PR rtl-optimization/61673
[official-gcc.git] / libgfortran / io / list_read.c
blob1cb329f7df41bee13fc35d5ee0429280b51be443
1 /* Copyright (C) 2002-2014 Free Software Foundation, Inc.
2 Contributed by Andy Vaught
3 Namelist input contributed by Paul Thomas
4 F2003 I/O support contributed by Jerry DeLisle
6 This file is part of the GNU Fortran runtime library (libgfortran).
8 Libgfortran is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3, or (at your option)
11 any later version.
13 Libgfortran is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 Under Section 7 of GPL version 3, you are granted additional
19 permissions described in the GCC Runtime Library Exception, version
20 3.1, as published by the Free Software Foundation.
22 You should have received a copy of the GNU General Public License and
23 a copy of the GCC Runtime Library Exception along with this program;
24 see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
25 <http://www.gnu.org/licenses/>. */
28 #include "io.h"
29 #include "fbuf.h"
30 #include "unix.h"
31 #include <string.h>
32 #include <stdlib.h>
33 #include <ctype.h>
35 typedef unsigned char uchar;
38 /* List directed input. Several parsing subroutines are practically
39 reimplemented from formatted input, the reason being that there are
40 all kinds of small differences between formatted and list directed
41 parsing. */
44 /* Subroutines for reading characters from the input. Because a
45 repeat count is ambiguous with an integer, we have to read the
46 whole digit string before seeing if there is a '*' which signals
47 the repeat count. Since we can have a lot of potential leading
48 zeros, we have to be able to back up by arbitrary amount. Because
49 the input might not be seekable, we have to buffer the data
50 ourselves. */
52 #define CASE_DIGITS case '0': case '1': case '2': case '3': case '4': \
53 case '5': case '6': case '7': case '8': case '9'
55 #define CASE_SEPARATORS case ' ': case ',': case '/': case '\n': case '\t': \
56 case '\r': case ';'
58 /* This macro assumes that we're operating on a variable. */
60 #define is_separator(c) (c == '/' || c == ',' || c == '\n' || c == ' ' \
61 || c == '\t' || c == '\r' || c == ';')
63 /* Maximum repeat count. Less than ten times the maximum signed int32. */
65 #define MAX_REPEAT 200000000
68 #define MSGLEN 100
71 /* Wrappers for calling the current worker functions. */
73 #define next_char(dtp) ((dtp)->u.p.current_unit->next_char_fn_ptr (dtp))
74 #define push_char(dtp, c) ((dtp)->u.p.current_unit->push_char_fn_ptr (dtp, c))
76 /* Worker function to save a default KIND=1 character to a string
77 buffer, enlarging it as necessary. */
79 static void
80 push_char_default (st_parameter_dt *dtp, int c)
84 if (dtp->u.p.saved_string == NULL)
86 // Plain malloc should suffice here, zeroing not needed?
87 dtp->u.p.saved_string = xcalloc (SCRATCH_SIZE, 1);
88 dtp->u.p.saved_length = SCRATCH_SIZE;
89 dtp->u.p.saved_used = 0;
92 if (dtp->u.p.saved_used >= dtp->u.p.saved_length)
94 dtp->u.p.saved_length = 2 * dtp->u.p.saved_length;
95 dtp->u.p.saved_string =
96 xrealloc (dtp->u.p.saved_string, dtp->u.p.saved_length);
98 // Also this should not be necessary.
99 memset (dtp->u.p.saved_string + dtp->u.p.saved_used, 0,
100 dtp->u.p.saved_length - dtp->u.p.saved_used);
104 dtp->u.p.saved_string[dtp->u.p.saved_used++] = (char) c;
108 /* Worker function to save a KIND=4 character to a string buffer,
109 enlarging the buffer as necessary. */
111 static void
112 push_char4 (st_parameter_dt *dtp, int c)
114 gfc_char4_t *new, *p = (gfc_char4_t *) dtp->u.p.saved_string;
116 if (p == NULL)
118 dtp->u.p.saved_string = xcalloc (SCRATCH_SIZE, sizeof (gfc_char4_t));
119 dtp->u.p.saved_length = SCRATCH_SIZE;
120 dtp->u.p.saved_used = 0;
121 p = (gfc_char4_t *) dtp->u.p.saved_string;
124 if (dtp->u.p.saved_used >= dtp->u.p.saved_length)
126 dtp->u.p.saved_length = 2 * dtp->u.p.saved_length;
127 p = xrealloc (p, dtp->u.p.saved_length * sizeof (gfc_char4_t));
129 memset4 (new + dtp->u.p.saved_used, 0,
130 dtp->u.p.saved_length - dtp->u.p.saved_used);
133 p[dtp->u.p.saved_used++] = c;
137 /* Free the input buffer if necessary. */
139 static void
140 free_saved (st_parameter_dt *dtp)
142 if (dtp->u.p.saved_string == NULL)
143 return;
145 free (dtp->u.p.saved_string);
147 dtp->u.p.saved_string = NULL;
148 dtp->u.p.saved_used = 0;
152 /* Free the line buffer if necessary. */
154 static void
155 free_line (st_parameter_dt *dtp)
157 dtp->u.p.line_buffer_pos = 0;
158 dtp->u.p.line_buffer_enabled = 0;
160 if (dtp->u.p.line_buffer == NULL)
161 return;
163 free (dtp->u.p.line_buffer);
164 dtp->u.p.line_buffer = NULL;
168 /* Unget saves the last character so when reading the next character,
169 we need to check to see if there is a character waiting. Similar,
170 if the line buffer is being used to read_logical, check it too. */
172 static int
173 check_buffers (st_parameter_dt *dtp)
175 int c;
177 c = '\0';
178 if (dtp->u.p.last_char != EOF - 1)
180 dtp->u.p.at_eol = 0;
181 c = dtp->u.p.last_char;
182 dtp->u.p.last_char = EOF - 1;
183 goto done;
186 /* Read from line_buffer if enabled. */
188 if (dtp->u.p.line_buffer_enabled)
190 dtp->u.p.at_eol = 0;
192 c = dtp->u.p.line_buffer[dtp->u.p.line_buffer_pos];
193 if (c != '\0' && dtp->u.p.line_buffer_pos < 64)
195 dtp->u.p.line_buffer[dtp->u.p.line_buffer_pos] = '\0';
196 dtp->u.p.line_buffer_pos++;
197 goto done;
200 dtp->u.p.line_buffer_pos = 0;
201 dtp->u.p.line_buffer_enabled = 0;
204 done:
205 dtp->u.p.at_eol = (c == '\n' || c == EOF);
206 return c;
210 /* Worker function for default character encoded file. */
211 static int
212 next_char_default (st_parameter_dt *dtp)
214 int c;
216 /* Always check the unget and line buffer first. */
217 if ((c = check_buffers (dtp)))
218 return c;
220 c = fbuf_getc (dtp->u.p.current_unit);
221 if (c != EOF && is_stream_io (dtp))
222 dtp->u.p.current_unit->strm_pos++;
224 dtp->u.p.at_eol = (c == '\n' || c == EOF);
225 return c;
229 /* Worker function for internal and array I/O units. */
230 static int
231 next_char_internal (st_parameter_dt *dtp)
233 ssize_t length;
234 gfc_offset record;
235 int c;
237 /* Always check the unget and line buffer first. */
238 if ((c = check_buffers (dtp)))
239 return c;
241 /* Handle the end-of-record and end-of-file conditions for
242 internal array unit. */
243 if (is_array_io (dtp))
245 if (dtp->u.p.at_eof)
246 return EOF;
248 /* Check for "end-of-record" condition. */
249 if (dtp->u.p.current_unit->bytes_left == 0)
251 int finished;
253 c = '\n';
254 record = next_array_record (dtp, dtp->u.p.current_unit->ls,
255 &finished);
257 /* Check for "end-of-file" condition. */
258 if (finished)
260 dtp->u.p.at_eof = 1;
261 goto done;
264 record *= dtp->u.p.current_unit->recl;
265 if (sseek (dtp->u.p.current_unit->s, record, SEEK_SET) < 0)
266 return EOF;
268 dtp->u.p.current_unit->bytes_left = dtp->u.p.current_unit->recl;
269 goto done;
273 /* Get the next character and handle end-of-record conditions. */
275 if (dtp->common.unit) /* Check for kind=4 internal unit. */
276 length = sread (dtp->u.p.current_unit->s, &c, 1);
277 else
279 char cc;
280 length = sread (dtp->u.p.current_unit->s, &cc, 1);
281 c = cc;
284 if (unlikely (length < 0))
286 generate_error (&dtp->common, LIBERROR_OS, NULL);
287 return '\0';
290 if (is_array_io (dtp))
292 /* Check whether we hit EOF. */
293 if (unlikely (length == 0))
295 generate_error (&dtp->common, LIBERROR_INTERNAL_UNIT, NULL);
296 return '\0';
298 dtp->u.p.current_unit->bytes_left--;
300 else
302 if (dtp->u.p.at_eof)
303 return EOF;
304 if (length == 0)
306 c = '\n';
307 dtp->u.p.at_eof = 1;
311 done:
312 dtp->u.p.at_eol = (c == '\n' || c == EOF);
313 return c;
317 /* Worker function for UTF encoded files. */
318 static int
319 next_char_utf8 (st_parameter_dt *dtp)
321 static const uchar masks[6] = { 0x7F, 0x1F, 0x0F, 0x07, 0x02, 0x01 };
322 static const uchar patns[6] = { 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC };
323 int i, nb;
324 gfc_char4_t c;
326 /* Always check the unget and line buffer first. */
327 if (!(c = check_buffers (dtp)))
328 c = fbuf_getc (dtp->u.p.current_unit);
330 if (c < 0x80)
331 goto utf_done;
333 /* The number of leading 1-bits in the first byte indicates how many
334 bytes follow. */
335 for (nb = 2; nb < 7; nb++)
336 if ((c & ~masks[nb-1]) == patns[nb-1])
337 goto found;
338 goto invalid;
340 found:
341 c = (c & masks[nb-1]);
343 /* Decode the bytes read. */
344 for (i = 1; i < nb; i++)
346 gfc_char4_t n = fbuf_getc (dtp->u.p.current_unit);
347 if ((n & 0xC0) != 0x80)
348 goto invalid;
349 c = ((c << 6) + (n & 0x3F));
352 /* Make sure the shortest possible encoding was used. */
353 if (c <= 0x7F && nb > 1) goto invalid;
354 if (c <= 0x7FF && nb > 2) goto invalid;
355 if (c <= 0xFFFF && nb > 3) goto invalid;
356 if (c <= 0x1FFFFF && nb > 4) goto invalid;
357 if (c <= 0x3FFFFFF && nb > 5) goto invalid;
359 /* Make sure the character is valid. */
360 if (c > 0x7FFFFFFF || (c >= 0xD800 && c <= 0xDFFF))
361 goto invalid;
363 utf_done:
364 dtp->u.p.at_eol = (c == '\n' || c == (gfc_char4_t) EOF);
365 return (int) c;
367 invalid:
368 generate_error (&dtp->common, LIBERROR_READ_VALUE, "Invalid UTF-8 encoding");
369 return (gfc_char4_t) '?';
372 /* Push a character back onto the input. */
374 static void
375 unget_char (st_parameter_dt *dtp, int c)
377 dtp->u.p.last_char = c;
381 /* Skip over spaces in the input. Returns the nonspace character that
382 terminated the eating and also places it back on the input. */
384 static int
385 eat_spaces (st_parameter_dt *dtp)
387 int c;
389 /* If internal character array IO, peak ahead and seek past spaces.
390 This is an optimization unique to character arrays with large
391 character lengths (PR38199). This code eliminates numerous calls
392 to next_character. */
393 if (is_array_io (dtp) && (dtp->u.p.last_char == EOF - 1))
395 gfc_offset offset = stell (dtp->u.p.current_unit->s);
396 gfc_offset i;
398 if (dtp->common.unit) /* kind=4 */
400 for (i = 0; i < dtp->u.p.current_unit->bytes_left; i++)
402 if (dtp->internal_unit[(offset + i) * sizeof (gfc_char4_t)]
403 != (gfc_char4_t)' ')
404 break;
407 else
409 for (i = 0; i < dtp->u.p.current_unit->bytes_left; i++)
411 if (dtp->internal_unit[offset + i] != ' ')
412 break;
416 if (i != 0)
418 sseek (dtp->u.p.current_unit->s, offset + i, SEEK_SET);
419 dtp->u.p.current_unit->bytes_left -= i;
423 /* Now skip spaces, EOF and EOL are handled in next_char. */
425 c = next_char (dtp);
426 while (c != EOF && (c == ' ' || c == '\t'));
428 unget_char (dtp, c);
429 return c;
433 /* This function reads characters through to the end of the current
434 line and just ignores them. Returns 0 for success and LIBERROR_END
435 if it hit EOF. */
437 static int
438 eat_line (st_parameter_dt *dtp)
440 int c;
443 c = next_char (dtp);
444 while (c != EOF && c != '\n');
445 if (c == EOF)
446 return LIBERROR_END;
447 return 0;
451 /* Skip over a separator. Technically, we don't always eat the whole
452 separator. This is because if we've processed the last input item,
453 then a separator is unnecessary. Plus the fact that operating
454 systems usually deliver console input on a line basis.
456 The upshot is that if we see a newline as part of reading a
457 separator, we stop reading. If there are more input items, we
458 continue reading the separator with finish_separator() which takes
459 care of the fact that we may or may not have seen a comma as part
460 of the separator.
462 Returns 0 for success, and non-zero error code otherwise. */
464 static int
465 eat_separator (st_parameter_dt *dtp)
467 int c, n;
468 int err = 0;
470 eat_spaces (dtp);
471 dtp->u.p.comma_flag = 0;
473 if ((c = next_char (dtp)) == EOF)
474 return LIBERROR_END;
475 switch (c)
477 case ',':
478 if (dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
480 unget_char (dtp, c);
481 break;
483 /* Fall through. */
484 case ';':
485 dtp->u.p.comma_flag = 1;
486 eat_spaces (dtp);
487 break;
489 case '/':
490 dtp->u.p.input_complete = 1;
491 break;
493 case '\r':
494 if ((n = next_char(dtp)) == EOF)
495 return LIBERROR_END;
496 if (n != '\n')
498 unget_char (dtp, n);
499 break;
501 /* Fall through. */
502 case '\n':
503 dtp->u.p.at_eol = 1;
504 if (dtp->u.p.namelist_mode)
508 if ((c = next_char (dtp)) == EOF)
509 return LIBERROR_END;
510 if (c == '!')
512 err = eat_line (dtp);
513 if (err)
514 return err;
515 c = '\n';
518 while (c == '\n' || c == '\r' || c == ' ' || c == '\t');
519 unget_char (dtp, c);
521 break;
523 case '!':
524 if (dtp->u.p.namelist_mode)
525 { /* Eat a namelist comment. */
526 err = eat_line (dtp);
527 if (err)
528 return err;
530 break;
533 /* Fall Through... */
535 default:
536 unget_char (dtp, c);
537 break;
539 return err;
543 /* Finish processing a separator that was interrupted by a newline.
544 If we're here, then another data item is present, so we finish what
545 we started on the previous line. Return 0 on success, error code
546 on failure. */
548 static int
549 finish_separator (st_parameter_dt *dtp)
551 int c;
552 int err = LIBERROR_OK;
554 restart:
555 eat_spaces (dtp);
557 if ((c = next_char (dtp)) == EOF)
558 return LIBERROR_END;
559 switch (c)
561 case ',':
562 if (dtp->u.p.comma_flag)
563 unget_char (dtp, c);
564 else
566 if ((c = eat_spaces (dtp)) == EOF)
567 return LIBERROR_END;
568 if (c == '\n' || c == '\r')
569 goto restart;
572 break;
574 case '/':
575 dtp->u.p.input_complete = 1;
576 if (!dtp->u.p.namelist_mode)
577 return err;
578 break;
580 case '\n':
581 case '\r':
582 goto restart;
584 case '!':
585 if (dtp->u.p.namelist_mode)
587 err = eat_line (dtp);
588 if (err)
589 return err;
590 goto restart;
592 /* Fall through. */
593 default:
594 unget_char (dtp, c);
595 break;
597 return err;
601 /* This function is needed to catch bad conversions so that namelist can
602 attempt to see if dtp->u.p.saved_string contains a new object name rather
603 than a bad value. */
605 static int
606 nml_bad_return (st_parameter_dt *dtp, char c)
608 if (dtp->u.p.namelist_mode)
610 dtp->u.p.nml_read_error = 1;
611 unget_char (dtp, c);
612 return 1;
614 return 0;
617 /* Convert an unsigned string to an integer. The length value is -1
618 if we are working on a repeat count. Returns nonzero if we have a
619 range problem. As a side effect, frees the dtp->u.p.saved_string. */
621 static int
622 convert_integer (st_parameter_dt *dtp, int length, int negative)
624 char c, *buffer, message[MSGLEN];
625 int m;
626 GFC_UINTEGER_LARGEST v, max, max10;
627 GFC_INTEGER_LARGEST value;
629 buffer = dtp->u.p.saved_string;
630 v = 0;
632 if (length == -1)
633 max = MAX_REPEAT;
634 else
636 max = si_max (length);
637 if (negative)
638 max++;
640 max10 = max / 10;
642 for (;;)
644 c = *buffer++;
645 if (c == '\0')
646 break;
647 c -= '0';
649 if (v > max10)
650 goto overflow;
651 v = 10 * v;
653 if (v > max - c)
654 goto overflow;
655 v += c;
658 m = 0;
660 if (length != -1)
662 if (negative)
663 value = -v;
664 else
665 value = v;
666 set_integer (dtp->u.p.value, value, length);
668 else
670 dtp->u.p.repeat_count = v;
672 if (dtp->u.p.repeat_count == 0)
674 snprintf (message, MSGLEN, "Zero repeat count in item %d of list input",
675 dtp->u.p.item_count);
677 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
678 m = 1;
682 free_saved (dtp);
683 return m;
685 overflow:
686 if (length == -1)
687 snprintf (message, MSGLEN, "Repeat count overflow in item %d of list input",
688 dtp->u.p.item_count);
689 else
690 snprintf (message, MSGLEN, "Integer overflow while reading item %d",
691 dtp->u.p.item_count);
693 free_saved (dtp);
694 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
696 return 1;
700 /* Parse a repeat count for logical and complex values which cannot
701 begin with a digit. Returns nonzero if we are done, zero if we
702 should continue on. */
704 static int
705 parse_repeat (st_parameter_dt *dtp)
707 char message[MSGLEN];
708 int c, repeat;
710 if ((c = next_char (dtp)) == EOF)
711 goto bad_repeat;
712 switch (c)
714 CASE_DIGITS:
715 repeat = c - '0';
716 break;
718 CASE_SEPARATORS:
719 unget_char (dtp, c);
720 eat_separator (dtp);
721 return 1;
723 default:
724 unget_char (dtp, c);
725 return 0;
728 for (;;)
730 c = next_char (dtp);
731 switch (c)
733 CASE_DIGITS:
734 repeat = 10 * repeat + c - '0';
736 if (repeat > MAX_REPEAT)
738 snprintf (message, MSGLEN,
739 "Repeat count overflow in item %d of list input",
740 dtp->u.p.item_count);
742 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
743 return 1;
746 break;
748 case '*':
749 if (repeat == 0)
751 snprintf (message, MSGLEN,
752 "Zero repeat count in item %d of list input",
753 dtp->u.p.item_count);
755 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
756 return 1;
759 goto done;
761 default:
762 goto bad_repeat;
766 done:
767 dtp->u.p.repeat_count = repeat;
768 return 0;
770 bad_repeat:
772 free_saved (dtp);
773 if (c == EOF)
775 free_line (dtp);
776 hit_eof (dtp);
777 return 1;
779 else
780 eat_line (dtp);
781 snprintf (message, MSGLEN, "Bad repeat count in item %d of list input",
782 dtp->u.p.item_count);
783 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
784 return 1;
788 /* To read a logical we have to look ahead in the input stream to make sure
789 there is not an equal sign indicating a variable name. To do this we use
790 line_buffer to point to a temporary buffer, pushing characters there for
791 possible later reading. */
793 static void
794 l_push_char (st_parameter_dt *dtp, char c)
796 if (dtp->u.p.line_buffer == NULL)
797 dtp->u.p.line_buffer = xcalloc (SCRATCH_SIZE, 1);
799 dtp->u.p.line_buffer[dtp->u.p.line_buffer_pos++] = c;
803 /* Read a logical character on the input. */
805 static void
806 read_logical (st_parameter_dt *dtp, int length)
808 char message[MSGLEN];
809 int c, i, v;
811 if (parse_repeat (dtp))
812 return;
814 c = tolower (next_char (dtp));
815 l_push_char (dtp, c);
816 switch (c)
818 case 't':
819 v = 1;
820 c = next_char (dtp);
821 l_push_char (dtp, c);
823 if (!is_separator(c) && c != EOF)
824 goto possible_name;
826 unget_char (dtp, c);
827 break;
828 case 'f':
829 v = 0;
830 c = next_char (dtp);
831 l_push_char (dtp, c);
833 if (!is_separator(c) && c != EOF)
834 goto possible_name;
836 unget_char (dtp, c);
837 break;
839 case '.':
840 c = tolower (next_char (dtp));
841 switch (c)
843 case 't':
844 v = 1;
845 break;
846 case 'f':
847 v = 0;
848 break;
849 default:
850 goto bad_logical;
853 break;
855 CASE_SEPARATORS:
856 case EOF:
857 unget_char (dtp, c);
858 eat_separator (dtp);
859 return; /* Null value. */
861 default:
862 /* Save the character in case it is the beginning
863 of the next object name. */
864 unget_char (dtp, c);
865 goto bad_logical;
868 dtp->u.p.saved_type = BT_LOGICAL;
869 dtp->u.p.saved_length = length;
871 /* Eat trailing garbage. */
873 c = next_char (dtp);
874 while (c != EOF && !is_separator (c));
876 unget_char (dtp, c);
877 eat_separator (dtp);
878 set_integer ((int *) dtp->u.p.value, v, length);
879 free_line (dtp);
881 return;
883 possible_name:
885 for(i = 0; i < 63; i++)
887 c = next_char (dtp);
888 if (is_separator(c))
890 /* All done if this is not a namelist read. */
891 if (!dtp->u.p.namelist_mode)
892 goto logical_done;
894 unget_char (dtp, c);
895 eat_separator (dtp);
896 c = next_char (dtp);
897 if (c != '=')
899 unget_char (dtp, c);
900 goto logical_done;
904 l_push_char (dtp, c);
905 if (c == '=')
907 dtp->u.p.nml_read_error = 1;
908 dtp->u.p.line_buffer_enabled = 1;
909 dtp->u.p.line_buffer_pos = 0;
910 return;
915 bad_logical:
917 if (nml_bad_return (dtp, c))
919 free_line (dtp);
920 return;
924 free_saved (dtp);
925 if (c == EOF)
927 free_line (dtp);
928 hit_eof (dtp);
929 return;
931 else if (c != '\n')
932 eat_line (dtp);
933 snprintf (message, MSGLEN, "Bad logical value while reading item %d",
934 dtp->u.p.item_count);
935 free_line (dtp);
936 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
937 return;
939 logical_done:
941 dtp->u.p.saved_type = BT_LOGICAL;
942 dtp->u.p.saved_length = length;
943 set_integer ((int *) dtp->u.p.value, v, length);
944 free_saved (dtp);
945 free_line (dtp);
949 /* Reading integers is tricky because we can actually be reading a
950 repeat count. We have to store the characters in a buffer because
951 we could be reading an integer that is larger than the default int
952 used for repeat counts. */
954 static void
955 read_integer (st_parameter_dt *dtp, int length)
957 char message[MSGLEN];
958 int c, negative;
960 negative = 0;
962 c = next_char (dtp);
963 switch (c)
965 case '-':
966 negative = 1;
967 /* Fall through... */
969 case '+':
970 if ((c = next_char (dtp)) == EOF)
971 goto bad_integer;
972 goto get_integer;
974 CASE_SEPARATORS: /* Single null. */
975 unget_char (dtp, c);
976 eat_separator (dtp);
977 return;
979 CASE_DIGITS:
980 push_char (dtp, c);
981 break;
983 default:
984 goto bad_integer;
987 /* Take care of what may be a repeat count. */
989 for (;;)
991 c = next_char (dtp);
992 switch (c)
994 CASE_DIGITS:
995 push_char (dtp, c);
996 break;
998 case '*':
999 push_char (dtp, '\0');
1000 goto repeat;
1002 CASE_SEPARATORS: /* Not a repeat count. */
1003 case EOF:
1004 goto done;
1006 default:
1007 goto bad_integer;
1011 repeat:
1012 if (convert_integer (dtp, -1, 0))
1013 return;
1015 /* Get the real integer. */
1017 if ((c = next_char (dtp)) == EOF)
1018 goto bad_integer;
1019 switch (c)
1021 CASE_DIGITS:
1022 break;
1024 CASE_SEPARATORS:
1025 unget_char (dtp, c);
1026 eat_separator (dtp);
1027 return;
1029 case '-':
1030 negative = 1;
1031 /* Fall through... */
1033 case '+':
1034 c = next_char (dtp);
1035 break;
1038 get_integer:
1039 if (!isdigit (c))
1040 goto bad_integer;
1041 push_char (dtp, c);
1043 for (;;)
1045 c = next_char (dtp);
1046 switch (c)
1048 CASE_DIGITS:
1049 push_char (dtp, c);
1050 break;
1052 CASE_SEPARATORS:
1053 case EOF:
1054 goto done;
1056 default:
1057 goto bad_integer;
1061 bad_integer:
1063 if (nml_bad_return (dtp, c))
1064 return;
1066 free_saved (dtp);
1067 if (c == EOF)
1069 free_line (dtp);
1070 hit_eof (dtp);
1071 return;
1073 else if (c != '\n')
1074 eat_line (dtp);
1076 snprintf (message, MSGLEN, "Bad integer for item %d in list input",
1077 dtp->u.p.item_count);
1078 free_line (dtp);
1079 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1081 return;
1083 done:
1084 unget_char (dtp, c);
1085 eat_separator (dtp);
1087 push_char (dtp, '\0');
1088 if (convert_integer (dtp, length, negative))
1090 free_saved (dtp);
1091 return;
1094 free_saved (dtp);
1095 dtp->u.p.saved_type = BT_INTEGER;
1099 /* Read a character variable. */
1101 static void
1102 read_character (st_parameter_dt *dtp, int length __attribute__ ((unused)))
1104 char quote, message[MSGLEN];
1105 int c;
1107 quote = ' '; /* Space means no quote character. */
1109 if ((c = next_char (dtp)) == EOF)
1110 goto eof;
1111 switch (c)
1113 CASE_DIGITS:
1114 push_char (dtp, c);
1115 break;
1117 CASE_SEPARATORS:
1118 case EOF:
1119 unget_char (dtp, c); /* NULL value. */
1120 eat_separator (dtp);
1121 return;
1123 case '"':
1124 case '\'':
1125 quote = c;
1126 goto get_string;
1128 default:
1129 if (dtp->u.p.namelist_mode)
1131 if (dtp->u.p.current_unit->delim_status == DELIM_NONE)
1133 /* No delimiters so finish reading the string now. */
1134 int i;
1135 push_char (dtp, c);
1136 for (i = dtp->u.p.ionml->string_length; i > 1; i--)
1138 if ((c = next_char (dtp)) == EOF)
1139 goto done_eof;
1140 push_char (dtp, c);
1142 dtp->u.p.saved_type = BT_CHARACTER;
1143 free_line (dtp);
1144 return;
1146 unget_char (dtp, c);
1147 return;
1149 push_char (dtp, c);
1150 goto get_string;
1153 /* Deal with a possible repeat count. */
1155 for (;;)
1157 c = next_char (dtp);
1158 switch (c)
1160 CASE_DIGITS:
1161 push_char (dtp, c);
1162 break;
1164 CASE_SEPARATORS:
1165 case EOF:
1166 unget_char (dtp, c);
1167 goto done; /* String was only digits! */
1169 case '*':
1170 push_char (dtp, '\0');
1171 goto got_repeat;
1173 default:
1174 push_char (dtp, c);
1175 goto get_string; /* Not a repeat count after all. */
1179 got_repeat:
1180 if (convert_integer (dtp, -1, 0))
1181 return;
1183 /* Now get the real string. */
1185 if ((c = next_char (dtp)) == EOF)
1186 goto eof;
1187 switch (c)
1189 CASE_SEPARATORS:
1190 unget_char (dtp, c); /* Repeated NULL values. */
1191 eat_separator (dtp);
1192 return;
1194 case '"':
1195 case '\'':
1196 quote = c;
1197 break;
1199 default:
1200 push_char (dtp, c);
1201 break;
1204 get_string:
1206 for (;;)
1208 if ((c = next_char (dtp)) == EOF)
1209 goto done_eof;
1210 switch (c)
1212 case '"':
1213 case '\'':
1214 if (c != quote)
1216 push_char (dtp, c);
1217 break;
1220 /* See if we have a doubled quote character or the end of
1221 the string. */
1223 if ((c = next_char (dtp)) == EOF)
1224 goto done_eof;
1225 if (c == quote)
1227 push_char (dtp, quote);
1228 break;
1231 unget_char (dtp, c);
1232 goto done;
1234 CASE_SEPARATORS:
1235 if (quote == ' ')
1237 unget_char (dtp, c);
1238 goto done;
1241 if (c != '\n' && c != '\r')
1242 push_char (dtp, c);
1243 break;
1245 default:
1246 push_char (dtp, c);
1247 break;
1251 /* At this point, we have to have a separator, or else the string is
1252 invalid. */
1253 done:
1254 c = next_char (dtp);
1255 done_eof:
1256 if (is_separator (c) || c == '!' || c == EOF)
1258 unget_char (dtp, c);
1259 eat_separator (dtp);
1260 dtp->u.p.saved_type = BT_CHARACTER;
1262 else
1264 free_saved (dtp);
1265 snprintf (message, MSGLEN, "Invalid string input in item %d",
1266 dtp->u.p.item_count);
1267 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1269 free_line (dtp);
1270 return;
1272 eof:
1273 free_saved (dtp);
1274 free_line (dtp);
1275 hit_eof (dtp);
1279 /* Parse a component of a complex constant or a real number that we
1280 are sure is already there. This is a straight real number parser. */
1282 static int
1283 parse_real (st_parameter_dt *dtp, void *buffer, int length)
1285 char message[MSGLEN];
1286 int c, m, seen_dp;
1288 if ((c = next_char (dtp)) == EOF)
1289 goto bad;
1291 if (c == '-' || c == '+')
1293 push_char (dtp, c);
1294 if ((c = next_char (dtp)) == EOF)
1295 goto bad;
1298 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1299 c = '.';
1301 if (!isdigit (c) && c != '.')
1303 if (c == 'i' || c == 'I' || c == 'n' || c == 'N')
1304 goto inf_nan;
1305 else
1306 goto bad;
1309 push_char (dtp, c);
1311 seen_dp = (c == '.') ? 1 : 0;
1313 for (;;)
1315 if ((c = next_char (dtp)) == EOF)
1316 goto bad;
1317 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1318 c = '.';
1319 switch (c)
1321 CASE_DIGITS:
1322 push_char (dtp, c);
1323 break;
1325 case '.':
1326 if (seen_dp)
1327 goto bad;
1329 seen_dp = 1;
1330 push_char (dtp, c);
1331 break;
1333 case 'e':
1334 case 'E':
1335 case 'd':
1336 case 'D':
1337 case 'q':
1338 case 'Q':
1339 push_char (dtp, 'e');
1340 goto exp1;
1342 case '-':
1343 case '+':
1344 push_char (dtp, 'e');
1345 push_char (dtp, c);
1346 if ((c = next_char (dtp)) == EOF)
1347 goto bad;
1348 goto exp2;
1350 CASE_SEPARATORS:
1351 case EOF:
1352 goto done;
1354 default:
1355 goto done;
1359 exp1:
1360 if ((c = next_char (dtp)) == EOF)
1361 goto bad;
1362 if (c != '-' && c != '+')
1363 push_char (dtp, '+');
1364 else
1366 push_char (dtp, c);
1367 c = next_char (dtp);
1370 exp2:
1371 if (!isdigit (c))
1372 goto bad;
1374 push_char (dtp, c);
1376 for (;;)
1378 if ((c = next_char (dtp)) == EOF)
1379 goto bad;
1380 switch (c)
1382 CASE_DIGITS:
1383 push_char (dtp, c);
1384 break;
1386 CASE_SEPARATORS:
1387 case EOF:
1388 unget_char (dtp, c);
1389 goto done;
1391 default:
1392 goto done;
1396 done:
1397 unget_char (dtp, c);
1398 push_char (dtp, '\0');
1400 m = convert_real (dtp, buffer, dtp->u.p.saved_string, length);
1401 free_saved (dtp);
1403 return m;
1405 done_infnan:
1406 unget_char (dtp, c);
1407 push_char (dtp, '\0');
1409 m = convert_infnan (dtp, buffer, dtp->u.p.saved_string, length);
1410 free_saved (dtp);
1412 return m;
1414 inf_nan:
1415 /* Match INF and Infinity. */
1416 if ((c == 'i' || c == 'I')
1417 && ((c = next_char (dtp)) == 'n' || c == 'N')
1418 && ((c = next_char (dtp)) == 'f' || c == 'F'))
1420 c = next_char (dtp);
1421 if ((c != 'i' && c != 'I')
1422 || ((c == 'i' || c == 'I')
1423 && ((c = next_char (dtp)) == 'n' || c == 'N')
1424 && ((c = next_char (dtp)) == 'i' || c == 'I')
1425 && ((c = next_char (dtp)) == 't' || c == 'T')
1426 && ((c = next_char (dtp)) == 'y' || c == 'Y')
1427 && (c = next_char (dtp))))
1429 if (is_separator (c) || (c == EOF))
1430 unget_char (dtp, c);
1431 push_char (dtp, 'i');
1432 push_char (dtp, 'n');
1433 push_char (dtp, 'f');
1434 goto done_infnan;
1436 } /* Match NaN. */
1437 else if (((c = next_char (dtp)) == 'a' || c == 'A')
1438 && ((c = next_char (dtp)) == 'n' || c == 'N')
1439 && (c = next_char (dtp)))
1441 if (is_separator (c) || (c == EOF))
1442 unget_char (dtp, c);
1443 push_char (dtp, 'n');
1444 push_char (dtp, 'a');
1445 push_char (dtp, 'n');
1447 /* Match "NAN(alphanum)". */
1448 if (c == '(')
1450 for ( ; c != ')'; c = next_char (dtp))
1451 if (is_separator (c))
1452 goto bad;
1454 c = next_char (dtp);
1455 if (is_separator (c) || (c == EOF))
1456 unget_char (dtp, c);
1458 goto done_infnan;
1461 bad:
1463 if (nml_bad_return (dtp, c))
1464 return 0;
1466 free_saved (dtp);
1467 if (c == EOF)
1469 free_line (dtp);
1470 hit_eof (dtp);
1471 return 1;
1473 else if (c != '\n')
1474 eat_line (dtp);
1476 snprintf (message, MSGLEN, "Bad floating point number for item %d",
1477 dtp->u.p.item_count);
1478 free_line (dtp);
1479 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1481 return 1;
1485 /* Reading a complex number is straightforward because we can tell
1486 what it is right away. */
1488 static void
1489 read_complex (st_parameter_dt *dtp, void * dest, int kind, size_t size)
1491 char message[MSGLEN];
1492 int c;
1494 if (parse_repeat (dtp))
1495 return;
1497 c = next_char (dtp);
1498 switch (c)
1500 case '(':
1501 break;
1503 CASE_SEPARATORS:
1504 case EOF:
1505 unget_char (dtp, c);
1506 eat_separator (dtp);
1507 return;
1509 default:
1510 goto bad_complex;
1513 eol_1:
1514 eat_spaces (dtp);
1515 c = next_char (dtp);
1516 if (c == '\n' || c== '\r')
1517 goto eol_1;
1518 else
1519 unget_char (dtp, c);
1521 if (parse_real (dtp, dest, kind))
1522 return;
1524 eol_2:
1525 eat_spaces (dtp);
1526 c = next_char (dtp);
1527 if (c == '\n' || c== '\r')
1528 goto eol_2;
1529 else
1530 unget_char (dtp, c);
1532 if (next_char (dtp)
1533 != (dtp->u.p.current_unit->decimal_status == DECIMAL_POINT ? ',' : ';'))
1534 goto bad_complex;
1536 eol_3:
1537 eat_spaces (dtp);
1538 c = next_char (dtp);
1539 if (c == '\n' || c== '\r')
1540 goto eol_3;
1541 else
1542 unget_char (dtp, c);
1544 if (parse_real (dtp, dest + size / 2, kind))
1545 return;
1547 eol_4:
1548 eat_spaces (dtp);
1549 c = next_char (dtp);
1550 if (c == '\n' || c== '\r')
1551 goto eol_4;
1552 else
1553 unget_char (dtp, c);
1555 if (next_char (dtp) != ')')
1556 goto bad_complex;
1558 c = next_char (dtp);
1559 if (!is_separator (c) && (c != EOF))
1560 goto bad_complex;
1562 unget_char (dtp, c);
1563 eat_separator (dtp);
1565 free_saved (dtp);
1566 dtp->u.p.saved_type = BT_COMPLEX;
1567 return;
1569 bad_complex:
1571 if (nml_bad_return (dtp, c))
1572 return;
1574 free_saved (dtp);
1575 if (c == EOF)
1577 free_line (dtp);
1578 hit_eof (dtp);
1579 return;
1581 else if (c != '\n')
1582 eat_line (dtp);
1584 snprintf (message, MSGLEN, "Bad complex value in item %d of list input",
1585 dtp->u.p.item_count);
1586 free_line (dtp);
1587 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1591 /* Parse a real number with a possible repeat count. */
1593 static void
1594 read_real (st_parameter_dt *dtp, void * dest, int length)
1596 char message[MSGLEN];
1597 int c;
1598 int seen_dp;
1599 int is_inf;
1601 seen_dp = 0;
1603 c = next_char (dtp);
1604 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1605 c = '.';
1606 switch (c)
1608 CASE_DIGITS:
1609 push_char (dtp, c);
1610 break;
1612 case '.':
1613 push_char (dtp, c);
1614 seen_dp = 1;
1615 break;
1617 case '+':
1618 case '-':
1619 goto got_sign;
1621 CASE_SEPARATORS:
1622 unget_char (dtp, c); /* Single null. */
1623 eat_separator (dtp);
1624 return;
1626 case 'i':
1627 case 'I':
1628 case 'n':
1629 case 'N':
1630 goto inf_nan;
1632 default:
1633 goto bad_real;
1636 /* Get the digit string that might be a repeat count. */
1638 for (;;)
1640 c = next_char (dtp);
1641 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1642 c = '.';
1643 switch (c)
1645 CASE_DIGITS:
1646 push_char (dtp, c);
1647 break;
1649 case '.':
1650 if (seen_dp)
1651 goto bad_real;
1653 seen_dp = 1;
1654 push_char (dtp, c);
1655 goto real_loop;
1657 case 'E':
1658 case 'e':
1659 case 'D':
1660 case 'd':
1661 case 'Q':
1662 case 'q':
1663 goto exp1;
1665 case '+':
1666 case '-':
1667 push_char (dtp, 'e');
1668 push_char (dtp, c);
1669 c = next_char (dtp);
1670 goto exp2;
1672 case '*':
1673 push_char (dtp, '\0');
1674 goto got_repeat;
1676 CASE_SEPARATORS:
1677 case EOF:
1678 if (c != '\n' && c != ',' && c != '\r' && c != ';')
1679 unget_char (dtp, c);
1680 goto done;
1682 default:
1683 goto bad_real;
1687 got_repeat:
1688 if (convert_integer (dtp, -1, 0))
1689 return;
1691 /* Now get the number itself. */
1693 if ((c = next_char (dtp)) == EOF)
1694 goto bad_real;
1695 if (is_separator (c))
1696 { /* Repeated null value. */
1697 unget_char (dtp, c);
1698 eat_separator (dtp);
1699 return;
1702 if (c != '-' && c != '+')
1703 push_char (dtp, '+');
1704 else
1706 got_sign:
1707 push_char (dtp, c);
1708 if ((c = next_char (dtp)) == EOF)
1709 goto bad_real;
1712 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1713 c = '.';
1715 if (!isdigit (c) && c != '.')
1717 if (c == 'i' || c == 'I' || c == 'n' || c == 'N')
1718 goto inf_nan;
1719 else
1720 goto bad_real;
1723 if (c == '.')
1725 if (seen_dp)
1726 goto bad_real;
1727 else
1728 seen_dp = 1;
1731 push_char (dtp, c);
1733 real_loop:
1734 for (;;)
1736 c = next_char (dtp);
1737 if (c == ',' && dtp->u.p.current_unit->decimal_status == DECIMAL_COMMA)
1738 c = '.';
1739 switch (c)
1741 CASE_DIGITS:
1742 push_char (dtp, c);
1743 break;
1745 CASE_SEPARATORS:
1746 case EOF:
1747 goto done;
1749 case '.':
1750 if (seen_dp)
1751 goto bad_real;
1753 seen_dp = 1;
1754 push_char (dtp, c);
1755 break;
1757 case 'E':
1758 case 'e':
1759 case 'D':
1760 case 'd':
1761 case 'Q':
1762 case 'q':
1763 goto exp1;
1765 case '+':
1766 case '-':
1767 push_char (dtp, 'e');
1768 push_char (dtp, c);
1769 c = next_char (dtp);
1770 goto exp2;
1772 default:
1773 goto bad_real;
1777 exp1:
1778 push_char (dtp, 'e');
1780 if ((c = next_char (dtp)) == EOF)
1781 goto bad_real;
1782 if (c != '+' && c != '-')
1783 push_char (dtp, '+');
1784 else
1786 push_char (dtp, c);
1787 c = next_char (dtp);
1790 exp2:
1791 if (!isdigit (c))
1792 goto bad_real;
1793 push_char (dtp, c);
1795 for (;;)
1797 c = next_char (dtp);
1799 switch (c)
1801 CASE_DIGITS:
1802 push_char (dtp, c);
1803 break;
1805 CASE_SEPARATORS:
1806 case EOF:
1807 goto done;
1809 default:
1810 goto bad_real;
1814 done:
1815 unget_char (dtp, c);
1816 eat_separator (dtp);
1817 push_char (dtp, '\0');
1818 if (convert_real (dtp, dest, dtp->u.p.saved_string, length))
1820 free_saved (dtp);
1821 return;
1824 free_saved (dtp);
1825 dtp->u.p.saved_type = BT_REAL;
1826 return;
1828 inf_nan:
1829 l_push_char (dtp, c);
1830 is_inf = 0;
1832 /* Match INF and Infinity. */
1833 if (c == 'i' || c == 'I')
1835 c = next_char (dtp);
1836 l_push_char (dtp, c);
1837 if (c != 'n' && c != 'N')
1838 goto unwind;
1839 c = next_char (dtp);
1840 l_push_char (dtp, c);
1841 if (c != 'f' && c != 'F')
1842 goto unwind;
1843 c = next_char (dtp);
1844 l_push_char (dtp, c);
1845 if (!is_separator (c) && (c != EOF))
1847 if (c != 'i' && c != 'I')
1848 goto unwind;
1849 c = next_char (dtp);
1850 l_push_char (dtp, c);
1851 if (c != 'n' && c != 'N')
1852 goto unwind;
1853 c = next_char (dtp);
1854 l_push_char (dtp, c);
1855 if (c != 'i' && c != 'I')
1856 goto unwind;
1857 c = next_char (dtp);
1858 l_push_char (dtp, c);
1859 if (c != 't' && c != 'T')
1860 goto unwind;
1861 c = next_char (dtp);
1862 l_push_char (dtp, c);
1863 if (c != 'y' && c != 'Y')
1864 goto unwind;
1865 c = next_char (dtp);
1866 l_push_char (dtp, c);
1868 is_inf = 1;
1869 } /* Match NaN. */
1870 else
1872 c = next_char (dtp);
1873 l_push_char (dtp, c);
1874 if (c != 'a' && c != 'A')
1875 goto unwind;
1876 c = next_char (dtp);
1877 l_push_char (dtp, c);
1878 if (c != 'n' && c != 'N')
1879 goto unwind;
1880 c = next_char (dtp);
1881 l_push_char (dtp, c);
1883 /* Match NAN(alphanum). */
1884 if (c == '(')
1886 for (c = next_char (dtp); c != ')'; c = next_char (dtp))
1887 if (is_separator (c))
1888 goto unwind;
1889 else
1890 l_push_char (dtp, c);
1892 l_push_char (dtp, ')');
1893 c = next_char (dtp);
1894 l_push_char (dtp, c);
1898 if (!is_separator (c) && (c != EOF))
1899 goto unwind;
1901 if (dtp->u.p.namelist_mode)
1903 if (c == ' ' || c =='\n' || c == '\r')
1907 if ((c = next_char (dtp)) == EOF)
1908 goto bad_real;
1910 while (c == ' ' || c =='\n' || c == '\r');
1912 l_push_char (dtp, c);
1914 if (c == '=')
1915 goto unwind;
1919 if (is_inf)
1921 push_char (dtp, 'i');
1922 push_char (dtp, 'n');
1923 push_char (dtp, 'f');
1925 else
1927 push_char (dtp, 'n');
1928 push_char (dtp, 'a');
1929 push_char (dtp, 'n');
1932 free_line (dtp);
1933 unget_char (dtp, c);
1934 eat_separator (dtp);
1935 push_char (dtp, '\0');
1936 if (convert_infnan (dtp, dest, dtp->u.p.saved_string, length))
1937 return;
1939 free_saved (dtp);
1940 dtp->u.p.saved_type = BT_REAL;
1941 return;
1943 unwind:
1944 if (dtp->u.p.namelist_mode)
1946 dtp->u.p.nml_read_error = 1;
1947 dtp->u.p.line_buffer_enabled = 1;
1948 dtp->u.p.line_buffer_pos = 0;
1949 return;
1952 bad_real:
1954 if (nml_bad_return (dtp, c))
1955 return;
1957 free_saved (dtp);
1958 if (c == EOF)
1960 free_line (dtp);
1961 hit_eof (dtp);
1962 return;
1964 else if (c != '\n')
1965 eat_line (dtp);
1967 snprintf (message, MSGLEN, "Bad real number in item %d of list input",
1968 dtp->u.p.item_count);
1969 free_line (dtp);
1970 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1974 /* Check the current type against the saved type to make sure they are
1975 compatible. Returns nonzero if incompatible. */
1977 static int
1978 check_type (st_parameter_dt *dtp, bt type, int kind)
1980 char message[MSGLEN];
1982 if (dtp->u.p.saved_type != BT_UNKNOWN && dtp->u.p.saved_type != type)
1984 snprintf (message, MSGLEN, "Read type %s where %s was expected for item %d",
1985 type_name (dtp->u.p.saved_type), type_name (type),
1986 dtp->u.p.item_count);
1987 free_line (dtp);
1988 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
1989 return 1;
1992 if (dtp->u.p.saved_type == BT_UNKNOWN || dtp->u.p.saved_type == BT_CHARACTER)
1993 return 0;
1995 if ((type != BT_COMPLEX && dtp->u.p.saved_length != kind)
1996 || (type == BT_COMPLEX && dtp->u.p.saved_length != kind*2))
1998 snprintf (message, MSGLEN,
1999 "Read kind %d %s where kind %d is required for item %d",
2000 type == BT_COMPLEX ? dtp->u.p.saved_length / 2
2001 : dtp->u.p.saved_length,
2002 type_name (dtp->u.p.saved_type), kind,
2003 dtp->u.p.item_count);
2004 free_line (dtp);
2005 generate_error (&dtp->common, LIBERROR_READ_VALUE, message);
2006 return 1;
2009 return 0;
2013 /* Initialize the function pointers to select the correct versions of
2014 next_char and push_char depending on what we are doing. */
2016 static void
2017 set_workers (st_parameter_dt *dtp)
2019 if (dtp->u.p.current_unit->flags.encoding == ENCODING_UTF8)
2021 dtp->u.p.current_unit->next_char_fn_ptr = &next_char_utf8;
2022 dtp->u.p.current_unit->push_char_fn_ptr = &push_char4;
2024 else if (is_internal_unit (dtp))
2026 dtp->u.p.current_unit->next_char_fn_ptr = &next_char_internal;
2027 dtp->u.p.current_unit->push_char_fn_ptr = &push_char_default;
2029 else
2031 dtp->u.p.current_unit->next_char_fn_ptr = &next_char_default;
2032 dtp->u.p.current_unit->push_char_fn_ptr = &push_char_default;
2037 /* Top level data transfer subroutine for list reads. Because we have
2038 to deal with repeat counts, the data item is always saved after
2039 reading, usually in the dtp->u.p.value[] array. If a repeat count is
2040 greater than one, we copy the data item multiple times. */
2042 static int
2043 list_formatted_read_scalar (st_parameter_dt *dtp, bt type, void *p,
2044 int kind, size_t size)
2046 gfc_char4_t *q, *r;
2047 int c, i, m;
2048 int err = 0;
2050 dtp->u.p.namelist_mode = 0;
2052 /* Set the next_char and push_char worker functions. */
2053 set_workers (dtp);
2055 if (dtp->u.p.first_item)
2057 dtp->u.p.first_item = 0;
2058 dtp->u.p.input_complete = 0;
2059 dtp->u.p.repeat_count = 1;
2060 dtp->u.p.at_eol = 0;
2062 if ((c = eat_spaces (dtp)) == EOF)
2064 err = LIBERROR_END;
2065 goto cleanup;
2067 if (is_separator (c))
2069 /* Found a null value. */
2070 dtp->u.p.repeat_count = 0;
2071 eat_separator (dtp);
2073 /* Set end-of-line flag. */
2074 if (c == '\n' || c == '\r')
2076 dtp->u.p.at_eol = 1;
2077 if (finish_separator (dtp) == LIBERROR_END)
2079 err = LIBERROR_END;
2080 goto cleanup;
2083 else
2084 goto cleanup;
2087 else
2089 if (dtp->u.p.repeat_count > 0)
2091 if (check_type (dtp, type, kind))
2092 return err;
2093 goto set_value;
2096 if (dtp->u.p.input_complete)
2097 goto cleanup;
2099 if (dtp->u.p.at_eol)
2100 finish_separator (dtp);
2101 else
2103 eat_spaces (dtp);
2104 /* Trailing spaces prior to end of line. */
2105 if (dtp->u.p.at_eol)
2106 finish_separator (dtp);
2109 dtp->u.p.saved_type = BT_UNKNOWN;
2110 dtp->u.p.repeat_count = 1;
2113 switch (type)
2115 case BT_INTEGER:
2116 read_integer (dtp, kind);
2117 break;
2118 case BT_LOGICAL:
2119 read_logical (dtp, kind);
2120 break;
2121 case BT_CHARACTER:
2122 read_character (dtp, kind);
2123 break;
2124 case BT_REAL:
2125 read_real (dtp, p, kind);
2126 /* Copy value back to temporary if needed. */
2127 if (dtp->u.p.repeat_count > 0)
2128 memcpy (dtp->u.p.value, p, size);
2129 break;
2130 case BT_COMPLEX:
2131 read_complex (dtp, p, kind, size);
2132 /* Copy value back to temporary if needed. */
2133 if (dtp->u.p.repeat_count > 0)
2134 memcpy (dtp->u.p.value, p, size);
2135 break;
2136 default:
2137 internal_error (&dtp->common, "Bad type for list read");
2140 if (dtp->u.p.saved_type != BT_CHARACTER && dtp->u.p.saved_type != BT_UNKNOWN)
2141 dtp->u.p.saved_length = size;
2143 if ((dtp->common.flags & IOPARM_LIBRETURN_MASK) != IOPARM_LIBRETURN_OK)
2144 goto cleanup;
2146 set_value:
2147 switch (dtp->u.p.saved_type)
2149 case BT_COMPLEX:
2150 case BT_REAL:
2151 if (dtp->u.p.repeat_count > 0)
2152 memcpy (p, dtp->u.p.value, size);
2153 break;
2155 case BT_INTEGER:
2156 case BT_LOGICAL:
2157 memcpy (p, dtp->u.p.value, size);
2158 break;
2160 case BT_CHARACTER:
2161 if (dtp->u.p.saved_string)
2163 m = ((int) size < dtp->u.p.saved_used)
2164 ? (int) size : dtp->u.p.saved_used;
2166 q = (gfc_char4_t *) p;
2167 r = (gfc_char4_t *) dtp->u.p.saved_string;
2168 if (dtp->u.p.current_unit->flags.encoding == ENCODING_UTF8)
2169 for (i = 0; i < m; i++)
2170 *q++ = *r++;
2171 else
2173 if (kind == 1)
2174 memcpy (p, dtp->u.p.saved_string, m);
2175 else
2176 for (i = 0; i < m; i++)
2177 *q++ = *r++;
2180 else
2181 /* Just delimiters encountered, nothing to copy but SPACE. */
2182 m = 0;
2184 if (m < (int) size)
2186 if (kind == 1)
2187 memset (((char *) p) + m, ' ', size - m);
2188 else
2190 q = (gfc_char4_t *) p;
2191 for (i = m; i < (int) size; i++)
2192 q[i] = (unsigned char) ' ';
2195 break;
2197 case BT_UNKNOWN:
2198 break;
2200 default:
2201 internal_error (&dtp->common, "Bad type for list read");
2204 if (--dtp->u.p.repeat_count <= 0)
2205 free_saved (dtp);
2207 cleanup:
2208 if (err == LIBERROR_END)
2210 free_line (dtp);
2211 hit_eof (dtp);
2213 return err;
2217 void
2218 list_formatted_read (st_parameter_dt *dtp, bt type, void *p, int kind,
2219 size_t size, size_t nelems)
2221 size_t elem;
2222 char *tmp;
2223 size_t stride = type == BT_CHARACTER ?
2224 size * GFC_SIZE_OF_CHAR_KIND(kind) : size;
2225 int err;
2227 tmp = (char *) p;
2229 /* Big loop over all the elements. */
2230 for (elem = 0; elem < nelems; elem++)
2232 dtp->u.p.item_count++;
2233 err = list_formatted_read_scalar (dtp, type, tmp + stride*elem,
2234 kind, size);
2235 if (err)
2236 break;
2241 /* Finish a list read. */
2243 void
2244 finish_list_read (st_parameter_dt *dtp)
2246 free_saved (dtp);
2248 fbuf_flush (dtp->u.p.current_unit, dtp->u.p.mode);
2250 if (dtp->u.p.at_eol)
2252 dtp->u.p.at_eol = 0;
2253 return;
2256 if (!is_internal_unit (dtp))
2258 int c;
2260 /* Set the next_char and push_char worker functions. */
2261 set_workers (dtp);
2263 c = next_char (dtp);
2264 if (c == EOF)
2266 free_line (dtp);
2267 hit_eof (dtp);
2268 return;
2270 if (c != '\n')
2271 eat_line (dtp);
2274 free_line (dtp);
2278 /* NAMELIST INPUT
2280 void namelist_read (st_parameter_dt *dtp)
2281 calls:
2282 static void nml_match_name (char *name, int len)
2283 static int nml_query (st_parameter_dt *dtp)
2284 static int nml_get_obj_data (st_parameter_dt *dtp,
2285 namelist_info **prev_nl, char *, size_t)
2286 calls:
2287 static void nml_untouch_nodes (st_parameter_dt *dtp)
2288 static namelist_info * find_nml_node (st_parameter_dt *dtp,
2289 char * var_name)
2290 static int nml_parse_qualifier(descriptor_dimension * ad,
2291 array_loop_spec * ls, int rank, char *)
2292 static void nml_touch_nodes (namelist_info * nl)
2293 static int nml_read_obj (namelist_info *nl, index_type offset,
2294 namelist_info **prev_nl, char *, size_t,
2295 index_type clow, index_type chigh)
2296 calls:
2297 -itself- */
2299 /* Inputs a rank-dimensional qualifier, which can contain
2300 singlets, doublets, triplets or ':' with the standard meanings. */
2302 static bool
2303 nml_parse_qualifier (st_parameter_dt *dtp, descriptor_dimension *ad,
2304 array_loop_spec *ls, int rank, bt nml_elem_type,
2305 char *parse_err_msg, size_t parse_err_msg_size,
2306 int *parsed_rank)
2308 int dim;
2309 int indx;
2310 int neg;
2311 int null_flag;
2312 int is_array_section, is_char;
2313 int c;
2315 is_char = 0;
2316 is_array_section = 0;
2317 dtp->u.p.expanded_read = 0;
2319 /* See if this is a character substring qualifier we are looking for. */
2320 if (rank == -1)
2322 rank = 1;
2323 is_char = 1;
2326 /* The next character in the stream should be the '('. */
2328 if ((c = next_char (dtp)) == EOF)
2329 goto err_ret;
2331 /* Process the qualifier, by dimension and triplet. */
2333 for (dim=0; dim < rank; dim++ )
2335 for (indx=0; indx<3; indx++)
2337 free_saved (dtp);
2338 eat_spaces (dtp);
2339 neg = 0;
2341 /* Process a potential sign. */
2342 if ((c = next_char (dtp)) == EOF)
2343 goto err_ret;
2344 switch (c)
2346 case '-':
2347 neg = 1;
2348 break;
2350 case '+':
2351 break;
2353 default:
2354 unget_char (dtp, c);
2355 break;
2358 /* Process characters up to the next ':' , ',' or ')'. */
2359 for (;;)
2361 c = next_char (dtp);
2362 switch (c)
2364 case EOF:
2365 goto err_ret;
2367 case ':':
2368 is_array_section = 1;
2369 break;
2371 case ',': case ')':
2372 if ((c==',' && dim == rank -1)
2373 || (c==')' && dim < rank -1))
2375 if (is_char)
2376 snprintf (parse_err_msg, parse_err_msg_size,
2377 "Bad substring qualifier");
2378 else
2379 snprintf (parse_err_msg, parse_err_msg_size,
2380 "Bad number of index fields");
2381 goto err_ret;
2383 break;
2385 CASE_DIGITS:
2386 push_char (dtp, c);
2387 continue;
2389 case ' ': case '\t': case '\r': case '\n':
2390 eat_spaces (dtp);
2391 break;
2393 default:
2394 if (is_char)
2395 snprintf (parse_err_msg, parse_err_msg_size,
2396 "Bad character in substring qualifier");
2397 else
2398 snprintf (parse_err_msg, parse_err_msg_size,
2399 "Bad character in index");
2400 goto err_ret;
2403 if ((c == ',' || c == ')') && indx == 0
2404 && dtp->u.p.saved_string == 0)
2406 if (is_char)
2407 snprintf (parse_err_msg, parse_err_msg_size,
2408 "Null substring qualifier");
2409 else
2410 snprintf (parse_err_msg, parse_err_msg_size,
2411 "Null index field");
2412 goto err_ret;
2415 if ((c == ':' && indx == 1 && dtp->u.p.saved_string == 0)
2416 || (indx == 2 && dtp->u.p.saved_string == 0))
2418 if (is_char)
2419 snprintf (parse_err_msg, parse_err_msg_size,
2420 "Bad substring qualifier");
2421 else
2422 snprintf (parse_err_msg, parse_err_msg_size,
2423 "Bad index triplet");
2424 goto err_ret;
2427 if (is_char && !is_array_section)
2429 snprintf (parse_err_msg, parse_err_msg_size,
2430 "Missing colon in substring qualifier");
2431 goto err_ret;
2434 /* If '( : ? )' or '( ? : )' break and flag read failure. */
2435 null_flag = 0;
2436 if ((c == ':' && indx == 0 && dtp->u.p.saved_string == 0)
2437 || (indx==1 && dtp->u.p.saved_string == 0))
2439 null_flag = 1;
2440 break;
2443 /* Now read the index. */
2444 if (convert_integer (dtp, sizeof(index_type), neg))
2446 if (is_char)
2447 snprintf (parse_err_msg, parse_err_msg_size,
2448 "Bad integer substring qualifier");
2449 else
2450 snprintf (parse_err_msg, parse_err_msg_size,
2451 "Bad integer in index");
2452 goto err_ret;
2454 break;
2457 /* Feed the index values to the triplet arrays. */
2458 if (!null_flag)
2460 if (indx == 0)
2461 memcpy (&ls[dim].start, dtp->u.p.value, sizeof(index_type));
2462 if (indx == 1)
2463 memcpy (&ls[dim].end, dtp->u.p.value, sizeof(index_type));
2464 if (indx == 2)
2465 memcpy (&ls[dim].step, dtp->u.p.value, sizeof(index_type));
2468 /* Singlet or doublet indices. */
2469 if (c==',' || c==')')
2471 if (indx == 0)
2473 memcpy (&ls[dim].start, dtp->u.p.value, sizeof(index_type));
2475 /* If -std=f95/2003 or an array section is specified,
2476 do not allow excess data to be processed. */
2477 if (is_array_section == 1
2478 || !(compile_options.allow_std & GFC_STD_GNU)
2479 || nml_elem_type == BT_DERIVED)
2480 ls[dim].end = ls[dim].start;
2481 else
2482 dtp->u.p.expanded_read = 1;
2485 /* Check for non-zero rank. */
2486 if (is_array_section == 1 && ls[dim].start != ls[dim].end)
2487 *parsed_rank = 1;
2489 break;
2493 if (is_array_section == 1 && dtp->u.p.expanded_read == 1)
2495 int i;
2496 dtp->u.p.expanded_read = 0;
2497 for (i = 0; i < dim; i++)
2498 ls[i].end = ls[i].start;
2501 /* Check the values of the triplet indices. */
2502 if ((ls[dim].start > GFC_DIMENSION_UBOUND(ad[dim]))
2503 || (ls[dim].start < GFC_DIMENSION_LBOUND(ad[dim]))
2504 || (ls[dim].end > GFC_DIMENSION_UBOUND(ad[dim]))
2505 || (ls[dim].end < GFC_DIMENSION_LBOUND(ad[dim])))
2507 if (is_char)
2508 snprintf (parse_err_msg, parse_err_msg_size,
2509 "Substring out of range");
2510 else
2511 snprintf (parse_err_msg, parse_err_msg_size,
2512 "Index %d out of range", dim + 1);
2513 goto err_ret;
2516 if (((ls[dim].end - ls[dim].start ) * ls[dim].step < 0)
2517 || (ls[dim].step == 0))
2519 snprintf (parse_err_msg, parse_err_msg_size,
2520 "Bad range in index %d", dim + 1);
2521 goto err_ret;
2524 /* Initialise the loop index counter. */
2525 ls[dim].idx = ls[dim].start;
2527 eat_spaces (dtp);
2528 return true;
2530 err_ret:
2532 /* The EOF error message is issued by hit_eof. Return true so that the
2533 caller does not use parse_err_msg and parse_err_msg_size to generate
2534 an unrelated error message. */
2535 if (c == EOF)
2537 hit_eof (dtp);
2538 dtp->u.p.input_complete = 1;
2539 return true;
2541 return false;
2545 static bool
2546 extended_look_ahead (char *p, char *q)
2548 char *r, *s;
2550 /* Scan ahead to find a '%' in the p string. */
2551 for(r = p, s = q; *r && *s; s++)
2552 if ((*s == '%' || *s == '+') && strcmp (r + 1, s + 1) == 0)
2553 return true;
2554 return false;
2558 static bool
2559 strcmp_extended_type (char *p, char *q)
2561 char *r, *s;
2563 for (r = p, s = q; *r && *s; r++, s++)
2565 if (*r != *s)
2567 if (*r == '%' && *s == '+' && extended_look_ahead (r, s))
2568 return true;
2569 break;
2572 return false;
2576 static namelist_info *
2577 find_nml_node (st_parameter_dt *dtp, char * var_name)
2579 namelist_info * t = dtp->u.p.ionml;
2580 while (t != NULL)
2582 if (strcmp (var_name, t->var_name) == 0)
2584 t->touched = 1;
2585 return t;
2587 if (strcmp_extended_type (var_name, t->var_name))
2589 t->touched = 1;
2590 return t;
2592 t = t->next;
2594 return NULL;
2597 /* Visits all the components of a derived type that have
2598 not explicitly been identified in the namelist input.
2599 touched is set and the loop specification initialised
2600 to default values */
2602 static void
2603 nml_touch_nodes (namelist_info * nl)
2605 index_type len = strlen (nl->var_name) + 1;
2606 int dim;
2607 char * ext_name = xmalloc (len + 1);
2608 memcpy (ext_name, nl->var_name, len-1);
2609 memcpy (ext_name + len - 1, "%", 2);
2610 for (nl = nl->next; nl; nl = nl->next)
2612 if (strncmp (nl->var_name, ext_name, len) == 0)
2614 nl->touched = 1;
2615 for (dim=0; dim < nl->var_rank; dim++)
2617 nl->ls[dim].step = 1;
2618 nl->ls[dim].end = GFC_DESCRIPTOR_UBOUND(nl,dim);
2619 nl->ls[dim].start = GFC_DESCRIPTOR_LBOUND(nl,dim);
2620 nl->ls[dim].idx = nl->ls[dim].start;
2623 else
2624 break;
2626 free (ext_name);
2627 return;
2630 /* Resets touched for the entire list of nml_nodes, ready for a
2631 new object. */
2633 static void
2634 nml_untouch_nodes (st_parameter_dt *dtp)
2636 namelist_info * t;
2637 for (t = dtp->u.p.ionml; t; t = t->next)
2638 t->touched = 0;
2639 return;
2642 /* Attempts to input name to namelist name. Returns
2643 dtp->u.p.nml_read_error = 1 on no match. */
2645 static void
2646 nml_match_name (st_parameter_dt *dtp, const char *name, index_type len)
2648 index_type i;
2649 int c;
2651 dtp->u.p.nml_read_error = 0;
2652 for (i = 0; i < len; i++)
2654 c = next_char (dtp);
2655 if (c == EOF || (tolower (c) != tolower (name[i])))
2657 dtp->u.p.nml_read_error = 1;
2658 break;
2663 /* If the namelist read is from stdin, output the current state of the
2664 namelist to stdout. This is used to implement the non-standard query
2665 features, ? and =?. If c == '=' the full namelist is printed. Otherwise
2666 the names alone are printed. */
2668 static void
2669 nml_query (st_parameter_dt *dtp, char c)
2671 gfc_unit * temp_unit;
2672 namelist_info * nl;
2673 index_type len;
2674 char * p;
2675 #ifdef HAVE_CRLF
2676 static const index_type endlen = 2;
2677 static const char endl[] = "\r\n";
2678 static const char nmlend[] = "&end\r\n";
2679 #else
2680 static const index_type endlen = 1;
2681 static const char endl[] = "\n";
2682 static const char nmlend[] = "&end\n";
2683 #endif
2685 if (dtp->u.p.current_unit->unit_number != options.stdin_unit)
2686 return;
2688 /* Store the current unit and transfer to stdout. */
2690 temp_unit = dtp->u.p.current_unit;
2691 dtp->u.p.current_unit = find_unit (options.stdout_unit);
2693 if (dtp->u.p.current_unit)
2695 dtp->u.p.mode = WRITING;
2696 next_record (dtp, 0);
2698 /* Write the namelist in its entirety. */
2700 if (c == '=')
2701 namelist_write (dtp);
2703 /* Or write the list of names. */
2705 else
2707 /* "&namelist_name\n" */
2709 len = dtp->namelist_name_len;
2710 p = write_block (dtp, len - 1 + endlen);
2711 if (!p)
2712 goto query_return;
2713 memcpy (p, "&", 1);
2714 memcpy ((char*)(p + 1), dtp->namelist_name, len);
2715 memcpy ((char*)(p + len + 1), &endl, endlen);
2716 for (nl = dtp->u.p.ionml; nl; nl = nl->next)
2718 /* " var_name\n" */
2720 len = strlen (nl->var_name);
2721 p = write_block (dtp, len + endlen);
2722 if (!p)
2723 goto query_return;
2724 memcpy (p, " ", 1);
2725 memcpy ((char*)(p + 1), nl->var_name, len);
2726 memcpy ((char*)(p + len + 1), &endl, endlen);
2729 /* "&end\n" */
2731 p = write_block (dtp, endlen + 4);
2732 if (!p)
2733 goto query_return;
2734 memcpy (p, &nmlend, endlen + 4);
2737 /* Flush the stream to force immediate output. */
2739 fbuf_flush (dtp->u.p.current_unit, WRITING);
2740 sflush (dtp->u.p.current_unit->s);
2741 unlock_unit (dtp->u.p.current_unit);
2744 query_return:
2746 /* Restore the current unit. */
2748 dtp->u.p.current_unit = temp_unit;
2749 dtp->u.p.mode = READING;
2750 return;
2753 /* Reads and stores the input for the namelist object nl. For an array,
2754 the function loops over the ranges defined by the loop specification.
2755 This default to all the data or to the specification from a qualifier.
2756 nml_read_obj recursively calls itself to read derived types. It visits
2757 all its own components but only reads data for those that were touched
2758 when the name was parsed. If a read error is encountered, an attempt is
2759 made to return to read a new object name because the standard allows too
2760 little data to be available. On the other hand, too much data is an
2761 error. */
2763 static bool
2764 nml_read_obj (st_parameter_dt *dtp, namelist_info * nl, index_type offset,
2765 namelist_info **pprev_nl, char *nml_err_msg,
2766 size_t nml_err_msg_size, index_type clow, index_type chigh)
2768 namelist_info * cmp;
2769 char * obj_name;
2770 int nml_carry;
2771 int len;
2772 int dim;
2773 index_type dlen;
2774 index_type m;
2775 size_t obj_name_len;
2776 void * pdata;
2778 /* If we have encountered a previous read error or this object has not been
2779 touched in name parsing, just return. */
2780 if (dtp->u.p.nml_read_error || !nl->touched)
2781 return true;
2783 dtp->u.p.repeat_count = 0;
2784 eat_spaces (dtp);
2786 len = nl->len;
2787 switch (nl->type)
2789 case BT_INTEGER:
2790 case BT_LOGICAL:
2791 dlen = len;
2792 break;
2794 case BT_REAL:
2795 dlen = size_from_real_kind (len);
2796 break;
2798 case BT_COMPLEX:
2799 dlen = size_from_complex_kind (len);
2800 break;
2802 case BT_CHARACTER:
2803 dlen = chigh ? (chigh - clow + 1) : nl->string_length;
2804 break;
2806 default:
2807 dlen = 0;
2812 /* Update the pointer to the data, using the current index vector */
2814 pdata = (void*)(nl->mem_pos + offset);
2815 for (dim = 0; dim < nl->var_rank; dim++)
2816 pdata = (void*)(pdata + (nl->ls[dim].idx
2817 - GFC_DESCRIPTOR_LBOUND(nl,dim))
2818 * GFC_DESCRIPTOR_STRIDE(nl,dim) * nl->size);
2820 /* If we are finished with the repeat count, try to read next value. */
2822 nml_carry = 0;
2823 if (--dtp->u.p.repeat_count <= 0)
2825 if (dtp->u.p.input_complete)
2826 return true;
2827 if (dtp->u.p.at_eol)
2828 finish_separator (dtp);
2829 if (dtp->u.p.input_complete)
2830 return true;
2832 dtp->u.p.saved_type = BT_UNKNOWN;
2833 free_saved (dtp);
2835 switch (nl->type)
2837 case BT_INTEGER:
2838 read_integer (dtp, len);
2839 break;
2841 case BT_LOGICAL:
2842 read_logical (dtp, len);
2843 break;
2845 case BT_CHARACTER:
2846 read_character (dtp, len);
2847 break;
2849 case BT_REAL:
2850 /* Need to copy data back from the real location to the temp in
2851 order to handle nml reads into arrays. */
2852 read_real (dtp, pdata, len);
2853 memcpy (dtp->u.p.value, pdata, dlen);
2854 break;
2856 case BT_COMPLEX:
2857 /* Same as for REAL, copy back to temp. */
2858 read_complex (dtp, pdata, len, dlen);
2859 memcpy (dtp->u.p.value, pdata, dlen);
2860 break;
2862 case BT_DERIVED:
2863 obj_name_len = strlen (nl->var_name) + 1;
2864 obj_name = xmalloc (obj_name_len+1);
2865 memcpy (obj_name, nl->var_name, obj_name_len-1);
2866 memcpy (obj_name + obj_name_len - 1, "%", 2);
2868 /* If reading a derived type, disable the expanded read warning
2869 since a single object can have multiple reads. */
2870 dtp->u.p.expanded_read = 0;
2872 /* Now loop over the components. */
2874 for (cmp = nl->next;
2875 cmp &&
2876 !strncmp (cmp->var_name, obj_name, obj_name_len);
2877 cmp = cmp->next)
2879 /* Jump over nested derived type by testing if the potential
2880 component name contains '%'. */
2881 if (strchr (cmp->var_name + obj_name_len, '%'))
2882 continue;
2884 if (!nml_read_obj (dtp, cmp, (index_type)(pdata - nl->mem_pos),
2885 pprev_nl, nml_err_msg, nml_err_msg_size,
2886 clow, chigh))
2888 free (obj_name);
2889 return false;
2892 if (dtp->u.p.input_complete)
2894 free (obj_name);
2895 return true;
2899 free (obj_name);
2900 goto incr_idx;
2902 default:
2903 snprintf (nml_err_msg, nml_err_msg_size,
2904 "Bad type for namelist object %s", nl->var_name);
2905 internal_error (&dtp->common, nml_err_msg);
2906 goto nml_err_ret;
2910 /* The standard permits array data to stop short of the number of
2911 elements specified in the loop specification. In this case, we
2912 should be here with dtp->u.p.nml_read_error != 0. Control returns to
2913 nml_get_obj_data and an attempt is made to read object name. */
2915 *pprev_nl = nl;
2916 if (dtp->u.p.nml_read_error)
2918 dtp->u.p.expanded_read = 0;
2919 return true;
2922 if (dtp->u.p.saved_type == BT_UNKNOWN)
2924 dtp->u.p.expanded_read = 0;
2925 goto incr_idx;
2928 switch (dtp->u.p.saved_type)
2931 case BT_COMPLEX:
2932 case BT_REAL:
2933 case BT_INTEGER:
2934 case BT_LOGICAL:
2935 memcpy (pdata, dtp->u.p.value, dlen);
2936 break;
2938 case BT_CHARACTER:
2939 if (dlen < dtp->u.p.saved_used)
2941 if (compile_options.bounds_check)
2943 snprintf (nml_err_msg, nml_err_msg_size,
2944 "Namelist object '%s' truncated on read.",
2945 nl->var_name);
2946 generate_warning (&dtp->common, nml_err_msg);
2948 m = dlen;
2950 else
2951 m = dtp->u.p.saved_used;
2953 if (dtp->u.p.current_unit->flags.encoding == ENCODING_UTF8)
2955 gfc_char4_t *q4, *p4 = pdata;
2956 int i;
2958 q4 = (gfc_char4_t *) dtp->u.p.saved_string;
2959 p4 += clow -1;
2960 for (i = 0; i < m; i++)
2961 *p4++ = *q4++;
2962 if (m < dlen)
2963 for (i = 0; i < dlen - m; i++)
2964 *p4++ = (gfc_char4_t) ' ';
2966 else
2968 pdata = (void*)( pdata + clow - 1 );
2969 memcpy (pdata, dtp->u.p.saved_string, m);
2970 if (m < dlen)
2971 memset ((void*)( pdata + m ), ' ', dlen - m);
2973 break;
2975 default:
2976 break;
2979 /* Warn if a non-standard expanded read occurs. A single read of a
2980 single object is acceptable. If a second read occurs, issue a warning
2981 and set the flag to zero to prevent further warnings. */
2982 if (dtp->u.p.expanded_read == 2)
2984 notify_std (&dtp->common, GFC_STD_GNU, "Non-standard expanded namelist read.");
2985 dtp->u.p.expanded_read = 0;
2988 /* If the expanded read warning flag is set, increment it,
2989 indicating that a single read has occurred. */
2990 if (dtp->u.p.expanded_read >= 1)
2991 dtp->u.p.expanded_read++;
2993 /* Break out of loop if scalar. */
2994 if (!nl->var_rank)
2995 break;
2997 /* Now increment the index vector. */
2999 incr_idx:
3001 nml_carry = 1;
3002 for (dim = 0; dim < nl->var_rank; dim++)
3004 nl->ls[dim].idx += nml_carry * nl->ls[dim].step;
3005 nml_carry = 0;
3006 if (((nl->ls[dim].step > 0) && (nl->ls[dim].idx > nl->ls[dim].end))
3008 ((nl->ls[dim].step < 0) && (nl->ls[dim].idx < nl->ls[dim].end)))
3010 nl->ls[dim].idx = nl->ls[dim].start;
3011 nml_carry = 1;
3014 } while (!nml_carry);
3016 if (dtp->u.p.repeat_count > 1)
3018 snprintf (nml_err_msg, nml_err_msg_size,
3019 "Repeat count too large for namelist object %s", nl->var_name);
3020 goto nml_err_ret;
3022 return true;
3024 nml_err_ret:
3026 return false;
3029 /* Parses the object name, including array and substring qualifiers. It
3030 iterates over derived type components, touching those components and
3031 setting their loop specifications, if there is a qualifier. If the
3032 object is itself a derived type, its components and subcomponents are
3033 touched. nml_read_obj is called at the end and this reads the data in
3034 the manner specified by the object name. */
3036 static bool
3037 nml_get_obj_data (st_parameter_dt *dtp, namelist_info **pprev_nl,
3038 char *nml_err_msg, size_t nml_err_msg_size)
3040 int c;
3041 namelist_info * nl;
3042 namelist_info * first_nl = NULL;
3043 namelist_info * root_nl = NULL;
3044 int dim, parsed_rank;
3045 int component_flag, qualifier_flag;
3046 index_type clow, chigh;
3047 int non_zero_rank_count;
3049 /* Look for end of input or object name. If '?' or '=?' are encountered
3050 in stdin, print the node names or the namelist to stdout. */
3052 eat_separator (dtp);
3053 if (dtp->u.p.input_complete)
3054 return true;
3056 if (dtp->u.p.at_eol)
3057 finish_separator (dtp);
3058 if (dtp->u.p.input_complete)
3059 return true;
3061 if ((c = next_char (dtp)) == EOF)
3062 goto nml_err_ret;
3063 switch (c)
3065 case '=':
3066 if ((c = next_char (dtp)) == EOF)
3067 goto nml_err_ret;
3068 if (c != '?')
3070 snprintf (nml_err_msg, nml_err_msg_size,
3071 "namelist read: misplaced = sign");
3072 goto nml_err_ret;
3074 nml_query (dtp, '=');
3075 return true;
3077 case '?':
3078 nml_query (dtp, '?');
3079 return true;
3081 case '$':
3082 case '&':
3083 nml_match_name (dtp, "end", 3);
3084 if (dtp->u.p.nml_read_error)
3086 snprintf (nml_err_msg, nml_err_msg_size,
3087 "namelist not terminated with / or &end");
3088 goto nml_err_ret;
3090 /* Fall through. */
3091 case '/':
3092 dtp->u.p.input_complete = 1;
3093 return true;
3095 default :
3096 break;
3099 /* Untouch all nodes of the namelist and reset the flags that are set for
3100 derived type components. */
3102 nml_untouch_nodes (dtp);
3103 component_flag = 0;
3104 qualifier_flag = 0;
3105 non_zero_rank_count = 0;
3107 /* Get the object name - should '!' and '\n' be permitted separators? */
3109 get_name:
3111 free_saved (dtp);
3115 if (!is_separator (c))
3116 push_char_default (dtp, tolower(c));
3117 if ((c = next_char (dtp)) == EOF)
3118 goto nml_err_ret;
3120 while (!( c=='=' || c==' ' || c=='\t' || c =='(' || c =='%' ));
3122 unget_char (dtp, c);
3124 /* Check that the name is in the namelist and get pointer to object.
3125 Three error conditions exist: (i) An attempt is being made to
3126 identify a non-existent object, following a failed data read or
3127 (ii) The object name does not exist or (iii) Too many data items
3128 are present for an object. (iii) gives the same error message
3129 as (i) */
3131 push_char_default (dtp, '\0');
3133 if (component_flag)
3135 size_t var_len = strlen (root_nl->var_name);
3136 size_t saved_len
3137 = dtp->u.p.saved_string ? strlen (dtp->u.p.saved_string) : 0;
3138 char ext_name[var_len + saved_len + 1];
3140 memcpy (ext_name, root_nl->var_name, var_len);
3141 if (dtp->u.p.saved_string)
3142 memcpy (ext_name + var_len, dtp->u.p.saved_string, saved_len);
3143 ext_name[var_len + saved_len] = '\0';
3144 nl = find_nml_node (dtp, ext_name);
3146 else
3147 nl = find_nml_node (dtp, dtp->u.p.saved_string);
3149 if (nl == NULL)
3151 if (dtp->u.p.nml_read_error && *pprev_nl)
3152 snprintf (nml_err_msg, nml_err_msg_size,
3153 "Bad data for namelist object %s", (*pprev_nl)->var_name);
3155 else
3156 snprintf (nml_err_msg, nml_err_msg_size,
3157 "Cannot match namelist object name %s",
3158 dtp->u.p.saved_string);
3160 goto nml_err_ret;
3163 /* Get the length, data length, base pointer and rank of the variable.
3164 Set the default loop specification first. */
3166 for (dim=0; dim < nl->var_rank; dim++)
3168 nl->ls[dim].step = 1;
3169 nl->ls[dim].end = GFC_DESCRIPTOR_UBOUND(nl,dim);
3170 nl->ls[dim].start = GFC_DESCRIPTOR_LBOUND(nl,dim);
3171 nl->ls[dim].idx = nl->ls[dim].start;
3174 /* Check to see if there is a qualifier: if so, parse it.*/
3176 if (c == '(' && nl->var_rank)
3178 parsed_rank = 0;
3179 if (!nml_parse_qualifier (dtp, nl->dim, nl->ls, nl->var_rank,
3180 nl->type, nml_err_msg, nml_err_msg_size,
3181 &parsed_rank))
3183 char *nml_err_msg_end = strchr (nml_err_msg, '\0');
3184 snprintf (nml_err_msg_end,
3185 nml_err_msg_size - (nml_err_msg_end - nml_err_msg),
3186 " for namelist variable %s", nl->var_name);
3187 goto nml_err_ret;
3189 if (parsed_rank > 0)
3190 non_zero_rank_count++;
3192 qualifier_flag = 1;
3194 if ((c = next_char (dtp)) == EOF)
3195 goto nml_err_ret;
3196 unget_char (dtp, c);
3198 else if (nl->var_rank > 0)
3199 non_zero_rank_count++;
3201 /* Now parse a derived type component. The root namelist_info address
3202 is backed up, as is the previous component level. The component flag
3203 is set and the iteration is made by jumping back to get_name. */
3205 if (c == '%')
3207 if (nl->type != BT_DERIVED)
3209 snprintf (nml_err_msg, nml_err_msg_size,
3210 "Attempt to get derived component for %s", nl->var_name);
3211 goto nml_err_ret;
3214 /* Don't move first_nl further in the list if a qualifier was found. */
3215 if ((*pprev_nl == NULL && !qualifier_flag) || !component_flag)
3216 first_nl = nl;
3218 root_nl = nl;
3220 component_flag = 1;
3221 if ((c = next_char (dtp)) == EOF)
3222 goto nml_err_ret;
3223 goto get_name;
3226 /* Parse a character qualifier, if present. chigh = 0 is a default
3227 that signals that the string length = string_length. */
3229 clow = 1;
3230 chigh = 0;
3232 if (c == '(' && nl->type == BT_CHARACTER)
3234 descriptor_dimension chd[1] = { {1, clow, nl->string_length} };
3235 array_loop_spec ind[1] = { {1, clow, nl->string_length, 1} };
3237 if (!nml_parse_qualifier (dtp, chd, ind, -1, nl->type,
3238 nml_err_msg, nml_err_msg_size, &parsed_rank))
3240 char *nml_err_msg_end = strchr (nml_err_msg, '\0');
3241 snprintf (nml_err_msg_end,
3242 nml_err_msg_size - (nml_err_msg_end - nml_err_msg),
3243 " for namelist variable %s", nl->var_name);
3244 goto nml_err_ret;
3247 clow = ind[0].start;
3248 chigh = ind[0].end;
3250 if (ind[0].step != 1)
3252 snprintf (nml_err_msg, nml_err_msg_size,
3253 "Step not allowed in substring qualifier"
3254 " for namelist object %s", nl->var_name);
3255 goto nml_err_ret;
3258 if ((c = next_char (dtp)) == EOF)
3259 goto nml_err_ret;
3260 unget_char (dtp, c);
3263 /* Make sure no extraneous qualifiers are there. */
3265 if (c == '(')
3267 snprintf (nml_err_msg, nml_err_msg_size,
3268 "Qualifier for a scalar or non-character namelist object %s",
3269 nl->var_name);
3270 goto nml_err_ret;
3273 /* Make sure there is no more than one non-zero rank object. */
3274 if (non_zero_rank_count > 1)
3276 snprintf (nml_err_msg, nml_err_msg_size,
3277 "Multiple sub-objects with non-zero rank in namelist object %s",
3278 nl->var_name);
3279 non_zero_rank_count = 0;
3280 goto nml_err_ret;
3283 /* According to the standard, an equal sign MUST follow an object name. The
3284 following is possibly lax - it allows comments, blank lines and so on to
3285 intervene. eat_spaces (dtp); c = next_char (dtp); would be compliant*/
3287 free_saved (dtp);
3289 eat_separator (dtp);
3290 if (dtp->u.p.input_complete)
3291 return true;
3293 if (dtp->u.p.at_eol)
3294 finish_separator (dtp);
3295 if (dtp->u.p.input_complete)
3296 return true;
3298 if ((c = next_char (dtp)) == EOF)
3299 goto nml_err_ret;
3301 if (c != '=')
3303 snprintf (nml_err_msg, nml_err_msg_size,
3304 "Equal sign must follow namelist object name %s",
3305 nl->var_name);
3306 goto nml_err_ret;
3308 /* If a derived type, touch its components and restore the root
3309 namelist_info if we have parsed a qualified derived type
3310 component. */
3312 if (nl->type == BT_DERIVED)
3313 nml_touch_nodes (nl);
3315 if (first_nl)
3317 if (first_nl->var_rank == 0)
3319 if (component_flag && qualifier_flag)
3320 nl = first_nl;
3322 else
3323 nl = first_nl;
3326 dtp->u.p.nml_read_error = 0;
3327 if (!nml_read_obj (dtp, nl, 0, pprev_nl, nml_err_msg, nml_err_msg_size,
3328 clow, chigh))
3329 goto nml_err_ret;
3331 return true;
3333 nml_err_ret:
3335 /* The EOF error message is issued by hit_eof. Return true so that the
3336 caller does not use nml_err_msg and nml_err_msg_size to generate
3337 an unrelated error message. */
3338 if (c == EOF)
3340 dtp->u.p.input_complete = 1;
3341 unget_char (dtp, c);
3342 hit_eof (dtp);
3343 return true;
3345 return false;
3348 /* Entry point for namelist input. Goes through input until namelist name
3349 is matched. Then cycles through nml_get_obj_data until the input is
3350 completed or there is an error. */
3352 void
3353 namelist_read (st_parameter_dt *dtp)
3355 int c;
3356 char nml_err_msg[200];
3358 /* Initialize the error string buffer just in case we get an unexpected fail
3359 somewhere and end up at nml_err_ret. */
3360 strcpy (nml_err_msg, "Internal namelist read error");
3362 /* Pointer to the previously read object, in case attempt is made to read
3363 new object name. Should this fail, error message can give previous
3364 name. */
3365 namelist_info *prev_nl = NULL;
3367 dtp->u.p.namelist_mode = 1;
3368 dtp->u.p.input_complete = 0;
3369 dtp->u.p.expanded_read = 0;
3371 /* Set the next_char and push_char worker functions. */
3372 set_workers (dtp);
3374 /* Look for &namelist_name . Skip all characters, testing for $nmlname.
3375 Exit on success or EOF. If '?' or '=?' encountered in stdin, print
3376 node names or namelist on stdout. */
3378 find_nml_name:
3379 c = next_char (dtp);
3380 switch (c)
3382 case '$':
3383 case '&':
3384 break;
3386 case '!':
3387 eat_line (dtp);
3388 goto find_nml_name;
3390 case '=':
3391 c = next_char (dtp);
3392 if (c == '?')
3393 nml_query (dtp, '=');
3394 else
3395 unget_char (dtp, c);
3396 goto find_nml_name;
3398 case '?':
3399 nml_query (dtp, '?');
3400 goto find_nml_name;
3402 case EOF:
3403 return;
3405 default:
3406 goto find_nml_name;
3409 /* Match the name of the namelist. */
3411 nml_match_name (dtp, dtp->namelist_name, dtp->namelist_name_len);
3413 if (dtp->u.p.nml_read_error)
3414 goto find_nml_name;
3416 /* A trailing space is required, we give a little latitude here, 10.9.1. */
3417 c = next_char (dtp);
3418 if (!is_separator(c) && c != '!')
3420 unget_char (dtp, c);
3421 goto find_nml_name;
3424 unget_char (dtp, c);
3425 eat_separator (dtp);
3427 /* Ready to read namelist objects. If there is an error in input
3428 from stdin, output the error message and continue. */
3430 while (!dtp->u.p.input_complete)
3432 if (!nml_get_obj_data (dtp, &prev_nl, nml_err_msg, sizeof nml_err_msg))
3434 if (dtp->u.p.current_unit->unit_number != options.stdin_unit)
3435 goto nml_err_ret;
3436 generate_error (&dtp->common, LIBERROR_READ_VALUE, nml_err_msg);
3439 /* Reset the previous namelist pointer if we know we are not going
3440 to be doing multiple reads within a single namelist object. */
3441 if (prev_nl && prev_nl->var_rank == 0)
3442 prev_nl = NULL;
3445 free_saved (dtp);
3446 free_line (dtp);
3447 return;
3450 nml_err_ret:
3452 /* All namelist error calls return from here */
3453 free_saved (dtp);
3454 free_line (dtp);
3455 generate_error (&dtp->common, LIBERROR_READ_VALUE, nml_err_msg);
3456 return;