/* SPDX-License-Identifier: LGPL-2.1+ */ #include #include #include "alloc-util.h" #include "fd-util.h" #include "fileio.h" #include "macro.h" #include "memory-util.h" #include "path-util.h" #include "process-util.h" #include "random-util.h" #include "rlimit-util.h" #include "serialize.h" #include "string-util.h" #include "tests.h" #include "tmpfile-util.h" static void test_close_many(void) { int fds[3]; char name0[] = "/tmp/test-close-many.XXXXXX"; char name1[] = "/tmp/test-close-many.XXXXXX"; char name2[] = "/tmp/test-close-many.XXXXXX"; fds[0] = mkostemp_safe(name0); fds[1] = mkostemp_safe(name1); fds[2] = mkostemp_safe(name2); close_many(fds, 2); assert_se(fcntl(fds[0], F_GETFD) == -1); assert_se(fcntl(fds[1], F_GETFD) == -1); assert_se(fcntl(fds[2], F_GETFD) >= 0); safe_close(fds[2]); unlink(name0); unlink(name1); unlink(name2); } static void test_close_nointr(void) { char name[] = "/tmp/test-test-close_nointr.XXXXXX"; int fd; fd = mkostemp_safe(name); assert_se(fd >= 0); assert_se(close_nointr(fd) >= 0); assert_se(close_nointr(fd) < 0); unlink(name); } static void test_same_fd(void) { _cleanup_close_pair_ int p[2] = { -1, -1 }; _cleanup_close_ int a = -1, b = -1, c = -1; assert_se(pipe2(p, O_CLOEXEC) >= 0); assert_se((a = fcntl(p[0], F_DUPFD, 3)) >= 0); assert_se((b = open("/dev/null", O_RDONLY|O_CLOEXEC)) >= 0); assert_se((c = fcntl(a, F_DUPFD, 3)) >= 0); assert_se(same_fd(p[0], p[0]) > 0); assert_se(same_fd(p[1], p[1]) > 0); assert_se(same_fd(a, a) > 0); assert_se(same_fd(b, b) > 0); assert_se(same_fd(a, p[0]) > 0); assert_se(same_fd(p[0], a) > 0); assert_se(same_fd(c, p[0]) > 0); assert_se(same_fd(p[0], c) > 0); assert_se(same_fd(a, c) > 0); assert_se(same_fd(c, a) > 0); assert_se(same_fd(p[0], p[1]) == 0); assert_se(same_fd(p[1], p[0]) == 0); assert_se(same_fd(p[0], b) == 0); assert_se(same_fd(b, p[0]) == 0); assert_se(same_fd(p[1], a) == 0); assert_se(same_fd(a, p[1]) == 0); assert_se(same_fd(p[1], b) == 0); assert_se(same_fd(b, p[1]) == 0); assert_se(same_fd(a, b) == 0); assert_se(same_fd(b, a) == 0); } static void test_open_serialization_fd(void) { _cleanup_close_ int fd = -1; fd = open_serialization_fd("test"); assert_se(fd >= 0); assert_se(write(fd, "test\n", 5) == 5); } static void test_acquire_data_fd_one(unsigned flags) { char wbuffer[196*1024 - 7]; char rbuffer[sizeof(wbuffer)]; int fd; fd = acquire_data_fd("foo", 3, flags); assert_se(fd >= 0); zero(rbuffer); assert_se(read(fd, rbuffer, sizeof(rbuffer)) == 3); assert_se(streq(rbuffer, "foo")); fd = safe_close(fd); fd = acquire_data_fd("", 0, flags); assert_se(fd >= 0); zero(rbuffer); assert_se(read(fd, rbuffer, sizeof(rbuffer)) == 0); assert_se(streq(rbuffer, "")); fd = safe_close(fd); random_bytes(wbuffer, sizeof(wbuffer)); fd = acquire_data_fd(wbuffer, sizeof(wbuffer), flags); assert_se(fd >= 0); zero(rbuffer); assert_se(read(fd, rbuffer, sizeof(rbuffer)) == sizeof(rbuffer)); assert_se(memcmp(rbuffer, wbuffer, sizeof(rbuffer)) == 0); fd = safe_close(fd); } static void test_acquire_data_fd(void) { test_acquire_data_fd_one(0); test_acquire_data_fd_one(ACQUIRE_NO_DEV_NULL); test_acquire_data_fd_one(ACQUIRE_NO_MEMFD); test_acquire_data_fd_one(ACQUIRE_NO_DEV_NULL|ACQUIRE_NO_MEMFD); test_acquire_data_fd_one(ACQUIRE_NO_PIPE); test_acquire_data_fd_one(ACQUIRE_NO_DEV_NULL|ACQUIRE_NO_PIPE); test_acquire_data_fd_one(ACQUIRE_NO_MEMFD|ACQUIRE_NO_PIPE); test_acquire_data_fd_one(ACQUIRE_NO_DEV_NULL|ACQUIRE_NO_MEMFD|ACQUIRE_NO_PIPE); test_acquire_data_fd_one(ACQUIRE_NO_DEV_NULL|ACQUIRE_NO_MEMFD|ACQUIRE_NO_PIPE|ACQUIRE_NO_TMPFILE); } static void test_fd_move_above_stdio(void) { int original_stdin, new_fd; original_stdin = fcntl(0, F_DUPFD, 3); assert_se(original_stdin >= 3); assert_se(close_nointr(0) != EBADF); new_fd = open("/dev/null", O_RDONLY); assert_se(new_fd == 0); new_fd = fd_move_above_stdio(new_fd); assert_se(new_fd >= 3); assert_se(dup(original_stdin) == 0); assert_se(close_nointr(original_stdin) != EBADF); assert_se(close_nointr(new_fd) != EBADF); } static void test_rearrange_stdio(void) { pid_t pid; int r; r = safe_fork("rearrange", FORK_WAIT|FORK_LOG, &pid); assert_se(r >= 0); if (r == 0) { _cleanup_free_ char *path = NULL; char buffer[10]; /* Child */ safe_close(STDERR_FILENO); /* Let's close an fd < 2, to make it more interesting */ assert_se(rearrange_stdio(-1, -1, -1) >= 0); assert_se(fd_get_path(STDIN_FILENO, &path) >= 0); assert_se(path_equal(path, "/dev/null")); path = mfree(path); assert_se(fd_get_path(STDOUT_FILENO, &path) >= 0); assert_se(path_equal(path, "/dev/null")); path = mfree(path); assert_se(fd_get_path(STDOUT_FILENO, &path) >= 0); assert_se(path_equal(path, "/dev/null")); path = mfree(path); safe_close(STDIN_FILENO); safe_close(STDOUT_FILENO); safe_close(STDERR_FILENO); { int pair[2]; assert_se(pipe(pair) >= 0); assert_se(pair[0] == 0); assert_se(pair[1] == 1); assert_se(fd_move_above_stdio(0) == 3); } assert_se(open("/dev/full", O_WRONLY|O_CLOEXEC) == 0); assert_se(acquire_data_fd("foobar", 6, 0) == 2); assert_se(rearrange_stdio(2, 0, 1) >= 0); assert_se(write(1, "x", 1) < 0 && errno == ENOSPC); assert_se(write(2, "z", 1) == 1); assert_se(read(3, buffer, sizeof(buffer)) == 1); assert_se(buffer[0] == 'z'); assert_se(read(0, buffer, sizeof(buffer)) == 6); assert_se(memcmp(buffer, "foobar", 6) == 0); assert_se(rearrange_stdio(-1, 1, 2) >= 0); assert_se(write(1, "a", 1) < 0 && errno == ENOSPC); assert_se(write(2, "y", 1) == 1); assert_se(read(3, buffer, sizeof(buffer)) == 1); assert_se(buffer[0] == 'y'); assert_se(fd_get_path(0, &path) >= 0); assert_se(path_equal(path, "/dev/null")); path = mfree(path); _exit(EXIT_SUCCESS); } } static void assert_equal_fd(int fd1, int fd2) { for (;;) { uint8_t a[4096], b[4096]; ssize_t x, y; x = read(fd1, a, sizeof(a)); assert_se(x >= 0); y = read(fd2, b, sizeof(b)); assert_se(y >= 0); assert_se(x == y); if (x == 0) break; assert_se(memcmp(a, b, x) == 0); } } static void test_fd_duplicate_data_fd(void) { _cleanup_close_ int fd1 = -1, fd2 = -1; _cleanup_(close_pairp) int sfd[2] = { -1, -1 }; _cleanup_(sigkill_waitp) pid_t pid = -1; uint64_t i, j; int r; fd1 = open("/etc/fstab", O_RDONLY|O_CLOEXEC); if (fd1 >= 0) { fd2 = fd_duplicate_data_fd(fd1); assert_se(fd2 >= 0); assert_se(lseek(fd1, 0, SEEK_SET) == 0); assert_equal_fd(fd1, fd2); } fd1 = safe_close(fd1); fd2 = safe_close(fd2); fd1 = acquire_data_fd("hallo", 6, 0); assert_se(fd1 >= 0); fd2 = fd_duplicate_data_fd(fd1); assert_se(fd2 >= 0); safe_close(fd1); fd1 = acquire_data_fd("hallo", 6, 0); assert_se(fd1 >= 0); assert_equal_fd(fd1, fd2); fd1 = safe_close(fd1); fd2 = safe_close(fd2); assert_se(socketpair(AF_UNIX, SOCK_STREAM|SOCK_CLOEXEC, 0, sfd) >= 0); r = safe_fork("(sd-pipe)", FORK_RESET_SIGNALS|FORK_DEATHSIG|FORK_LOG, &pid); assert_se(r >= 0); if (r == 0) { /* child */ sfd[0] = safe_close(sfd[0]); for (i = 0; i < 1536*1024 / sizeof(uint64_t); i++) assert_se(write(sfd[1], &i, sizeof(i)) == sizeof(i)); sfd[1] = safe_close(sfd[1]); _exit(EXIT_SUCCESS); } sfd[1] = safe_close(sfd[1]); fd2 = fd_duplicate_data_fd(sfd[0]); assert_se(fd2 >= 0); for (i = 0; i < 1536*1024 / sizeof(uint64_t); i++) { assert_se(read(fd2, &j, sizeof(j)) == sizeof(j)); assert_se(i == j); } assert_se(read(fd2, &j, sizeof(j)) == 0); } static void test_read_nr_open(void) { log_info("nr-open: %i", read_nr_open()); } static size_t validate_fds( bool opened, const int *fds, size_t n_fds) { size_t c = 0; /* Validates that fds in the specified array are one of the following three: * * 1. < 0 (test is skipped) or * 2. opened (if 'opened' param is true) or * 3. closed (if 'opened' param is false) */ for (size_t i = 0; i < n_fds; i++) { if (fds[i] < 0) continue; if (opened) assert_se(fcntl(fds[i], F_GETFD) >= 0); else assert_se(fcntl(fds[i], F_GETFD) < 0 && errno == EBADF); c++; } return c; /* Return number of fds >= 0 in the array */ } static void test_close_all_fds(void) { _cleanup_free_ int *fds = NULL, *keep = NULL; struct rlimit rl; size_t n_fds, n_keep; log_info("/* %s */", __func__); rlimit_nofile_bump(-1); assert_se(getrlimit(RLIMIT_NOFILE, &rl) >= 0); assert_se(rl.rlim_cur > 10); /* Try to use 5000 fds, but when we can't bump the rlimit to make that happen use the whole limit minus 10 */ n_fds = MIN((rl.rlim_cur & ~1U) - 10U, 5000U); assert_se((n_fds & 1U) == 0U); /* make sure even number of fds */ /* Allocate the determined number of fds, always two at a time */ assert_se(fds = new(int, n_fds)); for (size_t i = 0; i < n_fds; i += 2) assert_se(pipe2(fds + i, O_CLOEXEC) >= 0); /* Validate this worked */ assert_se(validate_fds(true, fds, n_fds) == n_fds); /* Randomized number of fds to keep, but at most every second */ n_keep = (random_u64() % (n_fds / 2)); /* Now randomly select a number of fds from the array above to keep */ assert_se(keep = new(int, n_keep)); for (size_t k = 0; k < n_keep; k++) { for (;;) { size_t p; p = random_u64() % n_fds; if (fds[p] >= 0) { keep[k] = TAKE_FD(fds[p]); break; } } } /* Check that all fds from both arrays are still open, and test how many in each are >= 0 */ assert_se(validate_fds(true, fds, n_fds) == n_fds - n_keep); assert_se(validate_fds(true, keep, n_keep) == n_keep); /* Close logging fd first, so that we don't confuse it by closing its fd */ log_close(); log_set_open_when_needed(true); /* Close all but the ones to keep */ assert_se(close_all_fds(keep, n_keep) >= 0); assert_se(validate_fds(false, fds, n_fds) == n_fds - n_keep); assert_se(validate_fds(true, keep, n_keep) == n_keep); /* Close everything else too! */ assert_se(close_all_fds(NULL, 0) >= 0); assert_se(validate_fds(false, fds, n_fds) == n_fds - n_keep); assert_se(validate_fds(false, keep, n_keep) == n_keep); log_set_open_when_needed(false); log_open(); } int main(int argc, char *argv[]) { test_setup_logging(LOG_DEBUG); test_close_many(); test_close_nointr(); test_same_fd(); test_open_serialization_fd(); test_acquire_data_fd(); test_fd_move_above_stdio(); test_rearrange_stdio(); test_fd_duplicate_data_fd(); test_read_nr_open(); test_close_all_fds(); return 0; }