| blob | 4da0606b5d12778f11d1ba2688490ed9e66ed613 |
1 /* Copyright (C) 2002-2016 Free Software Foundation, Inc.
2 Contributed by Andy Vaught
3 Namelist transfer functions 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 /* transfer.c -- Top level handling of data transfer statements. */
34 #include <string.h>
35 #include <assert.h>
36 #include <stdlib.h>
37 #include <errno.h>
40 /* Calling conventions: Data transfer statements are unlike other
41 library calls in that they extend over several calls.
43 The first call is always a call to st_read() or st_write(). These
44 subroutines return no status unless a namelist read or write is
45 being done, in which case there is the usual status. No further
46 calls are necessary in this case.
48 For other sorts of data transfer, there are zero or more data
49 transfer statement that depend on the format of the data transfer
50 statement. For READ (and for backwards compatibily: for WRITE), one has
52 transfer_integer
53 transfer_logical
54 transfer_character
55 transfer_character_wide
56 transfer_real
57 transfer_complex
58 transfer_real128
59 transfer_complex128
61 and for WRITE
63 transfer_integer_write
64 transfer_logical_write
65 transfer_character_write
66 transfer_character_wide_write
67 transfer_real_write
68 transfer_complex_write
69 transfer_real128_write
70 transfer_complex128_write
72 These subroutines do not return status. The *128 functions
73 are in the file transfer128.c.
75 The last call is a call to st_[read|write]_done(). While
76 something can easily go wrong with the initial st_read() or
77 st_write(), an error inhibits any data from actually being
78 transferred. */
118 gfc_charlen_type);
122 gfc_charlen_type);
134 };
141 };
151 };
159 };
165 };
172 };
178 };
183 }
184 file_mode;
187 static file_mode
189 {
190 file_mode m;
195 {
198 }
200 {
203 }
205 {
208 }
211 }
214 /* Mid level data transfer statements. */
216 /* Read sequential file - internal unit */
220 {
225 /* Zero size array gives internal unit len of 0. Nothing to read. */
230 /* If we have seen an eor previously, return a length of 0. The
231 caller is responsible for correctly padding the input field. */
233 {
235 /* Just return something that isn't a NULL pointer, otherwise the
236 caller thinks an error occurred. */
238 }
242 {
245 length);
249 }
250 else
254 {
257 }
266 }
268 /* When reading sequential formatted records we have a problem. We
269 don't know how long the line is until we read the trailing newline,
270 and we don't want to read too much. If we read too much, we might
271 have to do a physical seek backwards depending on how much data is
272 present, and devices like terminals aren't seekable and would cause
273 an I/O error.
275 Given this, the solution is to read a byte at a time, stopping if
276 we hit the newline. For small allocations, we use a static buffer.
277 For larger allocations, we are forced to allocate memory on the
278 heap. Hopefully this won't happen very often. */
280 /* Read sequential file - external unit */
284 {
289 /* If we have seen an eor previously, return a length of 0. The
290 caller is responsible for correctly padding the input field. */
292 {
294 /* Just return something that isn't a NULL pointer, otherwise the
295 caller thinks an error occurred. */
297 }
301 /* Read data into format buffer and scan through it. */
305 {
310 {
311 /* Unexpected end of line. Set the position. */
314 /* If we see an EOR during non-advancing I/O, we need to skip
315 the rest of the I/O statement. Set the corresponding flag. */
319 /* If we encounter a CR, it might be a CRLF. */
321 {
322 /* See if there is an LF. */
328 }
330 /* Without padding, terminate the I/O statement without assigning
331 the value. With padding, the value still needs to be assigned,
332 so we can just continue with a short read. */
334 {
337 }
341 }
342 /* Short circuit the read if a comma is found during numeric input.
343 The flag is set to zero during character reads so that commas in
344 strings are not ignored */
347 {
352 }
353 n++;
354 }
358 /* A short read implies we hit EOF, unless we hit EOR, a comma, or
359 some other stuff. Set the relevant flags. */
361 {
363 {
365 {
367 {
370 }
371 else
373 }
374 else
376 }
381 {
384 }
385 }
387 done:
394 /* We can't call fbuf_getptr before the loop doing fbuf_getc, because
395 fbuf_getc might reallocate the buffer. So return current pointer
396 minus all the advances, which is n plus up to two characters
397 of newline or comma. */
400 }
403 /* Function for reading the next couple of bytes from the current
404 file, advancing the current position. We return NULL on end of record or
405 end of file. This function is only for formatted I/O, unformatted uses
406 read_block_direct.
408 If the read is short, then it is because the current record does not
409 have enough data to satisfy the read request and the file was
410 opened with PAD=YES. The caller must assume tailing spaces for
411 short reads. */
415 {
420 {
422 {
423 /* For preconnected units with default record length, set bytes left
424 to unit record length and proceed, otherwise error. */
428 else
429 {
432 {
433 /* Not enough data left. */
436 }
437 }
441 {
444 }
447 }
448 }
453 {
456 else
462 }
464 /* If we reach here, we can assume it's direct access. */
476 {
477 /* Short read, this shouldn't happen. */
479 {
482 }
483 }
488 }
491 /* Read a block from a character(kind=4) internal unit, to be transferred into
492 a character(kind=4) variable. Note: Portions of this code borrowed from
493 read_sf_internal. */
496 {
504 /* Zero size array gives internal unit len of 0. Nothing to read. */
509 /* If we have seen an eor previously, return a length of 0. The
510 caller is responsible for correctly padding the input field. */
512 {
514 /* Just return something that isn't a NULL pointer, otherwise the
515 caller thinks an error occurred. */
517 }
523 {
526 }
534 }
537 /* Reads a block directly into application data space. This is for
538 unformatted files. */
540 static void
542 {
543 ssize_t to_read_record;
544 ssize_t have_read_record;
545 ssize_t to_read_subrecord;
546 ssize_t have_read_subrecord;
550 {
552 nbytes);
554 {
557 }
562 {
563 /* Short read, e.g. if we hit EOF. For stream files,
564 we have to set the end-of-file condition. */
566 }
568 }
571 {
573 {
577 }
578 else
579 {
582 }
588 {
591 }
594 {
595 /* Short read, e.g. if we hit EOF. Apparently, we read
596 more than was written to the last record. */
598 }
601 {
603 }
605 }
607 /* Unformatted sequential. We loop over the subrecords, reading
608 until the request has been fulfilled or the record has run out
609 of continuation subrecords. */
611 /* Check whether we exceed the total record length. */
615 {
618 }
619 else
620 {
623 }
627 {
630 {
633 }
634 else
635 {
638 }
645 {
648 }
653 {
654 /* Short read, e.g. if we hit EOF. This means the record
655 structure has been corrupted, or the trailing record
656 marker would still be present. */
660 }
663 {
665 {
668 }
669 else
670 {
671 /* Let's make sure the file position is correctly pre-positioned
672 for the next read statement. */
678 }
679 }
680 else
681 {
682 /* Normal exit, the read request has been fulfilled. */
684 }
685 }
689 {
692 }
694 }
697 /* Function for writing a block of bytes to the current file at the
698 current position, advancing the file pointer. We are given a length
699 and return a pointer to a buffer that the caller must (completely)
700 fill in. Returns NULL on error. */
704 {
708 {
710 {
711 /* For preconnected units with default record length, set bytes left
712 to unit record length and proceed, otherwise error. */
719 else
720 {
723 }
724 }
727 }
730 {
732 {
736 {
739 }
741 }
742 else
746 {
749 }
753 }
754 else
755 {
758 {
761 }
762 }
770 }
773 /* High level interface to swrite(), taking care of errors. This is only
774 called for unformatted files. There are three cases to consider:
775 Stream I/O, unformatted direct, unformatted sequential. */
777 static bool
779 {
781 ssize_t have_written;
782 ssize_t to_write_subrecord;
785 /* Stream I/O. */
788 {
791 {
794 }
799 }
801 /* Unformatted direct access. */
804 {
806 {
809 }
816 {
819 }
825 }
827 /* Unformatted sequential. */
833 {
836 }
837 else
838 {
840 }
843 {
845 to_write_subrecord =
855 {
858 }
869 }
872 {
875 }
877 }
880 /* Reverse memcpy - used for byte swapping. */
882 static void
884 {
891 /* Write with ascending order - this is likely faster
892 on modern architectures because of write combining. */
895 }
898 /* Utility function for byteswapping an array, using the bswap
899 builtins if possible. dest and src can overlap completely, or then
900 they must point to separate objects; partial overlaps are not
901 allowed. */
903 static void
905 {
910 {
929 {
937 }
943 {
950 }
955 {
958 {
962 }
963 }
964 else
965 {
966 /* In-place byte swap. */
968 {
971 {
975 low++;
976 high--;
977 }
979 }
980 }
981 }
982 }
985 /* Master function for unformatted reads. */
987 static void
990 {
997 {
998 /* Handle wide chracters. */
1000 {
1003 }
1005 /* Break up complex into its constituent reals. */
1007 {
1010 }
1012 }
1013 }
1016 /* Master function for unformatted writes. NOTE: For kind=10 the size is 16
1017 bytes on 64 bit machines. The unused bytes are not initialized and never
1018 used, which can show an error with memory checking analyzers like
1019 valgrind. */
1021 static void
1024 {
1027 {
1032 }
1033 else
1034 {
1035 #define BSWAP_BUFSZ 512
1042 /* Handle wide chracters. */
1044 {
1047 }
1049 /* Break up complex into its constituent reals. */
1051 {
1054 }
1056 /* By now, all complex variables have been split into their
1057 constituent reals. */
1060 do
1061 {
1065 else
1072 }
1074 }
1075 }
1078 /* Return a pointer to the name of a type. */
1082 {
1086 {
1104 }
1107 }
1110 /* Write a constant string to the output.
1111 This is complicated because the string can have doubled delimiters
1112 in it. The length in the format node is the true length. */
1114 static void
1116 {
1132 {
1136 }
1137 }
1140 /* Given actual and expected types in a formatted data transfer, make
1141 sure they agree. If not, an error message is generated. Returns
1142 nonzero if something went wrong. */
1144 static int
1146 {
1147 #define BUFLEN 100
1153 /* Adjust item_count before emitting error message. */
1160 }
1163 static int
1165 {
1166 #define BUFLEN 100
1172 /* Adjust item_count before emitting error message. */
1179 }
1182 /* This function is in the main loop for a formatted data transfer
1183 statement. It would be natural to implement this as a coroutine
1184 with the user program, but C makes that awkward. We loop,
1185 processing format elements. When we actually have to transfer
1186 data instead of just setting flags, we return control to the user
1187 program which calls a function that supplies the address and type
1188 of the next element, then comes back here to process it. */
1190 static void
1193 {
1196 format_token t;
1200 /* Change a complex data item into a pair of reals. */
1204 {
1207 }
1209 /* If there's an EOR condition, we simulate finalizing the transfer
1210 by doing nothing. */
1214 /* Set this flag so that commas in reads cause the read to complete before
1215 the entire field has been read. The next read field will start right after
1216 the comma in the stream. (Set to 0 for character reads). */
1221 {
1222 /* If reversion has occurred and there is another real data item,
1223 then we have to move to the next record. */
1225 {
1228 }
1236 {
1237 /* No data descriptors left. */
1242 }
1253 {
1302 /* It is possible to have FMT_A with something not BT_CHARACTER such
1303 as when writing out hollerith strings, so check both type
1304 and kind before calling wide character routines. */
1307 else
1361 {
1371 else
1379 }
1387 /* Format codes that don't transfer data. */
1402 {
1403 /* Handle the special case when no bytes have been used yet.
1404 Cannot go below zero. */
1406 {
1410 }
1413 }
1417 /* Standard 10.6.1.1: excessive left tabbing is reset to the
1418 left tab limit. We do not check if the position has gone
1419 beyond the end of record because a subsequent tab could
1420 bring us back again. */
1431 /* Adjust everything for end-of-record condition */
1433 {
1438 }
1440 {
1443 else
1447 }
1448 else
1534 /* A colon descriptor causes us to exit this loop (in
1535 particular preventing another / descriptor from being
1536 processed) unless there is another data item to be
1537 transferred. */
1545 }
1547 /* Adjust the item count and data pointer. */
1550 {
1551 n--;
1553 }
1559 }
1563 /* Come here when we need a data descriptor but don't have one. We
1564 push the current format node back onto the input, then return and
1565 let the user program call us back with the data. */
1566 need_read_data:
1568 }
1571 static void
1574 {
1577 format_token t;
1581 /* Change a complex data item into a pair of reals. */
1585 {
1588 }
1590 /* If there's an EOR condition, we simulate finalizing the transfer
1591 by doing nothing. */
1595 /* Set this flag so that commas in reads cause the read to complete before
1596 the entire field has been read. The next read field will start right after
1597 the comma in the stream. (Set to 0 for character reads). */
1602 {
1603 /* If reversion has occurred and there is another real data item,
1604 then we have to move to the next record. */
1606 {
1609 }
1617 {
1618 /* No data descriptors left. */
1623 }
1625 /* Now discharge T, TR and X movements to the right. This is delayed
1626 until a data producing format to suppress trailing spaces. */
1635 {
1637 {
1645 }
1647 {
1650 else
1653 }
1655 }
1664 {
1713 /* It is possible to have FMT_A with something not BT_CHARACTER such
1714 as when writing out hollerith strings, so check both type
1715 and kind before calling wide character routines. */
1718 else
1772 {
1782 else
1788 else
1794 }
1802 /* Format codes that don't transfer data. */
1810 /* Writes occur just before the switch on f->format, above, so
1811 that trailing blanks are suppressed, unless we are doing a
1812 non-advancing write in which case we want to output the blanks
1813 now. */
1815 {
1818 }
1826 {
1828 /* Handle the special case when no bytes have been used yet.
1829 Cannot go below zero. */
1831 {
1835 }
1838 }
1842 /* Standard 10.6.1.1: excessive left tabbing is reset to the
1843 left tab limit. We do not check if the position has gone
1844 beyond the end of record because a subsequent tab could
1845 bring us back again. */
1937 /* A colon descriptor causes us to exit this loop (in
1938 particular preventing another / descriptor from being
1939 processed) unless there is another data item to be
1940 transferred. */
1948 }
1950 /* Adjust the item count and data pointer. */
1953 {
1954 n--;
1956 }
1960 }
1964 /* Come here when we need a data descriptor but don't have one. We
1965 push the current format node back onto the input, then return and
1966 let the user program call us back with the data. */
1967 need_data:
1969 }
1971 /* This function is first called from data_init_transfer to initiate the loop
1972 over each item in the format, transferring data as required. Subsequent
1973 calls to this function occur for each data item foound in the READ/WRITE
1974 statement. The item_count is incremented for each call. Since the first
1975 call is from data_transfer_init, the item_count is always one greater than
1976 the actual count number of the item being transferred. */
1978 static void
1981 {
1989 {
1990 /* Big loop over all the elements. */
1992 {
1995 }
1996 }
1997 else
1998 {
1999 /* Big loop over all the elements. */
2001 {
2004 }
2005 }
2006 }
2009 /* Data transfer entry points. The type of the data entity is
2010 implicit in the subroutine call. This prevents us from having to
2011 share a common enum with the compiler. */
2013 void
2015 {
2019 }
2021 void
2023 {
2025 }
2027 void
2029 {
2035 }
2037 void
2039 {
2041 }
2043 void
2045 {
2049 }
2051 void
2053 {
2055 }
2057 void
2059 {
2065 /* Strings of zero length can have p == NULL, which confuses the
2066 transfer routines into thinking we need more data elements. To avoid
2067 this, we give them a nice pointer. */
2071 /* Set kind here to 1. */
2073 }
2075 void
2077 {
2079 }
2081 void
2083 {
2089 /* Strings of zero length can have p == NULL, which confuses the
2090 transfer routines into thinking we need more data elements. To avoid
2091 this, we give them a nice pointer. */
2095 /* Here we pass the actual kind value. */
2097 }
2099 void
2101 {
2103 }
2105 void
2107 {
2113 }
2115 void
2117 {
2119 }
2121 void
2123 gfc_charlen_type charlen)
2124 {
2131 bt iotype;
2141 {
2146 /* If the extent of even one dimension is zero, then the entire
2147 array section contains zero elements, so we return after writing
2148 a zero array record. */
2150 {
2155 }
2156 }
2160 /* If the innermost dimension has a stride of 1, we can do the transfer
2161 in contiguous chunks. */
2164 else
2170 {
2176 {
2179 n++;
2181 {
2184 }
2185 else
2186 {
2189 }
2190 }
2191 }
2192 }
2194 void
2196 gfc_charlen_type charlen)
2197 {
2199 }
2201 /* Preposition a sequential unformatted file while reading. */
2203 static void
2205 {
2207 GFC_INTEGER_4 i4;
2208 GFC_INTEGER_8 i8;
2209 gfc_offset i;
2213 else
2218 {
2221 }
2223 {
2226 }
2228 {
2231 }
2233 /* Only GFC_CONVERT_NATIVE and GFC_CONVERT_SWAP are valid here. */
2235 {
2237 {
2251 }
2252 }
2253 else
2254 {
2258 {
2276 }
2277 }
2280 {
2283 }
2284 else
2285 {
2288 }
2292 }
2295 /* Preposition a sequential unformatted file while writing. This
2296 amount to writing a bogus length that will be filled in later. */
2298 static void
2300 {
2301 ssize_t nbytes;
2302 gfc_offset dummy;
2308 else
2314 /* For sequential unformatted, if RECL= was not specified in the OPEN
2315 we write until we have more bytes than can fit in the subrecord
2316 markers, then we write a new subrecord. */
2321 }
2324 /* Position to the next record prior to transfer. We are assumed to
2325 be before the next record. We also calculate the bytes in the next
2326 record. */
2328 static void
2330 {
2335 {
2338 /* There are no records with stream I/O. If the position was specified
2339 data_transfer_init has already positioned the file. If no position
2340 was specified, we continue from where we last left off. I.e.
2341 there is nothing to do here. */
2347 else
2357 }
2360 }
2363 /* Initialize things for a data transfer. This code is common for
2364 both reading and writing. */
2366 static void
2368 {
2389 st_parameter_open opp;
2390 unit_convert conv;
2393 {
2399 }
2404 /* Is it unformatted? */
2408 else
2427 /* We use big_endian, which is 0 on little-endian machines
2428 and 1 on big-endian machines. */
2430 {
2446 }
2457 }
2459 /* Check the action. */
2462 {
2466 }
2469 {
2473 }
2477 /* Check the format. */
2485 {
2489 }
2492 {
2494 {
2498 }
2499 }
2502 {
2506 }
2510 {
2512 "Internal file cannot be accessed by UNFORMATTED "
2515 }
2517 /* Check the record or position number. */
2521 {
2525 }
2528 {
2530 {
2532 "Record number not allowed for sequential access "
2535 }
2539 {
2541 "Sequential READ or WRITE not allowed after "
2544 }
2546 }
2547 /* Process the ADVANCE option. */
2555 {
2557 {
2559 "ADVANCE specification conflicts with sequential "
2562 }
2565 {
2569 }
2573 {
2577 }
2578 }
2581 {
2585 {
2587 "EOR specification requires an ADVANCE specification "
2590 }
2594 {
2596 "SIZE specification requires an ADVANCE "
2599 }
2600 }
2601 else
2604 {
2606 "END specification cannot appear in a write "
2609 }
2612 {
2614 "EOR specification cannot appear in a write "
2617 }
2620 {
2622 "SIZE specification cannot appear in a write "
2625 }
2626 }
2631 /* Check the decimal mode. */
2641 /* Check the round mode. */
2651 /* Check the sign mode. */
2660 /* Check the blank mode. */
2664 blank_opt,
2670 /* Check the delim mode. */
2677 {
2680 else
2682 }
2684 /* Check the pad mode. */
2693 /* Check to see if we might be reading what we wrote before */
2697 {
2702 }
2704 /* Check the POS= specifier: that it is in range and that it is used with a
2705 unit that has been connected for STREAM access. F2003 9.5.1.10. */
2708 {
2710 {
2713 {
2717 }
2720 {
2724 }
2729 {
2730 /* Reset the endfile flag; if we hit EOF during reading
2731 we'll set the flag and generate an error at that point
2732 rather than worrying about it here. */
2734 }
2737 {
2740 {
2743 }
2745 }
2746 }
2747 else
2748 {
2750 "POS=specifier not allowed, "
2753 }
2754 }
2757 /* Sanity checks on the record number. */
2759 {
2761 {
2765 }
2768 {
2772 }
2774 /* Make sure format buffer is reset. */
2779 /* Check whether the record exists to be read. Only
2780 a partial record needs to exist. */
2784 {
2788 }
2790 /* Position the file. */
2793 {
2796 }
2798 /* TODO: This is required to maintain compatibility between
2799 4.3 and 4.4 runtime. Remove when ABI changes from 4.3 */
2804 /* TODO: Un-comment this code when ABI changes from 4.3.
2805 if (dtp->u.p.current_unit->flags.access == ACCESS_STREAM)
2806 {
2807 generate_error (&dtp->common, LIBERROR_OPTION_CONFLICT,
2808 "Record number not allowed for stream access "
2809 "data transfer");
2810 return;
2811 } */
2812 }
2814 /* Bugware for badly written mixed C-Fortran I/O. */
2820 /* Set the maximum position reached from the previous I/O operation. This
2821 could be greater than zero from a previous non-advancing write. */
2827 /* Set up the subroutine that will handle the transfers. */
2830 {
2833 else
2834 {
2836 {
2839 }
2840 else
2842 }
2843 }
2844 else
2845 {
2848 else
2849 {
2852 else
2854 }
2855 }
2857 /* Make sure that we don't do a read after a nonadvancing write. */
2860 {
2862 {
2866 }
2867 }
2868 else
2869 {
2872 }
2875 {
2876 #ifdef HAVE_USELOCALE
2878 #else
2881 {
2884 }
2886 #endif
2887 /* Start the data transfer if we are doing a formatted transfer. */
2891 }
2892 }
2895 /* Initialize an array_loop_spec given the array descriptor. The function
2896 returns the index of the last element of the array, and also returns
2897 starting record, where the first I/O goes to (necessary in case of
2898 negative strides). */
2900 gfc_offset
2903 {
2906 gfc_offset index;
2914 {
2923 {
2926 }
2927 else
2928 {
2933 }
2934 }
2938 else
2940 }
2942 /* Determine the index to the next record in an internal unit array by
2943 by incrementing through the array_loop_spec. */
2945 gfc_offset
2947 {
2949 gfc_offset index;
2955 {
2957 {
2960 {
2963 }
2964 else
2966 }
2968 }
2973 }
2977 /* Skip to the end of the current record, taking care of an optional
2978 record marker of size bytes. If the file is not seekable, we
2979 read chunks of size MAX_READ until we get to the right
2980 position. */
2982 static void
2984 {
2986 #define MAX_READ 4096
2993 /* Direct access files do not generate END conditions,
2994 only I/O errors. */
2997 {
2998 /* Seeking failed, fall back to seeking by reading data. */
3000 {
3001 rlength =
3007 {
3010 }
3013 }
3015 }
3017 }
3020 /* Advance to the next record reading unformatted files, taking
3021 care of subrecords. If complete_record is nonzero, we loop
3022 until all subrecords are cleared. */
3024 static void
3026 {
3033 {
3035 /* Skip over tail */
3043 }
3044 }
3047 static gfc_offset
3049 {
3051 }
3054 /* Space to the next record for read mode. */
3056 static void
3058 {
3059 gfc_offset record;
3065 {
3066 /* No records in unformatted STREAM I/O. */
3082 /* read_sf has already terminated input because of an '\n', or
3083 we have hit EOF. */
3085 {
3088 }
3091 {
3093 {
3101 /* Now seek to this record. */
3104 {
3107 }
3109 }
3110 else
3111 {
3118 {
3121 }
3124 }
3126 }
3127 else
3128 {
3129 do
3130 {
3134 {
3137 else
3138 {
3144 }
3146 }
3152 }
3154 }
3156 }
3157 }
3160 /* Small utility function to write a record marker, taking care of
3161 byte swapping and of choosing the correct size. */
3163 static int
3165 {
3167 GFC_INTEGER_4 buf4;
3168 GFC_INTEGER_8 buf8;
3172 else
3175 /* Only GFC_CONVERT_NATIVE and GFC_CONVERT_SWAP are valid here. */
3177 {
3179 {
3193 }
3194 }
3195 else
3196 {
3200 {
3218 }
3219 }
3221 }
3223 /* Position to the next (sub)record in write mode for
3224 unformatted sequential files. */
3226 static void
3228 {
3231 /* Bytes written. */
3237 else
3240 /* Seek to the head and overwrite the bogus length with the real
3241 length. */
3249 else
3255 /* Seek past the end of the current record. */
3260 /* Write the length tail. If we finish a record containing
3261 subrecords, we write out the negative length. */
3265 else
3273 io_error:
3277 }
3280 /* Utility function like memset() but operating on streams. Return
3281 value is same as for POSIX write(). */
3283 static ssize_t
3285 {
3286 #define WRITE_CHUNK 256
3292 else
3297 {
3303 }
3306 }
3309 /* Position to the next record in write mode. */
3311 static void
3313 {
3317 /* Zero counters for X- and T-editing. */
3322 {
3323 /* No records in unformatted STREAM I/O. */
3342 {
3346 }
3358 {
3361 {
3366 /* If the farthest position reached is greater than current
3367 position, adjust the position and set length to pad out
3368 whats left. Otherwise just pad whats left.
3369 (for character array unit) */
3373 {
3377 {
3380 }
3382 }
3389 {
3392 }
3393 else
3396 /* Now that the current record has been padded out,
3397 determine where the next record in the array is. */
3403 /* Now seek to this record */
3407 {
3410 }
3413 }
3414 else
3415 {
3418 /* If this is the last call to next_record move to the farthest
3419 position reached and set length to pad out the remainder
3420 of the record. (for character scaler unit) */
3422 {
3426 {
3430 {
3433 }
3435 }
3436 else
3438 }
3440 {
3446 {
3449 }
3450 else
3452 }
3453 }
3454 }
3455 else
3456 {
3457 #ifdef HAVE_CRLF
3459 #else
3461 #endif
3466 #ifdef HAVE_CRLF
3468 #endif
3471 {
3478 }
3479 }
3483 io_error:
3486 }
3487 }
3489 /* Position to the next record, which means moving to the end of the
3490 current record. This can happen under several different
3491 conditions. If the done flag is not set, we get ready to process
3492 the next record. */
3494 void
3496 {
3503 else
3507 {
3508 /* Since we have changed the position, set it to unspecified so
3509 that INQUIRE(POSITION=) knows it needs to look into it. */
3515 {
3517 /* Calculate next record, rounding up partial records. */
3521 }
3522 else
3524 }
3531 }
3534 /* Finalize the current data transfer. For a nonadvancing transfer,
3535 this means advancing to the next record. For internal units close the
3536 stream associated with the unit. */
3538 static void
3540 {
3547 {
3550 }
3553 {
3557 }
3561 {
3564 else
3566 }
3573 {
3576 }
3583 {
3589 }
3594 {
3598 }
3600 /* For non-advancing I/O, save the current maximum position for use in the
3601 next I/O operation if needed. */
3603 {
3605 {
3613 }
3620 }
3629 done:
3630 #ifdef HAVE_USELOCALE
3632 {
3635 }
3636 #else
3639 {
3642 }
3644 #endif
3645 }
3647 /* Transfer function for IOLENGTH. It doesn't actually do any
3648 data transfer, it just updates the length counter. */
3650 static void
3655 {
3658 }
3661 /* Initialize the IOLENGTH data transfer. This function is in essence
3662 a very much simplified version of data_transfer_init(), because it
3663 doesn't have to deal with units at all. */
3665 static void
3667 {
3673 /* Set up the subroutine that will handle the transfers. */
3676 }
3679 /* Library entry point for the IOLENGTH form of the INQUIRE
3680 statement. The IOLENGTH form requires no I/O to be performed, but
3681 it must still be a runtime library call so that we can determine
3682 the iolength for dynamic arrays and such. */
3687 void
3689 {
3692 }
3697 void
3699 {
3702 }
3705 /* The READ statement. */
3710 void
3712 {
3716 }
3721 void
3723 {
3727 {
3730 }
3740 }
3745 void
3747 {
3750 }
3755 void
3757 {
3760 /* Deal with endfile conditions associated with sequential files. */
3765 {
3774 /* Get rid of whatever is after this record. */
3781 }
3784 {
3787 }
3797 }
3800 /* F2003: This is a stub for the runtime portion of the WAIT statement. */
3801 void
3803 {
3804 }
3807 /* Receives the scalar information for namelist objects and stores it
3808 in a linked list of namelist_info types. */
3815 void
3818 GFC_INTEGER_4 dtype)
3819 {
3840 {
3845 }
3846 else
3847 {
3850 }
3855 {
3858 }
3859 else
3860 {
3863 }
3864 }
3866 /* Store the dimensional information for the namelist object. */
3869 index_type);
3872 void
3875 index_type ubound)
3876 {
3885 }
3888 /* Once upon a time, a poor innocent Fortran program was reading a
3889 file, when suddenly it hit the end-of-file (EOF). Unfortunately
3890 the OS doesn't tell whether we're at the EOF or whether we already
3891 went past it. Luckily our hero, libgfortran, keeps track of this.
3892 Call this function when you detect an EOF condition. See Section
3893 9.10.2 in F2003. */
3895 void
3897 {
3902 {
3907 {
3910 }
3911 else
3919 }
3920 else
3921 {
3922 /* Non-sequential files don't have an ENDFILE record, so we
3923 can't be at AFTER_ENDFILE. */
3927 }
3928 }