static int ar_entry_mtime(lua_State *L) {
struct archive_entry* self = *ar_entry_check(L, 1);
int is_set;
int num_results;
if ( NULL == self ) return 0;
is_set = ( lua_gettop(L) >= 2 );
num_results = 0;
if ( archive_entry_mtime_is_set(self) ) {
num_results = 2;
lua_pushnumber(L, archive_entry_mtime(self));
lua_pushnumber(L, archive_entry_mtime_nsec(self));
}
if ( is_set ) {
if ( lua_isnil(L, 2) ) {
archive_entry_unset_mtime(self);
} else if ( lua_istable(L, 2) ) {
lua_rawgeti(L, 2, 1);
lua_rawgeti(L, 2, 2);
archive_entry_set_mtime(self,
lua_tonumber(L, -2),
lua_tonumber(L, -1));
} else {
archive_entry_set_mtime(self,
lua_tonumber(L, 2),
lua_tonumber(L, 3));
}
}
return num_results;
}
static int
restore_time(struct cpio *cpio, struct archive_entry *entry,
const char *name, int fd)
{
#ifndef HAVE_UTIMES
static int warned = 0;
(void)cpio; /* UNUSED */
(void)entry; /* UNUSED */
(void)name; /* UNUSED */
if (!warned)
lafe_warnc(0, "Can't restore access times on this platform");
warned = 1;
return (fd);
#else
#if defined(_WIN32) && !defined(__CYGWIN__)
struct __timeval times[2];
#else
struct timeval times[2];
#endif
if (!cpio->option_atime_restore)
return (fd);
times[1].tv_sec = archive_entry_mtime(entry);
times[1].tv_usec = archive_entry_mtime_nsec(entry) / 1000;
times[0].tv_sec = archive_entry_atime(entry);
times[0].tv_usec = archive_entry_atime_nsec(entry) / 1000;
#if defined(HAVE_FUTIMES) && !defined(__CYGWIN__)
if (fd >= 0 && futimes(fd, times) == 0)
return (fd);
#endif
/*
* Some platform cannot restore access times if the file descriptor
* is still opened.
*/
if (fd >= 0) {
close(fd);
fd = -1;
}
#ifdef HAVE_LUTIMES
if (lutimes(name, times) != 0)
#else
if ((AE_IFLNK != archive_entry_filetype(entry))
&& utimes(name, times) != 0)
#endif
lafe_warnc(errno, "Can't update time for %s", name);
#endif
return (fd);
}
static int
set_timefilter_stat(struct archive_match *a, int timetype, struct stat *st)
{
struct archive_entry *ae;
time_t ctime_sec, mtime_sec;
long ctime_ns, mtime_ns;
ae = archive_entry_new();
if (ae == NULL)
return (error_nomem(a));
archive_entry_copy_stat(ae, st);
ctime_sec = archive_entry_ctime(ae);
ctime_ns = archive_entry_ctime_nsec(ae);
mtime_sec = archive_entry_mtime(ae);
mtime_ns = archive_entry_mtime_nsec(ae);
archive_entry_free(ae);
return set_timefilter(a, timetype, mtime_sec, mtime_ns,
ctime_sec, ctime_ns);
}
static void
verify_contents(struct archive *a, int expect_details)
{
char filedata[64];
struct archive_entry *ae;
/*
* Read and verify first file.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
/* Zip doesn't store high-resolution mtime. */
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
if (expect_details) {
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(8, archive_entry_size(ae));
} else {
assertEqualInt(0, archive_entry_size(ae));
}
assertEqualIntA(a, 8,
archive_read_data(a, filedata, sizeof(filedata)));
assertEqualMem(filedata, "12345678", 8);
/*
* Read the second file back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file2", archive_entry_pathname(ae));
if (expect_details) {
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(4, archive_entry_size(ae));
} else {
assertEqualInt(0, archive_entry_size(ae));
}
assertEqualIntA(a, 4,
archive_read_data(a, filedata, sizeof(filedata)));
assertEqualMem(filedata, "1234", 4);
/*
* Read the third file back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("symlink", archive_entry_pathname(ae));
if (expect_details) {
assertEqualInt(AE_IFLNK | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualString("file1", archive_entry_symlink(ae));
} else {
assertEqualInt(AE_IFREG | 0777, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
}
/*
* Read the dir entry back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("dir/", archive_entry_pathname(ae));
if (expect_details)
assertEqualInt(AE_IFDIR | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF, archive_read_next_header(a, &ae));
assertEqualInt(ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
}
/*
* Test if entry is excluded by its timestamp.
*/
static int
time_excluded(struct archive_match *a, struct archive_entry *entry)
{
struct match_file *f;
const void *pathname;
time_t sec;
long nsec;
/*
* If this file/dir is excluded by a time comparison, skip it.
*/
if (a->newer_ctime_filter) {
/* If ctime is not set, use mtime instead. */
if (archive_entry_ctime_is_set(entry))
sec = archive_entry_ctime(entry);
else
sec = archive_entry_mtime(entry);
if (sec < a->newer_ctime_sec)
return (1); /* Too old, skip it. */
if (sec == a->newer_ctime_sec) {
if (archive_entry_ctime_is_set(entry))
nsec = archive_entry_ctime_nsec(entry);
else
nsec = archive_entry_mtime_nsec(entry);
if (nsec < a->newer_ctime_nsec)
return (1); /* Too old, skip it. */
if (nsec == a->newer_ctime_nsec &&
(a->newer_ctime_filter & ARCHIVE_MATCH_EQUAL)
== 0)
return (1); /* Equal, skip it. */
}
}
if (a->older_ctime_filter) {
/* If ctime is not set, use mtime instead. */
if (archive_entry_ctime_is_set(entry))
sec = archive_entry_ctime(entry);
else
sec = archive_entry_mtime(entry);
if (sec > a->older_ctime_sec)
return (1); /* Too new, skip it. */
if (sec == a->older_ctime_sec) {
if (archive_entry_ctime_is_set(entry))
nsec = archive_entry_ctime_nsec(entry);
else
nsec = archive_entry_mtime_nsec(entry);
if (nsec > a->older_ctime_nsec)
return (1); /* Too new, skip it. */
if (nsec == a->older_ctime_nsec &&
(a->older_ctime_filter & ARCHIVE_MATCH_EQUAL)
== 0)
return (1); /* Equal, skip it. */
}
}
if (a->newer_mtime_filter) {
sec = archive_entry_mtime(entry);
if (sec < a->newer_mtime_sec)
return (1); /* Too old, skip it. */
if (sec == a->newer_mtime_sec) {
nsec = archive_entry_mtime_nsec(entry);
if (nsec < a->newer_mtime_nsec)
return (1); /* Too old, skip it. */
if (nsec == a->newer_mtime_nsec &&
(a->newer_mtime_filter & ARCHIVE_MATCH_EQUAL)
== 0)
return (1); /* Equal, skip it. */
}
}
if (a->older_mtime_filter) {
sec = archive_entry_mtime(entry);
if (sec > a->older_mtime_sec)
return (1); /* Too new, skip it. */
nsec = archive_entry_mtime_nsec(entry);
if (sec == a->older_mtime_sec) {
if (nsec > a->older_mtime_nsec)
return (1); /* Too new, skip it. */
if (nsec == a->older_mtime_nsec &&
(a->older_mtime_filter & ARCHIVE_MATCH_EQUAL)
== 0)
return (1); /* Equal, skip it. */
}
}
/* If there is no exclusion list, include the file. */
if (a->exclusion_entry_list.count == 0)
return (0);
#if defined(_WIN32) && !defined(__CYGWIN__)
pathname = archive_entry_pathname_w(entry);
a->exclusion_tree.rbt_ops = &rb_ops_wcs;
#else
(void)rb_ops_wcs;
pathname = archive_entry_pathname(entry);
a->exclusion_tree.rbt_ops = &rb_ops_mbs;
#endif
if (pathname == NULL)
return (0);
f = (struct match_file *)__archive_rb_tree_find_node(
&(a->exclusion_tree), pathname);
/* If the file wasn't rejected, include it. */
if (f == NULL)
return (0);
if (f->flag & ARCHIVE_MATCH_CTIME) {
sec = archive_entry_ctime(entry);
if (f->ctime_sec > sec) {
if (f->flag & ARCHIVE_MATCH_OLDER)
return (1);
} else if (f->ctime_sec < sec) {
if (f->flag & ARCHIVE_MATCH_NEWER)
return (1);
} else {
nsec = archive_entry_ctime_nsec(entry);
if (f->ctime_nsec > nsec) {
if (f->flag & ARCHIVE_MATCH_OLDER)
return (1);
} else if (f->ctime_nsec < nsec) {
if (f->flag & ARCHIVE_MATCH_NEWER)
return (1);
} else if (f->flag & ARCHIVE_MATCH_EQUAL)
return (1);
}
}
if (f->flag & ARCHIVE_MATCH_MTIME) {
sec = archive_entry_mtime(entry);
if (f->mtime_sec > sec) {
if (f->flag & ARCHIVE_MATCH_OLDER)
return (1);
} else if (f->mtime_sec < sec) {
if (f->flag & ARCHIVE_MATCH_NEWER)
return (1);
} else {
nsec = archive_entry_mtime_nsec(entry);
if (f->mtime_nsec > nsec) {
if (f->flag & ARCHIVE_MATCH_OLDER)
return (1);
} else if (f->mtime_nsec < nsec) {
if (f->flag & ARCHIVE_MATCH_NEWER)
return (1);
} else if (f->flag & ARCHIVE_MATCH_EQUAL)
return (1);
}
}
return (0);
}
static int
add_entry(struct archive_match *a, int flag,
struct archive_entry *entry)
{
struct match_file *f;
const void *pathname;
int r;
f = calloc(1, sizeof(*f));
if (f == NULL)
return (error_nomem(a));
#if defined(_WIN32) && !defined(__CYGWIN__)
pathname = archive_entry_pathname_w(entry);
if (pathname == NULL) {
free(f);
archive_set_error(&(a->archive), EINVAL, "pathname is NULL");
return (ARCHIVE_FAILED);
}
archive_mstring_copy_wcs(&(f->pathname), pathname);
a->exclusion_tree.rbt_ops = &rb_ops_wcs;
#else
(void)rb_ops_wcs;
pathname = archive_entry_pathname(entry);
if (pathname == NULL) {
free(f);
archive_set_error(&(a->archive), EINVAL, "pathname is NULL");
return (ARCHIVE_FAILED);
}
archive_mstring_copy_mbs(&(f->pathname), pathname);
a->exclusion_tree.rbt_ops = &rb_ops_mbs;
#endif
f->flag = flag;
f->mtime_sec = archive_entry_mtime(entry);
f->mtime_nsec = archive_entry_mtime_nsec(entry);
f->ctime_sec = archive_entry_ctime(entry);
f->ctime_nsec = archive_entry_ctime_nsec(entry);
r = __archive_rb_tree_insert_node(&(a->exclusion_tree), &(f->node));
if (!r) {
struct match_file *f2;
/* Get the duplicated file. */
f2 = (struct match_file *)__archive_rb_tree_find_node(
&(a->exclusion_tree), pathname);
/*
* We always overwrite comparison condition.
* If you do not want to overwrite it, you should not
* call archive_match_exclude_entry(). We cannot know
* what behavior you really expect since overwriting
* condition might be different with the flag.
*/
if (f2 != NULL) {
f2->flag = f->flag;
f2->mtime_sec = f->mtime_sec;
f2->mtime_nsec = f->mtime_nsec;
f2->ctime_sec = f->ctime_sec;
f2->ctime_nsec = f->ctime_nsec;
}
/* Release the duplicated file. */
archive_mstring_clean(&(f->pathname));
free(f);
return (ARCHIVE_OK);
}
entry_list_add(&(a->exclusion_entry_list), f);
a->setflag |= TIME_IS_SET;
return (ARCHIVE_OK);
}
static void
test_1(void)
{
struct archive_entry *ae;
struct archive *a;
size_t used;
size_t blocksize;
int64_t offset, length;
char *buff2;
size_t buff2_size = 0x13000;
char buff3[1024];
long i;
assert((buff2 = malloc(buff2_size)) != NULL);
/* Repeat the following for a variety of odd blocksizes. */
for (blocksize = 1; blocksize < 100000; blocksize += blocksize + 3) {
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK,
archive_write_set_format_pax(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_set_compression_none(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_set_bytes_per_block(a, (int)blocksize));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_set_bytes_in_last_block(a, (int)blocksize));
assertEqualInt(blocksize,
archive_write_get_bytes_in_last_block(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_open_memory(a, buff, sizeof(buff), &used));
assertEqualInt(blocksize,
archive_write_get_bytes_in_last_block(a));
/*
* Write a file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(10, archive_entry_mtime_nsec(ae));
archive_entry_copy_pathname(ae, "file");
assertEqualString("file", archive_entry_pathname(ae));
archive_entry_set_mode(ae, S_IFREG | 0755);
assertEqualInt(S_IFREG | 0755, archive_entry_mode(ae));
archive_entry_set_size(ae, 0x81000);
archive_entry_sparse_add_entry(ae, 0x10000, 0x1000);
archive_entry_sparse_add_entry(ae, 0x80000, 0x1000);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
archive_entry_free(ae);
memset(buff2, 'a', buff2_size);
for (i = 0; i < 0x81000;) {
size_t ws = buff2_size;
if (i + ws > 0x81000)
ws = 0x81000 - i;
assertEqualInt(ws,
archive_write_data(a, buff2, ws));
i += ws;
}
/* Close out the archive. */
assertEqualIntA(a, ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/* This calculation gives "the smallest multiple of
* the block size that is at least 11264 bytes". */
failure("blocksize=%d", blocksize);
assertEqualInt(((11264 - 1)/blocksize+1)*blocksize, used);
/*
* Now, read the data back.
*/
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK,
archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_read_open_memory(a, buff, used));
assertEqualIntA(a, ARCHIVE_OK,
archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(10, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assertEqualInt(AE_IFREG, archive_entry_filetype(ae));
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(0x81000, archive_entry_size(ae));
/* Verify sparse information. */
assertEqualInt(2, archive_entry_sparse_reset(ae));
assertEqualInt(0,
archive_entry_sparse_next(ae, &offset, &length));
assertEqualInt(0x10000, offset);
assertEqualInt(0x1000, length);
assertEqualInt(0,
archive_entry_sparse_next(ae, &offset, &length));
assertEqualInt(0x80000, offset);
assertEqualInt(0x1000, length);
/* Verify file contents. */
memset(buff3, 0, sizeof(buff3));
for (i = 0; i < 0x10000; i += 1024) {
assertEqualInt(1024, archive_read_data(a, buff2, 1024));
failure("Read data(0x%lx - 0x%lx) should be all zero",
i, i + 1024);
assertEqualMem(buff2, buff3, 1024);
}
memset(buff3, 'a', sizeof(buff3));
for (i = 0x10000; i < 0x11000; i += 1024) {
assertEqualInt(1024, archive_read_data(a, buff2, 1024));
failure("Read data(0x%lx - 0x%lx) should be all 'a'",
i, i + 1024);
assertEqualMem(buff2, buff3, 1024);
}
memset(buff3, 0, sizeof(buff3));
for (i = 0x11000; i < 0x80000; i += 1024) {
assertEqualInt(1024, archive_read_data(a, buff2, 1024));
failure("Read data(0x%lx - 0x%lx) should be all zero",
i, i + 1024);
assertEqualMem(buff2, buff3, 1024);
}
memset(buff3, 'a', sizeof(buff3));
for (i = 0x80000; i < 0x81000; i += 1024) {
assertEqualInt(1024, archive_read_data(a, buff2, 1024));
failure("Read data(0x%lx - 0x%lx) should be all 'a'",
i, i + 1024);
assertEqualMem(buff2, buff3, 1024);
}
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF,
archive_read_next_header(a, &ae));
assertEqualIntA(a, ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
}
free(buff2);
}
static void
test_format(int (*set_format)(struct archive *))
{
char filedata[64];
struct archive_entry *ae;
struct archive *a;
char *p;
size_t used;
size_t buffsize = 1000000;
char *buff;
int damaged = 0;
buff = malloc(buffsize);
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
assertA(0 == (*set_format)(a));
assertA(0 == archive_write_set_compression_none(a));
assertA(0 == archive_write_open_memory(a, buff, buffsize, &used));
/*
* Write a file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assert(1 == archive_entry_mtime(ae));
assert(10 == archive_entry_mtime_nsec(ae));
p = strdup("file");
archive_entry_copy_pathname(ae, p);
strcpy(p, "XXXX");
free(p);
assertEqualString("file", archive_entry_pathname(ae));
archive_entry_set_mode(ae, S_IFREG | 0755);
assert((S_IFREG | 0755) == archive_entry_mode(ae));
archive_entry_set_size(ae, 8);
assertA(0 == archive_write_header(a, ae));
archive_entry_free(ae);
assertA(8 == archive_write_data(a, "12345678", 9));
/*
* Write another file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assert(1 == archive_entry_mtime(ae));
assert(10 == archive_entry_mtime_nsec(ae));
p = strdup("file2");
archive_entry_copy_pathname(ae, p);
strcpy(p, "XXXX");
free(p);
assertEqualString("file2", archive_entry_pathname(ae));
archive_entry_set_mode(ae, S_IFREG | 0755);
assert((S_IFREG | 0755) == archive_entry_mode(ae));
archive_entry_set_size(ae, 4);
assertA(0 == archive_write_header(a, ae));
archive_entry_free(ae);
assertA(4 == archive_write_data(a, "1234", 5));
/*
* Write a directory to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 11, 110);
archive_entry_copy_pathname(ae, "dir");
archive_entry_set_mode(ae, S_IFDIR | 0755);
archive_entry_set_size(ae, 512);
assertA(0 == archive_write_header(a, ae));
assertEqualInt(0, archive_entry_size(ae));
archive_entry_free(ae);
assertEqualIntA(a, 0, archive_write_data(a, "12345678", 9));
/* Close out the archive. */
assertA(0 == archive_write_close(a));
#if ARCHIVE_API_VERSION > 1
assertA(0 == archive_write_finish(a));
#else
archive_write_finish(a);
#endif
/*
* Damage the second entry to test the search-ahead recovery.
*/
{
int i;
for (i = 80; i < 150; i++) {
if (memcmp(buff + i, "07070", 5) == 0) {
damaged = 1;
buff[i] = 'X';
break;
}
}
}
failure("Unable to locate the second header for damage-recovery test.");
assert(damaged = 1);
/*
* Now, read the data back.
*/
assert((a = archive_read_new()) != NULL);
assertA(0 == archive_read_support_format_all(a));
assertA(0 == archive_read_support_compression_all(a));
assertA(0 == archive_read_open_memory(a, buff, used));
assertEqualIntA(a, 0, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
/* Not the same as above: cpio doesn't store hi-res times. */
assert(0 == archive_entry_mtime_nsec(ae));
assert(0 == archive_entry_atime(ae));
assert(0 == archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assertEqualInt((S_IFREG | 0755), archive_entry_mode(ae));
assertEqualInt(8, archive_entry_size(ae));
assertA(8 == archive_read_data(a, filedata, 10));
assert(0 == memcmp(filedata, "12345678", 8));
/*
* Read the second file back.
*/
if (!damaged) {
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
/* Not the same as above: cpio doesn't store hi-res times. */
assert(0 == archive_entry_mtime_nsec(ae));
assert(0 == archive_entry_atime(ae));
assert(0 == archive_entry_ctime(ae));
assertEqualString("file2", archive_entry_pathname(ae));
assert((S_IFREG | 0755) == archive_entry_mode(ae));
assertEqualInt(4, archive_entry_size(ae));
assertEqualIntA(a, 4, archive_read_data(a, filedata, 10));
assert(0 == memcmp(filedata, "1234", 4));
}
/*
* Read the dir entry back.
*/
assertEqualIntA(a,
damaged ? ARCHIVE_WARN : ARCHIVE_OK,
archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assert(0 == archive_entry_mtime_nsec(ae));
assert(0 == archive_entry_atime(ae));
assert(0 == archive_entry_ctime(ae));
assertEqualString("dir", archive_entry_pathname(ae));
assertEqualInt((S_IFDIR | 0755), archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/* Verify the end of the archive. */
assertEqualIntA(a, 1, archive_read_next_header(a, &ae));
assert(0 == archive_read_close(a));
#if ARCHIVE_API_VERSION > 1
assert(0 == archive_read_finish(a));
#else
archive_read_finish(a);
#endif
free(buff);
}
static void
test_format(int (*set_format)(struct archive *))
{
char filedata[64];
struct archive_entry *ae;
struct archive *a;
char *p;
size_t used;
size_t buffsize = 1000000;
char *buff;
int damaged = 0;
buff = malloc(buffsize);
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
assertA(0 == (*set_format)(a));
assertA(0 == archive_write_add_filter_none(a));
assertA(0 == archive_write_open_memory(a, buff, buffsize, &used));
/*
* Write a file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assert(1 == archive_entry_mtime(ae));
assert(10 == archive_entry_mtime_nsec(ae));
p = strdup("file");
archive_entry_copy_pathname(ae, p);
strcpy(p, "XXXX");
free(p);
assertEqualString("file", archive_entry_pathname(ae));
archive_entry_set_mode(ae, S_IFREG | 0755);
assert((S_IFREG | 0755) == archive_entry_mode(ae));
archive_entry_set_size(ae, 8);
assertA(0 == archive_write_header(a, ae));
archive_entry_free(ae);
assertA(8 == archive_write_data(a, "12345678", 9));
/*
* Write another file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assert(1 == archive_entry_mtime(ae));
assert(10 == archive_entry_mtime_nsec(ae));
p = strdup("file2");
archive_entry_copy_pathname(ae, p);
strcpy(p, "XXXX");
free(p);
assertEqualString("file2", archive_entry_pathname(ae));
archive_entry_set_mode(ae, S_IFREG | 0755);
assert((S_IFREG | 0755) == archive_entry_mode(ae));
archive_entry_set_size(ae, 4);
assertA(0 == archive_write_header(a, ae));
archive_entry_free(ae);
assertA(4 == archive_write_data(a, "1234", 5));
/*
* Write a file with a name, filetype, and size.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_copy_pathname(ae, "name");
archive_entry_set_size(ae, 0);
archive_entry_set_filetype(ae, AE_IFREG);
assertEqualInt(ARCHIVE_OK, archive_write_header(a, ae));
assert(archive_error_string(a) == NULL);
archive_entry_free(ae);
/*
* Write a file with a name and filetype but no size.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_copy_pathname(ae, "name");
archive_entry_unset_size(ae);
archive_entry_set_filetype(ae, AE_IFREG);
assertEqualInt(ARCHIVE_FAILED, archive_write_header(a, ae));
assert(archive_error_string(a) != NULL);
archive_entry_free(ae);
/*
* Write a file with a name and size but no filetype.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_copy_pathname(ae, "name");
archive_entry_set_size(ae, 0);
assertEqualInt(ARCHIVE_FAILED, archive_write_header(a, ae));
assert(archive_error_string(a) != NULL);
archive_entry_free(ae);
/*
* Write a file with a size and filetype but no name.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_size(ae, 0);
archive_entry_set_filetype(ae, AE_IFREG);
assertEqualInt(ARCHIVE_FAILED, archive_write_header(a, ae));
assert(archive_error_string(a) != NULL);
archive_entry_free(ae);
/*
* Write a directory to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 11, 110);
archive_entry_copy_pathname(ae, "dir");
archive_entry_set_mode(ae, S_IFDIR | 0755);
archive_entry_set_size(ae, 512);
assertA(0 == archive_write_header(a, ae));
assertEqualInt(0, archive_entry_size(ae));
archive_entry_free(ae);
assertEqualIntA(a, 0, archive_write_data(a, "12345678", 9));
/* Close out the archive. */
assertEqualIntA(a, ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/*
* Damage the second entry to test the search-ahead recovery.
* TODO: Move the damage-recovery checking to a separate test;
* it doesn't really belong in this write test.
*/
{
int i;
for (i = 80; i < 150; i++) {
if (memcmp(buff + i, "07070", 5) == 0) {
damaged = 1;
buff[i] = 'X';
break;
}
}
}
failure("Unable to locate the second header for damage-recovery test.");
assert(damaged == 1);
/*
* Now, read the data back.
*/
assert((a = archive_read_new()) != NULL);
assertA(0 == archive_read_support_format_all(a));
assertA(0 == archive_read_support_filter_all(a));
assertA(0 == archive_read_open_memory(a, buff, used));
if (!assertEqualIntA(a, 0, archive_read_next_header(a, &ae))) {
archive_read_free(a);
return;
}
assertEqualInt(1, archive_entry_mtime(ae));
/* Not the same as above: cpio doesn't store hi-res times. */
assert(0 == archive_entry_mtime_nsec(ae));
assert(0 == archive_entry_atime(ae));
assert(0 == archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assertEqualInt((S_IFREG | 0755), archive_entry_mode(ae));
assertEqualInt(8, archive_entry_size(ae));
assertA(8 == archive_read_data(a, filedata, 10));
assertEqualMem(filedata, "12345678", 8);
/*
* The second file can't be read because we damaged its header.
*/
/*
* Read the third file back.
* ARCHIVE_WARN here because the damaged entry was skipped.
*/
assertEqualIntA(a, ARCHIVE_WARN, archive_read_next_header(a, &ae));
assertEqualString("name", archive_entry_pathname(ae));
/*
* Read the dir entry back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assert(0 == archive_entry_mtime_nsec(ae));
assert(0 == archive_entry_atime(ae));
assert(0 == archive_entry_ctime(ae));
assertEqualString("dir", archive_entry_pathname(ae));
assertEqualInt((S_IFDIR | 0755), archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/* Verify the end of the archive. */
assertEqualIntA(a, 1, archive_read_next_header(a, &ae));
assertEqualIntA(a, ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
free(buff);
}
static int
archive_write_mtree_finish_entry(struct archive_write *a)
{
struct mtree_writer *mtree = a->format_data;
struct archive_entry *entry;
struct archive_string *str;
const char *name;
int keys, ret;
entry = mtree->entry;
if (entry == NULL) {
archive_set_error(&a->archive, ARCHIVE_ERRNO_PROGRAMMER,
"Finished entry without being open first.");
return (ARCHIVE_FATAL);
}
mtree->entry = NULL;
if (mtree->dironly && archive_entry_filetype(entry) != AE_IFDIR) {
archive_entry_free(entry);
return (ARCHIVE_OK);
}
str = (mtree->indent)? &mtree->ebuf : &mtree->buf;
keys = get_keys(mtree, entry);
if ((keys & F_NLINK) != 0 &&
archive_entry_nlink(entry) != 1 &&
archive_entry_filetype(entry) != AE_IFDIR)
archive_string_sprintf(str,
" nlink=%u", archive_entry_nlink(entry));
if ((keys & F_GNAME) != 0 &&
(name = archive_entry_gname(entry)) != NULL) {
archive_strcat(str, " gname=");
mtree_quote(str, name);
}
if ((keys & F_UNAME) != 0 &&
(name = archive_entry_uname(entry)) != NULL) {
archive_strcat(str, " uname=");
mtree_quote(str, name);
}
if ((keys & F_FLAGS) != 0 &&
(name = archive_entry_fflags_text(entry)) != NULL) {
archive_strcat(str, " flags=");
mtree_quote(str, name);
}
if ((keys & F_TIME) != 0)
archive_string_sprintf(str, " time=%jd.%jd",
(intmax_t)archive_entry_mtime(entry),
(intmax_t)archive_entry_mtime_nsec(entry));
if ((keys & F_MODE) != 0)
archive_string_sprintf(str, " mode=%o",
archive_entry_mode(entry) & 07777);
if ((keys & F_GID) != 0)
archive_string_sprintf(str, " gid=%jd",
(intmax_t)archive_entry_gid(entry));
if ((keys & F_UID) != 0)
archive_string_sprintf(str, " uid=%jd",
(intmax_t)archive_entry_uid(entry));
switch (archive_entry_filetype(entry)) {
case AE_IFLNK:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=link");
if ((keys & F_SLINK) != 0) {
archive_strcat(str, " link=");
mtree_quote(str, archive_entry_symlink(entry));
}
break;
case AE_IFSOCK:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=socket");
break;
case AE_IFCHR:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=char");
if ((keys & F_DEV) != 0) {
archive_string_sprintf(str,
" device=native,%d,%d",
archive_entry_rdevmajor(entry),
archive_entry_rdevminor(entry));
}
break;
case AE_IFBLK:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=block");
if ((keys & F_DEV) != 0) {
archive_string_sprintf(str,
" device=native,%d,%d",
archive_entry_rdevmajor(entry),
archive_entry_rdevminor(entry));
}
break;
case AE_IFDIR:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=dir");
break;
case AE_IFIFO:
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=fifo");
break;
case AE_IFREG:
default: /* Handle unknown file types as regular files. */
if ((keys & F_TYPE) != 0)
archive_strcat(str, " type=file");
if ((keys & F_SIZE) != 0)
archive_string_sprintf(str, " size=%jd",
(intmax_t)archive_entry_size(entry));
break;
}
if (mtree->compute_sum & F_CKSUM) {
uint64_t len;
/* Include the length of the file. */
for (len = mtree->crc_len; len != 0; len >>= 8)
COMPUTE_CRC(mtree->crc, len & 0xff);
mtree->crc = ~mtree->crc;
archive_string_sprintf(str, " cksum=%ju",
(uintmax_t)mtree->crc);
}
void
tar_mode_u(struct bsdtar *bsdtar)
{
int64_t end_offset;
struct archive *a;
struct archive_entry *entry;
int format;
struct archive_dir_entry *p;
struct archive_dir archive_dir;
bsdtar->archive_dir = &archive_dir;
memset(&archive_dir, 0, sizeof(archive_dir));
format = ARCHIVE_FORMAT_TAR_PAX_RESTRICTED;
/* Sanity-test some arguments and the file. */
test_for_append(bsdtar);
bsdtar->fd = open(bsdtar->filename, O_RDWR | O_BINARY);
if (bsdtar->fd < 0)
lafe_errc(1, errno,
"Cannot open %s", bsdtar->filename);
a = archive_read_new();
archive_read_support_filter_all(a);
archive_read_support_format_tar(a);
archive_read_support_format_gnutar(a);
if (archive_read_open_fd(a, bsdtar->fd, bsdtar->bytes_per_block)
!= ARCHIVE_OK) {
lafe_errc(1, 0,
"Can't open %s: %s", bsdtar->filename,
archive_error_string(a));
}
/* Build a list of all entries and their recorded mod times. */
while (0 == archive_read_next_header(a, &entry)) {
if (archive_compression(a) != ARCHIVE_COMPRESSION_NONE) {
archive_read_free(a);
close(bsdtar->fd);
lafe_errc(1, 0,
"Cannot append to compressed archive.");
}
add_dir_list(bsdtar, archive_entry_pathname(entry),
archive_entry_mtime(entry),
archive_entry_mtime_nsec(entry));
/* Record the last format determination we see */
format = archive_format(a);
/* Keep going until we hit end-of-archive */
}
end_offset = archive_read_header_position(a);
archive_read_free(a);
/* Re-open archive for writing. */
a = archive_write_new();
/*
* Set format to same one auto-detected above.
*/
archive_write_set_format(a, format);
archive_write_set_bytes_per_block(a, bsdtar->bytes_per_block);
archive_write_set_bytes_in_last_block(a, bsdtar->bytes_in_last_block);
if (lseek(bsdtar->fd, end_offset, SEEK_SET) < 0)
lafe_errc(1, errno, "Could not seek to archive end");
if (ARCHIVE_OK != archive_write_set_options(a, bsdtar->option_options))
lafe_errc(1, 0, "%s", archive_error_string(a));
if (ARCHIVE_OK != archive_write_open_fd(a, bsdtar->fd))
lafe_errc(1, 0, "%s", archive_error_string(a));
write_archive(a, bsdtar);
close(bsdtar->fd);
bsdtar->fd = -1;
while (bsdtar->archive_dir->head != NULL) {
p = bsdtar->archive_dir->head->next;
free(bsdtar->archive_dir->head->name);
free(bsdtar->archive_dir->head);
bsdtar->archive_dir->head = p;
}
bsdtar->archive_dir->tail = NULL;
}
/*
* Test writing an empty file.
*/
static void
test_only_empty_file(void)
{
struct archive *a;
struct archive_entry *ae;
size_t buffsize = 1000;
char *buff;
size_t used;
buff = malloc(buffsize);
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_write_set_format_7zip(a));
assertEqualIntA(a, ARCHIVE_OK, archive_write_add_filter_none(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_open_memory(a, buff, buffsize, &used));
/*
* Write an empty file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(10, archive_entry_mtime_nsec(ae));
archive_entry_set_atime(ae, 2, 20);
assertEqualInt(2, archive_entry_atime(ae));
assertEqualInt(20, archive_entry_atime_nsec(ae));
archive_entry_set_ctime(ae, 0, 100);
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualInt(100, archive_entry_ctime_nsec(ae));
archive_entry_copy_pathname(ae, "empty");
assertEqualString("empty", archive_entry_pathname(ae));
archive_entry_set_mode(ae, AE_IFREG | 0755);
assertEqualInt((S_IFREG | 0755), archive_entry_mode(ae));
assertEqualInt(ARCHIVE_OK, archive_write_header(a, ae));
archive_entry_free(ae);
/* Close out the archive. */
assertEqualInt(ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/* Verify the archive file size. */
assertEqualInt(102, used);
/* Verify the initial header. */
assertEqualMem(buff,
"\x37\x7a\xbc\xaf\x27\x1c\x00\x03"
"\x00\x5b\x58\x25\x00\x00\x00\x00"
"\x00\x00\x00\x00\x46\x00\x00\x00"
"\x00\x00\x00\x00\x8f\xce\x1d\xf3", 32);
/*
* Now, read the data back.
*/
/* With the test memory reader -- seeking mode. */
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_OK, read_open_memory_seek(a, buff, used, 7));
/*
* Read and verify an empty file.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(2, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_atime_nsec(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualInt(100, archive_entry_ctime_nsec(ae));
assertEqualString("empty", archive_entry_pathname(ae));
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF, archive_read_next_header(a, &ae));
/* Verify archive format. */
assertEqualIntA(a, ARCHIVE_FILTER_NONE, archive_filter_code(a, 0));
assertEqualIntA(a, ARCHIVE_FORMAT_7ZIP, archive_format(a));
assertEqualInt(ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
free(buff);
}
static void
test_basic2(const char *compression_type)
{
char filedata[64];
struct archive_entry *ae;
struct archive *a;
size_t used;
size_t buffsize = 1000;
char *buff;
buff = malloc(buffsize);
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_write_set_format_7zip(a));
if (compression_type != NULL &&
ARCHIVE_OK != archive_write_set_format_option(a, "7zip",
"compression", compression_type)) {
skipping("%s writing not fully supported on this platform",
compression_type);
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
free(buff);
return;
}
assertEqualIntA(a, ARCHIVE_OK, archive_write_add_filter_none(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_open_memory(a, buff, buffsize, &used));
/*
* Write a file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 100);
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(100, archive_entry_mtime_nsec(ae));
archive_entry_copy_pathname(ae, "file");
assertEqualString("file", archive_entry_pathname(ae));
archive_entry_set_mode(ae, AE_IFREG | 0755);
assertEqualInt((AE_IFREG | 0755), archive_entry_mode(ae));
archive_entry_set_size(ae, 8);
assertEqualInt(0, archive_write_header(a, ae));
archive_entry_free(ae);
assertEqualInt(8, archive_write_data(a, "12345678", 9));
assertEqualInt(0, archive_write_data(a, "1", 1));
/*
* Write another file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 10);
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(10, archive_entry_mtime_nsec(ae));
archive_entry_copy_pathname(ae, "file2");
assertEqualString("file2", archive_entry_pathname(ae));
archive_entry_set_mode(ae, AE_IFREG | 0755);
assertEqualInt((AE_IFREG | 0755), archive_entry_mode(ae));
archive_entry_set_size(ae, 4);
assertEqualInt(ARCHIVE_OK, archive_write_header(a, ae));
archive_entry_free(ae);
assertEqualInt(4, archive_write_data(a, "1234", 5));
/*
* Write a directory to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 11, 100);
archive_entry_copy_pathname(ae, "dir");
archive_entry_set_mode(ae, AE_IFDIR | 0755);
archive_entry_set_size(ae, 512);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
failure("size should be zero so that applications know not to write");
assertEqualInt(0, archive_entry_size(ae));
archive_entry_free(ae);
assertEqualIntA(a, 0, archive_write_data(a, "12345678", 9));
/*
* Write a sub directory to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 11, 200);
archive_entry_copy_pathname(ae, "dir/subdir");
archive_entry_set_mode(ae, AE_IFDIR | 0755);
archive_entry_set_size(ae, 512);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
failure("size should be zero so that applications know not to write");
assertEqualInt(0, archive_entry_size(ae));
archive_entry_free(ae);
assertEqualIntA(a, 0, archive_write_data(a, "12345678", 9));
/*
* Write a sub sub-directory to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 11, 300);
archive_entry_copy_pathname(ae, "dir/subdir/subdir");
archive_entry_set_mode(ae, AE_IFDIR | 0755);
archive_entry_set_size(ae, 512);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
failure("size should be zero so that applications know not to write");
assertEqualInt(0, archive_entry_size(ae));
archive_entry_free(ae);
assertEqualIntA(a, 0, archive_write_data(a, "12345678", 9));
/* Close out the archive. */
assertEqualInt(ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/* Verify the initial header. */
assertEqualMem(buff, "\x37\x7a\xbc\xaf\x27\x1c\x00\x03", 8);
/*
* Now, read the data back.
*/
/* With the test memory reader -- seeking mode. */
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_OK, read_open_memory_seek(a, buff, used, 7));
/*
* Read and verify first file.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(100, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(8, archive_entry_size(ae));
assertEqualIntA(a, 8,
archive_read_data(a, filedata, sizeof(filedata)));
assertEqualMem(filedata, "12345678", 8);
/*
* Read the second file back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file2", archive_entry_pathname(ae));
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(4, archive_entry_size(ae));
assertEqualIntA(a, 4,
archive_read_data(a, filedata, sizeof(filedata)));
assertEqualMem(filedata, "1234", 4);
/*
* Read the sub sub-dir entry back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assertEqualInt(300, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("dir/subdir/subdir/", archive_entry_pathname(ae));
assertEqualInt(AE_IFDIR | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/*
* Read the sub dir entry back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assertEqualInt(200, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("dir/subdir/", archive_entry_pathname(ae));
assertEqualInt(AE_IFDIR | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/*
* Read the dir entry back.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(11, archive_entry_mtime(ae));
assertEqualInt(100, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("dir/", archive_entry_pathname(ae));
assertEqualInt(AE_IFDIR | 0755, archive_entry_mode(ae));
assertEqualInt(0, archive_entry_size(ae));
assertEqualIntA(a, 0, archive_read_data(a, filedata, 10));
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF, archive_read_next_header(a, &ae));
/* Verify archive format. */
assertEqualIntA(a, ARCHIVE_FILTER_NONE, archive_filter_code(a, 0));
assertEqualIntA(a, ARCHIVE_FORMAT_7ZIP, archive_format(a));
assertEqualInt(ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
free(buff);
}
void
tar_mode_u(struct bsdtar *bsdtar)
{
off_t end_offset;
struct archive *a;
struct archive_entry *entry;
int format;
struct archive_dir_entry *p;
struct archive_dir archive_dir;
bsdtar->archive_dir = &archive_dir;
memset(&archive_dir, 0, sizeof(archive_dir));
format = ARCHIVE_FORMAT_TAR_PAX_RESTRICTED;
/* Sanity-test some arguments and the file. */
test_for_append(bsdtar);
bsdtar->fd = open(bsdtar->filename, O_RDWR);
if (bsdtar->fd < 0)
bsdtar_errc(bsdtar, 1, errno,
"Cannot open %s", bsdtar->filename);
a = archive_read_new();
archive_read_support_compression_all(a);
archive_read_support_format_tar(a);
archive_read_support_format_gnutar(a);
if (archive_read_open_fd(a, bsdtar->fd,
bsdtar->bytes_per_block != 0 ? bsdtar->bytes_per_block :
DEFAULT_BYTES_PER_BLOCK) != ARCHIVE_OK) {
bsdtar_errc(bsdtar, 1, 0,
"Can't open %s: %s", bsdtar->filename,
archive_error_string(a));
}
/* Build a list of all entries and their recorded mod times. */
while (0 == archive_read_next_header(a, &entry)) {
if (archive_compression(a) != ARCHIVE_COMPRESSION_NONE) {
archive_read_finish(a);
close(bsdtar->fd);
bsdtar_errc(bsdtar, 1, 0,
"Cannot append to compressed archive.");
}
add_dir_list(bsdtar, archive_entry_pathname(entry),
archive_entry_mtime(entry),
archive_entry_mtime_nsec(entry));
/* Record the last format determination we see */
format = archive_format(a);
/* Keep going until we hit end-of-archive */
}
end_offset = archive_read_header_position(a);
archive_read_finish(a);
/* Re-open archive for writing. */
a = archive_write_new();
archive_write_set_compression_none(a);
/*
* Set format to same one auto-detected above, except that
* we don't write GNU tar format, so use ustar instead.
*/
if (format == ARCHIVE_FORMAT_TAR_GNUTAR)
format = ARCHIVE_FORMAT_TAR_USTAR;
archive_write_set_format(a, format);
if (bsdtar->bytes_per_block != 0) {
archive_write_set_bytes_per_block(a, bsdtar->bytes_per_block);
archive_write_set_bytes_in_last_block(a,
bsdtar->bytes_per_block);
} else
archive_write_set_bytes_per_block(a, DEFAULT_BYTES_PER_BLOCK);
lseek(bsdtar->fd, end_offset, SEEK_SET);
ftruncate(bsdtar->fd, end_offset);
if (ARCHIVE_OK != archive_write_set_options(a, bsdtar->option_options))
bsdtar_errc(bsdtar, 1, 0, archive_error_string(a));
if (ARCHIVE_OK != archive_write_open_fd(a, bsdtar->fd))
bsdtar_errc(bsdtar, 1, 0, archive_error_string(a));
write_archive(a, bsdtar);
close(bsdtar->fd);
bsdtar->fd = -1;
while (bsdtar->archive_dir->head != NULL) {
p = bsdtar->archive_dir->head->next;
free(bsdtar->archive_dir->head->name);
free(bsdtar->archive_dir->head);
bsdtar->archive_dir->head = p;
}
bsdtar->archive_dir->tail = NULL;
}
static void
test_large(const char *compression_type)
{
struct archive_entry *ae;
struct archive *a;
size_t used;
size_t buffsize = LARGE_SIZE + 1024 * 256;
size_t datasize = LARGE_SIZE;
char *buff, *filedata, *filedata2;
unsigned i;
assert((buff = malloc(buffsize)) != NULL);
assert((filedata = malloc(datasize)) != NULL);
assert((filedata2 = malloc(datasize)) != NULL);
/* Create a new archive in memory. */
assert((a = archive_write_new()) != NULL);
if (a == NULL || buff == NULL || filedata == NULL || filedata2 == NULL) {
archive_write_free(a);
free(buff);
free(filedata);
free(filedata2);
return;
}
assertEqualIntA(a, ARCHIVE_OK, archive_write_set_format_7zip(a));
if (compression_type != NULL &&
ARCHIVE_OK != archive_write_set_format_option(a, "7zip",
"compression", compression_type)) {
skipping("%s writing not fully supported on this platform",
compression_type);
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
free(buff);
free(filedata);
free(filedata2);
return;
}
assertEqualIntA(a, ARCHIVE_OK, archive_write_add_filter_none(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_open_memory(a, buff, buffsize, &used));
/*
* Write a large file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 100);
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(100, archive_entry_mtime_nsec(ae));
archive_entry_copy_pathname(ae, "file");
assertEqualString("file", archive_entry_pathname(ae));
archive_entry_set_mode(ae, AE_IFREG | 0755);
assertEqualInt((AE_IFREG | 0755), archive_entry_mode(ae));
archive_entry_set_size(ae, datasize);
assertEqualInt(0, archive_write_header(a, ae));
archive_entry_free(ae);
if (strcmp(compression_type, "ppmd") == 0) {
/* NOTE: PPMd cannot handle random data correctly.*/
memset(filedata, 'a', datasize);
} else {
for (i = 0; i < datasize; i++)
filedata[i] = (char)rand();
}
assertEqualInt(datasize, archive_write_data(a, filedata, datasize));
/* Close out the archive. */
assertEqualIntA(a, ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/* Verify the initial header. */
assertEqualMem(buff, "\x37\x7a\xbc\xaf\x27\x1c\x00\x03", 8);
/*
* Now, read the data back.
*/
/* With the test memory reader -- seeking mode. */
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_OK, read_open_memory_seek(a, buff, used, 7));
/*
* Read and verify a large file.
*/
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(100, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assertEqualInt(AE_IFREG | 0755, archive_entry_mode(ae));
assertEqualInt(datasize, archive_entry_size(ae));
assertEqualIntA(a, datasize, archive_read_data(a, filedata2, datasize));
assertEqualMem(filedata, filedata2, datasize);
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF, archive_read_next_header(a, &ae));
/* Verify archive format. */
assertEqualIntA(a, ARCHIVE_FILTER_NONE, archive_filter_code(a, 0));
assertEqualIntA(a, ARCHIVE_FORMAT_7ZIP, archive_format(a));
assertEqualInt(ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
free(buff);
free(filedata);
free(filedata2);
}
const struct stat *
archive_entry_stat(struct archive_entry *entry)
{
struct stat *st;
if (entry->stat == NULL) {
entry->stat = calloc(1, sizeof(*st));
if (entry->stat == NULL)
return (NULL);
entry->stat_valid = 0;
}
/*
* If none of the underlying fields have been changed, we
* don't need to regenerate. In theory, we could use a bitmap
* here to flag only those items that have changed, but the
* extra complexity probably isn't worth it. It will be very
* rare for anyone to change just one field then request a new
* stat structure.
*/
if (entry->stat_valid)
return (entry->stat);
st = entry->stat;
/*
* Use the public interfaces to extract items, so that
* the appropriate conversions get invoked.
*/
st->st_atime = archive_entry_atime(entry);
#if HAVE_STRUCT_STAT_ST_BIRTHTIME
st->st_birthtime = archive_entry_birthtime(entry);
#endif
st->st_ctime = archive_entry_ctime(entry);
st->st_mtime = archive_entry_mtime(entry);
st->st_dev = archive_entry_dev(entry);
st->st_gid = archive_entry_gid(entry);
st->st_uid = archive_entry_uid(entry);
st->st_ino = archive_entry_ino64(entry);
st->st_nlink = archive_entry_nlink(entry);
st->st_rdev = archive_entry_rdev(entry);
st->st_size = archive_entry_size(entry);
st->st_mode = archive_entry_mode(entry);
/*
* On systems that support high-res timestamps, copy that
* information into struct stat.
*/
#if HAVE_STRUCT_STAT_ST_MTIMESPEC_TV_NSEC
st->st_atimespec.tv_nsec = archive_entry_atime_nsec(entry);
st->st_ctimespec.tv_nsec = archive_entry_ctime_nsec(entry);
st->st_mtimespec.tv_nsec = archive_entry_mtime_nsec(entry);
#elif HAVE_STRUCT_STAT_ST_MTIM_TV_NSEC
st->st_atim.tv_nsec = archive_entry_atime_nsec(entry);
st->st_ctim.tv_nsec = archive_entry_ctime_nsec(entry);
st->st_mtim.tv_nsec = archive_entry_mtime_nsec(entry);
#elif HAVE_STRUCT_STAT_ST_MTIME_N
st->st_atime_n = archive_entry_atime_nsec(entry);
st->st_ctime_n = archive_entry_ctime_nsec(entry);
st->st_mtime_n = archive_entry_mtime_nsec(entry);
#elif HAVE_STRUCT_STAT_ST_UMTIME
st->st_uatime = archive_entry_atime_nsec(entry) / 1000;
st->st_uctime = archive_entry_ctime_nsec(entry) / 1000;
st->st_umtime = archive_entry_mtime_nsec(entry) / 1000;
#elif HAVE_STRUCT_STAT_ST_MTIME_USEC
st->st_atime_usec = archive_entry_atime_nsec(entry) / 1000;
st->st_ctime_usec = archive_entry_ctime_nsec(entry) / 1000;
st->st_mtime_usec = archive_entry_mtime_nsec(entry) / 1000;
#endif
#if HAVE_STRUCT_STAT_ST_BIRTHTIMESPEC_TV_NSEC
st->st_birthtimespec.tv_nsec = archive_entry_birthtime_nsec(entry);
#endif
/*
* TODO: On Linux, store 32 or 64 here depending on whether
* the cached stat structure is a stat32 or a stat64. This
* will allow us to support both variants interchangeably.
*/
entry->stat_valid = 1;
return (st);
}
static void
test_open_filename_mbs(void)
{
char buff[64];
struct archive_entry *ae;
struct archive *a;
/* Write an archive through this FILE *. */
assert((a = archive_write_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_write_set_format_ustar(a));
assertEqualIntA(a, ARCHIVE_OK, archive_write_set_compression_none(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_write_open_filename(a, "test.tar"));
/*
* Write a file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_set_mtime(ae, 1, 0);
archive_entry_copy_pathname(ae, "file");
archive_entry_set_mode(ae, S_IFREG | 0755);
archive_entry_set_size(ae, 8);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
archive_entry_free(ae);
assertEqualIntA(a, 8, archive_write_data(a, "12345678", 9));
/*
* Write a second file to it.
*/
assert((ae = archive_entry_new()) != NULL);
archive_entry_copy_pathname(ae, "file2");
archive_entry_set_mode(ae, S_IFREG | 0755);
archive_entry_set_size(ae, 819200);
assertEqualIntA(a, ARCHIVE_OK, archive_write_header(a, ae));
archive_entry_free(ae);
/* Close out the archive. */
assertEqualIntA(a, ARCHIVE_OK, archive_write_close(a));
assertEqualInt(ARCHIVE_OK, archive_write_free(a));
/*
* Now, read the data back.
*/
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_OK,
archive_read_open_filename(a, "test.tar", 512));
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualInt(1, archive_entry_mtime(ae));
assertEqualInt(0, archive_entry_mtime_nsec(ae));
assertEqualInt(0, archive_entry_atime(ae));
assertEqualInt(0, archive_entry_ctime(ae));
assertEqualString("file", archive_entry_pathname(ae));
assert((S_IFREG | 0755) == archive_entry_mode(ae));
assertEqualInt(8, archive_entry_size(ae));
assertEqualIntA(a, 8, archive_read_data(a, buff, 10));
assertEqualMem(buff, "12345678", 8);
assertEqualIntA(a, ARCHIVE_OK, archive_read_next_header(a, &ae));
assertEqualString("file2", archive_entry_pathname(ae));
assert((S_IFREG | 0755) == archive_entry_mode(ae));
assertEqualInt(819200, archive_entry_size(ae));
assertEqualIntA(a, ARCHIVE_OK, archive_read_data_skip(a));
/* Verify the end of the archive. */
assertEqualIntA(a, ARCHIVE_EOF, archive_read_next_header(a, &ae));
assertEqualIntA(a, ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
/*
* Verify some of the error handling.
*/
assert((a = archive_read_new()) != NULL);
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_format_all(a));
assertEqualIntA(a, ARCHIVE_OK, archive_read_support_filter_all(a));
assertEqualIntA(a, ARCHIVE_FATAL,
archive_read_open_filename(a, "nonexistent.tar", 512));
assertEqualIntA(a, ARCHIVE_OK, archive_read_close(a));
assertEqualInt(ARCHIVE_OK, archive_read_free(a));
}
/*
* Handle 'x' and 't' modes.
*/
static void
read_archive(struct bsdtar *bsdtar, char mode, struct archive *writer)
{
struct progress_data progress_data;
FILE *out;
struct archive *a;
struct archive_entry *entry;
int r;
time_t sec;
long nsec;
while (*bsdtar->argv) {
lafe_include(&bsdtar->matching, *bsdtar->argv);
bsdtar->argv++;
}
if (bsdtar->names_from_file != NULL)
lafe_include_from_file(&bsdtar->matching,
bsdtar->names_from_file, bsdtar->option_null);
a = archive_read_new();
if (bsdtar->compress_program != NULL)
archive_read_support_filter_program(a, bsdtar->compress_program);
else
archive_read_support_filter_all(a);
archive_read_support_format_all(a);
if (ARCHIVE_OK != archive_read_set_options(a, bsdtar->option_options))
lafe_errc(1, 0, "%s", archive_error_string(a));
if (archive_read_open_file(a, bsdtar->filename, bsdtar->bytes_per_block))
lafe_errc(1, 0, "Error opening archive: %s",
archive_error_string(a));
do_chdir(bsdtar);
if (mode == 'x') {
/* Set an extract callback so that we can handle SIGINFO. */
progress_data.bsdtar = bsdtar;
progress_data.archive = a;
archive_read_extract_set_progress_callback(a, progress_func,
&progress_data);
}
if (mode == 'x' && bsdtar->option_chroot) {
#if HAVE_CHROOT
if (chroot(".") != 0)
lafe_errc(1, errno, "Can't chroot to \".\"");
#else
lafe_errc(1, 0,
"chroot isn't supported on this platform");
#endif
}
for (;;) {
/* Support --fast-read option */
if (bsdtar->option_fast_read &&
lafe_unmatched_inclusions(bsdtar->matching) == 0)
break;
r = archive_read_next_header(a, &entry);
progress_data.entry = entry;
if (r == ARCHIVE_EOF)
break;
if (r < ARCHIVE_OK)
lafe_warnc(0, "%s", archive_error_string(a));
if (r <= ARCHIVE_WARN)
bsdtar->return_value = 1;
if (r == ARCHIVE_RETRY) {
/* Retryable error: try again */
lafe_warnc(0, "Retrying...");
continue;
}
if (r == ARCHIVE_FATAL)
break;
if (bsdtar->uid >= 0) {
archive_entry_set_uid(entry, bsdtar->uid);
archive_entry_set_uname(entry, NULL);
}
if (bsdtar->gid >= 0) {
archive_entry_set_gid(entry, bsdtar->gid);
archive_entry_set_gname(entry, NULL);
}
if (bsdtar->uname)
archive_entry_set_uname(entry, bsdtar->uname);
if (bsdtar->gname)
archive_entry_set_gname(entry, bsdtar->gname);
/*
* Exclude entries that are too old.
*/
if (bsdtar->newer_ctime_filter) {
/* Use ctime if format provides, else mtime. */
if (archive_entry_ctime_is_set(entry)) {
sec = archive_entry_ctime(entry);
nsec = archive_entry_ctime_nsec(entry);
} else if (archive_entry_mtime_is_set(entry)) {
sec = archive_entry_mtime(entry);
nsec = archive_entry_mtime_nsec(entry);
} else {
sec = 0;
nsec = 0;
}
if (sec < bsdtar->newer_ctime_sec)
continue; /* Too old, skip it. */
if (sec == bsdtar->newer_ctime_sec
&& nsec <= bsdtar->newer_ctime_nsec)
continue; /* Too old, skip it. */
}
if (bsdtar->newer_mtime_filter) {
if (archive_entry_mtime_is_set(entry)) {
sec = archive_entry_mtime(entry);
nsec = archive_entry_mtime_nsec(entry);
} else {
sec = 0;
nsec = 0;
}
if (sec < bsdtar->newer_mtime_sec)
continue; /* Too old, skip it. */
if (sec == bsdtar->newer_mtime_sec
&& nsec <= bsdtar->newer_mtime_nsec)
continue; /* Too old, skip it. */
}
/*
* Note that pattern exclusions are checked before
* pathname rewrites are handled. This gives more
* control over exclusions, since rewrites always lose
* information. (For example, consider a rewrite
* s/foo[0-9]/foo/. If we check exclusions after the
* rewrite, there would be no way to exclude foo1/bar
* while allowing foo2/bar.)
*/
if (lafe_excluded(bsdtar->matching, archive_entry_pathname(entry)))
continue; /* Excluded by a pattern test. */
if (mode == 't') {
/* Perversely, gtar uses -O to mean "send to stderr"
* when used with -t. */
out = bsdtar->option_stdout ? stderr : stdout;
/*
* TODO: Provide some reasonable way to
* preview rewrites. gtar always displays
* the unedited path in -t output, which means
* you cannot easily preview rewrites.
*/
if (bsdtar->verbose < 2)
safe_fprintf(out, "%s",
archive_entry_pathname(entry));
else
list_item_verbose(bsdtar, out, entry);
fflush(out);
r = archive_read_data_skip(a);
if (r == ARCHIVE_WARN) {
fprintf(out, "\n");
lafe_warnc(0, "%s",
archive_error_string(a));
}
if (r == ARCHIVE_RETRY) {
fprintf(out, "\n");
lafe_warnc(0, "%s",
archive_error_string(a));
}
if (r == ARCHIVE_FATAL) {
fprintf(out, "\n");
lafe_warnc(0, "%s",
archive_error_string(a));
bsdtar->return_value = 1;
break;
}
fprintf(out, "\n");
} else {
/* Note: some rewrite failures prevent extraction. */
if (edit_pathname(bsdtar, entry))
continue; /* Excluded by a rewrite failure. */
if (bsdtar->option_interactive &&
!yes("extract '%s'", archive_entry_pathname(entry)))
continue;
/*
* Format here is from SUSv2, including the
* deferred '\n'.
*/
if (bsdtar->verbose) {
safe_fprintf(stderr, "x %s",
archive_entry_pathname(entry));
fflush(stderr);
}
/* TODO siginfo_printinfo(bsdtar, 0); */
if (bsdtar->option_stdout)
r = archive_read_data_into_fd(a, 1);
else
r = archive_read_extract2(a, entry, writer);
if (r != ARCHIVE_OK) {
if (!bsdtar->verbose)
safe_fprintf(stderr, "%s",
archive_entry_pathname(entry));
safe_fprintf(stderr, ": %s",
archive_error_string(a));
if (!bsdtar->verbose)
fprintf(stderr, "\n");
bsdtar->return_value = 1;
}
if (bsdtar->verbose)
fprintf(stderr, "\n");
if (r == ARCHIVE_FATAL)
break;
}
}
r = archive_read_close(a);
if (r != ARCHIVE_OK)
lafe_warnc(0, "%s", archive_error_string(a));
if (r <= ARCHIVE_WARN)
bsdtar->return_value = 1;
if (bsdtar->verbose > 2)
fprintf(stdout, "Archive Format: %s, Compression: %s\n",
archive_format_name(a), archive_compression_name(a));
archive_read_free(a);
}