDUCTION_TIMES
;
4722 else if (strcmp (p
, "-") == 0)
4723 rop
= OMP_REDUCTION_MINUS
;
4724 else if (strcmp (p
, ".and.") == 0)
4725 rop
= OMP_REDUCTION_AND
;
4726 else if (strcmp (p
, ".or.") == 0)
4727 rop
= OMP_REDUCTION_OR
;
4728 else if (strcmp (p
, ".eqv.") == 0)
4729 rop
= OMP_REDUCTION_EQV
;
4730 else if (strcmp (p
, ".neqv.") == 0)
4731 rop
= OMP_REDUCTION_NEQV
;
4734 if (rop
== OMP_REDUCTION_USER
&& name
[0] == '.')
4736 size_t len
= strlen (name
+ 1);
4737 altname
= XALLOCAVEC (char, len
);
4738 gcc_assert (name
[len
] == '.');
4739 memcpy (altname
, name
+ 1, len
- 1);
4740 altname
[len
- 1] = '\0';
4743 if (rop
== OMP_REDUCTION_USER
)
4744 newname
= find_use_name (altname
? altname
: name
, !!altname
);
4745 else if (only_flag
&& find_use_operator ((gfc_intrinsic_op
) rop
) == NULL
)
4747 if (newname
== NULL
)
4752 if (altname
&& newname
!= altname
)
4754 size_t len
= strlen (newname
);
4755 altname
= XALLOCAVEC (char, len
+ 3);
4757 memcpy (altname
+ 1, newname
, len
);
4758 altname
[len
+ 1] = '.';
4759 altname
[len
+ 2] = '\0';
4760 name
= gfc_get_string (altname
);
4762 st
= gfc_find_symtree (gfc_current_ns
->omp_udr_root
, name
);
4763 gfc_omp_udr
*udr
= gfc_omp_udr_find (st
, &ts
);
4766 require_atom (ATOM_INTEGER
);
4767 pointer_info
*p
= get_integer (atom_int
);
4768 if (strcmp (p
->u
.rsym
.module
, udr
->omp_out
->module
))
4770 gfc_error ("Ambiguous !$OMP DECLARE REDUCTION from "
4772 p
->u
.rsym
.module
, &gfc_current_locus
);
4773 gfc_error ("Previous !$OMP DECLARE REDUCTION from module "
4775 udr
->omp_out
->module
, &udr
->where
);
4780 udr
= gfc_get_omp_udr ();
4784 udr
->where
= gfc_current_locus
;
4785 udr
->combiner_ns
= gfc_get_namespace (gfc_current_ns
, 1);
4786 udr
->combiner_ns
->proc_name
= gfc_current_ns
->proc_name
;
4787 mio_omp_udr_expr (udr
, &udr
->omp_out
, &udr
->omp_in
, udr
->combiner_ns
,
4789 if (peek_atom () != ATOM_RPAREN
)
4791 udr
->initializer_ns
= gfc_get_namespace (gfc_current_ns
, 1);
4792 udr
->initializer_ns
->proc_name
= gfc_current_ns
->proc_name
;
4793 mio_omp_udr_expr (udr
, &udr
->omp_priv
, &udr
->omp_orig
,
4794 udr
->initializer_ns
, true);
4798 udr
->next
= st
->n
.omp_udr
;
4799 st
->n
.omp_udr
= udr
;
4803 st
= gfc_new_symtree (&gfc_current_ns
->omp_udr_root
, name
);
4804 st
->n
.omp_udr
= udr
;
4812 /* Recursive function to traverse the pointer_info tree and load a
4813 needed symbol. We return nonzero if we load a symbol and stop the
4814 traversal, because the act of loading can alter the tree. */
4817 load_needed (pointer_info
*p
)
4828 rv
|= load_needed (p
->left
);
4829 rv
|= load_needed (p
->right
);
4831 if (p
->type
!= P_SYMBOL
|| p
->u
.rsym
.state
!= NEEDED
)
4834 p
->u
.rsym
.state
= USED
;
4836 set_module_locus (&p
->u
.rsym
.where
);
4838 sym
= p
->u
.rsym
.sym
;
4841 q
= get_integer (p
->u
.rsym
.ns
);
4843 ns
= (gfc_namespace
*) q
->u
.pointer
;
4846 /* Create an interface namespace if necessary. These are
4847 the namespaces that hold the formal parameters of module
4850 ns
= gfc_get_namespace (NULL
, 0);
4851 associate_integer_pointer (q
, ns
);
4854 /* Use the module sym as 'proc_name' so that gfc_get_symbol_decl
4855 doesn't go pear-shaped if the symbol is used. */
4857 gfc_find_symbol (p
->u
.rsym
.module
, gfc_current_ns
,
4860 sym
= gfc_new_symbol (p
->u
.rsym
.true_name
, ns
);
4861 sym
->name
= gfc_dt_lower_string (p
->u
.rsym
.true_name
);
4862 sym
->module
= gfc_get_string (p
->u
.rsym
.module
);
4863 if (p
->u
.rsym
.binding_label
)
4864 sym
->binding_label
= IDENTIFIER_POINTER (get_identifier
4865 (p
->u
.rsym
.binding_label
));
4867 associate_integer_pointer (p
, sym
);
4871 sym
->attr
.use_assoc
= 1;
4873 /* Unliked derived types, a STRUCTURE may share names with other symbols.
4874 We greedily converted the the symbol name to lowercase before we knew its
4875 type, so now we must fix it. */
4876 if (sym
->attr
.flavor
== FL_STRUCT
)
4877 sym
->name
= gfc_dt_upper_string (sym
->name
);
4879 /* Mark as only or rename for later diagnosis for explicitly imported
4880 but not used warnings; don't mark internal symbols such as __vtab,
4881 __def_init etc. Only mark them if they have been explicitly loaded. */
4883 if (only_flag
&& sym
->name
[0] != '_' && sym
->name
[1] != '_')
4887 /* Search the use/rename list for the variable; if the variable is
4889 for (u
= gfc_rename_list
; u
; u
= u
->next
)
4891 if (strcmp (u
->use_name
, sym
->name
) == 0)
4893 sym
->attr
.use_only
= 1;
4899 if (p
->u
.rsym
.renamed
)
4900 sym
->attr
.use_rename
= 1;
4906 /* Recursive function for cleaning up things after a module has been read. */
4909 read_cleanup (pointer_info
*p
)
4917 read_cleanup (p
->left
);
4918 read_cleanup (p
->right
);
4920 if (p
->type
== P_SYMBOL
&& p
->u
.rsym
.state
== USED
&& !p
->u
.rsym
.referenced
)
4923 /* Add hidden symbols to the symtree. */
4924 q
= get_integer (p
->u
.rsym
.ns
);
4925 ns
= (gfc_namespace
*) q
->u
.pointer
;
4927 if (!p
->u
.rsym
.sym
->attr
.vtype
4928 && !p
->u
.rsym
.sym
->attr
.vtab
)
4929 st
= gfc_get_unique_symtree (ns
);
4932 /* There is no reason to use 'unique_symtrees' for vtabs or
4933 vtypes - their name is fine for a symtree and reduces the
4934 namespace pollution. */
4935 st
= gfc_find_symtree (ns
->sym_root
, p
->u
.rsym
.sym
->name
);
4937 st
= gfc_new_symtree (&ns
->sym_root
, p
->u
.rsym
.sym
->name
);
4940 st
->n
.sym
= p
->u
.rsym
.sym
;
4943 /* Fixup any symtree references. */
4944 p
->u
.rsym
.symtree
= st
;
4945 resolve_fixups (p
->u
.rsym
.stfixup
, st
);
4946 p
->u
.rsym
.stfixup
= NULL
;
4949 /* Free unused symbols. */
4950 if (p
->type
== P_SYMBOL
&& p
->u
.rsym
.state
== UNUSED
)
4951 gfc_free_symbol (p
->u
.rsym
.sym
);
4955 /* It is not quite enough to check for ambiguity in the symbols by
4956 the loaded symbol and the new symbol not being identical. */
4958 check_for_ambiguous (gfc_symtree
*st
, pointer_info
*info
)
4962 symbol_attribute attr
;
4965 if (gfc_current_ns
->proc_name
&& st
->name
== gfc_current_ns
->proc_name
->name
)
4967 gfc_error ("%qs of module %qs, imported at %C, is also the name of the "
4968 "current program unit", st
->name
, module_name
);
4973 rsym
= info
->u
.rsym
.sym
;
4977 if (st_sym
->attr
.vtab
|| st_sym
->attr
.vtype
)
4980 /* If the existing symbol is generic from a different module and
4981 the new symbol is generic there can be no ambiguity. */
4982 if (st_sym
->attr
.generic
4984 && st_sym
->module
!= module_name
)
4986 /* The new symbol's attributes have not yet been read. Since
4987 we need attr.generic, read it directly. */
4988 get_module_locus (&locus
);
4989 set_module_locus (&info
->u
.rsym
.where
);
4992 mio_symbol_attribute (&attr
);
4993 set_module_locus (&locus
);
5002 /* Read a module file. */
5007 module_locus operator_interfaces
, user_operators
, omp_udrs
;
5009 char name
[GFC_MAX_SYMBOL_LEN
+ 1];
5011 /* Workaround -Wmaybe-uninitialized false positive during
5012 profiledbootstrap by initializing them. */
5013 int ambiguous
= 0, j
, nuse
, symbol
= 0;
5014 pointer_info
*info
, *q
;
5015 gfc_use_rename
*u
= NULL
;
5019 get_module_locus (&operator_interfaces
); /* Skip these for now. */
5022 get_module_locus (&user_operators
);
5026 /* Skip commons and equivalences for now. */
5030 /* Skip OpenMP UDRs. */
5031 get_module_locus (&omp_udrs
);
5036 /* Create the fixup nodes for all the symbols. */
5038 while (peek_atom () != ATOM_RPAREN
)
5041 require_atom (ATOM_INTEGER
);
5042 info
= get_integer (atom_int
);
5044 info
->type
= P_SYMBOL
;
5045 info
->u
.rsym
.state
= UNUSED
;
5047 info
->u
.rsym
.true_name
= read_string ();
5048 info
->u
.rsym
.module
= read_string ();
5049 bind_label
= read_string ();
5050 if (strlen (bind_label
))
5051 info
->u
.rsym
.binding_label
= bind_label
;
5053 XDELETEVEC (bind_label
);
5055 require_atom (ATOM_INTEGER
);
5056 info
->u
.rsym
.ns
= atom_int
;
5058 get_module_locus (&info
->u
.rsym
.where
);
5060 /* See if the symbol has already been loaded by a previous module.
5061 If so, we reference the existing symbol and prevent it from
5062 being loaded again. This should not happen if the symbol being
5063 read is an index for an assumed shape dummy array (ns != 1). */
5065 sym
= find_true_name (info
->u
.rsym
.true_name
, info
->u
.rsym
.module
);
5068 || (sym
->attr
.flavor
== FL_VARIABLE
&& info
->u
.rsym
.ns
!=1))
5074 info
->u
.rsym
.state
= USED
;
5075 info
->u
.rsym
.sym
= sym
;
5076 /* The current symbol has already been loaded, so we can avoid loading
5077 it again. However, if it is a derived type, some of its components
5078 can be used in expressions in the module. To avoid the module loading
5079 failing, we need to associate the module's component pointer indexes
5080 with the existing symbol's component pointers. */
5081 if (gfc_fl_struct (sym
->attr
.flavor
))
5085 /* First seek to the symbol's component list. */
5086 mio_lparen (); /* symbol opening. */
5087 skip_list (); /* skip symbol attribute. */
5089 mio_lparen (); /* component list opening. */
5090 for (c
= sym
->components
; c
; c
= c
->next
)
5093 const char *comp_name
;
5096 mio_lparen (); /* component opening. */
5098 p
= get_integer (n
);
5099 if (p
->u
.pointer
== NULL
)
5100 associate_integer_pointer (p
, c
);
5101 mio_pool_string (&comp_name
);
5102 gcc_assert (comp_name
== c
->name
);
5103 skip_list (1); /* component end. */
5105 mio_rparen (); /* component list closing. */
5107 skip_list (1); /* symbol end. */
5112 /* Some symbols do not have a namespace (eg. formal arguments),
5113 so the automatic "unique symtree" mechanism must be suppressed
5114 by marking them as referenced. */
5115 q
= get_integer (info
->u
.rsym
.ns
);
5116 if (q
->u
.pointer
== NULL
)
5118 info
->u
.rsym
.referenced
= 1;
5122 /* If possible recycle the symtree that references the symbol.
5123 If a symtree is not found and the module does not import one,
5124 a unique-name symtree is found by read_cleanup. */
5125 st
= find_symtree_for_symbol (gfc_current_ns
->sym_root
, sym
);
5128 info
->u
.rsym
.symtree
= st
;
5129 info
->u
.rsym
.referenced
= 1;
5135 /* Parse the symtree lists. This lets us mark which symbols need to
5136 be loaded. Renaming is also done at this point by replacing the
5141 while (peek_atom () != ATOM_RPAREN
)
5143 mio_internal_string (name
);
5144 mio_integer (&ambiguous
);
5145 mio_integer (&symbol
);
5147 info
= get_integer (symbol
);
5149 /* See how many use names there are. If none, go through the start
5150 of the loop at least once. */
5151 nuse
= number_use_names (name
, false);
5152 info
->u
.rsym
.renamed
= nuse
? 1 : 0;
5157 for (j
= 1; j
<= nuse
; j
++)
5159 /* Get the jth local name for this symbol. */
5160 p
= find_use_name_n (name
, &j
, false);
5162 if (p
== NULL
&& strcmp (name
, module_name
) == 0)
5165 /* Exception: Always import vtabs & vtypes. */
5166 if (p
== NULL
&& name
[0] == '_'
5167 && (strncmp (name
, "__vtab_", 5) == 0
5168 || strncmp (name
, "__vtype_", 6) == 0))
5171 /* Skip symtree nodes not in an ONLY clause, unless there
5172 is an existing symtree loaded from another USE statement. */
5175 st
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
5177 && strcmp (st
->n
.sym
->name
, info
->u
.rsym
.true_name
) == 0
5178 && st
->n
.sym
->module
!= NULL
5179 && strcmp (st
->n
.sym
->module
, info
->u
.rsym
.module
) == 0)
5181 info
->u
.rsym
.symtree
= st
;
5182 info
->u
.rsym
.sym
= st
->n
.sym
;
5187 /* If a symbol of the same name and module exists already,
5188 this symbol, which is not in an ONLY clause, must not be
5189 added to the namespace(11.3.2). Note that find_symbol
5190 only returns the first occurrence that it finds. */
5191 if (!only_flag
&& !info
->u
.rsym
.renamed
5192 && strcmp (name
, module_name
) != 0
5193 && find_symbol (gfc_current_ns
->sym_root
, name
,
5197 st
= gfc_find_symtree (gfc_current_ns
->sym_root
, p
);
5200 && !(st
->n
.sym
&& st
->n
.sym
->attr
.used_in_submodule
))
5202 /* Check for ambiguous symbols. */
5203 if (check_for_ambiguous (st
, info
))
5206 info
->u
.rsym
.symtree
= st
;
5212 /* This symbol is host associated from a module in a
5213 submodule. Hide it with a unique symtree. */
5214 gfc_symtree
*s
= gfc_get_unique_symtree (gfc_current_ns
);
5215 s
->n
.sym
= st
->n
.sym
;
5220 /* Create a symtree node in the current namespace for this
5222 st
= check_unique_name (p
)
5223 ? gfc_get_unique_symtree (gfc_current_ns
)
5224 : gfc_new_symtree (&gfc_current_ns
->sym_root
, p
);
5225 st
->ambiguous
= ambiguous
;
5228 sym
= info
->u
.rsym
.sym
;
5230 /* Create a symbol node if it doesn't already exist. */
5233 info
->u
.rsym
.sym
= gfc_new_symbol (info
->u
.rsym
.true_name
,
5235 info
->u
.rsym
.sym
->name
= gfc_dt_lower_string (info
->u
.rsym
.true_name
);
5236 sym
= info
->u
.rsym
.sym
;
5237 sym
->module
= gfc_get_string (info
->u
.rsym
.module
);
5239 if (info
->u
.rsym
.binding_label
)
5240 sym
->binding_label
=
5241 IDENTIFIER_POINTER (get_identifier
5242 (info
->u
.rsym
.binding_label
));
5248 if (strcmp (name
, p
) != 0)
5249 sym
->attr
.use_rename
= 1;
5252 || (strncmp (name
, "__vtab_", 5) != 0
5253 && strncmp (name
, "__vtype_", 6) != 0))
5254 sym
->attr
.use_only
= only_flag
;
5256 /* Store the symtree pointing to this symbol. */
5257 info
->u
.rsym
.symtree
= st
;
5259 if (info
->u
.rsym
.state
== UNUSED
)
5260 info
->u
.rsym
.state
= NEEDED
;
5261 info
->u
.rsym
.referenced
= 1;
5268 /* Load intrinsic operator interfaces. */
5269 set_module_locus (&operator_interfaces
);
5272 for (i
= GFC_INTRINSIC_BEGIN
; i
!= GFC_INTRINSIC_END
; i
++)
5274 if (i
== INTRINSIC_USER
)
5279 u
= find_use_operator ((gfc_intrinsic_op
) i
);
5290 mio_interface (&gfc_current_ns
->op
[i
]);
5291 if (u
&& !gfc_current_ns
->op
[i
])
5297 /* Load generic and user operator interfaces. These must follow the
5298 loading of symtree because otherwise symbols can be marked as
5301 set_module_locus (&user_operators
);
5303 load_operator_interfaces ();
5304 load_generic_interfaces ();
5309 /* Load OpenMP user defined reductions. */
5310 set_module_locus (&omp_udrs
);
5313 /* At this point, we read those symbols that are needed but haven't
5314 been loaded yet. If one symbol requires another, the other gets
5315 marked as NEEDED if its previous state was UNUSED. */
5317 while (load_needed (pi_root
));
5319 /* Make sure all elements of the rename-list were found in the module. */
5321 for (u
= gfc_rename_list
; u
; u
= u
->next
)
5326 if (u
->op
== INTRINSIC_NONE
)
5328 gfc_error ("Symbol %qs referenced at %L not found in module %qs",
5329 u
->use_name
, &u
->where
, module_name
);
5333 if (u
->op
== INTRINSIC_USER
)
5335 gfc_error ("User operator %qs referenced at %L not found "
5336 "in module %qs", u
->use_name
, &u
->where
, module_name
);
5340 gfc_error ("Intrinsic operator %qs referenced at %L not found "
5341 "in module %qs", gfc_op2string (u
->op
), &u
->where
,
5345 /* Clean up symbol nodes that were never loaded, create references
5346 to hidden symbols. */
5348 read_cleanup (pi_root
);
5352 /* Given an access type that is specific to an entity and the default
5353 access, return nonzero if the entity is publicly accessible. If the
5354 element is declared as PUBLIC, then it is public; if declared
5355 PRIVATE, then private, and otherwise it is public unless the default
5356 access in this context has been declared PRIVATE. */
5358 static bool dump_smod
= false;
5361 check_access (gfc_access specific_access
, gfc_access default_access
)
5366 if (specific_access
== ACCESS_PUBLIC
)
5368 if (specific_access
== ACCESS_PRIVATE
)
5371 if (flag_module_private
)
5372 return default_access
== ACCESS_PUBLIC
;
5374 return default_access
!= ACCESS_PRIVATE
;
5379 gfc_check_symbol_access (gfc_symbol
*sym
)
5381 if (sym
->attr
.vtab
|| sym
->attr
.vtype
)
5384 return check_access (sym
->attr
.access
, sym
->ns
->default_access
);
5388 /* A structure to remember which commons we've already written. */
5390 struct written_common
5392 BBT_HEADER(written_common
);
5393 const char *name
, *label
;
5396 static struct written_common
*written_commons
= NULL
;
5398 /* Comparison function used for balancing the binary tree. */
5401 compare_written_commons (void *a1
, void *b1
)
5403 const char *aname
= ((struct written_common
*) a1
)->name
;
5404 const char *alabel
= ((struct written_common
*) a1
)->label
;
5405 const char *bname
= ((struct written_common
*) b1
)->name
;
5406 const char *blabel
= ((struct written_common
*) b1
)->label
;
5407 int c
= strcmp (aname
, bname
);
5409 return (c
!= 0 ? c
: strcmp (alabel
, blabel
));
5412 /* Free a list of written commons. */
5415 free_written_common (struct written_common
*w
)
5421 free_written_common (w
->left
);
5423 free_written_common (w
->right
);
5428 /* Write a common block to the module -- recursive helper function. */
5431 write_common_0 (gfc_symtree
*st
, bool this_module
)
5437 struct written_common
*w
;
5438 bool write_me
= true;
5443 write_common_0 (st
->left
, this_module
);
5445 /* We will write out the binding label, or "" if no label given. */
5446 name
= st
->n
.common
->name
;
5448 label
= (p
->is_bind_c
&& p
->binding_label
) ? p
->binding_label
: "";
5450 /* Check if we've already output this common. */
5451 w
= written_commons
;
5454 int c
= strcmp (name
, w
->name
);
5455 c
= (c
!= 0 ? c
: strcmp (label
, w
->label
));
5459 w
= (c
< 0) ? w
->left
: w
->right
;
5462 if (this_module
&& p
->use_assoc
)
5467 /* Write the common to the module. */
5469 mio_pool_string (&name
);
5471 mio_symbol_ref (&p
->head
);
5472 flags
= p
->saved
? 1 : 0;
5473 if (p
->threadprivate
)
5475 mio_integer (&flags
);
5477 /* Write out whether the common block is bind(c) or not. */
5478 mio_integer (&(p
->is_bind_c
));
5480 mio_pool_string (&label
);
5483 /* Record that we have written this common. */
5484 w
= XCNEW (struct written_common
);
5487 gfc_insert_bbt (&written_commons
, w
, compare_written_commons
);
5490 write_common_0 (st
->right
, this_module
);
5494 /* Write a common, by initializing the list of written commons, calling
5495 the recursive function write_common_0() and cleaning up afterwards. */
5498 write_common (gfc_symtree
*st
)
5500 written_commons
= NULL
;
5501 write_common_0 (st
, true);
5502 write_common_0 (st
, false);
5503 free_written_common (written_commons
);
5504 written_commons
= NULL
;
5508 /* Write the blank common block to the module. */
5511 write_blank_common (void)
5513 const char * name
= BLANK_COMMON_NAME
;
5515 /* TODO: Blank commons are not bind(c). The F2003 standard probably says
5516 this, but it hasn't been checked. Just making it so for now. */
5519 if (gfc_current_ns
->blank_common
.head
== NULL
)
5524 mio_pool_string (&name
);
5526 mio_symbol_ref (&gfc_current_ns
->blank_common
.head
);
5527 saved
= gfc_current_ns
->blank_common
.saved
;
5528 mio_integer (&saved
);
5530 /* Write out whether the common block is bind(c) or not. */
5531 mio_integer (&is_bind_c
);
5533 /* Write out an empty binding label. */
5534 write_atom (ATOM_STRING
, "");
5540 /* Write equivalences to the module. */
5549 for (eq
= gfc_current_ns
->equiv
; eq
; eq
= eq
->next
)
5553 for (e
= eq
; e
; e
= e
->eq
)
5555 if (e
->module
== NULL
)
5556 e
->module
= gfc_get_string ("%s.eq.%d", module_name
, num
);
5557 mio_allocated_string (e
->module
);
5558 mio_expr (&e
->expr
);
5567 /* Write a symbol to the module. */
5570 write_symbol (int n
, gfc_symbol
*sym
)
5574 if (sym
->attr
.flavor
== FL_UNKNOWN
|| sym
->attr
.flavor
== FL_LABEL
)
5575 gfc_internal_error ("write_symbol(): bad module symbol %qs", sym
->name
);
5579 if (gfc_fl_struct (sym
->attr
.flavor
))
5582 name
= gfc_dt_upper_string (sym
->name
);
5583 mio_pool_string (&name
);
5586 mio_pool_string (&sym
->name
);
5588 mio_pool_string (&sym
->module
);
5589 if ((sym
->attr
.is_bind_c
|| sym
->attr
.is_iso_c
) && sym
->binding_label
)
5591 label
= sym
->binding_label
;
5592 mio_pool_string (&label
);
5595 write_atom (ATOM_STRING
, "");
5597 mio_pointer_ref (&sym
->ns
);
5604 /* Recursive traversal function to write the initial set of symbols to
5605 the module. We check to see if the symbol should be written
5606 according to the access specification. */
5609 write_symbol0 (gfc_symtree
*st
)
5613 bool dont_write
= false;
5618 write_symbol0 (st
->left
);
5621 if (sym
->module
== NULL
)
5622 sym
->module
= module_name
;
5624 if (sym
->attr
.flavor
== FL_PROCEDURE
&& sym
->attr
.generic
5625 && !sym
->attr
.subroutine
&& !sym
->attr
.function
)
5628 if (!gfc_check_symbol_access (sym
))
5633 p
= get_pointer (sym
);
5634 if (p
->type
== P_UNKNOWN
)
5637 if (p
->u
.wsym
.state
!= WRITTEN
)
5639 write_symbol (p
->integer
, sym
);
5640 p
->u
.wsym
.state
= WRITTEN
;
5644 write_symbol0 (st
->right
);
5649 write_omp_udr (gfc_omp_udr
*udr
)
5653 case OMP_REDUCTION_USER
:
5654 /* Non-operators can't be used outside of the module. */
5655 if (udr
->name
[0] != '.')
5660 size_t len
= strlen (udr
->name
+ 1);
5661 char *name
= XALLOCAVEC (char, len
);
5662 memcpy (name
, udr
->name
, len
- 1);
5663 name
[len
- 1] = '\0';
5664 st
= gfc_find_symtree (gfc_current_ns
->uop_root
, name
);
5665 /* If corresponding user operator is private, don't write
5669 gfc_user_op
*uop
= st
->n
.uop
;
5670 if (!check_access (uop
->access
, uop
->ns
->default_access
))
5675 case OMP_REDUCTION_PLUS
:
5676 case OMP_REDUCTION_MINUS
:
5677 case OMP_REDUCTION_TIMES
:
5678 case OMP_REDUCTION_AND
:
5679 case OMP_REDUCTION_OR
:
5680 case OMP_REDUCTION_EQV
:
5681 case OMP_REDUCTION_NEQV
:
5682 /* If corresponding operator is private, don't write the UDR. */
5683 if (!check_access (gfc_current_ns
->operator_access
[udr
->rop
],
5684 gfc_current_ns
->default_access
))
5690 if (udr
->ts
.type
== BT_DERIVED
|| udr
->ts
.type
== BT_CLASS
)
5692 /* If derived type is private, don't write the UDR. */
5693 if (!gfc_check_symbol_access (udr
->ts
.u
.derived
))
5698 mio_pool_string (&udr
->name
);
5699 mio_typespec (&udr
->ts
);
5700 mio_omp_udr_expr (udr
, &udr
->omp_out
, &udr
->omp_in
, udr
->combiner_ns
, false);
5701 if (udr
->initializer_ns
)
5702 mio_omp_udr_expr (udr
, &udr
->omp_priv
, &udr
->omp_orig
,
5703 udr
->initializer_ns
, true);
5709 write_omp_udrs (gfc_symtree
*st
)
5714 write_omp_udrs (st
->left
);
5716 for (udr
= st
->n
.omp_udr
; udr
; udr
= udr
->next
)
5717 write_omp_udr (udr
);
5718 write_omp_udrs (st
->right
);
5722 /* Type for the temporary tree used when writing secondary symbols. */
5724 struct sorted_pointer_info
5726 BBT_HEADER (sorted_pointer_info
);
5731 #define gfc_get_sorted_pointer_info() XCNEW (sorted_pointer_info)
5733 /* Recursively traverse the temporary tree, free its contents. */
5736 free_sorted_pointer_info_tree (sorted_pointer_info
*p
)
5741 free_sorted_pointer_info_tree (p
->left
);
5742 free_sorted_pointer_info_tree (p
->right
);
5747 /* Comparison function for the temporary tree. */
5750 compare_sorted_pointer_info (void *_spi1
, void *_spi2
)
5752 sorted_pointer_info
*spi1
, *spi2
;
5753 spi1
= (sorted_pointer_info
*)_spi1
;
5754 spi2
= (sorted_pointer_info
*)_spi2
;
5756 if (spi1
->p
->integer
< spi2
->p
->integer
)
5758 if (spi1
->p
->integer
> spi2
->p
->integer
)
5764 /* Finds the symbols that need to be written and collects them in the
5765 sorted_pi tree so that they can be traversed in an order
5766 independent of memory addresses. */
5769 find_symbols_to_write(sorted_pointer_info
**tree
, pointer_info
*p
)
5774 if (p
->type
== P_SYMBOL
&& p
->u
.wsym
.state
== NEEDS_WRITE
)
5776 sorted_pointer_info
*sp
= gfc_get_sorted_pointer_info();
5779 gfc_insert_bbt (tree
, sp
, compare_sorted_pointer_info
);
5782 find_symbols_to_write (tree
, p
->left
);
5783 find_symbols_to_write (tree
, p
->right
);
5787 /* Recursive function that traverses the tree of symbols that need to be
5788 written and writes them in order. */
5791 write_symbol1_recursion (sorted_pointer_info
*sp
)
5796 write_symbol1_recursion (sp
->left
);
5798 pointer_info
*p1
= sp
->p
;
5799 gcc_assert (p1
->type
== P_SYMBOL
&& p1
->u
.wsym
.state
== NEEDS_WRITE
);
5801 p1
->u
.wsym
.state
= WRITTEN
;
5802 write_symbol (p1
->integer
, p1
->u
.wsym
.sym
);
5803 p1
->u
.wsym
.sym
->attr
.public_used
= 1;
5805 write_symbol1_recursion (sp
->right
);
5809 /* Write the secondary set of symbols to the module file. These are
5810 symbols that were not public yet are needed by the public symbols
5811 or another dependent symbol. The act of writing a symbol can add
5812 symbols to the pointer_info tree, so we return nonzero if a symbol
5813 was written and pass that information upwards. The caller will
5814 then call this function again until nothing was written. It uses
5815 the utility functions and a temporary tree to ensure a reproducible
5816 ordering of the symbol output and thus the module file. */
5819 write_symbol1 (pointer_info
*p
)
5824 /* Put symbols that need to be written into a tree sorted on the
5827 sorted_pointer_info
*spi_root
= NULL
;
5828 find_symbols_to_write (&spi_root
, p
);
5830 /* No symbols to write, return. */
5834 /* Otherwise, write and free the tree again. */
5835 write_symbol1_recursion (spi_root
);
5836 free_sorted_pointer_info_tree (spi_root
);
5842 /* Write operator interfaces associated with a symbol. */
5845 write_operator (gfc_user_op
*uop
)
5847 static char nullstring
[] = "";
5848 const char *p
= nullstring
;
5850 if (uop
->op
== NULL
|| !check_access (uop
->access
, uop
->ns
->default_access
))
5853 mio_symbol_interface (&uop
->name
, &p
, &uop
->op
);
5857 /* Write generic interfaces from the namespace sym_root. */
5860 write_generic (gfc_symtree
*st
)
5867 write_generic (st
->left
);
5870 if (sym
&& !check_unique_name (st
->name
)
5871 && sym
->generic
&& gfc_check_symbol_access (sym
))
5874 sym
->module
= module_name
;
5876 mio_symbol_interface (&st
->name
, &sym
->module
, &sym
->generic
);
5879 write_generic (st
->right
);
5884 write_symtree (gfc_symtree
*st
)
5891 /* A symbol in an interface body must not be visible in the
5893 if (sym
->ns
!= gfc_current_ns
5894 && sym
->ns
->proc_name
5895 && sym
->ns
->proc_name
->attr
.if_source
== IFSRC_IFBODY
)
5898 if (!gfc_check_symbol_access (sym
)
5899 || (sym
->attr
.flavor
== FL_PROCEDURE
&& sym
->attr
.generic
5900 && !sym
->attr
.subroutine
&& !sym
->attr
.function
))
5903 if (check_unique_name (st
->name
))
5906 p
= find_pointer (sym
);
5908 gfc_internal_error ("write_symtree(): Symbol not written");
5910 mio_pool_string (&st
->name
);
5911 mio_integer (&st
->ambiguous
);
5912 mio_integer (&p
->integer
);
5921 /* Write the operator interfaces. */
5924 for (i
= GFC_INTRINSIC_BEGIN
; i
!= GFC_INTRINSIC_END
; i
++)
5926 if (i
== INTRINSIC_USER
)
5929 mio_interface (check_access (gfc_current_ns
->operator_access
[i
],
5930 gfc_current_ns
->default_access
)
5931 ? &gfc_current_ns
->op
[i
] : NULL
);
5939 gfc_traverse_user_op (gfc_current_ns
, write_operator
);
5945 write_generic (gfc_current_ns
->sym_root
);
5951 write_blank_common ();
5952 write_common (gfc_current_ns
->common_root
);
5964 write_omp_udrs (gfc_current_ns
->omp_udr_root
);
5969 /* Write symbol information. First we traverse all symbols in the
5970 primary namespace, writing those that need to be written.
5971 Sometimes writing one symbol will cause another to need to be
5972 written. A list of these symbols ends up on the write stack, and
5973 we end by popping the bottom of the stack and writing the symbol
5974 until the stack is empty. */
5978 write_symbol0 (gfc_current_ns
->sym_root
);
5979 while (write_symbol1 (pi_root
))
5988 gfc_traverse_symtree (gfc_current_ns
->sym_root
, write_symtree
);
5993 /* Read a CRC32 sum from the gzip trailer of a module file. Returns
5994 true on success, false on failure. */
5997 read_crc32_from_module_file (const char* filename
, uLong
* crc
)
6003 /* Open the file in binary mode. */
6004 if ((file
= fopen (filename
, "rb")) == NULL
)
6007 /* The gzip crc32 value is found in the [END-8, END-4] bytes of the
6008 file. See RFC 1952. */
6009 if (fseek (file
, -8, SEEK_END
) != 0)
6015 /* Read the CRC32. */
6016 if (fread (buf
, 1, 4, file
) != 4)
6022 /* Close the file. */
6025 val
= (buf
[0] & 0xFF) + ((buf
[1] & 0xFF) << 8) + ((buf
[2] & 0xFF) << 16)
6026 + ((buf
[3] & 0xFF) << 24);
6029 /* For debugging, the CRC value printed in hexadecimal should match
6030 the CRC printed by "zcat -l -v filename".
6031 printf("CRC of file %s is %x\n", filename, val); */
6037 /* Given module, dump it to disk. If there was an error while
6038 processing the module, dump_flag will be set to zero and we delete
6039 the module file, even if it was already there. */
6042 dump_module (const char *name
, int dump_flag
)
6045 char *filename
, *filename_tmp
;
6048 module_name
= gfc_get_string (name
);
6052 name
= submodule_name
;
6053 n
= strlen (name
) + strlen (SUBMODULE_EXTENSION
) + 1;
6056 n
= strlen (name
) + strlen (MODULE_EXTENSION
) + 1;
6058 if (gfc_option
.module_dir
!= NULL
)
6060 n
+= strlen (gfc_option
.module_dir
);
6061 filename
= (char *) alloca (n
);
6062 strcpy (filename
, gfc_option
.module_dir
);
6063 strcat (filename
, name
);
6067 filename
= (char *) alloca (n
);
6068 strcpy (filename
, name
);
6072 strcat (filename
, SUBMODULE_EXTENSION
);
6074 strcat (filename
, MODULE_EXTENSION
);
6076 /* Name of the temporary file used to write the module. */
6077 filename_tmp
= (char *) alloca (n
+ 1);
6078 strcpy (filename_tmp
, filename
);
6079 strcat (filename_tmp
, "0");
6081 /* There was an error while processing the module. We delete the
6082 module file, even if it was already there. */
6089 if (gfc_cpp_makedep ())
6090 gfc_cpp_add_target (filename
);
6092 /* Write the module to the temporary file. */
6093 module_fp
= gzopen (filename_tmp
, "w");
6094 if (module_fp
== NULL
)
6095 gfc_fatal_error ("Can't open module file %qs for writing at %C: %s",
6096 filename_tmp
, xstrerror (errno
));
6098 gzprintf (module_fp
, "GFORTRAN module version '%s' created from %s\n",
6099 MOD_VERSION
, gfc_source_file
);
6101 /* Write the module itself. */
6108 free_pi_tree (pi_root
);
6113 if (gzclose (module_fp
))
6114 gfc_fatal_error ("Error writing module file %qs for writing: %s",
6115 filename_tmp
, xstrerror (errno
));
6117 /* Read the CRC32 from the gzip trailers of the module files and
6119 if (!read_crc32_from_module_file (filename_tmp
, &crc
)
6120 || !read_crc32_from_module_file (filename
, &crc_old
)
6123 /* Module file have changed, replace the old one. */
6124 if (remove (filename
) && errno
!= ENOENT
)
6125 gfc_fatal_error ("Can't delete module file %qs: %s", filename
,
6127 if (rename (filename_tmp
, filename
))
6128 gfc_fatal_error ("Can't rename module file %qs to %qs: %s",
6129 filename_tmp
, filename
, xstrerror (errno
));
6133 if (remove (filename_tmp
))
6134 gfc_fatal_error ("Can't delete temporary module file %qs: %s",
6135 filename_tmp
, xstrerror (errno
));
6141 gfc_dump_module (const char *name
, int dump_flag
)
6143 if (gfc_state_stack
->state
== COMP_SUBMODULE
)
6148 no_module_procedures
= true;
6149 dump_module (name
, dump_flag
);
6151 if (no_module_procedures
|| dump_smod
)
6154 /* Write a submodule file from a module. The 'dump_smod' flag switches
6155 off the check for PRIVATE entities. */
6157 submodule_name
= module_name
;
6158 dump_module (name
, dump_flag
);
6163 create_intrinsic_function (const char *name
, int id
,
6164 const char *modname
, intmod_id module
,
6165 bool subroutine
, gfc_symbol
*result_type
)
6167 gfc_intrinsic_sym
*isym
;
6168 gfc_symtree
*tmp_symtree
;
6171 tmp_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
6174 if (tmp_symtree
->n
.sym
&& tmp_symtree
->n
.sym
->module
6175 && strcmp (modname
, tmp_symtree
->n
.sym
->module
) == 0)
6177 gfc_error ("Symbol %qs at %C already declared", name
);
6181 gfc_get_sym_tree (name
, gfc_current_ns
, &tmp_symtree
, false);
6182 sym
= tmp_symtree
->n
.sym
;
6186 gfc_isym_id isym_id
= gfc_isym_id_by_intmod (module
, id
);
6187 isym
= gfc_intrinsic_subroutine_by_id (isym_id
);
6188 sym
->attr
.subroutine
= 1;
6192 gfc_isym_id isym_id
= gfc_isym_id_by_intmod (module
, id
);
6193 isym
= gfc_intrinsic_function_by_id (isym_id
);
6195 sym
->attr
.function
= 1;
6198 sym
->ts
.type
= BT_DERIVED
;
6199 sym
->ts
.u
.derived
= result_type
;
6200 sym
->ts
.is_c_interop
= 1;
6201 isym
->ts
.f90_type
= BT_VOID
;
6202 isym
->ts
.type
= BT_DERIVED
;
6203 isym
->ts
.f90_type
= BT_VOID
;
6204 isym
->ts
.u
.derived
= result_type
;
6205 isym
->ts
.is_c_interop
= 1;
6210 sym
->attr
.flavor
= FL_PROCEDURE
;
6211 sym
->attr
.intrinsic
= 1;
6213 sym
->module
= gfc_get_string (modname
);
6214 sym
->attr
.use_assoc
= 1;
6215 sym
->from_intmod
= module
;
6216 sym
->intmod_sym_id
= id
;
6220 /* Import the intrinsic ISO_C_BINDING module, generating symbols in
6221 the current namespace for all named constants, pointer types, and
6222 procedures in the module unless the only clause was used or a rename
6223 list was provided. */
6226 import_iso_c_binding_module (void)
6228 gfc_symbol
*mod_sym
= NULL
, *return_type
;
6229 gfc_symtree
*mod_symtree
= NULL
, *tmp_symtree
;
6230 gfc_symtree
*c_ptr
= NULL
, *c_funptr
= NULL
;
6231 const char *iso_c_module_name
= "__iso_c_binding";
6234 bool want_c_ptr
= false, want_c_funptr
= false;
6236 /* Look only in the current namespace. */
6237 mod_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, iso_c_module_name
);
6239 if (mod_symtree
== NULL
)
6241 /* symtree doesn't already exist in current namespace. */
6242 gfc_get_sym_tree (iso_c_module_name
, gfc_current_ns
, &mod_symtree
,
6245 if (mod_symtree
!= NULL
)
6246 mod_sym
= mod_symtree
->n
.sym
;
6248 gfc_internal_error ("import_iso_c_binding_module(): Unable to "
6249 "create symbol for %s", iso_c_module_name
);
6251 mod_sym
->attr
.flavor
= FL_MODULE
;
6252 mod_sym
->attr
.intrinsic
= 1;
6253 mod_sym
->module
= gfc_get_string (iso_c_module_name
);
6254 mod_sym
->from_intmod
= INTMOD_ISO_C_BINDING
;
6257 /* Check whether C_PTR or C_FUNPTR are in the include list, if so, load it;
6258 check also whether C_NULL_(FUN)PTR or C_(FUN)LOC are requested, which
6260 for (u
= gfc_rename_list
; u
; u
= u
->next
)
6262 if (strcmp (c_interop_kinds_table
[ISOCBINDING_NULL_PTR
].name
,
6265 else if (strcmp (c_interop_kinds_table
[ISOCBINDING_LOC
].name
,
6268 else if (strcmp (c_interop_kinds_table
[ISOCBINDING_NULL_FUNPTR
].name
,
6270 want_c_funptr
= true;
6271 else if (strcmp (c_interop_kinds_table
[ISOCBINDING_FUNLOC
].name
,
6273 want_c_funptr
= true;
6274 else if (strcmp (c_interop_kinds_table
[ISOCBINDING_PTR
].name
,
6277 c_ptr
= generate_isocbinding_symbol (iso_c_module_name
,
6278 (iso_c_binding_symbol
)
6280 u
->local_name
[0] ? u
->local_name
6284 else if (strcmp (c_interop_kinds_table
[ISOCBINDING_FUNPTR
].name
,
6288 = generate_isocbinding_symbol (iso_c_module_name
,
6289 (iso_c_binding_symbol
)
6291 u
->local_name
[0] ? u
->local_name
6297 if ((want_c_ptr
|| !only_flag
) && !c_ptr
)
6298 c_ptr
= generate_isocbinding_symbol (iso_c_module_name
,
6299 (iso_c_binding_symbol
)
6301 NULL
, NULL
, only_flag
);
6302 if ((want_c_funptr
|| !only_flag
) && !c_funptr
)
6303 c_funptr
= generate_isocbinding_symbol (iso_c_module_name
,
6304 (iso_c_binding_symbol
)
6306 NULL
, NULL
, only_flag
);
6308 /* Generate the symbols for the named constants representing
6309 the kinds for intrinsic data types. */
6310 for (i
= 0; i
< ISOCBINDING_NUMBER
; i
++)
6313 for (u
= gfc_rename_list
; u
; u
= u
->next
)
6314 if (strcmp (c_interop_kinds_table
[i
].name
, u
->use_name
) == 0)
6323 #define NAMED_FUNCTION(a,b,c,d) \
6325 not_in_std = (gfc_option.allow_std & d) == 0; \
6328 #define NAMED_SUBROUTINE(a,b,c,d) \
6330 not_in_std = (gfc_option.allow_std & d) == 0; \
6333 #define NAMED_INTCST(a,b,c,d) \
6335 not_in_std = (gfc_option.allow_std & d) == 0; \
6338 #define NAMED_REALCST(a,b,c,d) \
6340 not_in_std = (gfc_option.allow_std & d) == 0; \
6343 #define NAMED_CMPXCST(a,b,c,d) \
6345 not_in_std = (gfc_option.allow_std & d) == 0; \
6348 #include "iso-c-binding.def"
6356 gfc_error ("The symbol %qs, referenced at %L, is not "
6357 "in the selected standard", name
, &u
->where
);
6363 #define NAMED_FUNCTION(a,b,c,d) \
6365 if (a == ISOCBINDING_LOC) \
6366 return_type = c_ptr->n.sym; \
6367 else if (a == ISOCBINDING_FUNLOC) \
6368 return_type = c_funptr->n.sym; \
6370 return_type = NULL; \
6371 create_intrinsic_function (u->local_name[0] \
6372 ? u->local_name : u->use_name, \
6373 a, iso_c_module_name, \
6374 INTMOD_ISO_C_BINDING, false, \
6377 #define NAMED_SUBROUTINE(a,b,c,d) \
6379 create_intrinsic_function (u->local_name[0] ? u->local_name \
6381 a, iso_c_module_name, \
6382 INTMOD_ISO_C_BINDING, true, NULL); \
6384 #include "iso-c-binding.def"
6386 case ISOCBINDING_PTR
:
6387 case ISOCBINDING_FUNPTR
:
6388 /* Already handled above. */
6391 if (i
== ISOCBINDING_NULL_PTR
)
6392 tmp_symtree
= c_ptr
;
6393 else if (i
== ISOCBINDING_NULL_FUNPTR
)
6394 tmp_symtree
= c_funptr
;
6397 generate_isocbinding_symbol (iso_c_module_name
,
6398 (iso_c_binding_symbol
) i
,
6400 ? u
->local_name
: u
->use_name
,
6401 tmp_symtree
, false);
6405 if (!found
&& !only_flag
)
6407 /* Skip, if the symbol is not in the enabled standard. */
6410 #define NAMED_FUNCTION(a,b,c,d) \
6412 if ((gfc_option.allow_std & d) == 0) \
6415 #define NAMED_SUBROUTINE(a,b,c,d) \
6417 if ((gfc_option.allow_std & d) == 0) \
6420 #define NAMED_INTCST(a,b,c,d) \
6422 if ((gfc_option.allow_std & d) == 0) \
6425 #define NAMED_REALCST(a,b,c,d) \
6427 if ((gfc_option.allow_std & d) == 0) \
6430 #define NAMED_CMPXCST(a,b,c,d) \
6432 if ((gfc_option.allow_std & d) == 0) \
6435 #include "iso-c-binding.def"
6437 ; /* Not GFC_STD_* versioned. */
6442 #define NAMED_FUNCTION(a,b,c,d) \
6444 if (a == ISOCBINDING_LOC) \
6445 return_type = c_ptr->n.sym; \
6446 else if (a == ISOCBINDING_FUNLOC) \
6447 return_type = c_funptr->n.sym; \
6449 return_type = NULL; \
6450 create_intrinsic_function (b, a, iso_c_module_name, \
6451 INTMOD_ISO_C_BINDING, false, \
6454 #define NAMED_SUBROUTINE(a,b,c,d) \
6456 create_intrinsic_function (b, a, iso_c_module_name, \
6457 INTMOD_ISO_C_BINDING, true, NULL); \
6459 #include "iso-c-binding.def"
6461 case ISOCBINDING_PTR
:
6462 case ISOCBINDING_FUNPTR
:
6463 /* Already handled above. */
6466 if (i
== ISOCBINDING_NULL_PTR
)
6467 tmp_symtree
= c_ptr
;
6468 else if (i
== ISOCBINDING_NULL_FUNPTR
)
6469 tmp_symtree
= c_funptr
;
6472 generate_isocbinding_symbol (iso_c_module_name
,
6473 (iso_c_binding_symbol
) i
, NULL
,
6474 tmp_symtree
, false);
6479 for (u
= gfc_rename_list
; u
; u
= u
->next
)
6484 gfc_error ("Symbol %qs referenced at %L not found in intrinsic "
6485 "module ISO_C_BINDING", u
->use_name
, &u
->where
);
6490 /* Add an integer named constant from a given module. */
6493 create_int_parameter (const char *name
, int value
, const char *modname
,
6494 intmod_id module
, int id
)
6496 gfc_symtree
*tmp_symtree
;
6499 tmp_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
6500 if (tmp_symtree
!= NULL
)
6502 if (strcmp (modname
, tmp_symtree
->n
.sym
->module
) == 0)
6505 gfc_error ("Symbol %qs already declared", name
);
6508 gfc_get_sym_tree (name
, gfc_current_ns
, &tmp_symtree
, false);
6509 sym
= tmp_symtree
->n
.sym
;
6511 sym
->module
= gfc_get_string (modname
);
6512 sym
->attr
.flavor
= FL_PARAMETER
;
6513 sym
->ts
.type
= BT_INTEGER
;
6514 sym
->ts
.kind
= gfc_default_integer_kind
;
6515 sym
->value
= gfc_get_int_expr (gfc_default_integer_kind
, NULL
, value
);
6516 sym
->attr
.use_assoc
= 1;
6517 sym
->from_intmod
= module
;
6518 sym
->intmod_sym_id
= id
;
6522 /* Value is already contained by the array constructor, but not
6526 create_int_parameter_array (const char *name
, int size
, gfc_expr
*value
,
6527 const char *modname
, intmod_id module
, int id
)
6529 gfc_symtree
*tmp_symtree
;
6532 tmp_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
6533 if (tmp_symtree
!= NULL
)
6535 if (strcmp (modname
, tmp_symtree
->n
.sym
->module
) == 0)
6538 gfc_error ("Symbol %qs already declared", name
);
6541 gfc_get_sym_tree (name
, gfc_current_ns
, &tmp_symtree
, false);
6542 sym
= tmp_symtree
->n
.sym
;
6544 sym
->module
= gfc_get_string (modname
);
6545 sym
->attr
.flavor
= FL_PARAMETER
;
6546 sym
->ts
.type
= BT_INTEGER
;
6547 sym
->ts
.kind
= gfc_default_integer_kind
;
6548 sym
->attr
.use_assoc
= 1;
6549 sym
->from_intmod
= module
;
6550 sym
->intmod_sym_id
= id
;
6551 sym
->attr
.dimension
= 1;
6552 sym
->as
= gfc_get_array_spec ();
6554 sym
->as
->type
= AS_EXPLICIT
;
6555 sym
->as
->lower
[0] = gfc_get_int_expr (gfc_default_integer_kind
, NULL
, 1);
6556 sym
->as
->upper
[0] = gfc_get_int_expr (gfc_default_integer_kind
, NULL
, size
);
6559 sym
->value
->shape
= gfc_get_shape (1);
6560 mpz_init_set_ui (sym
->value
->shape
[0], size
);
6564 /* Add an derived type for a given module. */
6567 create_derived_type (const char *name
, const char *modname
,
6568 intmod_id module
, int id
)
6570 gfc_symtree
*tmp_symtree
;
6571 gfc_symbol
*sym
, *dt_sym
;
6572 gfc_interface
*intr
, *head
;
6574 tmp_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, name
);
6575 if (tmp_symtree
!= NULL
)
6577 if (strcmp (modname
, tmp_symtree
->n
.sym
->module
) == 0)
6580 gfc_error ("Symbol %qs already declared", name
);
6583 gfc_get_sym_tree (name
, gfc_current_ns
, &tmp_symtree
, false);
6584 sym
= tmp_symtree
->n
.sym
;
6585 sym
->module
= gfc_get_string (modname
);
6586 sym
->from_intmod
= module
;
6587 sym
->intmod_sym_id
= id
;
6588 sym
->attr
.flavor
= FL_PROCEDURE
;
6589 sym
->attr
.function
= 1;
6590 sym
->attr
.generic
= 1;
6592 gfc_get_sym_tree (gfc_dt_upper_string (sym
->name
),
6593 gfc_current_ns
, &tmp_symtree
, false);
6594 dt_sym
= tmp_symtree
->n
.sym
;
6595 dt_sym
->name
= gfc_get_string (sym
->name
);
6596 dt_sym
->attr
.flavor
= FL_DERIVED
;
6597 dt_sym
->attr
.private_comp
= 1;
6598 dt_sym
->attr
.zero_comp
= 1;
6599 dt_sym
->attr
.use_assoc
= 1;
6600 dt_sym
->module
= gfc_get_string (modname
);
6601 dt_sym
->from_intmod
= module
;
6602 dt_sym
->intmod_sym_id
= id
;
6604 head
= sym
->generic
;
6605 intr
= gfc_get_interface ();
6607 intr
->where
= gfc_current_locus
;
6609 sym
->generic
= intr
;
6610 sym
->attr
.if_source
= IFSRC_DECL
;
6614 /* Read the contents of the module file into a temporary buffer. */
6617 read_module_to_tmpbuf ()
6619 /* We don't know the uncompressed size, so enlarge the buffer as
6625 module_content
= XNEWVEC (char, cursz
);
6629 int nread
= gzread (module_fp
, module_content
+ len
, rsize
);
6634 module_content
= XRESIZEVEC (char, module_content
, cursz
);
6635 rsize
= cursz
- len
;
6638 module_content
= XRESIZEVEC (char, module_content
, len
+ 1);
6639 module_content
[len
] = '\0';
6645 /* USE the ISO_FORTRAN_ENV intrinsic module. */
6648 use_iso_fortran_env_module (void)
6650 static char mod
[] = "iso_fortran_env";
6652 gfc_symbol
*mod_sym
;
6653 gfc_symtree
*mod_symtree
;
6657 intmod_sym symbol
[] = {
6658 #define NAMED_INTCST(a,b,c,d) { a, b, 0, d },
6659 #define NAMED_KINDARRAY(a,b,c,d) { a, b, 0, d },
6660 #define NAMED_DERIVED_TYPE(a,b,c,d) { a, b, 0, d },
6661 #define NAMED_FUNCTION(a,b,c,d) { a, b, c, d },
6662 #define NAMED_SUBROUTINE(a,b,c,d) { a, b, c, d },
6663 #include "iso-fortran-env.def"
6664 { ISOFORTRANENV_INVALID
, NULL
, -1234, 0 } };
6667 #define NAMED_INTCST(a,b,c,d) symbol[i++].value = c;
6668 #include "iso-fortran-env.def"
6670 /* Generate the symbol for the module itself. */
6671 mod_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, mod
);
6672 if (mod_symtree
== NULL
)
6674 gfc_get_sym_tree (mod
, gfc_current_ns
, &mod_symtree
, false);
6675 gcc_assert (mod_symtree
);
6676 mod_sym
= mod_symtree
->n
.sym
;
6678 mod_sym
->attr
.flavor
= FL_MODULE
;
6679 mod_sym
->attr
.intrinsic
= 1;
6680 mod_sym
->module
= gfc_get_string (mod
);
6681 mod_sym
->from_intmod
= INTMOD_ISO_FORTRAN_ENV
;
6684 if (!mod_symtree
->n
.sym
->attr
.intrinsic
)
6685 gfc_error ("Use of intrinsic module %qs at %C conflicts with "
6686 "non-intrinsic module name used previously", mod
);
6688 /* Generate the symbols for the module integer named constants. */
6690 for (i
= 0; symbol
[i
].name
; i
++)
6693 for (u
= gfc_rename_list
; u
; u
= u
->next
)
6695 if (strcmp (symbol
[i
].name
, u
->use_name
) == 0)
6700 if (!gfc_notify_std (symbol
[i
].standard
, "The symbol %qs, "
6701 "referenced at %L, is not in the selected "
6702 "standard", symbol
[i
].name
, &u
->where
))
6705 if ((flag_default_integer
|| flag_default_real
)
6706 && symbol
[i
].id
== ISOFORTRANENV_NUMERIC_STORAGE_SIZE
)
6707 gfc_warning_now (0, "Use of the NUMERIC_STORAGE_SIZE named "
6708 "constant from intrinsic module "
6709 "ISO_FORTRAN_ENV at %L is incompatible with "
6710 "option %qs", &u
->where
,
6711 flag_default_integer
6712 ? "-fdefault-integer-8"
6713 : "-fdefault-real-8");
6714 switch (symbol
[i
].id
)
6716 #define NAMED_INTCST(a,b,c,d) \
6718 #include "iso-fortran-env.def"
6719 create_int_parameter (u
->local_name
[0] ? u
->local_name
6721 symbol
[i
].value
, mod
,
6722 INTMOD_ISO_FORTRAN_ENV
, symbol
[i
].id
);
6725 #define NAMED_KINDARRAY(a,b,KINDS,d) \
6727 expr = gfc_get_array_expr (BT_INTEGER, \
6728 gfc_default_integer_kind,\
6730 for (j = 0; KINDS[j].kind != 0; j++) \
6731 gfc_constructor_append_expr (&expr->value.constructor, \
6732 gfc_get_int_expr (gfc_default_integer_kind, NULL, \
6733 KINDS[j].kind), NULL); \
6734 create_int_parameter_array (u->local_name[0] ? u->local_name \
6737 INTMOD_ISO_FORTRAN_ENV, \
6740 #include "iso-fortran-env.def"
6742 #define NAMED_DERIVED_TYPE(a,b,TYPE,STD) \
6744 #include "iso-fortran-env.def"
6745 create_derived_type (u
->local_name
[0] ? u
->local_name
6747 mod
, INTMOD_ISO_FORTRAN_ENV
,
6751 #define NAMED_FUNCTION(a,b,c,d) \
6753 #include "iso-fortran-env.def"
6754 create_intrinsic_function (u
->local_name
[0] ? u
->local_name
6757 INTMOD_ISO_FORTRAN_ENV
, false,
6767 if (!found
&& !only_flag
)
6769 if ((gfc_option
.allow_std
& symbol
[i
].standard
) == 0)
6772 if ((flag_default_integer
|| flag_default_real
)
6773 && symbol
[i
].id
== ISOFORTRANENV_NUMERIC_STORAGE_SIZE
)
6775 "Use of the NUMERIC_STORAGE_SIZE named constant "
6776 "from intrinsic module ISO_FORTRAN_ENV at %C is "
6777 "incompatible with option %s",
6778 flag_default_integer
6779 ? "-fdefault-integer-8" : "-fdefault-real-8");
6781 switch (symbol
[i
].id
)
6783 #define NAMED_INTCST(a,b,c,d) \
6785 #include "iso-fortran-env.def"
6786 create_int_parameter (symbol
[i
].name
, symbol
[i
].value
, mod
,
6787 INTMOD_ISO_FORTRAN_ENV
, symbol
[i
].id
);
6790 #define NAMED_KINDARRAY(a,b,KINDS,d) \
6792 expr = gfc_get_array_expr (BT_INTEGER, gfc_default_integer_kind, \
6794 for (j = 0; KINDS[j].kind != 0; j++) \
6795 gfc_constructor_append_expr (&expr->value.constructor, \
6796 gfc_get_int_expr (gfc_default_integer_kind, NULL, \
6797 KINDS[j].kind), NULL); \
6798 create_int_parameter_array (symbol[i].name, j, expr, mod, \
6799 INTMOD_ISO_FORTRAN_ENV, symbol[i].id);\
6801 #include "iso-fortran-env.def"
6803 #define NAMED_DERIVED_TYPE(a,b,TYPE,STD) \
6805 #include "iso-fortran-env.def"
6806 create_derived_type (symbol
[i
].name
, mod
, INTMOD_ISO_FORTRAN_ENV
,
6810 #define NAMED_FUNCTION(a,b,c,d) \
6812 #include "iso-fortran-env.def"
6813 create_intrinsic_function (symbol
[i
].name
, symbol
[i
].id
, mod
,
6814 INTMOD_ISO_FORTRAN_ENV
, false,
6824 for (u
= gfc_rename_list
; u
; u
= u
->next
)
6829 gfc_error ("Symbol %qs referenced at %L not found in intrinsic "
6830 "module ISO_FORTRAN_ENV", u
->use_name
, &u
->where
);
6835 /* Process a USE directive. */
6838 gfc_use_module (gfc_use_list
*module
)
6843 gfc_symtree
*mod_symtree
;
6844 gfc_use_list
*use_stmt
;
6845 locus old_locus
= gfc_current_locus
;
6847 gfc_current_locus
= module
->where
;
6848 module_name
= module
->module_name
;
6849 gfc_rename_list
= module
->rename
;
6850 only_flag
= module
->only_flag
;
6851 current_intmod
= INTMOD_NONE
;
6854 gfc_warning_now (OPT_Wuse_without_only
,
6855 "USE statement at %C has no ONLY qualifier");
6857 if (gfc_state_stack
->state
== COMP_MODULE
6858 || module
->submodule_name
== NULL
)
6860 filename
= XALLOCAVEC (char, strlen (module_name
)
6861 + strlen (MODULE_EXTENSION
) + 1);
6862 strcpy (filename
, module_name
);
6863 strcat (filename
, MODULE_EXTENSION
);
6867 filename
= XALLOCAVEC (char, strlen (module
->submodule_name
)
6868 + strlen (SUBMODULE_EXTENSION
) + 1);
6869 strcpy (filename
, module
->submodule_name
);
6870 strcat (filename
, SUBMODULE_EXTENSION
);
6873 /* First, try to find an non-intrinsic module, unless the USE statement
6874 specified that the module is intrinsic. */
6876 if (!module
->intrinsic
)
6877 module_fp
= gzopen_included_file (filename
, true, true);
6879 /* Then, see if it's an intrinsic one, unless the USE statement
6880 specified that the module is non-intrinsic. */
6881 if (module_fp
== NULL
&& !module
->non_intrinsic
)
6883 if (strcmp (module_name
, "iso_fortran_env") == 0
6884 && gfc_notify_std (GFC_STD_F2003
, "ISO_FORTRAN_ENV "
6885 "intrinsic module at %C"))
6887 use_iso_fortran_env_module ();
6888 free_rename (module
->rename
);
6889 module
->rename
= NULL
;
6890 gfc_current_locus
= old_locus
;
6891 module
->intrinsic
= true;
6895 if (strcmp (module_name
, "iso_c_binding") == 0
6896 && gfc_notify_std (GFC_STD_F2003
, "ISO_C_BINDING module at %C"))
6898 import_iso_c_binding_module();
6899 free_rename (module
->rename
);
6900 module
->rename
= NULL
;
6901 gfc_current_locus
= old_locus
;
6902 module
->intrinsic
= true;
6906 module_fp
= gzopen_intrinsic_module (filename
);
6908 if (module_fp
== NULL
&& module
->intrinsic
)
6909 gfc_fatal_error ("Can't find an intrinsic module named %qs at %C",
6912 /* Check for the IEEE modules, so we can mark their symbols
6913 accordingly when we read them. */
6914 if (strcmp (module_name
, "ieee_features") == 0
6915 && gfc_notify_std (GFC_STD_F2003
, "IEEE_FEATURES module at %C"))
6917 current_intmod
= INTMOD_IEEE_FEATURES
;
6919 else if (strcmp (module_name
, "ieee_exceptions") == 0
6920 && gfc_notify_std (GFC_STD_F2003
,
6921 "IEEE_EXCEPTIONS module at %C"))
6923 current_intmod
= INTMOD_IEEE_EXCEPTIONS
;
6925 else if (strcmp (module_name
, "ieee_arithmetic") == 0
6926 && gfc_notify_std (GFC_STD_F2003
,
6927 "IEEE_ARITHMETIC module at %C"))
6929 current_intmod
= INTMOD_IEEE_ARITHMETIC
;
6933 if (module_fp
== NULL
)
6935 if (gfc_state_stack
->state
!= COMP_SUBMODULE
6936 && module
->submodule_name
== NULL
)
6937 gfc_fatal_error ("Can't open module file %qs for reading at %C: %s",
6938 filename
, xstrerror (errno
));
6940 gfc_fatal_error ("Module file %qs has not been generated, either "
6941 "because the module does not contain a MODULE "
6942 "PROCEDURE or there is an error in the module.",
6946 /* Check that we haven't already USEd an intrinsic module with the
6949 mod_symtree
= gfc_find_symtree (gfc_current_ns
->sym_root
, module_name
);
6950 if (mod_symtree
&& mod_symtree
->n
.sym
->attr
.intrinsic
)
6951 gfc_error ("Use of non-intrinsic module %qs at %C conflicts with "
6952 "intrinsic module name used previously", module_name
);
6959 read_module_to_tmpbuf ();
6960 gzclose (module_fp
);
6962 /* Skip the first line of the module, after checking that this is
6963 a gfortran module file. */
6969 bad_module ("Unexpected end of module");
6972 if ((start
== 1 && strcmp (atom_name
, "GFORTRAN") != 0)
6973 || (start
== 2 && strcmp (atom_name
, " module") != 0))
6974 gfc_fatal_error ("File %qs opened at %C is not a GNU Fortran"
6975 " module file", filename
);
6978 if (strcmp (atom_name
, " version") != 0
6979 || module_char () != ' '
6980 || parse_atom () != ATOM_STRING
6981 || strcmp (atom_string
, MOD_VERSION
))
6982 gfc_fatal_error ("Cannot read module file %qs opened at %C,"
6983 " because it was created by a different"
6984 " version of GNU Fortran", filename
);
6993 /* Make sure we're not reading the same module that we may be building. */
6994 for (p
= gfc_state_stack
; p
; p
= p
->previous
)
6995 if ((p
->state
== COMP_MODULE
|| p
->state
== COMP_SUBMODULE
)
6996 && strcmp (p
->sym
->name
, module_name
) == 0)
6997 gfc_fatal_error ("Can't USE the same %smodule we're building!",
6998 p
->state
== COMP_SUBMODULE
? "sub" : "");
7001 init_true_name_tree ();
7005 free_true_name (true_name_root
);
7006 true_name_root
= NULL
;
7008 free_pi_tree (pi_root
);
7011 XDELETEVEC (module_content
);
7012 module_content
= NULL
;
7014 use_stmt
= gfc_get_use_list ();
7015 *use_stmt
= *module
;
7016 use_stmt
->next
= gfc_current_ns
->use_stmts
;
7017 gfc_current_ns
->use_stmts
= use_stmt
;
7019 gfc_current_locus
= old_locus
;
7023 /* Remove duplicated intrinsic operators from the rename list. */
7026 rename_list_remove_duplicate (gfc_use_rename
*list
)
7028 gfc_use_rename
*seek
, *last
;
7030 for (; list
; list
= list
->next
)
7031 if (list
->op
!= INTRINSIC_USER
&& list
->op
!= INTRINSIC_NONE
)
7034 for (seek
= list
->next
; seek
; seek
= last
->next
)
7036 if (list
->op
== seek
->op
)
7038 last
->next
= seek
->next
;
7048 /* Process all USE directives. */
7051 gfc_use_modules (void)
7053 gfc_use_list
*next
, *seek
, *last
;
7055 for (next
= module_list
; next
; next
= next
->next
)
7057 bool non_intrinsic
= next
->non_intrinsic
;
7058 bool intrinsic
= next
->intrinsic
;
7059 bool neither
= !non_intrinsic
&& !intrinsic
;
7061 for (seek
= next
->next
; seek
; seek
= seek
->next
)
7063 if (next
->module_name
!= seek
->module_name
)
7066 if (seek
->non_intrinsic
)
7067 non_intrinsic
= true;
7068 else if (seek
->intrinsic
)
7074 if (intrinsic
&& neither
&& !non_intrinsic
)
7079 filename
= XALLOCAVEC (char,
7080 strlen (next
->module_name
)
7081 + strlen (MODULE_EXTENSION
) + 1);
7082 strcpy (filename
, next
->module_name
);
7083 strcat (filename
, MODULE_EXTENSION
);
7084 fp
= gfc_open_included_file (filename
, true, true);
7087 non_intrinsic
= true;
7093 for (seek
= next
->next
; seek
; seek
= last
->next
)
7095 if (next
->module_name
!= seek
->module_name
)
7101 if ((!next
->intrinsic
&& !seek
->intrinsic
)
7102 || (next
->intrinsic
&& seek
->intrinsic
)
7105 if (!seek
->only_flag
)
7106 next
->only_flag
= false;
7109 gfc_use_rename
*r
= seek
->rename
;
7112 r
->next
= next
->rename
;
7113 next
->rename
= seek
->rename
;
7115 last
->next
= seek
->next
;
7123 for (; module_list
; module_list
= next
)
7125 next
= module_list
->next
;
7126 rename_list_remove_duplicate (module_list
->rename
);
7127 gfc_use_module (module_list
);
7130 gfc_rename_list
= NULL
;
7135 gfc_free_use_stmts (gfc_use_list
*use_stmts
)
7138 for (; use_stmts
; use_stmts
= next
)
7140 gfc_use_rename
*next_rename
;
7142 for (; use_stmts
->rename
; use_stmts
->rename
= next_rename
)
7144 next_rename
= use_stmts
->rename
->next
;
7145 free (use_stmts
->rename
);
7147 next
= use_stmts
->next
;
7154 gfc_module_init_2 (void)
7156 last_atom
= ATOM_LPAREN
;
7157 gfc_rename_list
= NULL
;
7163 gfc_module_done_2 (void)
7165 free_rename (gfc_rename_list
);
7166 gfc_rename_list
= NULL
;