2 * Copyright (c) 2003-2009 Tim Kientzle
3 * Copyright (c) 2010-2012 Michihiro NAKAJIMA
6 * Redistribution and use in source and binary forms, with or without
7 * modification, are permitted provided that the following conditions
9 * 1. Redistributions of source code must retain the above copyright
10 * notice, this list of conditions and the following disclaimer
11 * in this position and unchanged.
12 * 2. Redistributions in binary form must reproduce the above copyright
13 * notice, this list of conditions and the following disclaimer in the
14 * documentation and/or other materials provided with the distribution.
16 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR(S) ``AS IS'' AND ANY EXPRESS OR
17 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
18 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
19 * IN NO EVENT SHALL THE AUTHOR(S) BE LIABLE FOR ANY DIRECT, INDIRECT,
20 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
21 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
22 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
23 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
24 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
25 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28 /* This is the tree-walking code for POSIX systems. */
29 #if !defined(_WIN32) || defined(__CYGWIN__)
31 #include "archive_platform.h"
32 __FBSDID("$FreeBSD$");
34 #ifdef HAVE_SYS_PARAM_H
35 #include <sys/param.h>
37 #ifdef HAVE_SYS_MOUNT_H
38 #include <sys/mount.h>
40 #ifdef HAVE_SYS_STAT_H
43 #ifdef HAVE_SYS_STATFS_H
44 #include <sys/statfs.h>
46 #ifdef HAVE_SYS_STATVFS_H
47 #include <sys/statvfs.h>
49 #ifdef HAVE_SYS_TIME_H
52 #ifdef HAVE_LINUX_MAGIC_H
53 #include <linux/magic.h>
55 #ifdef HAVE_LINUX_FS_H
59 * Some Linux distributions have both linux/ext2_fs.h and ext2fs/ext2_fs.h.
60 * As the include guards don't agree, the order of include is important.
62 #ifdef HAVE_LINUX_EXT2_FS_H
63 #include <linux/ext2_fs.h> /* for Linux file flags */
65 #if defined(HAVE_EXT2FS_EXT2_FS_H) && !defined(__CYGWIN__)
66 #include <ext2fs/ext2_fs.h> /* Linux file flags, broken on Cygwin */
92 #ifdef HAVE_SYS_IOCTL_H
93 #include <sys/ioctl.h>
97 #include "archive_string.h"
98 #include "archive_entry.h"
99 #include "archive_private.h"
100 #include "archive_read_disk_private.h"
103 #error fchdir function required.
113 * This is a new directory-walking system that addresses a number
114 * of problems I've had with fts(3). In particular, it has no
115 * pathname-length limits (other than the size of 'int'), handles
116 * deep logical traversals, uses considerably less memory, and has
117 * an opaque interface (easier to modify in the future).
119 * Internally, it keeps a single list of "tree_entry" items that
120 * represent filesystem objects that require further attention.
121 * Non-directories are not kept in memory: they are pulled from
122 * readdir(), returned to the client, then freed as soon as possible.
123 * Any directory entry to be traversed gets pushed onto the stack.
125 * There is surprisingly little information that needs to be kept for
126 * each item on the stack. Just the name, depth (represented here as the
127 * string length of the parent directory's pathname), and some markers
128 * indicating how to get back to the parent (via chdir("..") for a
129 * regular dir or via fchdir(2) for a symlink).
134 * 3) Arbitrary logical traversals by closing/reopening intermediate fds.
137 struct restore_time {
149 struct tree_entry *next;
150 struct tree_entry *parent;
151 struct archive_string name;
152 size_t dirname_length;
157 /* How to return back to the parent of a symlink. */
158 int symlink_parent_fd;
159 /* How to restore time of a directory. */
160 struct restore_time restore_time;
168 #if defined(USE_READDIR_R)
177 * Buffer used for reading file contents.
179 /* Exactly allocated memory pointer. */
180 unsigned char *allocation_ptr;
181 /* Pointer adjusted to the filesystem alignment . */
186 /* Definitions for tree_entry.flags bitmap. */
187 #define isDir 1 /* This entry is a regular directory. */
188 #define isDirLink 2 /* This entry is a symbolic link to a directory. */
189 #define needsFirstVisit 4 /* This is an initial entry. */
190 #define needsDescent 8 /* This entry needs to be previsited. */
191 #define needsOpen 16 /* This is a directory that needs to be opened. */
192 #define needsAscent 32 /* This entry needs to be postvisited. */
195 * Local data for this package.
198 struct tree_entry *stack;
199 struct tree_entry *current;
201 #define INVALID_DIR_HANDLE NULL
203 #if defined(USE_READDIR_R)
204 struct dirent *dirent;
205 size_t dirent_allocated;
209 /* Error code from last failed operation. */
212 /* Dynamically-sized buffer for holding path */
213 struct archive_string path;
215 /* Last path element */
216 const char *basename;
217 /* Leading dir length */
218 size_t dirname_length;
230 /* How to restore time of a file. */
231 struct restore_time restore_time;
233 struct entry_sparse {
236 } *sparse_list, *current_sparse;
238 int sparse_list_size;
240 char initial_symlink_mode;
242 struct filesystem *current_filesystem;
243 struct filesystem *filesystem_table;
244 int initial_filesystem_id;
245 int current_filesystem_id;
246 int max_filesystem_id;
247 int allocated_filesystem;
251 int64_t entry_remaining_bytes;
253 unsigned char *entry_buff;
254 size_t entry_buff_size;
257 /* Definitions for tree.flags bitmap. */
258 #define hasStat 16 /* The st entry is valid. */
259 #define hasLstat 32 /* The lst entry is valid. */
260 #define onWorkingDir 64 /* We are on the working dir where we are
261 * reading directory entry at this time. */
262 #define needsRestoreTimes 128
263 #define onInitialDir 256 /* We are on the initial dir. */
266 tree_dir_next_posix(struct tree *t);
268 #ifdef HAVE_DIRENT_D_NAMLEN
269 /* BSD extension; avoids need for a strlen() call. */
270 #define D_NAMELEN(dp) (dp)->d_namlen
272 #define D_NAMELEN(dp) (strlen((dp)->d_name))
275 /* Initiate/terminate a tree traversal. */
276 static struct tree *tree_open(const char *, int, int);
277 static struct tree *tree_reopen(struct tree *, const char *, int);
278 static void tree_close(struct tree *);
279 static void tree_free(struct tree *);
280 static void tree_push(struct tree *, const char *, int, int64_t, int64_t,
281 struct restore_time *);
282 static int tree_enter_initial_dir(struct tree *);
283 static int tree_enter_working_dir(struct tree *);
284 static int tree_current_dir_fd(struct tree *);
287 * tree_next() returns Zero if there is no next entry, non-zero if
288 * there is. Note that directories are visited three times.
289 * Directories are always visited first as part of enumerating their
290 * parent; that is a "regular" visit. If tree_descend() is invoked at
291 * that time, the directory is added to a work list and will
292 * subsequently be visited two more times: once just after descending
293 * into the directory ("postdescent") and again just after ascending
294 * back to the parent ("postascent").
296 * TREE_ERROR_DIR is returned if the descent failed (because the
297 * directory couldn't be opened, for instance). This is returned
298 * instead of TREE_POSTDESCENT/TREE_POSTASCENT. TREE_ERROR_DIR is not a
299 * fatal error, but it does imply that the relevant subtree won't be
300 * visited. TREE_ERROR_FATAL is returned for an error that left the
301 * traversal completely hosed. Right now, this is only returned for
302 * chdir() failures during ascent.
304 #define TREE_REGULAR 1
305 #define TREE_POSTDESCENT 2
306 #define TREE_POSTASCENT 3
307 #define TREE_ERROR_DIR -1
308 #define TREE_ERROR_FATAL -2
310 static int tree_next(struct tree *);
313 * Return information about the current entry.
317 * The current full pathname, length of the full pathname, and a name
318 * that can be used to access the file. Because tree does use chdir
319 * extensively, the access path is almost never the same as the full
322 * TODO: On platforms that support it, use openat()-style operations
323 * to eliminate the chdir() operations entirely while still supporting
324 * arbitrarily deep traversals. This makes access_path troublesome to
325 * support, of course, which means we'll need a rich enough interface
326 * that clients can function without it. (In particular, we'll need
327 * tree_current_open() that returns an open file descriptor.)
330 static const char *tree_current_path(struct tree *);
331 static const char *tree_current_access_path(struct tree *);
334 * Request the lstat() or stat() data for the current path. Since the
335 * tree package needs to do some of this anyway, and caches the
336 * results, you should take advantage of it here if you need it rather
337 * than make a redundant stat() or lstat() call of your own.
339 static const struct stat *tree_current_stat(struct tree *);
340 static const struct stat *tree_current_lstat(struct tree *);
341 static int tree_current_is_symblic_link_target(struct tree *);
343 /* The following functions use tricks to avoid a certain number of
344 * stat()/lstat() calls. */
345 /* "is_physical_dir" is equivalent to S_ISDIR(tree_current_lstat()->st_mode) */
346 static int tree_current_is_physical_dir(struct tree *);
347 /* "is_dir" is equivalent to S_ISDIR(tree_current_stat()->st_mode) */
348 static int tree_current_is_dir(struct tree *);
349 static int update_current_filesystem(struct archive_read_disk *a,
351 static int setup_current_filesystem(struct archive_read_disk *);
352 static int tree_target_is_same_as_parent(struct tree *, const struct stat *);
354 static int _archive_read_disk_open(struct archive *, const char *);
355 static int _archive_read_free(struct archive *);
356 static int _archive_read_close(struct archive *);
357 static int _archive_read_data_block(struct archive *,
358 const void **, size_t *, int64_t *);
359 static int _archive_read_next_header(struct archive *,
360 struct archive_entry **);
361 static int _archive_read_next_header2(struct archive *,
362 struct archive_entry *);
363 static const char *trivial_lookup_gname(void *, int64_t gid);
364 static const char *trivial_lookup_uname(void *, int64_t uid);
365 static int setup_sparse(struct archive_read_disk *, struct archive_entry *);
366 static int close_and_restore_time(int fd, struct tree *,
367 struct restore_time *);
368 static int open_on_current_dir(struct tree *, const char *, int);
369 static int tree_dup(int);
372 static struct archive_vtable *
373 archive_read_disk_vtable(void)
375 static struct archive_vtable av;
376 static int inited = 0;
379 av.archive_free = _archive_read_free;
380 av.archive_close = _archive_read_close;
381 av.archive_read_data_block = _archive_read_data_block;
382 av.archive_read_next_header = _archive_read_next_header;
383 av.archive_read_next_header2 = _archive_read_next_header2;
390 archive_read_disk_gname(struct archive *_a, la_int64_t gid)
392 struct archive_read_disk *a = (struct archive_read_disk *)_a;
393 if (ARCHIVE_OK != __archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
394 ARCHIVE_STATE_ANY, "archive_read_disk_gname"))
396 if (a->lookup_gname == NULL)
398 return ((*a->lookup_gname)(a->lookup_gname_data, gid));
402 archive_read_disk_uname(struct archive *_a, la_int64_t uid)
404 struct archive_read_disk *a = (struct archive_read_disk *)_a;
405 if (ARCHIVE_OK != __archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
406 ARCHIVE_STATE_ANY, "archive_read_disk_uname"))
408 if (a->lookup_uname == NULL)
410 return ((*a->lookup_uname)(a->lookup_uname_data, uid));
414 archive_read_disk_set_gname_lookup(struct archive *_a,
416 const char * (*lookup_gname)(void *private, la_int64_t gid),
417 void (*cleanup_gname)(void *private))
419 struct archive_read_disk *a = (struct archive_read_disk *)_a;
420 archive_check_magic(&a->archive, ARCHIVE_READ_DISK_MAGIC,
421 ARCHIVE_STATE_ANY, "archive_read_disk_set_gname_lookup");
423 if (a->cleanup_gname != NULL && a->lookup_gname_data != NULL)
424 (a->cleanup_gname)(a->lookup_gname_data);
426 a->lookup_gname = lookup_gname;
427 a->cleanup_gname = cleanup_gname;
428 a->lookup_gname_data = private_data;
433 archive_read_disk_set_uname_lookup(struct archive *_a,
435 const char * (*lookup_uname)(void *private, la_int64_t uid),
436 void (*cleanup_uname)(void *private))
438 struct archive_read_disk *a = (struct archive_read_disk *)_a;
439 archive_check_magic(&a->archive, ARCHIVE_READ_DISK_MAGIC,
440 ARCHIVE_STATE_ANY, "archive_read_disk_set_uname_lookup");
442 if (a->cleanup_uname != NULL && a->lookup_uname_data != NULL)
443 (a->cleanup_uname)(a->lookup_uname_data);
445 a->lookup_uname = lookup_uname;
446 a->cleanup_uname = cleanup_uname;
447 a->lookup_uname_data = private_data;
452 * Create a new archive_read_disk object and initialize it with global state.
455 archive_read_disk_new(void)
457 struct archive_read_disk *a;
459 a = (struct archive_read_disk *)calloc(1, sizeof(*a));
462 a->archive.magic = ARCHIVE_READ_DISK_MAGIC;
463 a->archive.state = ARCHIVE_STATE_NEW;
464 a->archive.vtable = archive_read_disk_vtable();
465 a->entry = archive_entry_new2(&a->archive);
466 a->lookup_uname = trivial_lookup_uname;
467 a->lookup_gname = trivial_lookup_gname;
468 a->flags = ARCHIVE_READDISK_MAC_COPYFILE;
469 a->open_on_current_dir = open_on_current_dir;
470 a->tree_current_dir_fd = tree_current_dir_fd;
471 a->tree_enter_working_dir = tree_enter_working_dir;
472 return (&a->archive);
476 _archive_read_free(struct archive *_a)
478 struct archive_read_disk *a = (struct archive_read_disk *)_a;
483 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
484 ARCHIVE_STATE_ANY | ARCHIVE_STATE_FATAL, "archive_read_free");
486 if (a->archive.state != ARCHIVE_STATE_CLOSED)
487 r = _archive_read_close(&a->archive);
492 if (a->cleanup_gname != NULL && a->lookup_gname_data != NULL)
493 (a->cleanup_gname)(a->lookup_gname_data);
494 if (a->cleanup_uname != NULL && a->lookup_uname_data != NULL)
495 (a->cleanup_uname)(a->lookup_uname_data);
496 archive_string_free(&a->archive.error_string);
497 archive_entry_free(a->entry);
498 a->archive.magic = 0;
499 __archive_clean(&a->archive);
505 _archive_read_close(struct archive *_a)
507 struct archive_read_disk *a = (struct archive_read_disk *)_a;
509 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
510 ARCHIVE_STATE_ANY | ARCHIVE_STATE_FATAL, "archive_read_close");
512 if (a->archive.state != ARCHIVE_STATE_FATAL)
513 a->archive.state = ARCHIVE_STATE_CLOSED;
521 setup_symlink_mode(struct archive_read_disk *a, char symlink_mode,
524 a->symlink_mode = symlink_mode;
525 a->follow_symlinks = follow_symlinks;
526 if (a->tree != NULL) {
527 a->tree->initial_symlink_mode = a->symlink_mode;
528 a->tree->symlink_mode = a->symlink_mode;
533 archive_read_disk_set_symlink_logical(struct archive *_a)
535 struct archive_read_disk *a = (struct archive_read_disk *)_a;
536 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
537 ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_logical");
538 setup_symlink_mode(a, 'L', 1);
543 archive_read_disk_set_symlink_physical(struct archive *_a)
545 struct archive_read_disk *a = (struct archive_read_disk *)_a;
546 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
547 ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_physical");
548 setup_symlink_mode(a, 'P', 0);
553 archive_read_disk_set_symlink_hybrid(struct archive *_a)
555 struct archive_read_disk *a = (struct archive_read_disk *)_a;
556 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
557 ARCHIVE_STATE_ANY, "archive_read_disk_set_symlink_hybrid");
558 setup_symlink_mode(a, 'H', 1);/* Follow symlinks initially. */
563 archive_read_disk_set_atime_restored(struct archive *_a)
565 struct archive_read_disk *a = (struct archive_read_disk *)_a;
566 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
567 ARCHIVE_STATE_ANY, "archive_read_disk_restore_atime");
569 a->flags |= ARCHIVE_READDISK_RESTORE_ATIME;
571 a->tree->flags |= needsRestoreTimes;
574 /* Display warning and unset flag */
575 archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC,
576 "Cannot restore access time on this system");
577 a->flags &= ~ARCHIVE_READDISK_RESTORE_ATIME;
578 return (ARCHIVE_WARN);
583 archive_read_disk_set_behavior(struct archive *_a, int flags)
585 struct archive_read_disk *a = (struct archive_read_disk *)_a;
588 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
589 ARCHIVE_STATE_ANY, "archive_read_disk_honor_nodump");
593 if (flags & ARCHIVE_READDISK_RESTORE_ATIME)
594 r = archive_read_disk_set_atime_restored(_a);
597 a->tree->flags &= ~needsRestoreTimes;
603 * Trivial implementations of gname/uname lookup functions.
604 * These are normally overridden by the client, but these stub
605 * versions ensure that we always have something that works.
608 trivial_lookup_gname(void *private_data, int64_t gid)
610 (void)private_data; /* UNUSED */
611 (void)gid; /* UNUSED */
616 trivial_lookup_uname(void *private_data, int64_t uid)
618 (void)private_data; /* UNUSED */
619 (void)uid; /* UNUSED */
624 * Allocate memory for the reading buffer adjusted to the filesystem
628 setup_suitable_read_buffer(struct archive_read_disk *a)
630 struct tree *t = a->tree;
631 struct filesystem *cf = t->current_filesystem;
635 if (cf->allocation_ptr == NULL) {
636 /* If we couldn't get a filesystem alignment,
637 * we use 4096 as default value but we won't use
638 * O_DIRECT to open() and openat() operations. */
639 long xfer_align = (cf->xfer_align == -1)?4096:cf->xfer_align;
641 if (cf->max_xfer_size != -1)
642 asize = cf->max_xfer_size + xfer_align;
644 long incr = cf->incr_xfer_size;
645 /* Some platform does not set a proper value to
648 incr = cf->min_xfer_size;
649 if (cf->min_xfer_size < 0) {
653 asize = cf->min_xfer_size;
655 /* Increase a buffer size up to 64K bytes in
656 * a proper increment size. */
657 while (asize < 1024*64)
659 /* Take a margin to adjust to the filesystem
663 cf->allocation_ptr = malloc(asize);
664 if (cf->allocation_ptr == NULL) {
665 archive_set_error(&a->archive, ENOMEM,
666 "Couldn't allocate memory");
667 a->archive.state = ARCHIVE_STATE_FATAL;
668 return (ARCHIVE_FATAL);
672 * Calculate proper address for the filesystem.
674 s = (uintptr_t)cf->allocation_ptr;
680 * Set a read buffer pointer in the proper alignment of
681 * the current filesystem.
683 cf->buff = cf->allocation_ptr + s;
684 cf->buff_size = asize - xfer_align;
690 _archive_read_data_block(struct archive *_a, const void **buff,
691 size_t *size, int64_t *offset)
693 struct archive_read_disk *a = (struct archive_read_disk *)_a;
694 struct tree *t = a->tree;
698 int empty_sparse_region = 0;
700 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA,
701 "archive_read_data_block");
703 if (t->entry_eof || t->entry_remaining_bytes <= 0) {
705 goto abort_read_data;
709 * Open the current file.
711 if (t->entry_fd < 0) {
712 int flags = O_RDONLY | O_BINARY | O_CLOEXEC;
715 * Eliminate or reduce cache effects if we can.
717 * Carefully consider this to be enabled.
719 #if defined(O_DIRECT) && 0/* Disabled for now */
720 if (t->current_filesystem->xfer_align != -1 &&
724 #if defined(O_NOATIME)
726 * Linux has O_NOATIME flag; use it if we need.
728 if ((t->flags & needsRestoreTimes) != 0 &&
729 t->restore_time.noatime == 0)
733 t->entry_fd = open_on_current_dir(t,
734 tree_current_access_path(t), flags);
735 __archive_ensure_cloexec_flag(t->entry_fd);
736 #if defined(O_NOATIME)
738 * When we did open the file with O_NOATIME flag,
739 * if successful, set 1 to t->restore_time.noatime
740 * not to restore an atime of the file later.
741 * if failed by EPERM, retry it without O_NOATIME flag.
743 if (flags & O_NOATIME) {
744 if (t->entry_fd >= 0)
745 t->restore_time.noatime = 1;
746 else if (errno == EPERM) {
753 if (t->entry_fd < 0) {
754 archive_set_error(&a->archive, errno,
755 "Couldn't open %s", tree_current_path(t));
757 tree_enter_initial_dir(t);
758 goto abort_read_data;
760 tree_enter_initial_dir(t);
764 * Allocate read buffer if not allocated.
766 if (t->current_filesystem->allocation_ptr == NULL) {
767 r = setup_suitable_read_buffer(a);
768 if (r != ARCHIVE_OK) {
769 a->archive.state = ARCHIVE_STATE_FATAL;
770 goto abort_read_data;
773 t->entry_buff = t->current_filesystem->buff;
774 t->entry_buff_size = t->current_filesystem->buff_size;
776 buffbytes = t->entry_buff_size;
777 if ((int64_t)buffbytes > t->current_sparse->length)
778 buffbytes = t->current_sparse->length;
780 if (t->current_sparse->length == 0)
781 empty_sparse_region = 1;
785 * TODO: Should we consider t->current_filesystem->xfer_align?
787 if (t->current_sparse->offset > t->entry_total) {
788 if (lseek(t->entry_fd,
789 (off_t)t->current_sparse->offset, SEEK_SET) < 0) {
790 archive_set_error(&a->archive, errno, "Seek error");
792 a->archive.state = ARCHIVE_STATE_FATAL;
793 goto abort_read_data;
795 bytes = t->current_sparse->offset - t->entry_total;
796 t->entry_remaining_bytes -= bytes;
797 t->entry_total += bytes;
801 * Read file contents.
804 bytes = read(t->entry_fd, t->entry_buff, buffbytes);
806 archive_set_error(&a->archive, errno, "Read error");
808 a->archive.state = ARCHIVE_STATE_FATAL;
809 goto abort_read_data;
814 * Return an EOF unless we've read a leading empty sparse region, which
815 * is used to represent fully-sparse files.
817 if (bytes == 0 && !empty_sparse_region) {
821 goto abort_read_data;
823 *buff = t->entry_buff;
825 *offset = t->entry_total;
826 t->entry_total += bytes;
827 t->entry_remaining_bytes -= bytes;
828 if (t->entry_remaining_bytes == 0) {
829 /* Close the current file descriptor */
830 close_and_restore_time(t->entry_fd, t, &t->restore_time);
834 t->current_sparse->offset += bytes;
835 t->current_sparse->length -= bytes;
836 if (t->current_sparse->length == 0 && !t->entry_eof)
843 *offset = t->entry_total;
844 if (t->entry_fd >= 0) {
845 /* Close the current file descriptor */
846 close_and_restore_time(t->entry_fd, t, &t->restore_time);
853 next_entry(struct archive_read_disk *a, struct tree *t,
854 struct archive_entry *entry)
856 const struct stat *st; /* info to use for this entry */
857 const struct stat *lst;/* lstat() information */
865 switch (tree_next(t)) {
866 case TREE_ERROR_FATAL:
867 archive_set_error(&a->archive, t->tree_errno,
868 "%s: Unable to continue traversing directory tree",
869 tree_current_path(t));
870 a->archive.state = ARCHIVE_STATE_FATAL;
871 tree_enter_initial_dir(t);
872 return (ARCHIVE_FATAL);
874 archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC,
875 "%s: Couldn't visit directory",
876 tree_current_path(t));
877 tree_enter_initial_dir(t);
878 return (ARCHIVE_FAILED);
880 tree_enter_initial_dir(t);
881 return (ARCHIVE_EOF);
882 case TREE_POSTDESCENT:
883 case TREE_POSTASCENT:
886 lst = tree_current_lstat(t);
888 archive_set_error(&a->archive, errno,
890 tree_current_path(t));
891 tree_enter_initial_dir(t);
892 return (ARCHIVE_FAILED);
896 } while (lst == NULL);
899 if (a->flags & ARCHIVE_READDISK_MAC_COPYFILE) {
900 /* If we're using copyfile(), ignore "._XXX" files. */
901 const char *bname = strrchr(tree_current_path(t), '/');
903 bname = tree_current_path(t);
906 if (bname[0] == '.' && bname[1] == '_')
907 return (ARCHIVE_RETRY);
911 archive_entry_copy_pathname(entry, tree_current_path(t));
913 * Perform path matching.
916 r = archive_match_path_excluded(a->matching, entry);
918 archive_set_error(&(a->archive), errno,
919 "Failed : %s", archive_error_string(a->matching));
923 if (a->excluded_cb_func)
924 a->excluded_cb_func(&(a->archive),
925 a->excluded_cb_data, entry);
926 return (ARCHIVE_RETRY);
931 * Distinguish 'L'/'P'/'H' symlink following.
933 switch(t->symlink_mode) {
935 /* 'H': After the first item, rest like 'P'. */
936 t->symlink_mode = 'P';
937 /* 'H': First item (from command line) like 'L'. */
940 /* 'L': Do descend through a symlink to dir. */
941 descend = tree_current_is_dir(t);
942 /* 'L': Follow symlinks to files. */
943 a->symlink_mode = 'L';
944 a->follow_symlinks = 1;
945 /* 'L': Archive symlinks as targets, if we can. */
946 st = tree_current_stat(t);
947 if (st != NULL && !tree_target_is_same_as_parent(t, st))
949 /* If stat fails, we have a broken symlink;
950 * in that case, don't follow the link. */
953 /* 'P': Don't descend through a symlink to dir. */
954 descend = tree_current_is_physical_dir(t);
955 /* 'P': Don't follow symlinks to files. */
956 a->symlink_mode = 'P';
957 a->follow_symlinks = 0;
958 /* 'P': Archive symlinks as symlinks. */
963 if (update_current_filesystem(a, st->st_dev) != ARCHIVE_OK) {
964 a->archive.state = ARCHIVE_STATE_FATAL;
965 tree_enter_initial_dir(t);
966 return (ARCHIVE_FATAL);
968 if (t->initial_filesystem_id == -1)
969 t->initial_filesystem_id = t->current_filesystem_id;
970 if (a->flags & ARCHIVE_READDISK_NO_TRAVERSE_MOUNTS) {
971 if (t->initial_filesystem_id != t->current_filesystem_id)
974 t->descend = descend;
978 * If the file is marked with nodump flag, do not return this entry.
980 if (a->flags & ARCHIVE_READDISK_HONOR_NODUMP) {
981 #if defined(HAVE_STRUCT_STAT_ST_FLAGS) && defined(UF_NODUMP)
982 if (st->st_flags & UF_NODUMP)
983 return (ARCHIVE_RETRY);
984 #elif (defined(FS_IOC_GETFLAGS) && defined(FS_NODUMP_FL) && \
985 defined(HAVE_WORKING_FS_IOC_GETFLAGS)) || \
986 (defined(EXT2_IOC_GETFLAGS) && defined(EXT2_NODUMP_FL) && \
987 defined(HAVE_WORKING_EXT2_IOC_GETFLAGS))
988 if (S_ISREG(st->st_mode) || S_ISDIR(st->st_mode)) {
991 t->entry_fd = open_on_current_dir(t,
992 tree_current_access_path(t),
993 O_RDONLY | O_NONBLOCK | O_CLOEXEC);
994 __archive_ensure_cloexec_flag(t->entry_fd);
995 if (t->entry_fd >= 0) {
996 r = ioctl(t->entry_fd,
997 #ifdef FS_IOC_GETFLAGS
1004 if (r == 0 && (stflags & FS_NODUMP_FL) != 0)
1006 if (r == 0 && (stflags & EXT2_NODUMP_FL) != 0)
1008 return (ARCHIVE_RETRY);
1014 archive_entry_copy_stat(entry, st);
1016 /* Save the times to be restored. This must be in before
1017 * calling archive_read_disk_descend() or any chance of it,
1018 * especially, invoking a callback. */
1019 t->restore_time.mtime = archive_entry_mtime(entry);
1020 t->restore_time.mtime_nsec = archive_entry_mtime_nsec(entry);
1021 t->restore_time.atime = archive_entry_atime(entry);
1022 t->restore_time.atime_nsec = archive_entry_atime_nsec(entry);
1023 t->restore_time.filetype = archive_entry_filetype(entry);
1024 t->restore_time.noatime = t->current_filesystem->noatime;
1027 * Perform time matching.
1030 r = archive_match_time_excluded(a->matching, entry);
1032 archive_set_error(&(a->archive), errno,
1033 "Failed : %s", archive_error_string(a->matching));
1037 if (a->excluded_cb_func)
1038 a->excluded_cb_func(&(a->archive),
1039 a->excluded_cb_data, entry);
1040 return (ARCHIVE_RETRY);
1044 /* Lookup uname/gname */
1045 name = archive_read_disk_uname(&(a->archive), archive_entry_uid(entry));
1047 archive_entry_copy_uname(entry, name);
1048 name = archive_read_disk_gname(&(a->archive), archive_entry_gid(entry));
1050 archive_entry_copy_gname(entry, name);
1053 * Perform owner matching.
1056 r = archive_match_owner_excluded(a->matching, entry);
1058 archive_set_error(&(a->archive), errno,
1059 "Failed : %s", archive_error_string(a->matching));
1063 if (a->excluded_cb_func)
1064 a->excluded_cb_func(&(a->archive),
1065 a->excluded_cb_data, entry);
1066 return (ARCHIVE_RETRY);
1071 * Invoke a meta data filter callback.
1073 if (a->metadata_filter_func) {
1074 if (!a->metadata_filter_func(&(a->archive),
1075 a->metadata_filter_data, entry))
1076 return (ARCHIVE_RETRY);
1080 * Populate the archive_entry with metadata from the disk.
1082 archive_entry_copy_sourcepath(entry, tree_current_access_path(t));
1083 r = archive_read_disk_entry_from_file(&(a->archive), entry,
1090 _archive_read_next_header(struct archive *_a, struct archive_entry **entryp)
1093 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1095 ret = _archive_read_next_header2(_a, a->entry);
1101 _archive_read_next_header2(struct archive *_a, struct archive_entry *entry)
1103 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1107 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1108 ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA,
1109 "archive_read_next_header2");
1112 if (t->entry_fd >= 0) {
1113 close_and_restore_time(t->entry_fd, t, &t->restore_time);
1118 r = next_entry(a, t, entry);
1119 if (t->entry_fd >= 0) {
1124 if (r == ARCHIVE_RETRY) {
1125 archive_entry_clear(entry);
1131 /* Return to the initial directory. */
1132 tree_enter_initial_dir(t);
1135 * EOF and FATAL are persistent at this layer. By
1136 * modifying the state, we guarantee that future calls to
1137 * read a header or read data will fail.
1141 a->archive.state = ARCHIVE_STATE_EOF;
1145 /* Overwrite the sourcepath based on the initial directory. */
1146 archive_entry_copy_sourcepath(entry, tree_current_path(t));
1148 if (archive_entry_filetype(entry) == AE_IFREG) {
1149 t->nlink = archive_entry_nlink(entry);
1150 t->entry_remaining_bytes = archive_entry_size(entry);
1151 t->entry_eof = (t->entry_remaining_bytes == 0)? 1: 0;
1152 if (!t->entry_eof &&
1153 setup_sparse(a, entry) != ARCHIVE_OK)
1154 return (ARCHIVE_FATAL);
1156 t->entry_remaining_bytes = 0;
1159 a->archive.state = ARCHIVE_STATE_DATA;
1164 a->archive.state = ARCHIVE_STATE_FATAL;
1168 __archive_reset_read_data(&a->archive);
1173 setup_sparse(struct archive_read_disk *a, struct archive_entry *entry)
1175 struct tree *t = a->tree;
1176 int64_t length, offset;
1179 t->sparse_count = archive_entry_sparse_reset(entry);
1180 if (t->sparse_count+1 > t->sparse_list_size) {
1181 free(t->sparse_list);
1182 t->sparse_list_size = t->sparse_count + 1;
1183 t->sparse_list = malloc(sizeof(t->sparse_list[0]) *
1184 t->sparse_list_size);
1185 if (t->sparse_list == NULL) {
1186 t->sparse_list_size = 0;
1187 archive_set_error(&a->archive, ENOMEM,
1188 "Can't allocate data");
1189 a->archive.state = ARCHIVE_STATE_FATAL;
1190 return (ARCHIVE_FATAL);
1193 for (i = 0; i < t->sparse_count; i++) {
1194 archive_entry_sparse_next(entry, &offset, &length);
1195 t->sparse_list[i].offset = offset;
1196 t->sparse_list[i].length = length;
1199 t->sparse_list[i].offset = 0;
1200 t->sparse_list[i].length = archive_entry_size(entry);
1202 t->sparse_list[i].offset = archive_entry_size(entry);
1203 t->sparse_list[i].length = 0;
1205 t->current_sparse = t->sparse_list;
1207 return (ARCHIVE_OK);
1211 archive_read_disk_set_matching(struct archive *_a, struct archive *_ma,
1212 void (*_excluded_func)(struct archive *, void *, struct archive_entry *),
1215 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1216 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1217 ARCHIVE_STATE_ANY, "archive_read_disk_set_matching");
1219 a->excluded_cb_func = _excluded_func;
1220 a->excluded_cb_data = _client_data;
1221 return (ARCHIVE_OK);
1225 archive_read_disk_set_metadata_filter_callback(struct archive *_a,
1226 int (*_metadata_filter_func)(struct archive *, void *,
1227 struct archive_entry *), void *_client_data)
1229 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1231 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_ANY,
1232 "archive_read_disk_set_metadata_filter_callback");
1234 a->metadata_filter_func = _metadata_filter_func;
1235 a->metadata_filter_data = _client_data;
1236 return (ARCHIVE_OK);
1240 archive_read_disk_can_descend(struct archive *_a)
1242 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1243 struct tree *t = a->tree;
1245 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1246 ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA,
1247 "archive_read_disk_can_descend");
1249 return (t->visit_type == TREE_REGULAR && t->descend);
1253 * Called by the client to mark the directory just returned from
1254 * tree_next() as needing to be visited.
1257 archive_read_disk_descend(struct archive *_a)
1259 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1260 struct tree *t = a->tree;
1262 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1263 ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA,
1264 "archive_read_disk_descend");
1266 if (t->visit_type != TREE_REGULAR || !t->descend)
1267 return (ARCHIVE_OK);
1269 if (tree_current_is_physical_dir(t)) {
1270 tree_push(t, t->basename, t->current_filesystem_id,
1271 t->lst.st_dev, t->lst.st_ino, &t->restore_time);
1272 t->stack->flags |= isDir;
1273 } else if (tree_current_is_dir(t)) {
1274 tree_push(t, t->basename, t->current_filesystem_id,
1275 t->st.st_dev, t->st.st_ino, &t->restore_time);
1276 t->stack->flags |= isDirLink;
1279 return (ARCHIVE_OK);
1283 archive_read_disk_open(struct archive *_a, const char *pathname)
1285 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1287 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1288 ARCHIVE_STATE_NEW | ARCHIVE_STATE_CLOSED,
1289 "archive_read_disk_open");
1290 archive_clear_error(&a->archive);
1292 return (_archive_read_disk_open(_a, pathname));
1296 archive_read_disk_open_w(struct archive *_a, const wchar_t *pathname)
1298 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1299 struct archive_string path;
1302 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC,
1303 ARCHIVE_STATE_NEW | ARCHIVE_STATE_CLOSED,
1304 "archive_read_disk_open_w");
1305 archive_clear_error(&a->archive);
1307 /* Make a char string from a wchar_t string. */
1308 archive_string_init(&path);
1309 if (archive_string_append_from_wcs(&path, pathname,
1310 wcslen(pathname)) != 0) {
1311 if (errno == ENOMEM)
1312 archive_set_error(&a->archive, ENOMEM,
1313 "Can't allocate memory");
1315 archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC,
1316 "Can't convert a path to a char string");
1317 a->archive.state = ARCHIVE_STATE_FATAL;
1318 ret = ARCHIVE_FATAL;
1320 ret = _archive_read_disk_open(_a, path.s);
1322 archive_string_free(&path);
1327 _archive_read_disk_open(struct archive *_a, const char *pathname)
1329 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1331 if (a->tree != NULL)
1332 a->tree = tree_reopen(a->tree, pathname,
1333 a->flags & ARCHIVE_READDISK_RESTORE_ATIME);
1335 a->tree = tree_open(pathname, a->symlink_mode,
1336 a->flags & ARCHIVE_READDISK_RESTORE_ATIME);
1337 if (a->tree == NULL) {
1338 archive_set_error(&a->archive, ENOMEM,
1339 "Can't allocate tar data");
1340 a->archive.state = ARCHIVE_STATE_FATAL;
1341 return (ARCHIVE_FATAL);
1343 a->archive.state = ARCHIVE_STATE_HEADER;
1345 return (ARCHIVE_OK);
1349 * Return a current filesystem ID which is index of the filesystem entry
1350 * you've visited through archive_read_disk.
1353 archive_read_disk_current_filesystem(struct archive *_a)
1355 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1357 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA,
1358 "archive_read_disk_current_filesystem");
1360 return (a->tree->current_filesystem_id);
1364 update_current_filesystem(struct archive_read_disk *a, int64_t dev)
1366 struct tree *t = a->tree;
1369 if (t->current_filesystem != NULL &&
1370 t->current_filesystem->dev == dev)
1371 return (ARCHIVE_OK);
1373 for (i = 0; i < t->max_filesystem_id; i++) {
1374 if (t->filesystem_table[i].dev == dev) {
1375 /* There is the filesystem ID we've already generated. */
1376 t->current_filesystem_id = i;
1377 t->current_filesystem = &(t->filesystem_table[i]);
1378 return (ARCHIVE_OK);
1383 * This is the new filesystem which we have to generate a new ID for.
1385 fid = t->max_filesystem_id++;
1386 if (t->max_filesystem_id > t->allocated_filesystem) {
1390 s = t->max_filesystem_id * 2;
1391 p = realloc(t->filesystem_table,
1392 s * sizeof(*t->filesystem_table));
1394 archive_set_error(&a->archive, ENOMEM,
1395 "Can't allocate tar data");
1396 return (ARCHIVE_FATAL);
1398 t->filesystem_table = (struct filesystem *)p;
1399 t->allocated_filesystem = s;
1401 t->current_filesystem_id = fid;
1402 t->current_filesystem = &(t->filesystem_table[fid]);
1403 t->current_filesystem->dev = dev;
1404 t->current_filesystem->allocation_ptr = NULL;
1405 t->current_filesystem->buff = NULL;
1407 /* Setup the current filesystem properties which depend on
1408 * platform specific. */
1409 return (setup_current_filesystem(a));
1413 * Returns 1 if current filesystem is generated filesystem, 0 if it is not
1414 * or -1 if it is unknown.
1417 archive_read_disk_current_filesystem_is_synthetic(struct archive *_a)
1419 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1421 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA,
1422 "archive_read_disk_current_filesystem");
1424 return (a->tree->current_filesystem->synthetic);
1428 * Returns 1 if current filesystem is remote filesystem, 0 if it is not
1429 * or -1 if it is unknown.
1432 archive_read_disk_current_filesystem_is_remote(struct archive *_a)
1434 struct archive_read_disk *a = (struct archive_read_disk *)_a;
1436 archive_check_magic(_a, ARCHIVE_READ_DISK_MAGIC, ARCHIVE_STATE_DATA,
1437 "archive_read_disk_current_filesystem");
1439 return (a->tree->current_filesystem->remote);
1442 #if defined(_PC_REC_INCR_XFER_SIZE) && defined(_PC_REC_MAX_XFER_SIZE) &&\
1443 defined(_PC_REC_MIN_XFER_SIZE) && defined(_PC_REC_XFER_ALIGN)
1445 get_xfer_size(struct tree *t, int fd, const char *path)
1447 t->current_filesystem->xfer_align = -1;
1450 t->current_filesystem->incr_xfer_size =
1451 fpathconf(fd, _PC_REC_INCR_XFER_SIZE);
1452 t->current_filesystem->max_xfer_size =
1453 fpathconf(fd, _PC_REC_MAX_XFER_SIZE);
1454 t->current_filesystem->min_xfer_size =
1455 fpathconf(fd, _PC_REC_MIN_XFER_SIZE);
1456 t->current_filesystem->xfer_align =
1457 fpathconf(fd, _PC_REC_XFER_ALIGN);
1458 } else if (path != NULL) {
1459 t->current_filesystem->incr_xfer_size =
1460 pathconf(path, _PC_REC_INCR_XFER_SIZE);
1461 t->current_filesystem->max_xfer_size =
1462 pathconf(path, _PC_REC_MAX_XFER_SIZE);
1463 t->current_filesystem->min_xfer_size =
1464 pathconf(path, _PC_REC_MIN_XFER_SIZE);
1465 t->current_filesystem->xfer_align =
1466 pathconf(path, _PC_REC_XFER_ALIGN);
1468 /* At least we need an alignment size. */
1469 if (t->current_filesystem->xfer_align == -1)
1470 return ((errno == EINVAL)?1:-1);
1476 get_xfer_size(struct tree *t, int fd, const char *path)
1478 (void)t; /* UNUSED */
1479 (void)fd; /* UNUSED */
1480 (void)path; /* UNUSED */
1481 return (1);/* Not supported */
1485 #if defined(HAVE_STATFS) && defined(HAVE_FSTATFS) && defined(MNT_LOCAL) \
1486 && !defined(ST_LOCAL)
1489 * Gather current filesystem properties on FreeBSD, OpenBSD and Mac OS X.
1492 setup_current_filesystem(struct archive_read_disk *a)
1494 struct tree *t = a->tree;
1496 #if defined(HAVE_GETVFSBYNAME) && defined(VFCF_SYNTHETIC)
1497 /* TODO: configure should set GETVFSBYNAME_ARG_TYPE to make
1498 * this accurate; some platforms have both and we need the one that's
1499 * used by getvfsbyname()
1501 * Then the following would become:
1502 * #if defined(GETVFSBYNAME_ARG_TYPE)
1503 * GETVFSBYNAME_ARG_TYPE vfc;
1506 # if defined(HAVE_STRUCT_XVFSCONF)
1507 struct xvfsconf vfc;
1513 #if !defined(HAVE_STRUCT_STATFS_F_NAMEMAX)
1517 t->current_filesystem->synthetic = -1;
1518 t->current_filesystem->remote = -1;
1519 if (tree_current_is_symblic_link_target(t)) {
1520 #if defined(HAVE_OPENAT)
1522 * Get file system statistics on any directory
1525 int fd = openat(tree_current_dir_fd(t),
1526 tree_current_access_path(t), O_RDONLY | O_CLOEXEC);
1527 __archive_ensure_cloexec_flag(fd);
1529 archive_set_error(&a->archive, errno,
1531 return (ARCHIVE_FAILED);
1533 r = fstatfs(fd, &sfs);
1535 xr = get_xfer_size(t, fd, NULL);
1538 if (tree_enter_working_dir(t) != 0) {
1539 archive_set_error(&a->archive, errno, "fchdir failed");
1540 return (ARCHIVE_FAILED);
1542 r = statfs(tree_current_access_path(t), &sfs);
1544 xr = get_xfer_size(t, -1, tree_current_access_path(t));
1547 r = fstatfs(tree_current_dir_fd(t), &sfs);
1549 xr = get_xfer_size(t, tree_current_dir_fd(t), NULL);
1551 if (r == -1 || xr == -1) {
1552 archive_set_error(&a->archive, errno, "statfs failed");
1553 return (ARCHIVE_FAILED);
1554 } else if (xr == 1) {
1555 /* pathconf(_PC_REX_*) operations are not supported. */
1556 t->current_filesystem->xfer_align = sfs.f_bsize;
1557 t->current_filesystem->max_xfer_size = -1;
1558 t->current_filesystem->min_xfer_size = sfs.f_iosize;
1559 t->current_filesystem->incr_xfer_size = sfs.f_iosize;
1561 if (sfs.f_flags & MNT_LOCAL)
1562 t->current_filesystem->remote = 0;
1564 t->current_filesystem->remote = 1;
1566 #if defined(HAVE_GETVFSBYNAME) && defined(VFCF_SYNTHETIC)
1567 r = getvfsbyname(sfs.f_fstypename, &vfc);
1569 archive_set_error(&a->archive, errno, "getvfsbyname failed");
1570 return (ARCHIVE_FAILED);
1572 if (vfc.vfc_flags & VFCF_SYNTHETIC)
1573 t->current_filesystem->synthetic = 1;
1575 t->current_filesystem->synthetic = 0;
1578 #if defined(MNT_NOATIME)
1579 if (sfs.f_flags & MNT_NOATIME)
1580 t->current_filesystem->noatime = 1;
1583 t->current_filesystem->noatime = 0;
1585 #if defined(USE_READDIR_R)
1586 /* Set maximum filename length. */
1587 #if defined(HAVE_STRUCT_STATFS_F_NAMEMAX)
1588 t->current_filesystem->name_max = sfs.f_namemax;
1590 # if defined(_PC_NAME_MAX)
1591 /* Mac OS X does not have f_namemax in struct statfs. */
1592 if (tree_current_is_symblic_link_target(t)) {
1593 if (tree_enter_working_dir(t) != 0) {
1594 archive_set_error(&a->archive, errno, "fchdir failed");
1595 return (ARCHIVE_FAILED);
1597 nm = pathconf(tree_current_access_path(t), _PC_NAME_MAX);
1599 nm = fpathconf(tree_current_dir_fd(t), _PC_NAME_MAX);
1604 t->current_filesystem->name_max = NAME_MAX;
1606 t->current_filesystem->name_max = nm;
1608 #endif /* USE_READDIR_R */
1609 return (ARCHIVE_OK);
1612 #elif (defined(HAVE_STATVFS) || defined(HAVE_FSTATVFS)) && defined(ST_LOCAL)
1615 * Gather current filesystem properties on NetBSD
1618 setup_current_filesystem(struct archive_read_disk *a)
1620 struct tree *t = a->tree;
1624 t->current_filesystem->synthetic = -1;
1625 if (tree_enter_working_dir(t) != 0) {
1626 archive_set_error(&a->archive, errno, "fchdir failed");
1627 return (ARCHIVE_FAILED);
1629 if (tree_current_is_symblic_link_target(t)) {
1630 r = statvfs(tree_current_access_path(t), &sfs);
1632 xr = get_xfer_size(t, -1, tree_current_access_path(t));
1634 #ifdef HAVE_FSTATVFS
1635 r = fstatvfs(tree_current_dir_fd(t), &sfs);
1637 xr = get_xfer_size(t, tree_current_dir_fd(t), NULL);
1639 r = statvfs(".", &sfs);
1641 xr = get_xfer_size(t, -1, ".");
1644 if (r == -1 || xr == -1) {
1645 t->current_filesystem->remote = -1;
1646 archive_set_error(&a->archive, errno, "statvfs failed");
1647 return (ARCHIVE_FAILED);
1648 } else if (xr == 1) {
1649 /* Usually come here unless NetBSD supports _PC_REC_XFER_ALIGN
1650 * for pathconf() function. */
1651 t->current_filesystem->xfer_align = sfs.f_frsize;
1652 t->current_filesystem->max_xfer_size = -1;
1653 #if defined(HAVE_STRUCT_STATVFS_F_IOSIZE)
1654 t->current_filesystem->min_xfer_size = sfs.f_iosize;
1655 t->current_filesystem->incr_xfer_size = sfs.f_iosize;
1657 t->current_filesystem->min_xfer_size = sfs.f_bsize;
1658 t->current_filesystem->incr_xfer_size = sfs.f_bsize;
1661 if (sfs.f_flag & ST_LOCAL)
1662 t->current_filesystem->remote = 0;
1664 t->current_filesystem->remote = 1;
1666 #if defined(ST_NOATIME)
1667 if (sfs.f_flag & ST_NOATIME)
1668 t->current_filesystem->noatime = 1;
1671 t->current_filesystem->noatime = 0;
1673 /* Set maximum filename length. */
1674 t->current_filesystem->name_max = sfs.f_namemax;
1675 return (ARCHIVE_OK);
1678 #elif defined(HAVE_SYS_STATFS_H) && defined(HAVE_LINUX_MAGIC_H) &&\
1679 defined(HAVE_STATFS) && defined(HAVE_FSTATFS)
1681 * Note: statfs is deprecated since LSB 3.2
1684 #ifndef CIFS_SUPER_MAGIC
1685 #define CIFS_SUPER_MAGIC 0xFF534D42
1687 #ifndef DEVFS_SUPER_MAGIC
1688 #define DEVFS_SUPER_MAGIC 0x1373
1692 * Gather current filesystem properties on Linux
1695 setup_current_filesystem(struct archive_read_disk *a)
1697 struct tree *t = a->tree;
1699 #if defined(HAVE_STATVFS)
1700 struct statvfs svfs;
1702 int r, vr = 0, xr = 0;
1704 if (tree_current_is_symblic_link_target(t)) {
1705 #if defined(HAVE_OPENAT)
1707 * Get file system statistics on any directory
1710 int fd = openat(tree_current_dir_fd(t),
1711 tree_current_access_path(t), O_RDONLY | O_CLOEXEC);
1712 __archive_ensure_cloexec_flag(fd);
1714 archive_set_error(&a->archive, errno,
1716 return (ARCHIVE_FAILED);
1718 #if defined(HAVE_FSTATVFS)
1719 vr = fstatvfs(fd, &svfs);/* for f_flag, mount flags */
1721 r = fstatfs(fd, &sfs);
1723 xr = get_xfer_size(t, fd, NULL);
1726 if (tree_enter_working_dir(t) != 0) {
1727 archive_set_error(&a->archive, errno, "fchdir failed");
1728 return (ARCHIVE_FAILED);
1730 #if defined(HAVE_STATVFS)
1731 vr = statvfs(tree_current_access_path(t), &svfs);
1733 r = statfs(tree_current_access_path(t), &sfs);
1735 xr = get_xfer_size(t, -1, tree_current_access_path(t));
1739 #if defined(HAVE_FSTATVFS)
1740 vr = fstatvfs(tree_current_dir_fd(t), &svfs);
1742 r = fstatfs(tree_current_dir_fd(t), &sfs);
1744 xr = get_xfer_size(t, tree_current_dir_fd(t), NULL);
1746 if (tree_enter_working_dir(t) != 0) {
1747 archive_set_error(&a->archive, errno, "fchdir failed");
1748 return (ARCHIVE_FAILED);
1750 #if defined(HAVE_STATVFS)
1751 vr = statvfs(".", &svfs);
1753 r = statfs(".", &sfs);
1755 xr = get_xfer_size(t, -1, ".");
1758 if (r == -1 || xr == -1 || vr == -1) {
1759 t->current_filesystem->synthetic = -1;
1760 t->current_filesystem->remote = -1;
1761 archive_set_error(&a->archive, errno, "statfs failed");
1762 return (ARCHIVE_FAILED);
1763 } else if (xr == 1) {
1764 /* pathconf(_PC_REX_*) operations are not supported. */
1765 #if defined(HAVE_STATVFS)
1766 t->current_filesystem->xfer_align = svfs.f_frsize;
1767 t->current_filesystem->max_xfer_size = -1;
1768 t->current_filesystem->min_xfer_size = svfs.f_bsize;
1769 t->current_filesystem->incr_xfer_size = svfs.f_bsize;
1771 t->current_filesystem->xfer_align = sfs.f_frsize;
1772 t->current_filesystem->max_xfer_size = -1;
1773 t->current_filesystem->min_xfer_size = sfs.f_bsize;
1774 t->current_filesystem->incr_xfer_size = sfs.f_bsize;
1777 switch (sfs.f_type) {
1778 case AFS_SUPER_MAGIC:
1779 case CIFS_SUPER_MAGIC:
1780 case CODA_SUPER_MAGIC:
1781 case NCP_SUPER_MAGIC:/* NetWare */
1782 case NFS_SUPER_MAGIC:
1783 case SMB_SUPER_MAGIC:
1784 t->current_filesystem->remote = 1;
1785 t->current_filesystem->synthetic = 0;
1787 case DEVFS_SUPER_MAGIC:
1788 case PROC_SUPER_MAGIC:
1789 case USBDEVICE_SUPER_MAGIC:
1790 t->current_filesystem->remote = 0;
1791 t->current_filesystem->synthetic = 1;
1794 t->current_filesystem->remote = 0;
1795 t->current_filesystem->synthetic = 0;
1799 #if defined(ST_NOATIME)
1800 #if defined(HAVE_STATVFS)
1801 if (svfs.f_flag & ST_NOATIME)
1803 if (sfs.f_flag & ST_NOATIME)
1805 t->current_filesystem->noatime = 1;
1808 t->current_filesystem->noatime = 0;
1810 #if defined(USE_READDIR_R)
1811 /* Set maximum filename length. */
1812 t->current_filesystem->name_max = sfs.f_namelen;
1814 return (ARCHIVE_OK);
1817 #elif defined(HAVE_SYS_STATVFS_H) &&\
1818 (defined(HAVE_STATVFS) || defined(HAVE_FSTATVFS))
1821 * Gather current filesystem properties on other posix platform.
1824 setup_current_filesystem(struct archive_read_disk *a)
1826 struct tree *t = a->tree;
1830 t->current_filesystem->synthetic = -1;/* Not supported */
1831 t->current_filesystem->remote = -1;/* Not supported */
1832 if (tree_current_is_symblic_link_target(t)) {
1833 #if defined(HAVE_OPENAT)
1835 * Get file system statistics on any directory
1838 int fd = openat(tree_current_dir_fd(t),
1839 tree_current_access_path(t), O_RDONLY | O_CLOEXEC);
1840 __archive_ensure_cloexec_flag(fd);
1842 archive_set_error(&a->archive, errno,
1844 return (ARCHIVE_FAILED);
1846 r = fstatvfs(fd, &sfs);
1848 xr = get_xfer_size(t, fd, NULL);
1851 if (tree_enter_working_dir(t) != 0) {
1852 archive_set_error(&a->archive, errno, "fchdir failed");
1853 return (ARCHIVE_FAILED);
1855 r = statvfs(tree_current_access_path(t), &sfs);
1857 xr = get_xfer_size(t, -1, tree_current_access_path(t));
1860 #ifdef HAVE_FSTATVFS
1861 r = fstatvfs(tree_current_dir_fd(t), &sfs);
1863 xr = get_xfer_size(t, tree_current_dir_fd(t), NULL);
1865 if (tree_enter_working_dir(t) != 0) {
1866 archive_set_error(&a->archive, errno, "fchdir failed");
1867 return (ARCHIVE_FAILED);
1869 r = statvfs(".", &sfs);
1871 xr = get_xfer_size(t, -1, ".");
1874 if (r == -1 || xr == -1) {
1875 t->current_filesystem->synthetic = -1;
1876 t->current_filesystem->remote = -1;
1877 archive_set_error(&a->archive, errno, "statvfs failed");
1878 return (ARCHIVE_FAILED);
1879 } else if (xr == 1) {
1880 /* pathconf(_PC_REX_*) operations are not supported. */
1881 t->current_filesystem->xfer_align = sfs.f_frsize;
1882 t->current_filesystem->max_xfer_size = -1;
1883 t->current_filesystem->min_xfer_size = sfs.f_bsize;
1884 t->current_filesystem->incr_xfer_size = sfs.f_bsize;
1887 #if defined(ST_NOATIME)
1888 if (sfs.f_flag & ST_NOATIME)
1889 t->current_filesystem->noatime = 1;
1892 t->current_filesystem->noatime = 0;
1894 #if defined(USE_READDIR_R)
1895 /* Set maximum filename length. */
1896 t->current_filesystem->name_max = sfs.f_namemax;
1898 return (ARCHIVE_OK);
1904 * Generic: Gather current filesystem properties.
1905 * TODO: Is this generic function really needed?
1908 setup_current_filesystem(struct archive_read_disk *a)
1910 struct tree *t = a->tree;
1911 #if defined(_PC_NAME_MAX) && defined(USE_READDIR_R)
1914 t->current_filesystem->synthetic = -1;/* Not supported */
1915 t->current_filesystem->remote = -1;/* Not supported */
1916 t->current_filesystem->noatime = 0;
1917 (void)get_xfer_size(t, -1, ".");/* Dummy call to avoid build error. */
1918 t->current_filesystem->xfer_align = -1;/* Unknown */
1919 t->current_filesystem->max_xfer_size = -1;
1920 t->current_filesystem->min_xfer_size = -1;
1921 t->current_filesystem->incr_xfer_size = -1;
1923 #if defined(USE_READDIR_R)
1924 /* Set maximum filename length. */
1925 # if defined(_PC_NAME_MAX)
1926 if (tree_current_is_symblic_link_target(t)) {
1927 if (tree_enter_working_dir(t) != 0) {
1928 archive_set_error(&a->archive, errno, "fchdir failed");
1929 return (ARCHIVE_FAILED);
1931 nm = pathconf(tree_current_access_path(t), _PC_NAME_MAX);
1933 nm = fpathconf(tree_current_dir_fd(t), _PC_NAME_MAX);
1935 # endif /* _PC_NAME_MAX */
1937 * Some systems (HP-UX or others?) incorrectly defined
1938 * NAME_MAX macro to be a smaller value.
1940 # if defined(NAME_MAX) && NAME_MAX >= 255
1941 t->current_filesystem->name_max = NAME_MAX;
1943 /* No way to get a trusted value of maximum filename
1945 t->current_filesystem->name_max = PATH_MAX;
1946 # endif /* NAME_MAX */
1947 # if defined(_PC_NAME_MAX)
1949 t->current_filesystem->name_max = nm;
1950 # endif /* _PC_NAME_MAX */
1951 #endif /* USE_READDIR_R */
1952 return (ARCHIVE_OK);
1958 close_and_restore_time(int fd, struct tree *t, struct restore_time *rt)
1961 (void)t; /* UNUSED */
1962 (void)rt; /* UNUSED */
1965 #if defined(HAVE_FUTIMENS) && !defined(__CYGWIN__)
1966 struct timespec timespecs[2];
1968 struct timeval times[2];
1970 if ((t->flags & needsRestoreTimes) == 0 || rt->noatime) {
1977 #if defined(HAVE_FUTIMENS) && !defined(__CYGWIN__)
1978 timespecs[1].tv_sec = rt->mtime;
1979 timespecs[1].tv_nsec = rt->mtime_nsec;
1981 timespecs[0].tv_sec = rt->atime;
1982 timespecs[0].tv_nsec = rt->atime_nsec;
1983 /* futimens() is defined in POSIX.1-2008. */
1984 if (futimens(fd, timespecs) == 0)
1988 times[1].tv_sec = rt->mtime;
1989 times[1].tv_usec = rt->mtime_nsec / 1000;
1991 times[0].tv_sec = rt->atime;
1992 times[0].tv_usec = rt->atime_nsec / 1000;
1994 #if !defined(HAVE_FUTIMENS) && defined(HAVE_FUTIMES) && !defined(__CYGWIN__)
1995 if (futimes(fd, times) == 0)
1999 #if defined(HAVE_FUTIMESAT)
2000 if (futimesat(tree_current_dir_fd(t), rt->name, times) == 0)
2004 if (lutimes(rt->name, times) != 0)
2006 if (AE_IFLNK != rt->filetype && utimes(rt->name, times) != 0)
2014 open_on_current_dir(struct tree *t, const char *path, int flags)
2017 return (openat(tree_current_dir_fd(t), path, flags));
2019 if (tree_enter_working_dir(t) != 0)
2021 return (open(path, flags));
2029 #ifdef F_DUPFD_CLOEXEC
2030 static volatile int can_dupfd_cloexec = 1;
2032 if (can_dupfd_cloexec) {
2033 new_fd = fcntl(fd, F_DUPFD_CLOEXEC, 0);
2036 /* Linux 2.6.18 - 2.6.23 declare F_DUPFD_CLOEXEC,
2037 * but it cannot be used. So we have to try dup(). */
2038 /* We won't try F_DUPFD_CLOEXEC. */
2039 can_dupfd_cloexec = 0;
2041 #endif /* F_DUPFD_CLOEXEC */
2043 __archive_ensure_cloexec_flag(new_fd);
2048 * Add a directory path to the current stack.
2051 tree_push(struct tree *t, const char *path, int filesystem_id,
2052 int64_t dev, int64_t ino, struct restore_time *rt)
2054 struct tree_entry *te;
2056 te = calloc(1, sizeof(*te));
2057 te->next = t->stack;
2058 te->parent = t->current;
2060 te->depth = te->parent->depth + 1;
2062 archive_string_init(&te->name);
2063 te->symlink_parent_fd = -1;
2064 archive_strcpy(&te->name, path);
2065 te->flags = needsDescent | needsOpen | needsAscent;
2066 te->filesystem_id = filesystem_id;
2069 te->dirname_length = t->dirname_length;
2070 te->restore_time.name = te->name.s;
2072 te->restore_time.mtime = rt->mtime;
2073 te->restore_time.mtime_nsec = rt->mtime_nsec;
2074 te->restore_time.atime = rt->atime;
2075 te->restore_time.atime_nsec = rt->atime_nsec;
2076 te->restore_time.filetype = rt->filetype;
2077 te->restore_time.noatime = rt->noatime;
2082 * Append a name to the current dir path.
2085 tree_append(struct tree *t, const char *name, size_t name_length)
2089 t->path.s[t->dirname_length] = '\0';
2090 t->path.length = t->dirname_length;
2091 /* Strip trailing '/' from name, unless entire name is "/". */
2092 while (name_length > 1 && name[name_length - 1] == '/')
2095 /* Resize pathname buffer as needed. */
2096 size_needed = name_length + t->dirname_length + 2;
2097 archive_string_ensure(&t->path, size_needed);
2098 /* Add a separating '/' if it's needed. */
2099 if (t->dirname_length > 0 && t->path.s[archive_strlen(&t->path)-1] != '/')
2100 archive_strappend_char(&t->path, '/');
2101 t->basename = t->path.s + archive_strlen(&t->path);
2102 archive_strncat(&t->path, name, name_length);
2103 t->restore_time.name = t->basename;
2107 * Open a directory tree for traversal.
2109 static struct tree *
2110 tree_open(const char *path, int symlink_mode, int restore_time)
2114 if ((t = calloc(1, sizeof(*t))) == NULL)
2116 archive_string_init(&t->path);
2117 archive_string_ensure(&t->path, 31);
2118 t->initial_symlink_mode = symlink_mode;
2119 return (tree_reopen(t, path, restore_time));
2122 static struct tree *
2123 tree_reopen(struct tree *t, const char *path, int restore_time)
2125 t->flags = (restore_time != 0)?needsRestoreTimes:0;
2126 t->flags |= onInitialDir;
2129 t->dirname_length = 0;
2133 t->d = INVALID_DIR_HANDLE;
2134 t->symlink_mode = t->initial_symlink_mode;
2135 archive_string_empty(&t->path);
2138 t->entry_remaining_bytes = 0;
2139 t->initial_filesystem_id = -1;
2141 /* First item is set up a lot like a symlink traversal. */
2142 tree_push(t, path, 0, 0, 0, NULL);
2143 t->stack->flags = needsFirstVisit;
2144 t->maxOpenCount = t->openCount = 1;
2145 t->initial_dir_fd = open(".", O_RDONLY | O_CLOEXEC);
2146 __archive_ensure_cloexec_flag(t->initial_dir_fd);
2147 t->working_dir_fd = tree_dup(t->initial_dir_fd);
2152 tree_descent(struct tree *t)
2154 int flag, new_fd, r = 0;
2156 t->dirname_length = archive_strlen(&t->path);
2157 flag = O_RDONLY | O_CLOEXEC;
2158 #if defined(O_DIRECTORY)
2159 flag |= O_DIRECTORY;
2161 new_fd = open_on_current_dir(t, t->stack->name.s, flag);
2162 __archive_ensure_cloexec_flag(new_fd);
2164 t->tree_errno = errno;
2168 /* If it is a link, set up fd for the ascent. */
2169 if (t->stack->flags & isDirLink) {
2170 t->stack->symlink_parent_fd = t->working_dir_fd;
2172 if (t->openCount > t->maxOpenCount)
2173 t->maxOpenCount = t->openCount;
2175 close(t->working_dir_fd);
2176 /* Renew the current working directory. */
2177 t->working_dir_fd = new_fd;
2178 t->flags &= ~onWorkingDir;
2184 * We've finished a directory; ascend back to the parent.
2187 tree_ascend(struct tree *t)
2189 struct tree_entry *te;
2190 int new_fd, r = 0, prev_dir_fd;
2193 prev_dir_fd = t->working_dir_fd;
2194 if (te->flags & isDirLink)
2195 new_fd = te->symlink_parent_fd;
2197 new_fd = open_on_current_dir(t, "..", O_RDONLY | O_CLOEXEC);
2198 __archive_ensure_cloexec_flag(new_fd);
2201 t->tree_errno = errno;
2202 r = TREE_ERROR_FATAL;
2204 /* Renew the current working directory. */
2205 t->working_dir_fd = new_fd;
2206 t->flags &= ~onWorkingDir;
2207 /* Current directory has been changed, we should
2208 * close an fd of previous working directory. */
2209 close_and_restore_time(prev_dir_fd, t, &te->restore_time);
2210 if (te->flags & isDirLink) {
2212 te->symlink_parent_fd = -1;
2220 * Return to the initial directory where tree_open() was performed.
2223 tree_enter_initial_dir(struct tree *t)
2227 if ((t->flags & onInitialDir) == 0) {
2228 r = fchdir(t->initial_dir_fd);
2230 t->flags &= ~onWorkingDir;
2231 t->flags |= onInitialDir;
2238 * Restore working directory of directory traversals.
2241 tree_enter_working_dir(struct tree *t)
2246 * Change the current directory if really needed.
2247 * Sometimes this is unneeded when we did not do
2250 if (t->depth > 0 && (t->flags & onWorkingDir) == 0) {
2251 r = fchdir(t->working_dir_fd);
2253 t->flags &= ~onInitialDir;
2254 t->flags |= onWorkingDir;
2261 tree_current_dir_fd(struct tree *t)
2263 return (t->working_dir_fd);
2267 * Pop the working stack.
2270 tree_pop(struct tree *t)
2272 struct tree_entry *te;
2274 t->path.s[t->dirname_length] = '\0';
2275 t->path.length = t->dirname_length;
2276 if (t->stack == t->current && t->current != NULL)
2277 t->current = t->current->parent;
2279 t->stack = te->next;
2280 t->dirname_length = te->dirname_length;
2281 t->basename = t->path.s + t->dirname_length;
2282 while (t->basename[0] == '/')
2284 archive_string_free(&te->name);
2289 * Get the next item in the tree traversal.
2292 tree_next(struct tree *t)
2296 while (t->stack != NULL) {
2297 /* If there's an open dir, get the next entry from there. */
2298 if (t->d != INVALID_DIR_HANDLE) {
2299 r = tree_dir_next_posix(t);
2305 if (t->stack->flags & needsFirstVisit) {
2306 /* Top stack item needs a regular visit. */
2307 t->current = t->stack;
2308 tree_append(t, t->stack->name.s,
2309 archive_strlen(&(t->stack->name)));
2310 /* t->dirname_length = t->path_length; */
2312 t->stack->flags &= ~needsFirstVisit;
2313 return (t->visit_type = TREE_REGULAR);
2314 } else if (t->stack->flags & needsDescent) {
2315 /* Top stack item is dir to descend into. */
2316 t->current = t->stack;
2317 tree_append(t, t->stack->name.s,
2318 archive_strlen(&(t->stack->name)));
2319 t->stack->flags &= ~needsDescent;
2320 r = tree_descent(t);
2325 t->visit_type = TREE_POSTDESCENT;
2326 return (t->visit_type);
2327 } else if (t->stack->flags & needsOpen) {
2328 t->stack->flags &= ~needsOpen;
2329 r = tree_dir_next_posix(t);
2333 } else if (t->stack->flags & needsAscent) {
2334 /* Top stack item is dir and we're done with it. */
2337 t->visit_type = r != 0 ? r : TREE_POSTASCENT;
2338 return (t->visit_type);
2340 /* Top item on stack is dead. */
2342 t->flags &= ~hasLstat;
2343 t->flags &= ~hasStat;
2346 return (t->visit_type = 0);
2350 tree_dir_next_posix(struct tree *t)
2357 #if defined(USE_READDIR_R)
2361 #if defined(HAVE_FDOPENDIR)
2362 t->d = fdopendir(tree_dup(t->working_dir_fd));
2363 #else /* HAVE_FDOPENDIR */
2364 if (tree_enter_working_dir(t) == 0) {
2365 t->d = opendir(".");
2366 #if HAVE_DIRFD || defined(dirfd)
2367 __archive_ensure_cloexec_flag(dirfd(t->d));
2370 #endif /* HAVE_FDOPENDIR */
2372 r = tree_ascend(t); /* Undo "chdir" */
2374 t->tree_errno = errno;
2375 t->visit_type = r != 0 ? r : TREE_ERROR_DIR;
2376 return (t->visit_type);
2378 #if defined(USE_READDIR_R)
2379 dirent_size = offsetof(struct dirent, d_name) +
2380 t->filesystem_table[t->current->filesystem_id].name_max + 1;
2381 if (t->dirent == NULL || t->dirent_allocated < dirent_size) {
2383 t->dirent = malloc(dirent_size);
2384 if (t->dirent == NULL) {
2386 t->d = INVALID_DIR_HANDLE;
2387 (void)tree_ascend(t);
2389 t->tree_errno = ENOMEM;
2390 t->visit_type = TREE_ERROR_DIR;
2391 return (t->visit_type);
2393 t->dirent_allocated = dirent_size;
2395 #endif /* USE_READDIR_R */
2399 #if defined(USE_READDIR_R)
2400 r = readdir_r(t->d, t->dirent, &t->de);
2402 /* Note: According to the man page, return value 9 indicates
2403 * that the readdir_r was not successful and the error code
2404 * is set to the global errno variable. And then if the end
2405 * of directory entries was reached, the return value is 9
2406 * and the third parameter is set to NULL and errno is
2411 if (r != 0 || t->de == NULL) {
2413 t->de = readdir(t->d);
2414 if (t->de == NULL) {
2418 t->d = INVALID_DIR_HANDLE;
2421 t->visit_type = TREE_ERROR_DIR;
2422 return (t->visit_type);
2426 name = t->de->d_name;
2427 namelen = D_NAMELEN(t->de);
2428 t->flags &= ~hasLstat;
2429 t->flags &= ~hasStat;
2430 if (name[0] == '.' && name[1] == '\0')
2432 if (name[0] == '.' && name[1] == '.' && name[2] == '\0')
2434 tree_append(t, name, namelen);
2435 return (t->visit_type = TREE_REGULAR);
2441 * Get the stat() data for the entry just returned from tree_next().
2443 static const struct stat *
2444 tree_current_stat(struct tree *t)
2446 if (!(t->flags & hasStat)) {
2448 if (fstatat(tree_current_dir_fd(t),
2449 tree_current_access_path(t), &t->st, 0) != 0)
2451 if (tree_enter_working_dir(t) != 0)
2453 if (stat(tree_current_access_path(t), &t->st) != 0)
2456 t->flags |= hasStat;
2462 * Get the lstat() data for the entry just returned from tree_next().
2464 static const struct stat *
2465 tree_current_lstat(struct tree *t)
2467 if (!(t->flags & hasLstat)) {
2469 if (fstatat(tree_current_dir_fd(t),
2470 tree_current_access_path(t), &t->lst,
2471 AT_SYMLINK_NOFOLLOW) != 0)
2473 if (tree_enter_working_dir(t) != 0)
2475 if (lstat(tree_current_access_path(t), &t->lst) != 0)
2478 t->flags |= hasLstat;
2484 * Test whether current entry is a dir or link to a dir.
2487 tree_current_is_dir(struct tree *t)
2489 const struct stat *st;
2491 * If we already have lstat() info, then try some
2492 * cheap tests to determine if this is a dir.
2494 if (t->flags & hasLstat) {
2495 /* If lstat() says it's a dir, it must be a dir. */
2496 st = tree_current_lstat(t);
2499 if (S_ISDIR(st->st_mode))
2501 /* Not a dir; might be a link to a dir. */
2502 /* If it's not a link, then it's not a link to a dir. */
2503 if (!S_ISLNK(st->st_mode))
2506 * It's a link, but we don't know what it's a link to,
2507 * so we'll have to use stat().
2511 st = tree_current_stat(t);
2512 /* If we can't stat it, it's not a dir. */
2515 /* Use the definitive test. Hopefully this is cached. */
2516 return (S_ISDIR(st->st_mode));
2520 * Test whether current entry is a physical directory. Usually, we
2521 * already have at least one of stat() or lstat() in memory, so we
2522 * use tricks to try to avoid an extra trip to the disk.
2525 tree_current_is_physical_dir(struct tree *t)
2527 const struct stat *st;
2530 * If stat() says it isn't a dir, then it's not a dir.
2531 * If stat() data is cached, this check is free, so do it first.
2533 if (t->flags & hasStat) {
2534 st = tree_current_stat(t);
2537 if (!S_ISDIR(st->st_mode))
2542 * Either stat() said it was a dir (in which case, we have
2543 * to determine whether it's really a link to a dir) or
2544 * stat() info wasn't available. So we use lstat(), which
2545 * hopefully is already cached.
2548 st = tree_current_lstat(t);
2549 /* If we can't stat it, it's not a dir. */
2552 /* Use the definitive test. Hopefully this is cached. */
2553 return (S_ISDIR(st->st_mode));
2557 * Test whether the same file has been in the tree as its parent.
2560 tree_target_is_same_as_parent(struct tree *t, const struct stat *st)
2562 struct tree_entry *te;
2564 for (te = t->current->parent; te != NULL; te = te->parent) {
2565 if (te->dev == (int64_t)st->st_dev &&
2566 te->ino == (int64_t)st->st_ino)
2573 * Test whether the current file is symbolic link target and
2574 * on the other filesystem.
2577 tree_current_is_symblic_link_target(struct tree *t)
2579 static const struct stat *lst, *st;
2581 lst = tree_current_lstat(t);
2582 st = tree_current_stat(t);
2583 return (st != NULL && lst != NULL &&
2584 (int64_t)st->st_dev == t->current_filesystem->dev &&
2585 st->st_dev != lst->st_dev);
2589 * Return the access path for the entry just returned from tree_next().
2592 tree_current_access_path(struct tree *t)
2594 return (t->basename);
2598 * Return the full path for the entry just returned from tree_next().
2601 tree_current_path(struct tree *t)
2607 * Terminate the traversal.
2610 tree_close(struct tree *t)
2615 if (t->entry_fd >= 0) {
2616 close_and_restore_time(t->entry_fd, t, &t->restore_time);
2619 /* Close the handle of readdir(). */
2620 if (t->d != INVALID_DIR_HANDLE) {
2622 t->d = INVALID_DIR_HANDLE;
2624 /* Release anything remaining in the stack. */
2625 while (t->stack != NULL) {
2626 if (t->stack->flags & isDirLink)
2627 close(t->stack->symlink_parent_fd);
2630 if (t->working_dir_fd >= 0) {
2631 close(t->working_dir_fd);
2632 t->working_dir_fd = -1;
2634 if (t->initial_dir_fd >= 0) {
2635 close(t->initial_dir_fd);
2636 t->initial_dir_fd = -1;
2641 * Release any resources.
2644 tree_free(struct tree *t)
2650 archive_string_free(&t->path);
2651 #if defined(USE_READDIR_R)
2654 free(t->sparse_list);
2655 for (i = 0; i < t->max_filesystem_id; i++)
2656 free(t->filesystem_table[i].allocation_ptr);
2657 free(t->filesystem_table);