| blob | 41db2934aea9ad273d099ba4fad1f3b0dc82784c |
1 /*-
2 * Copyright (c) 1992 Keith Muller.
3 * Copyright (c) 1992, 1993
4 * The Regents of the University of California. All rights reserved.
5 *
6 * This code is derived from software contributed to Berkeley by
7 * Keith Muller of the University of California, San Diego.
8 *
9 * Redistribution and use in source and binary forms, with or without
10 * modification, are permitted provided that the following conditions
11 * are met:
12 * 1. Redistributions of source code must retain the above copyright
13 * notice, this list of conditions and the following disclaimer.
14 * 2. Redistributions in binary form must reproduce the above copyright
15 * notice, this list of conditions and the following disclaimer in the
16 * documentation and/or other materials provided with the distribution.
17 * 4. Neither the name of the University nor the names of its contributors
18 * may be used to endorse or promote products derived from this software
19 * without specific prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
22 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
23 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
24 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
25 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
26 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
27 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
28 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
29 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
30 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
31 * SUCH DAMAGE.
32 */
34 #ifndef lint
35 #if 0
37 #endif
40 #include <sys/types.h>
41 #include <sys/time.h>
42 #include <sys/stat.h>
43 #include <fcntl.h>
44 #include <errno.h>
45 #include <stdio.h>
46 #include <stdlib.h>
47 #include <string.h>
48 #include <unistd.h>
53 /*
54 * Routines for controlling the contents of all the different databases pax
55 * keeps. Tables are dynamically created only when they are needed. The
56 * goal was speed and the ability to work with HUGE archives. The databases
57 * were kept simple, but do have complex rules for when the contents change.
58 * As of this writing, the POSIX library functions were more complex than
59 * needed for this application (pax databases have very short lifetimes and
60 * do not survive after pax is finished). Pax is required to handle very
61 * large archives. These database routines carefully combine memory usage and
62 * temporary file storage in ways which will not significantly impact runtime
63 * performance while allowing the largest possible archives to be handled.
64 * Trying to force the fit to the POSIX databases routines was not considered
65 * time well spent.
66 */
79 /*
80 * hard link table routines
81 *
82 * The hard link table tries to detect hard links to files using the device and
83 * inode values. We do this when writing an archive, so we can tell the format
84 * write routine that this file is a hard link to another file. The format
85 * write routine then can store this file in whatever way it wants (as a hard
86 * link if the format supports that like tar, or ignore this info like cpio).
87 * (Actually a field in the format driver table tells us if the format wants
88 * hard link info. if not, we do not waste time looking for them). We also use
89 * the same table when reading an archive. In that situation, this table is
90 * used by the format read routine to detect hard links from stored dev and
91 * inode numbers (like cpio). This will allow pax to create a link when one
92 * can be detected by the archive format.
93 */
95 /*
96 * lnk_start
97 * Creates the hard link table.
98 * Return:
99 * 0 if created, -1 if failure
100 */
102 int
104 {
110 }
112 }
114 /*
115 * chk_lnk()
116 * Looks up entry in hard link hash table. If found, it copies the name
117 * of the file it is linked to (we already saw that file) into ln_name.
118 * lnkcnt is decremented and if goes to 1 the node is deleted from the
119 * database. (We have seen all the links to this file). If not found,
120 * we add the file to the database if it has the potential for having
121 * hard links to other files we may process (it has a link count > 1)
122 * Return:
123 * if found returns 1; if not found returns 0; -1 on error
124 */
126 int
128 {
131 u_int indx;
135 /*
136 * ignore those nodes that cannot have hard links
137 */
141 /*
142 * hash inode number and look for this file
143 */
146 /*
147 * it's hash chain in not empty, walk down looking for it
148 */
156 }
159 /*
160 * found a link. set the node type and copy in the
161 * name of the file it is to link to. we need to
162 * handle hardlinks to regular files differently than
163 * other links.
164 */
170 else
173 /*
174 * if we have found all the links to this file, remove
175 * it from the database
176 */
181 }
183 }
184 }
186 /*
187 * we never saw this file before. It has links so we add it to the
188 * front of this hash chain
189 */
198 }
200 }
204 }
206 /*
207 * purg_lnk
208 * remove reference for a file that we may have added to the data base as
209 * a potential source for hard links. We ended up not using the file, so
210 * we do not want to accidently point another file at it later on.
211 */
213 void
215 {
218 u_int indx;
222 /*
223 * do not bother to look if it could not be in the database
224 */
229 /*
230 * find the hash chain for this inode value, if empty return
231 */
236 /*
237 * walk down the list looking for the inode/dev pair, unlink and
238 * free if found
239 */
247 }
251 /*
252 * remove and free it
253 */
257 }
259 /*
260 * lnk_end()
261 * Pull apart an existing link table so we can reuse it. We do this between
262 * read and write phases of append with update. (The format may have
263 * used the link table, and we need to start with a fresh table for the
264 * write phase).
265 */
267 void
269 {
283 /*
284 * free up each entry on this chain
285 */
291 }
292 }
294 }
296 /*
297 * modification time table routines
298 *
299 * The modification time table keeps track of last modification times for all
300 * files stored in an archive during a write phase when -u is set. We only
301 * add a file to the archive if it is newer than a file with the same name
302 * already stored on the archive (if there is no other file with the same
303 * name on the archive it is added). This applies to writes and appends.
304 * An append with an -u must read the archive and store the modification time
305 * for every file on that archive before starting the write phase. It is clear
306 * that this is one HUGE database. To save memory space, the actual file names
307 * are stored in a scatch file and indexed by an in memory hash table. The
308 * hash table is indexed by hashing the file path. The nodes in the table store
309 * the length of the filename and the lseek offset within the scratch file
310 * where the actual name is stored. Since there are never any deletions to this
311 * table, fragmentation of the scratch file is never an issue. Lookups seem to
312 * not exhibit any locality at all (files in the database are rarely
313 * looked up more than once...). So caching is just a waste of memory. The
314 * only limitation is the amount of scatch file space available to store the
315 * path names.
316 */
318 /*
319 * ftime_start()
320 * create the file time hash table and open for read/write the scratch
321 * file. (after created it is unlinked, so when we exit we leave
322 * no witnesses).
323 * Return:
324 * 0 if the table and file was created ok, -1 otherwise
325 */
327 int
329 {
336 }
338 /*
339 * get random name and create temporary scratch file, unlink name
340 * so it will get removed on exit
341 */
345 tempfile);
347 }
351 }
353 /*
354 * chk_ftime()
355 * looks up entry in file time hash table. If not found, the file is
356 * added to the hash table and the file named stored in the scratch file.
357 * If a file with the same name is found, the file times are compared and
358 * the most recent file time is retained. If the new file was younger (or
359 * was not in the database) the new file is selected for storage.
360 * Return:
361 * 0 if file should be added to the archive, 1 if it should be skipped,
362 * -1 on error
363 */
365 int
367 {
370 u_int indx;
373 /*
374 * no info, go ahead and add to archive
375 */
379 /*
380 * hash the pathname and look up in table
381 */
385 /*
386 * the hash chain is not empty, walk down looking for match
387 * only read up the path names if the lengths match, speeds
388 * up the search a lot
389 */
392 /*
393 * potential match, have to read the name
394 * from the scratch file.
395 */
400 }
405 }
407 /*
408 * if the names match, we are done
409 */
412 }
414 /*
415 * try the next entry on the chain
416 */
418 }
421 /*
422 * found the file, compare the times, save the newer
423 */
425 /*
426 * file is newer
427 */
430 }
431 /*
432 * file is older
433 */
435 }
436 }
438 /*
439 * not in table, add it
440 */
442 /*
443 * add the name at the end of the scratch file, saving the
444 * offset. add the file to the head of the hash chain
445 */
453 }
463 }
465 /*
466 * Interactive rename table routines
467 *
468 * The interactive rename table keeps track of the new names that the user
469 * assigns to files from tty input. Since this map is unique for each file
470 * we must store it in case there is a reference to the file later in archive
471 * (a link). Otherwise we will be unable to find the file we know was
472 * extracted. The remapping of these files is stored in a memory based hash
473 * table (it is assumed since input must come from /dev/tty, it is unlikely to
474 * be a very large table).
475 */
477 /*
478 * name_start()
479 * create the interactive rename table
480 * Return:
481 * 0 if successful, -1 otherwise
482 */
484 int
486 {
492 }
494 }
496 /*
497 * add_name()
498 * add the new name to old name mapping just created by the user.
499 * If an old name mapping is found (there may be duplicate names on an
500 * archive) only the most recent is kept.
501 * Return:
502 * 0 if added, -1 otherwise
503 */
505 int
507 {
509 u_int indx;
512 /*
513 * should never happen
514 */
517 }
519 /*
520 * look to see if we have already mapped this file, if so we
521 * will update it
522 */
525 /*
526 * look down the has chain for the file
527 */
532 /*
533 * found an old mapping, replace it with the new one
534 * the user just input (if it is different)
535 */
543 }
545 }
546 }
548 /*
549 * this is a new mapping, add it to the table
550 */
557 }
559 }
561 }
564 }
566 /*
567 * sub_name()
568 * look up a link name to see if it points at a file that has been
569 * remapped by the user. If found, the link is adjusted to contain the
570 * new name (oname is the link to name)
571 */
573 void
575 {
577 u_int indx;
581 /*
582 * look the name up in the hash table
583 */
589 /*
590 * walk down the hash chain looking for a match
591 */
593 /*
594 * found it, replace it with the new name
595 * and return (we know that oname has enough space)
596 */
600 }
602 }
604 /*
605 * no match, just return
606 */
608 }
610 /*
611 * device/inode mapping table routines
612 * (used with formats that store device and inodes fields)
613 *
614 * device/inode mapping tables remap the device field in an archive header. The
615 * device/inode fields are used to determine when files are hard links to each
616 * other. However these values have very little meaning outside of that. This
617 * database is used to solve one of two different problems.
618 *
619 * 1) when files are appended to an archive, while the new files may have hard
620 * links to each other, you cannot determine if they have hard links to any
621 * file already stored on the archive from a prior run of pax. We must assume
622 * that these inode/device pairs are unique only within a SINGLE run of pax
623 * (which adds a set of files to an archive). So we have to make sure the
624 * inode/dev pairs we add each time are always unique. We do this by observing
625 * while the inode field is very dense, the use of the dev field is fairly
626 * sparse. Within each run of pax, we remap any device number of a new archive
627 * member that has a device number used in a prior run and already stored in a
628 * file on the archive. During the read phase of the append, we store the
629 * device numbers used and mark them to not be used by any file during the
630 * write phase. If during write we go to use one of those old device numbers,
631 * we remap it to a new value.
632 *
633 * 2) Often the fields in the archive header used to store these values are
634 * too small to store the entire value. The result is an inode or device value
635 * which can be truncated. This really can foul up an archive. With truncation
636 * we end up creating links between files that are really not links (after
637 * truncation the inodes are the same value). We address that by detecting
638 * truncation and forcing a remap of the device field to split truncated
639 * inodes away from each other. Each truncation creates a pattern of bits that
640 * are removed. We use this pattern of truncated bits to partition the inodes
641 * on a single device to many different devices (each one represented by the
642 * truncated bit pattern). All inodes on the same device that have the same
643 * truncation pattern are mapped to the same new device. Two inodes that
644 * truncate to the same value clearly will always have different truncation
645 * bit patterns, so they will be split from away each other. When we spot
646 * device truncation we remap the device number to a non truncated value.
647 * (for more info see table.h for the data structures involved).
648 */
650 /*
651 * dev_start()
652 * create the device mapping table
653 * Return:
654 * 0 if successful, -1 otherwise
655 */
657 int
659 {
665 }
667 }
669 /*
670 * add_dev()
671 * add a device number to the table. this will force the device to be
672 * remapped to a new value if it be used during a write phase. This
673 * function is called during the read phase of an append to prohibit the
674 * use of any device number already in the archive.
675 * Return:
676 * 0 if added ok, -1 otherwise
677 */
679 int
681 {
685 }
687 /*
688 * chk_dev()
689 * check for a device value in the device table. If not found and the add
690 * flag is set, it is added. This does NOT assign any mapping values, just
691 * adds the device number as one that need to be remapped. If this device
692 * is already mapped, just return with a pointer to that entry.
693 * Return:
694 * pointer to the entry for this device in the device map table. Null
695 * if the add flag is not set and the device is not in the table (it is
696 * not been seen yet). If add is set and the device cannot be added, null
697 * is returned (indicates an error).
698 */
702 {
704 u_int indx;
708 /*
709 * look to see if this device is already in the table
710 */
716 /*
717 * found it, return a pointer to it
718 */
721 }
723 /*
724 * not in table, we add it only if told to as this may just be a check
725 * to see if a device number is being used.
726 */
730 /*
731 * allocate a node for this device and add it to the front of the hash
732 * chain. Note we do not assign remaps values here, so the pt->list
733 * list must be NULL.
734 */
738 }
744 }
745 /*
746 * map_dev()
747 * given an inode and device storage mask (the mask has a 1 for each bit
748 * the archive format is able to store in a header), we check for inode
749 * and device truncation and remap the device as required. Device mapping
750 * can also occur when during the read phase of append a device number was
751 * seen (and was marked as do not use during the write phase). WE ASSUME
752 * that unsigned longs are the same size or bigger than the fields used
753 * for ino_t and dev_t. If not the types will have to be changed.
754 * Return:
755 * 0 if all ok, -1 otherwise.
756 */
758 int
760 {
767 ino_t nino;
771 /*
772 * check for device and inode truncation, and extract the truncated
773 * bit pattern.
774 */
780 }
782 /*
783 * see if this device is already being mapped, look up the device
784 * then find the truncation bit pattern which applies
785 */
787 /*
788 * this device is already marked to be remapped
789 */
795 /*
796 * we are being remapped for this device and pattern
797 * change the device number to be stored and return
798 */
802 }
804 /*
805 * this device is not being remapped YET. if we do not have any
806 * form of truncation, we do not need a remap
807 */
811 /*
812 * we have truncation, have to add this as a device to remap
813 */
817 /*
818 * if we just have a truncated inode, we have to make sure that
819 * all future inodes that do not truncate (they have the
820 * truncation pattern of all 0's) continue to map to the same
821 * device number. We probably have already written inodes with
822 * this device number to the archive with the truncation
823 * pattern of all 0's. So we add the mapping for all 0's to the
824 * same device number.
825 */
833 }
834 }
836 /*
837 * look for a device number not being used. We must watch for wrap
838 * around on lastdev (so we do not get stuck looking forever!)
839 */
843 /*
844 * found an unused value. If we have reached truncation point
845 * for this format we are hosed, so we give up. Otherwise we
846 * mark it as being used.
847 */
852 }
857 /*
858 * got a new device number, store it under this truncation pattern.
859 * change the device number this file is being stored with.
860 */
869 bad:
874 }
876 /*
877 * directory access/mod time reset table routines (for directories READ by pax)
878 *
879 * The pax -t flag requires that access times of archive files to be the same
880 * before being read by pax. For regular files, access time is restored after
881 * the file has been copied. This database provides the same functionality for
882 * directories read during file tree traversal. Restoring directory access time
883 * is more complex than files since directories may be read several times until
884 * all the descendants in their subtree are visited by fts. Directory access
885 * and modification times are stored during the fts pre-order visit (done
886 * before any descendants in the subtree is visited) and restored after the
887 * fts post-order visit (after all the descendants have been visited). In the
888 * case of premature exit from a subtree (like from the effects of -n), any
889 * directory entries left in this database are reset during final cleanup
890 * operations of pax. Entries are hashed by inode number for fast lookup.
891 */
893 /*
894 * atdir_start()
895 * create the directory access time database for directories READ by pax.
896 * Return:
897 * 0 is created ok, -1 otherwise.
898 */
900 int
902 {
908 }
910 }
913 /*
914 * atdir_end()
915 * walk through the directory access time table and reset the access time
916 * of any directory who still has an entry left in the database. These
917 * entries are for directories READ by pax
918 */
920 void
922 {
928 /*
929 * for each non-empty hash table entry reset all the directories
930 * chained there.
931 */
935 /*
936 * remember to force the times, set_ftime() looks at pmtime
937 * and patime, which only applies to things CREATED by pax,
938 * not read by pax. Read time reset is controlled by -t.
939 */
942 }
943 }
945 /*
946 * add_atdir()
947 * add a directory to the directory access time table. Table is hashed
948 * and chained by inode number. This is for directories READ by pax
949 */
951 void
953 {
955 u_int indx;
960 /*
961 * make sure this directory is not already in the table, if so just
962 * return (the older entry always has the correct time). The only
963 * way this will happen is when the same subtree can be traversed by
964 * different args to pax and the -n option is aborting fts out of a
965 * subtree before all the post-order visits have been made).
966 */
973 }
975 /*
976 * oops, already there. Leave it alone.
977 */
980 }
982 /*
983 * add it to the front of the hash chain
984 */
994 }
996 }
1000 }
1002 /*
1003 * get_atdir()
1004 * look up a directory by inode and device number to obtain the access
1005 * and modification time you want to set to. If found, the modification
1006 * and access time parameters are set and the entry is removed from the
1007 * table (as it is no longer needed). These are for directories READ by
1008 * pax
1009 * Return:
1010 * 0 if found, -1 if not found.
1011 */
1013 int
1015 {
1018 u_int indx;
1022 /*
1023 * hash by inode and search the chain for an inode and device match
1024 */
1033 /*
1034 * no match, go to next one
1035 */
1038 }
1040 /*
1041 * return if we did not find it.
1042 */
1046 /*
1047 * found it. return the times and remove the entry from the table.
1048 */
1055 }
1057 /*
1058 * directory access mode and time storage routines (for directories CREATED
1059 * by pax).
1060 *
1061 * Pax requires that extracted directories, by default, have their access/mod
1062 * times and permissions set to the values specified in the archive. During the
1063 * actions of extracting (and creating the destination subtree during -rw copy)
1064 * directories extracted may be modified after being created. Even worse is
1065 * that these directories may have been created with file permissions which
1066 * prohibits any descendants of these directories from being extracted. When
1067 * directories are created by pax, access rights may be added to permit the
1068 * creation of files in their subtree. Every time pax creates a directory, the
1069 * times and file permissions specified by the archive are stored. After all
1070 * files have been extracted (or copied), these directories have their times
1071 * and file modes reset to the stored values. The directory info is restored in
1072 * reverse order as entries were added to the data file from root to leaf. To
1073 * restore atime properly, we must go backwards. The data file consists of
1074 * records with two parts, the file name followed by a DIRDATA trailer. The
1075 * fixed sized trailer contains the size of the name plus the off_t location in
1076 * the file. To restore we work backwards through the file reading the trailer
1077 * then the file name.
1078 */
1080 /*
1081 * dir_start()
1082 * set up the directory time and file mode storage for directories CREATED
1083 * by pax.
1084 * Return:
1085 * 0 if ok, -1 otherwise
1086 */
1088 int
1090 {
1095 /*
1096 * unlink the file so it goes away at termination by itself
1097 */
1102 }
1104 tempfile);
1106 }
1108 /*
1109 * add_dir()
1110 * add the mode and times for a newly CREATED directory
1111 * name is name of the directory, psb the stat buffer with the data in it,
1112 * frc_mode is a flag that says whether to force the setting of the mode
1113 * (ignoring the user set values for preserving file mode). Frc_mode is
1114 * for the case where we created a file and found that the resulting
1115 * directory was not writeable and the user asked for file modes to NOT
1116 * be preserved. (we have to preserve what was created by default, so we
1117 * have to force the setting at the end. this is stated explicitly in the
1118 * pax spec)
1119 */
1121 void
1123 {
1124 DIRDATA dblk;
1129 /*
1130 * get current position (where file name will start) so we can store it
1131 * in the trailer
1132 */
1136 }
1138 /*
1139 * write the file name followed by the trailer
1140 */
1150 }
1154 }
1156 /*
1157 * proc_dir()
1158 * process all file modes and times stored for directories CREATED
1159 * by pax
1160 */
1162 void
1164 {
1166 DIRDATA dblk;
1167 u_long cnt;
1171 /*
1172 * read backwards through the file and process each directory
1173 */
1175 /*
1176 * read the trailer, then the file name, if this fails
1177 * just give up.
1178 */
1190 /*
1191 * frc_mode set, make sure we set the file modes even if
1192 * the user didn't ask for it (see file_subs.c for more info)
1193 */
1198 }
1205 }
1207 /*
1208 * database independent routines
1209 */
1211 /*
1212 * st_hash()
1213 * hashes filenames to a u_int for hashing into a table. Looks at the tail
1214 * end of file, as this provides far better distribution than any other
1215 * part of the name. For performance reasons we only care about the last
1216 * MAXKEYLEN chars (should be at LEAST large enough to pick off the file
1217 * name). Was tested on 500,000 name file tree traversal from the root
1218 * and gave almost a perfectly uniform distribution of keys when used with
1219 * prime sized tables (MAXKEYLEN was 128 in test). Hashes (sizeof int)
1220 * chars at a time and pads with 0 for last addition.
1221 * Return:
1222 * the hash value of the string MOD (%) the table size.
1223 */
1225 u_int
1227 {
1235 u_int val;
1237 /*
1238 * only look at the tail up to MAXKEYLEN, we do not need to waste
1239 * time here (remember these are pathnames, the tail is what will
1240 * spread out the keys)
1241 */
1248 /*
1249 * calculate the number of u_int size steps in the string and if
1250 * there is a runt to deal with
1251 */
1255 /*
1256 * add up the value of the string in unsigned integer sized pieces
1257 * too bad we cannot have unsigned int aligned strings, then we
1258 * could avoid the expensive copy.
1259 */
1266 }
1268 /*
1269 * add in the runt padded with zero to the right
1270 */
1278 }
1280 /*
1281 * return the result mod the table size
1282 */
1284 }