// SPDX-License-Identifier: GPL-2.0 #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../kselftest_harness.h" #include "../filesystems/utils.h" #include "wrappers.h" #ifndef FD_NSFS_ROOT #define FD_NSFS_ROOT -10003 /* Root of the nsfs filesystem */ #endif #ifndef FILEID_NSFS #define FILEID_NSFS 0xf1 #endif /* * Test that initial namespaces can be reopened via file handle. * Initial namespaces should have active ref count of 1 from boot. */ TEST(init_ns_always_active) { struct file_handle *handle; int mount_id; int ret; int fd1, fd2; struct stat st1, st2; handle = malloc(sizeof(*handle) + MAX_HANDLE_SZ); ASSERT_NE(handle, NULL); /* Open initial network namespace */ fd1 = open("/proc/1/ns/net", O_RDONLY); ASSERT_GE(fd1, 0); /* Get file handle for initial namespace */ handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd1, "", handle, &mount_id, AT_EMPTY_PATH); if (ret < 0 && errno == EOPNOTSUPP) { SKIP(free(handle); close(fd1); return, "nsfs doesn't support file handles"); } ASSERT_EQ(ret, 0); /* Close the namespace fd */ close(fd1); /* Try to reopen via file handle - should succeed since init ns is always active */ fd2 = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); if (fd2 < 0 && (errno == EINVAL || errno == EOPNOTSUPP)) { SKIP(free(handle); return, "open_by_handle_at with FD_NSFS_ROOT not supported"); } ASSERT_GE(fd2, 0); /* Verify we opened the same namespace */ fd1 = open("/proc/1/ns/net", O_RDONLY); ASSERT_GE(fd1, 0); ASSERT_EQ(fstat(fd1, &st1), 0); ASSERT_EQ(fstat(fd2, &st2), 0); ASSERT_EQ(st1.st_ino, st2.st_ino); close(fd1); close(fd2); free(handle); } /* * Test namespace lifecycle: create a namespace in a child process, * get a file handle while it's active, then try to reopen after * the process exits (namespace becomes inactive). */ TEST(ns_inactive_after_exit) { struct file_handle *handle; int mount_id; int ret; int fd; int pipefd[2]; pid_t pid; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; /* Create pipe for passing file handle from child */ ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); /* Create new network namespace */ ret = unshare(CLONE_NEWNET); if (ret < 0) { close(pipefd[1]); exit(1); } /* Open our new namespace */ fd = open("/proc/self/ns/net", O_RDONLY); if (fd < 0) { close(pipefd[1]); exit(1); } /* Get file handle for the namespace */ handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd, "", handle, &mount_id, AT_EMPTY_PATH); close(fd); if (ret < 0) { close(pipefd[1]); exit(1); } /* Send handle to parent */ write(pipefd[1], buf, sizeof(*handle) + handle->handle_bytes); close(pipefd[1]); /* Exit - namespace should become inactive */ exit(0); } /* Parent process */ close(pipefd[1]); /* Read file handle from child */ ret = read(pipefd[0], buf, sizeof(buf)); close(pipefd[0]); /* Wait for child to exit */ waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; /* Try to reopen namespace - should fail with ENOENT since it's inactive */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(fd, 0); /* Should fail with ENOENT (namespace inactive) or ESTALE */ ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test that a namespace remains active while a process is using it, * even after the creating process exits. */ TEST(ns_active_with_multiple_processes) { struct file_handle *handle; int mount_id; int ret; int fd; int pipefd[2]; int syncpipe[2]; pid_t pid1, pid2; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; char sync_byte; /* Create pipes for communication */ ASSERT_EQ(pipe(pipefd), 0); ASSERT_EQ(pipe(syncpipe), 0); pid1 = fork(); ASSERT_GE(pid1, 0); if (pid1 == 0) { /* First child - creates namespace */ close(pipefd[0]); close(syncpipe[1]); /* Create new network namespace */ ret = unshare(CLONE_NEWNET); if (ret < 0) { close(pipefd[1]); close(syncpipe[0]); exit(1); } /* Open and get handle */ fd = open("/proc/self/ns/net", O_RDONLY); if (fd < 0) { close(pipefd[1]); close(syncpipe[0]); exit(1); } handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd, "", handle, &mount_id, AT_EMPTY_PATH); close(fd); if (ret < 0) { close(pipefd[1]); close(syncpipe[0]); exit(1); } /* Send handle to parent */ write(pipefd[1], buf, sizeof(*handle) + handle->handle_bytes); close(pipefd[1]); /* Wait for signal before exiting */ read(syncpipe[0], &sync_byte, 1); close(syncpipe[0]); exit(0); } /* Parent reads handle */ close(pipefd[1]); ret = read(pipefd[0], buf, sizeof(buf)); close(pipefd[0]); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; /* Create second child that will keep namespace active */ pid2 = fork(); ASSERT_GE(pid2, 0); if (pid2 == 0) { /* Second child - reopens the namespace */ close(syncpipe[0]); close(syncpipe[1]); /* Open the namespace via handle */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); if (fd < 0) { exit(1); } /* Join the namespace */ ret = setns(fd, CLONE_NEWNET); close(fd); if (ret < 0) { exit(1); } /* Sleep to keep namespace active */ sleep(1); exit(0); } /* Let second child enter the namespace */ usleep(100000); /* 100ms */ /* Signal first child to exit */ close(syncpipe[0]); sync_byte = 'X'; write(syncpipe[1], &sync_byte, 1); close(syncpipe[1]); /* Wait for first child */ waitpid(pid1, &status, 0); ASSERT_TRUE(WIFEXITED(status)); /* Namespace should still be active because second child is using it */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_GE(fd, 0); close(fd); /* Wait for second child */ waitpid(pid2, &status, 0); ASSERT_TRUE(WIFEXITED(status)); } /* * Test user namespace active ref tracking via credential lifecycle */ TEST(userns_active_ref_lifecycle) { struct file_handle *handle; int mount_id; int ret; int fd; int pipefd[2]; pid_t pid; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); /* Create new user namespace */ ret = unshare(CLONE_NEWUSER); if (ret < 0) { close(pipefd[1]); exit(1); } /* Set up uid/gid mappings */ int uid_map_fd = open("/proc/self/uid_map", O_WRONLY); int gid_map_fd = open("/proc/self/gid_map", O_WRONLY); int setgroups_fd = open("/proc/self/setgroups", O_WRONLY); if (uid_map_fd >= 0 && gid_map_fd >= 0 && setgroups_fd >= 0) { write(setgroups_fd, "deny", 4); close(setgroups_fd); char mapping[64]; snprintf(mapping, sizeof(mapping), "0 %d 1", getuid()); write(uid_map_fd, mapping, strlen(mapping)); close(uid_map_fd); snprintf(mapping, sizeof(mapping), "0 %d 1", getgid()); write(gid_map_fd, mapping, strlen(mapping)); close(gid_map_fd); } /* Get file handle */ fd = open("/proc/self/ns/user", O_RDONLY); if (fd < 0) { close(pipefd[1]); exit(1); } handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd, "", handle, &mount_id, AT_EMPTY_PATH); close(fd); if (ret < 0) { close(pipefd[1]); exit(1); } /* Send handle to parent */ write(pipefd[1], buf, sizeof(*handle) + handle->handle_bytes); close(pipefd[1]); exit(0); } /* Parent */ close(pipefd[1]); ret = read(pipefd[0], buf, sizeof(buf)); close(pipefd[0]); waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; /* Namespace should be inactive after all tasks exit */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(fd, 0); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test PID namespace active ref tracking */ TEST(pidns_active_ref_lifecycle) { struct file_handle *handle; int mount_id; int ret; int fd; int pipefd[2]; pid_t pid; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); /* Create new PID namespace */ ret = unshare(CLONE_NEWPID); if (ret < 0) { close(pipefd[1]); exit(1); } /* Fork to actually enter the PID namespace */ pid_t child = fork(); if (child < 0) { close(pipefd[1]); exit(1); } if (child == 0) { /* Grandchild - in new PID namespace */ fd = open("/proc/self/ns/pid", O_RDONLY); if (fd < 0) { exit(1); } handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd, "", handle, &mount_id, AT_EMPTY_PATH); close(fd); if (ret < 0) { exit(1); } /* Send handle to grandparent */ write(pipefd[1], buf, sizeof(*handle) + handle->handle_bytes); close(pipefd[1]); exit(0); } /* Wait for grandchild */ waitpid(child, NULL, 0); exit(0); } /* Parent */ close(pipefd[1]); ret = read(pipefd[0], buf, sizeof(buf)); close(pipefd[0]); waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; /* Namespace should be inactive after all processes exit */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(fd, 0); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test that an open file descriptor keeps a namespace active. * Even after the creating process exits, the namespace should remain * active as long as an fd is held open. */ TEST(ns_fd_keeps_active) { struct file_handle *handle; int mount_id; int ret; int nsfd; int pipe_child_ready[2]; int pipe_parent_ready[2]; pid_t pid; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; char sync_byte; char proc_path[64]; ASSERT_EQ(pipe(pipe_child_ready), 0); ASSERT_EQ(pipe(pipe_parent_ready), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipe_child_ready[0]); close(pipe_parent_ready[1]); TH_LOG("Child: creating new network namespace"); /* Create new network namespace */ ret = unshare(CLONE_NEWNET); if (ret < 0) { TH_LOG("Child: unshare(CLONE_NEWNET) failed: %s", strerror(errno)); close(pipe_child_ready[1]); close(pipe_parent_ready[0]); exit(1); } TH_LOG("Child: network namespace created successfully"); /* Get file handle for the namespace */ nsfd = open("/proc/self/ns/net", O_RDONLY); if (nsfd < 0) { TH_LOG("Child: failed to open /proc/self/ns/net: %s", strerror(errno)); close(pipe_child_ready[1]); close(pipe_parent_ready[0]); exit(1); } TH_LOG("Child: opened namespace fd %d", nsfd); handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(nsfd, "", handle, &mount_id, AT_EMPTY_PATH); close(nsfd); if (ret < 0) { TH_LOG("Child: name_to_handle_at failed: %s", strerror(errno)); close(pipe_child_ready[1]); close(pipe_parent_ready[0]); exit(1); } TH_LOG("Child: got file handle (bytes=%u)", handle->handle_bytes); /* Send file handle to parent */ ret = write(pipe_child_ready[1], buf, sizeof(*handle) + handle->handle_bytes); TH_LOG("Child: sent %d bytes of file handle to parent", ret); close(pipe_child_ready[1]); /* Wait for parent to open the fd */ TH_LOG("Child: waiting for parent to open fd"); ret = read(pipe_parent_ready[0], &sync_byte, 1); close(pipe_parent_ready[0]); TH_LOG("Child: parent signaled (read %d bytes), exiting now", ret); /* Exit - namespace should stay active because parent holds fd */ exit(0); } /* Parent process */ close(pipe_child_ready[1]); close(pipe_parent_ready[0]); TH_LOG("Parent: reading file handle from child"); /* Read file handle from child */ ret = read(pipe_child_ready[0], buf, sizeof(buf)); close(pipe_child_ready[0]); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; TH_LOG("Parent: received %d bytes, handle size=%u", ret, handle->handle_bytes); /* Open the child's namespace while it's still alive */ snprintf(proc_path, sizeof(proc_path), "/proc/%d/ns/net", pid); TH_LOG("Parent: opening child's namespace at %s", proc_path); nsfd = open(proc_path, O_RDONLY); if (nsfd < 0) { TH_LOG("Parent: failed to open %s: %s", proc_path, strerror(errno)); close(pipe_parent_ready[1]); kill(pid, SIGKILL); waitpid(pid, NULL, 0); SKIP(return, "Failed to open child's namespace"); } TH_LOG("Parent: opened child's namespace, got fd %d", nsfd); /* Signal child that we have the fd */ sync_byte = 'G'; write(pipe_parent_ready[1], &sync_byte, 1); close(pipe_parent_ready[1]); TH_LOG("Parent: signaled child that we have the fd"); /* Wait for child to exit */ waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); TH_LOG("Child exited, parent holds fd %d to namespace", nsfd); /* * Namespace should still be ACTIVE because we hold an fd. * We should be able to reopen it via file handle. */ TH_LOG("Attempting to reopen namespace via file handle (should succeed - fd held)"); int fd2 = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_GE(fd2, 0); TH_LOG("Successfully reopened namespace via file handle, got fd %d", fd2); /* Verify it's the same namespace */ struct stat st1, st2; ASSERT_EQ(fstat(nsfd, &st1), 0); ASSERT_EQ(fstat(fd2, &st2), 0); TH_LOG("Namespace inodes: nsfd=%lu, fd2=%lu", st1.st_ino, st2.st_ino); ASSERT_EQ(st1.st_ino, st2.st_ino); close(fd2); /* Now close the fd - namespace should become inactive */ TH_LOG("Closing fd %d - namespace should become inactive", nsfd); close(nsfd); /* Now reopening should fail - namespace is inactive */ TH_LOG("Attempting to reopen namespace via file handle (should fail - inactive)"); fd2 = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(fd2, 0); /* Should fail with ENOENT (inactive) or ESTALE (gone) */ TH_LOG("Reopen failed as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test hierarchical active reference propagation. * When a child namespace is active, its owning user namespace should also * be active automatically due to hierarchical active reference propagation. * This ensures parents are always reachable when children are active. */ TEST(ns_parent_always_reachable) { struct file_handle *parent_handle, *child_handle; int ret; int child_nsfd; int pipefd[2]; pid_t pid; int status; __u64 parent_id, child_id; char parent_buf[sizeof(*parent_handle) + MAX_HANDLE_SZ]; char child_buf[sizeof(*child_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); TH_LOG("Child: creating parent user namespace and setting up mappings"); /* Create parent user namespace with mappings */ ret = setup_userns(); if (ret < 0) { TH_LOG("Child: setup_userns() for parent failed: %s", strerror(errno)); close(pipefd[1]); exit(1); } TH_LOG("Child: parent user namespace created, now uid=%d gid=%d", getuid(), getgid()); /* Get namespace ID for parent user namespace */ int parent_fd = open("/proc/self/ns/user", O_RDONLY); if (parent_fd < 0) { TH_LOG("Child: failed to open parent /proc/self/ns/user: %s", strerror(errno)); close(pipefd[1]); exit(1); } TH_LOG("Child: opened parent userns fd %d", parent_fd); if (ioctl(parent_fd, NS_GET_ID, &parent_id) < 0) { TH_LOG("Child: NS_GET_ID for parent failed: %s", strerror(errno)); close(parent_fd); close(pipefd[1]); exit(1); } close(parent_fd); TH_LOG("Child: got parent namespace ID %llu", (unsigned long long)parent_id); /* Create child user namespace within parent */ TH_LOG("Child: creating nested child user namespace"); ret = setup_userns(); if (ret < 0) { TH_LOG("Child: setup_userns() for child failed: %s", strerror(errno)); close(pipefd[1]); exit(1); } TH_LOG("Child: nested child user namespace created, uid=%d gid=%d", getuid(), getgid()); /* Get namespace ID for child user namespace */ int child_fd = open("/proc/self/ns/user", O_RDONLY); if (child_fd < 0) { TH_LOG("Child: failed to open child /proc/self/ns/user: %s", strerror(errno)); close(pipefd[1]); exit(1); } TH_LOG("Child: opened child userns fd %d", child_fd); if (ioctl(child_fd, NS_GET_ID, &child_id) < 0) { TH_LOG("Child: NS_GET_ID for child failed: %s", strerror(errno)); close(child_fd); close(pipefd[1]); exit(1); } close(child_fd); TH_LOG("Child: got child namespace ID %llu", (unsigned long long)child_id); /* Send both namespace IDs to parent */ TH_LOG("Child: sending both namespace IDs to parent"); write(pipefd[1], &parent_id, sizeof(parent_id)); write(pipefd[1], &child_id, sizeof(child_id)); close(pipefd[1]); TH_LOG("Child: exiting - parent userns should become inactive"); /* Exit - parent user namespace should become inactive */ exit(0); } /* Parent process */ close(pipefd[1]); TH_LOG("Parent: reading both namespace IDs from child"); /* Read both namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &parent_id, sizeof(parent_id)); if (ret != sizeof(parent_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read parent namespace ID from child"); } ret = read(pipefd[0], &child_id, sizeof(child_id)); close(pipefd[0]); if (ret != sizeof(child_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read child namespace ID from child"); } TH_LOG("Parent: received parent_id=%llu, child_id=%llu", (unsigned long long)parent_id, (unsigned long long)child_id); /* Construct file handles from namespace IDs */ parent_handle = (struct file_handle *)parent_buf; parent_handle->handle_bytes = sizeof(struct nsfs_file_handle); parent_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *parent_fh = (struct nsfs_file_handle *)parent_handle->f_handle; parent_fh->ns_id = parent_id; parent_fh->ns_type = 0; parent_fh->ns_inum = 0; child_handle = (struct file_handle *)child_buf; child_handle->handle_bytes = sizeof(struct nsfs_file_handle); child_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *child_fh = (struct nsfs_file_handle *)child_handle->f_handle; child_fh->ns_id = child_id; child_fh->ns_type = 0; child_fh->ns_inum = 0; TH_LOG("Parent: opening child namespace BEFORE child exits"); /* Open child namespace while child is still alive to keep it active */ child_nsfd = open_by_handle_at(FD_NSFS_ROOT, child_handle, O_RDONLY); if (child_nsfd < 0) { TH_LOG("Failed to open child namespace: %s (errno=%d)", strerror(errno), errno); waitpid(pid, NULL, 0); SKIP(return, "Failed to open child namespace"); } TH_LOG("Opened child namespace fd %d", child_nsfd); /* Now wait for child to exit */ TH_LOG("Parent: waiting for child to exit"); waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); TH_LOG("Child process exited, parent holds fd to child namespace"); /* * With hierarchical active reference propagation: * Since the child namespace is active (parent process holds fd), * the parent user namespace should ALSO be active automatically. * This is because when we took an active reference on the child, * it propagated up to the owning user namespace. */ TH_LOG("Attempting to reopen parent namespace (should SUCCEED - hierarchical propagation)"); int parent_fd = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_GE(parent_fd, 0); TH_LOG("SUCCESS: Parent namespace is active (fd=%d) due to active child", parent_fd); /* Verify we can also get parent via NS_GET_USERNS */ TH_LOG("Verifying NS_GET_USERNS also works"); int parent_fd2 = ioctl(child_nsfd, NS_GET_USERNS); if (parent_fd2 < 0) { close(parent_fd); close(child_nsfd); TH_LOG("NS_GET_USERNS failed: %s (errno=%d)", strerror(errno), errno); SKIP(return, "NS_GET_USERNS not supported or failed"); } TH_LOG("NS_GET_USERNS succeeded, got parent fd %d", parent_fd2); /* Verify both methods give us the same namespace */ struct stat st1, st2; ASSERT_EQ(fstat(parent_fd, &st1), 0); ASSERT_EQ(fstat(parent_fd2, &st2), 0); TH_LOG("Parent namespace inodes: parent_fd=%lu, parent_fd2=%lu", st1.st_ino, st2.st_ino); ASSERT_EQ(st1.st_ino, st2.st_ino); /* * Close child fd - parent should remain active because we still * hold direct references to it (parent_fd and parent_fd2). */ TH_LOG("Closing child fd - parent should remain active (direct refs held)"); close(child_nsfd); /* Parent should still be openable */ TH_LOG("Verifying parent still active via file handle"); int parent_fd3 = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_GE(parent_fd3, 0); close(parent_fd3); TH_LOG("Closing all fds to parent namespace"); close(parent_fd); close(parent_fd2); /* Both should now be inactive */ TH_LOG("Attempting to reopen parent (should fail - inactive, no refs)"); parent_fd = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_LT(parent_fd, 0); TH_LOG("Parent inactive as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test that bind mounts keep namespaces in the tree even when inactive */ TEST(ns_bind_mount_keeps_in_tree) { struct file_handle *handle; int mount_id; int ret; int fd; int pipefd[2]; pid_t pid; int status; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; char tmpfile[] = "/tmp/ns-test-XXXXXX"; int tmpfd; /* Create temporary file for bind mount */ tmpfd = mkstemp(tmpfile); if (tmpfd < 0) { SKIP(return, "Cannot create temporary file"); } close(tmpfd); ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); /* Unshare mount namespace and make mounts private to avoid propagation */ ret = unshare(CLONE_NEWNS); if (ret < 0) { close(pipefd[1]); unlink(tmpfile); exit(1); } ret = mount(NULL, "/", NULL, MS_PRIVATE | MS_REC, NULL); if (ret < 0) { close(pipefd[1]); unlink(tmpfile); exit(1); } /* Create new network namespace */ ret = unshare(CLONE_NEWNET); if (ret < 0) { close(pipefd[1]); unlink(tmpfile); exit(1); } /* Bind mount the namespace */ ret = mount("/proc/self/ns/net", tmpfile, NULL, MS_BIND, NULL); if (ret < 0) { close(pipefd[1]); unlink(tmpfile); exit(1); } /* Get file handle */ fd = open("/proc/self/ns/net", O_RDONLY); if (fd < 0) { umount(tmpfile); close(pipefd[1]); unlink(tmpfile); exit(1); } handle = (struct file_handle *)buf; handle->handle_bytes = MAX_HANDLE_SZ; ret = name_to_handle_at(fd, "", handle, &mount_id, AT_EMPTY_PATH); close(fd); if (ret < 0) { umount(tmpfile); close(pipefd[1]); unlink(tmpfile); exit(1); } /* Send handle to parent */ write(pipefd[1], buf, sizeof(*handle) + handle->handle_bytes); close(pipefd[1]); exit(0); } /* Parent */ close(pipefd[1]); ret = read(pipefd[0], buf, sizeof(buf)); close(pipefd[0]); waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); ASSERT_GT(ret, 0); handle = (struct file_handle *)buf; /* * Namespace should be inactive but still in tree due to bind mount. * Reopening should fail with ENOENT (inactive) not ESTALE (not in tree). */ fd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(fd, 0); /* Should be ENOENT (inactive) since bind mount keeps it in tree */ if (errno != ENOENT && errno != ESTALE) { TH_LOG("Unexpected error: %d", errno); } /* Cleanup */ umount(tmpfile); unlink(tmpfile); } /* * Test multi-level hierarchy (3+ levels deep). * Grandparent → Parent → Child * When child is active, both parent AND grandparent should be active. */ TEST(ns_multilevel_hierarchy) { struct file_handle *gp_handle, *p_handle, *c_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 gp_id, p_id, c_id; char gp_buf[sizeof(*gp_handle) + MAX_HANDLE_SZ]; char p_buf[sizeof(*p_handle) + MAX_HANDLE_SZ]; char c_buf[sizeof(*c_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); /* Create grandparent user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int gp_fd = open("/proc/self/ns/user", O_RDONLY); if (gp_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(gp_fd, NS_GET_ID, &gp_id) < 0) { close(gp_fd); close(pipefd[1]); exit(1); } close(gp_fd); /* Create parent user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int p_fd = open("/proc/self/ns/user", O_RDONLY); if (p_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(p_fd, NS_GET_ID, &p_id) < 0) { close(p_fd); close(pipefd[1]); exit(1); } close(p_fd); /* Create child user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int c_fd = open("/proc/self/ns/user", O_RDONLY); if (c_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(c_fd, NS_GET_ID, &c_id) < 0) { close(c_fd); close(pipefd[1]); exit(1); } close(c_fd); /* Send all three namespace IDs */ write(pipefd[1], &gp_id, sizeof(gp_id)); write(pipefd[1], &p_id, sizeof(p_id)); write(pipefd[1], &c_id, sizeof(c_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &gp_id, sizeof(gp_id)); if (ret != sizeof(gp_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read grandparent namespace ID from child"); } ret = read(pipefd[0], &p_id, sizeof(p_id)); if (ret != sizeof(p_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read parent namespace ID from child"); } ret = read(pipefd[0], &c_id, sizeof(c_id)); close(pipefd[0]); if (ret != sizeof(c_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read child namespace ID from child"); } /* Construct file handles from namespace IDs */ gp_handle = (struct file_handle *)gp_buf; gp_handle->handle_bytes = sizeof(struct nsfs_file_handle); gp_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *gp_fh = (struct nsfs_file_handle *)gp_handle->f_handle; gp_fh->ns_id = gp_id; gp_fh->ns_type = 0; gp_fh->ns_inum = 0; p_handle = (struct file_handle *)p_buf; p_handle->handle_bytes = sizeof(struct nsfs_file_handle); p_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *p_fh = (struct nsfs_file_handle *)p_handle->f_handle; p_fh->ns_id = p_id; p_fh->ns_type = 0; p_fh->ns_inum = 0; c_handle = (struct file_handle *)c_buf; c_handle->handle_bytes = sizeof(struct nsfs_file_handle); c_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *c_fh = (struct nsfs_file_handle *)c_handle->f_handle; c_fh->ns_id = c_id; c_fh->ns_type = 0; c_fh->ns_inum = 0; /* Open child before process exits */ int c_fd = open_by_handle_at(FD_NSFS_ROOT, c_handle, O_RDONLY); if (c_fd < 0) { waitpid(pid, NULL, 0); SKIP(return, "Failed to open child namespace"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* * With 3-level hierarchy and child active: * - Child is active (we hold fd) * - Parent should be active (propagated from child) * - Grandparent should be active (propagated from parent) */ TH_LOG("Testing parent active when child is active"); int p_fd = open_by_handle_at(FD_NSFS_ROOT, p_handle, O_RDONLY); ASSERT_GE(p_fd, 0); TH_LOG("Testing grandparent active when child is active"); int gp_fd = open_by_handle_at(FD_NSFS_ROOT, gp_handle, O_RDONLY); ASSERT_GE(gp_fd, 0); close(c_fd); close(p_fd); close(gp_fd); } /* * Test multiple children sharing same parent. * Parent should stay active as long as ANY child is active. */ TEST(ns_multiple_children_same_parent) { struct file_handle *p_handle, *c1_handle, *c2_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 p_id, c1_id, c2_id; char p_buf[sizeof(*p_handle) + MAX_HANDLE_SZ]; char c1_buf[sizeof(*c1_handle) + MAX_HANDLE_SZ]; char c2_buf[sizeof(*c2_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); /* Create parent user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int p_fd = open("/proc/self/ns/user", O_RDONLY); if (p_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(p_fd, NS_GET_ID, &p_id) < 0) { close(p_fd); close(pipefd[1]); exit(1); } close(p_fd); /* Create first child user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int c1_fd = open("/proc/self/ns/user", O_RDONLY); if (c1_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(c1_fd, NS_GET_ID, &c1_id) < 0) { close(c1_fd); close(pipefd[1]); exit(1); } close(c1_fd); /* Return to parent user namespace and create second child */ /* We can't actually do this easily, so let's create a sibling namespace * by creating a network namespace instead */ if (unshare(CLONE_NEWNET) < 0) { close(pipefd[1]); exit(1); } int c2_fd = open("/proc/self/ns/net", O_RDONLY); if (c2_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(c2_fd, NS_GET_ID, &c2_id) < 0) { close(c2_fd); close(pipefd[1]); exit(1); } close(c2_fd); /* Send all namespace IDs */ write(pipefd[1], &p_id, sizeof(p_id)); write(pipefd[1], &c1_id, sizeof(c1_id)); write(pipefd[1], &c2_id, sizeof(c2_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &p_id, sizeof(p_id)); if (ret != sizeof(p_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read parent namespace ID"); } ret = read(pipefd[0], &c1_id, sizeof(c1_id)); if (ret != sizeof(c1_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read first child namespace ID"); } ret = read(pipefd[0], &c2_id, sizeof(c2_id)); close(pipefd[0]); if (ret != sizeof(c2_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read second child namespace ID"); } /* Construct file handles from namespace IDs */ p_handle = (struct file_handle *)p_buf; p_handle->handle_bytes = sizeof(struct nsfs_file_handle); p_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *p_fh = (struct nsfs_file_handle *)p_handle->f_handle; p_fh->ns_id = p_id; p_fh->ns_type = 0; p_fh->ns_inum = 0; c1_handle = (struct file_handle *)c1_buf; c1_handle->handle_bytes = sizeof(struct nsfs_file_handle); c1_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *c1_fh = (struct nsfs_file_handle *)c1_handle->f_handle; c1_fh->ns_id = c1_id; c1_fh->ns_type = 0; c1_fh->ns_inum = 0; c2_handle = (struct file_handle *)c2_buf; c2_handle->handle_bytes = sizeof(struct nsfs_file_handle); c2_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *c2_fh = (struct nsfs_file_handle *)c2_handle->f_handle; c2_fh->ns_id = c2_id; c2_fh->ns_type = 0; c2_fh->ns_inum = 0; /* Open both children before process exits */ int c1_fd = open_by_handle_at(FD_NSFS_ROOT, c1_handle, O_RDONLY); int c2_fd = open_by_handle_at(FD_NSFS_ROOT, c2_handle, O_RDONLY); if (c1_fd < 0 || c2_fd < 0) { if (c1_fd >= 0) close(c1_fd); if (c2_fd >= 0) close(c2_fd); waitpid(pid, NULL, 0); SKIP(return, "Failed to open child namespaces"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* Parent should be active (both children active) */ TH_LOG("Both children active - parent should be active"); int p_fd = open_by_handle_at(FD_NSFS_ROOT, p_handle, O_RDONLY); ASSERT_GE(p_fd, 0); close(p_fd); /* Close first child - parent should STILL be active */ TH_LOG("Closing first child - parent should still be active"); close(c1_fd); p_fd = open_by_handle_at(FD_NSFS_ROOT, p_handle, O_RDONLY); ASSERT_GE(p_fd, 0); close(p_fd); /* Close second child - NOW parent should become inactive */ TH_LOG("Closing second child - parent should become inactive"); close(c2_fd); p_fd = open_by_handle_at(FD_NSFS_ROOT, p_handle, O_RDONLY); ASSERT_LT(p_fd, 0); } /* * Test that different namespace types with same owner all contribute * active references to the owning user namespace. */ TEST(ns_different_types_same_owner) { struct file_handle *u_handle, *n_handle, *ut_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 u_id, n_id, ut_id; char u_buf[sizeof(*u_handle) + MAX_HANDLE_SZ]; char n_buf[sizeof(*n_handle) + MAX_HANDLE_SZ]; char ut_buf[sizeof(*ut_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); /* Create user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int u_fd = open("/proc/self/ns/user", O_RDONLY); if (u_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(u_fd, NS_GET_ID, &u_id) < 0) { close(u_fd); close(pipefd[1]); exit(1); } close(u_fd); /* Create network namespace (owned by user namespace) */ if (unshare(CLONE_NEWNET) < 0) { close(pipefd[1]); exit(1); } int n_fd = open("/proc/self/ns/net", O_RDONLY); if (n_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(n_fd, NS_GET_ID, &n_id) < 0) { close(n_fd); close(pipefd[1]); exit(1); } close(n_fd); /* Create UTS namespace (also owned by user namespace) */ if (unshare(CLONE_NEWUTS) < 0) { close(pipefd[1]); exit(1); } int ut_fd = open("/proc/self/ns/uts", O_RDONLY); if (ut_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ut_fd, NS_GET_ID, &ut_id) < 0) { close(ut_fd); close(pipefd[1]); exit(1); } close(ut_fd); /* Send all namespace IDs */ write(pipefd[1], &u_id, sizeof(u_id)); write(pipefd[1], &n_id, sizeof(n_id)); write(pipefd[1], &ut_id, sizeof(ut_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &u_id, sizeof(u_id)); if (ret != sizeof(u_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user namespace ID"); } ret = read(pipefd[0], &n_id, sizeof(n_id)); if (ret != sizeof(n_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read network namespace ID"); } ret = read(pipefd[0], &ut_id, sizeof(ut_id)); close(pipefd[0]); if (ret != sizeof(ut_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read UTS namespace ID"); } /* Construct file handles from namespace IDs */ u_handle = (struct file_handle *)u_buf; u_handle->handle_bytes = sizeof(struct nsfs_file_handle); u_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *u_fh = (struct nsfs_file_handle *)u_handle->f_handle; u_fh->ns_id = u_id; u_fh->ns_type = 0; u_fh->ns_inum = 0; n_handle = (struct file_handle *)n_buf; n_handle->handle_bytes = sizeof(struct nsfs_file_handle); n_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *n_fh = (struct nsfs_file_handle *)n_handle->f_handle; n_fh->ns_id = n_id; n_fh->ns_type = 0; n_fh->ns_inum = 0; ut_handle = (struct file_handle *)ut_buf; ut_handle->handle_bytes = sizeof(struct nsfs_file_handle); ut_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ut_fh = (struct nsfs_file_handle *)ut_handle->f_handle; ut_fh->ns_id = ut_id; ut_fh->ns_type = 0; ut_fh->ns_inum = 0; /* Open both non-user namespaces before process exits */ int n_fd = open_by_handle_at(FD_NSFS_ROOT, n_handle, O_RDONLY); int ut_fd = open_by_handle_at(FD_NSFS_ROOT, ut_handle, O_RDONLY); if (n_fd < 0 || ut_fd < 0) { if (n_fd >= 0) close(n_fd); if (ut_fd >= 0) close(ut_fd); waitpid(pid, NULL, 0); SKIP(return, "Failed to open namespaces"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* * Both network and UTS namespaces are active. * User namespace should be active (gets 2 active refs). */ TH_LOG("Both net and uts active - user namespace should be active"); int u_fd = open_by_handle_at(FD_NSFS_ROOT, u_handle, O_RDONLY); ASSERT_GE(u_fd, 0); close(u_fd); /* Close network namespace - user namespace should STILL be active */ TH_LOG("Closing network ns - user ns should still be active (uts still active)"); close(n_fd); u_fd = open_by_handle_at(FD_NSFS_ROOT, u_handle, O_RDONLY); ASSERT_GE(u_fd, 0); close(u_fd); /* Close UTS namespace - user namespace should become inactive */ TH_LOG("Closing uts ns - user ns should become inactive"); close(ut_fd); u_fd = open_by_handle_at(FD_NSFS_ROOT, u_handle, O_RDONLY); ASSERT_LT(u_fd, 0); } /* * Test hierarchical propagation with deep namespace hierarchy. * Create: init_user_ns -> user_A -> user_B -> net_ns * When net_ns is active, both user_A and user_B should be active. * This verifies the conditional recursion in __ns_ref_active_put() works. */ TEST(ns_deep_hierarchy_propagation) { struct file_handle *ua_handle, *ub_handle, *net_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 ua_id, ub_id, net_id; char ua_buf[sizeof(*ua_handle) + MAX_HANDLE_SZ]; char ub_buf[sizeof(*ub_handle) + MAX_HANDLE_SZ]; char net_buf[sizeof(*net_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); /* Create user_A -> user_B -> net hierarchy */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int ua_fd = open("/proc/self/ns/user", O_RDONLY); if (ua_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ua_fd, NS_GET_ID, &ua_id) < 0) { close(ua_fd); close(pipefd[1]); exit(1); } close(ua_fd); if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int ub_fd = open("/proc/self/ns/user", O_RDONLY); if (ub_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ub_fd, NS_GET_ID, &ub_id) < 0) { close(ub_fd); close(pipefd[1]); exit(1); } close(ub_fd); if (unshare(CLONE_NEWNET) < 0) { close(pipefd[1]); exit(1); } int net_fd = open("/proc/self/ns/net", O_RDONLY); if (net_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(net_fd, NS_GET_ID, &net_id) < 0) { close(net_fd); close(pipefd[1]); exit(1); } close(net_fd); /* Send all three namespace IDs */ write(pipefd[1], &ua_id, sizeof(ua_id)); write(pipefd[1], &ub_id, sizeof(ub_id)); write(pipefd[1], &net_id, sizeof(net_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &ua_id, sizeof(ua_id)); if (ret != sizeof(ua_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user_A namespace ID"); } ret = read(pipefd[0], &ub_id, sizeof(ub_id)); if (ret != sizeof(ub_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user_B namespace ID"); } ret = read(pipefd[0], &net_id, sizeof(net_id)); close(pipefd[0]); if (ret != sizeof(net_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read network namespace ID"); } /* Construct file handles from namespace IDs */ ua_handle = (struct file_handle *)ua_buf; ua_handle->handle_bytes = sizeof(struct nsfs_file_handle); ua_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ua_fh = (struct nsfs_file_handle *)ua_handle->f_handle; ua_fh->ns_id = ua_id; ua_fh->ns_type = 0; ua_fh->ns_inum = 0; ub_handle = (struct file_handle *)ub_buf; ub_handle->handle_bytes = sizeof(struct nsfs_file_handle); ub_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ub_fh = (struct nsfs_file_handle *)ub_handle->f_handle; ub_fh->ns_id = ub_id; ub_fh->ns_type = 0; ub_fh->ns_inum = 0; net_handle = (struct file_handle *)net_buf; net_handle->handle_bytes = sizeof(struct nsfs_file_handle); net_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *net_fh = (struct nsfs_file_handle *)net_handle->f_handle; net_fh->ns_id = net_id; net_fh->ns_type = 0; net_fh->ns_inum = 0; /* Open net_ns before child exits to keep it active */ int net_fd = open_by_handle_at(FD_NSFS_ROOT, net_handle, O_RDONLY); if (net_fd < 0) { waitpid(pid, NULL, 0); SKIP(return, "Failed to open network namespace"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* With net_ns active, both user_A and user_B should be active */ TH_LOG("Testing user_B active (net_ns active causes propagation)"); int ub_fd = open_by_handle_at(FD_NSFS_ROOT, ub_handle, O_RDONLY); ASSERT_GE(ub_fd, 0); TH_LOG("Testing user_A active (propagated through user_B)"); int ua_fd = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_GE(ua_fd, 0); /* Close net_ns - user_B should stay active (we hold direct ref) */ TH_LOG("Closing net_ns, user_B should remain active (direct ref held)"); close(net_fd); int ub_fd2 = open_by_handle_at(FD_NSFS_ROOT, ub_handle, O_RDONLY); ASSERT_GE(ub_fd2, 0); close(ub_fd2); /* Close user_B - user_A should stay active (we hold direct ref) */ TH_LOG("Closing user_B, user_A should remain active (direct ref held)"); close(ub_fd); int ua_fd2 = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_GE(ua_fd2, 0); close(ua_fd2); /* Close user_A - everything should become inactive */ TH_LOG("Closing user_A, all should become inactive"); close(ua_fd); /* All should now be inactive */ ua_fd = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_LT(ua_fd, 0); } /* * Test that parent stays active as long as ANY child is active. * Create parent user namespace with two child net namespaces. * Parent should remain active until BOTH children are inactive. */ TEST(ns_parent_multiple_children_refcount) { struct file_handle *parent_handle, *net1_handle, *net2_handle; int ret, pipefd[2], syncpipe[2]; pid_t pid; int status; __u64 p_id, n1_id, n2_id; char p_buf[sizeof(*parent_handle) + MAX_HANDLE_SZ]; char n1_buf[sizeof(*net1_handle) + MAX_HANDLE_SZ]; char n2_buf[sizeof(*net2_handle) + MAX_HANDLE_SZ]; char sync_byte; ASSERT_EQ(pipe(pipefd), 0); ASSERT_EQ(pipe(syncpipe), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); close(syncpipe[1]); /* Create parent user namespace */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int p_fd = open("/proc/self/ns/user", O_RDONLY); if (p_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(p_fd, NS_GET_ID, &p_id) < 0) { close(p_fd); close(pipefd[1]); exit(1); } close(p_fd); /* Create first network namespace */ if (unshare(CLONE_NEWNET) < 0) { close(pipefd[1]); close(syncpipe[0]); exit(1); } int n1_fd = open("/proc/self/ns/net", O_RDONLY); if (n1_fd < 0) { close(pipefd[1]); close(syncpipe[0]); exit(1); } if (ioctl(n1_fd, NS_GET_ID, &n1_id) < 0) { close(n1_fd); close(pipefd[1]); close(syncpipe[0]); exit(1); } /* Keep n1_fd open so first namespace stays active */ /* Create second network namespace */ if (unshare(CLONE_NEWNET) < 0) { close(n1_fd); close(pipefd[1]); close(syncpipe[0]); exit(1); } int n2_fd = open("/proc/self/ns/net", O_RDONLY); if (n2_fd < 0) { close(n1_fd); close(pipefd[1]); close(syncpipe[0]); exit(1); } if (ioctl(n2_fd, NS_GET_ID, &n2_id) < 0) { close(n1_fd); close(n2_fd); close(pipefd[1]); close(syncpipe[0]); exit(1); } /* Keep both n1_fd and n2_fd open */ /* Send all namespace IDs */ write(pipefd[1], &p_id, sizeof(p_id)); write(pipefd[1], &n1_id, sizeof(n1_id)); write(pipefd[1], &n2_id, sizeof(n2_id)); close(pipefd[1]); /* Wait for parent to signal before exiting */ read(syncpipe[0], &sync_byte, 1); close(syncpipe[0]); exit(0); } close(pipefd[1]); close(syncpipe[0]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &p_id, sizeof(p_id)); if (ret != sizeof(p_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read parent namespace ID"); } ret = read(pipefd[0], &n1_id, sizeof(n1_id)); if (ret != sizeof(n1_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read first network namespace ID"); } ret = read(pipefd[0], &n2_id, sizeof(n2_id)); close(pipefd[0]); if (ret != sizeof(n2_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read second network namespace ID"); } /* Construct file handles from namespace IDs */ parent_handle = (struct file_handle *)p_buf; parent_handle->handle_bytes = sizeof(struct nsfs_file_handle); parent_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *p_fh = (struct nsfs_file_handle *)parent_handle->f_handle; p_fh->ns_id = p_id; p_fh->ns_type = 0; p_fh->ns_inum = 0; net1_handle = (struct file_handle *)n1_buf; net1_handle->handle_bytes = sizeof(struct nsfs_file_handle); net1_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *n1_fh = (struct nsfs_file_handle *)net1_handle->f_handle; n1_fh->ns_id = n1_id; n1_fh->ns_type = 0; n1_fh->ns_inum = 0; net2_handle = (struct file_handle *)n2_buf; net2_handle->handle_bytes = sizeof(struct nsfs_file_handle); net2_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *n2_fh = (struct nsfs_file_handle *)net2_handle->f_handle; n2_fh->ns_id = n2_id; n2_fh->ns_type = 0; n2_fh->ns_inum = 0; /* Open both net namespaces while child is still alive */ int n1_fd = open_by_handle_at(FD_NSFS_ROOT, net1_handle, O_RDONLY); int n2_fd = open_by_handle_at(FD_NSFS_ROOT, net2_handle, O_RDONLY); if (n1_fd < 0 || n2_fd < 0) { if (n1_fd >= 0) close(n1_fd); if (n2_fd >= 0) close(n2_fd); sync_byte = 'G'; write(syncpipe[1], &sync_byte, 1); close(syncpipe[1]); waitpid(pid, NULL, 0); SKIP(return, "Failed to open net namespaces"); } /* Signal child that we have opened the namespaces */ sync_byte = 'G'; write(syncpipe[1], &sync_byte, 1); close(syncpipe[1]); /* Wait for child to exit */ waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* Parent should be active (has 2 active children) */ TH_LOG("Both net namespaces active - parent should be active"); int p_fd = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_GE(p_fd, 0); close(p_fd); /* Close first net namespace - parent should STILL be active */ TH_LOG("Closing first net ns - parent should still be active"); close(n1_fd); p_fd = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_GE(p_fd, 0); close(p_fd); /* Close second net namespace - parent should become inactive */ TH_LOG("Closing second net ns - parent should become inactive"); close(n2_fd); p_fd = open_by_handle_at(FD_NSFS_ROOT, parent_handle, O_RDONLY); ASSERT_LT(p_fd, 0); } /* * Test that user namespace as a child also propagates correctly. * Create user_A -> user_B, verify when user_B is active that user_A * is also active. This is different from non-user namespace children. */ TEST(ns_userns_child_propagation) { struct file_handle *ua_handle, *ub_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 ua_id, ub_id; char ua_buf[sizeof(*ua_handle) + MAX_HANDLE_SZ]; char ub_buf[sizeof(*ub_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); /* Create user_A */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int ua_fd = open("/proc/self/ns/user", O_RDONLY); if (ua_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ua_fd, NS_GET_ID, &ua_id) < 0) { close(ua_fd); close(pipefd[1]); exit(1); } close(ua_fd); /* Create user_B (child of user_A) */ if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int ub_fd = open("/proc/self/ns/user", O_RDONLY); if (ub_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ub_fd, NS_GET_ID, &ub_id) < 0) { close(ub_fd); close(pipefd[1]); exit(1); } close(ub_fd); /* Send both namespace IDs */ write(pipefd[1], &ua_id, sizeof(ua_id)); write(pipefd[1], &ub_id, sizeof(ub_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read both namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &ua_id, sizeof(ua_id)); if (ret != sizeof(ua_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user_A namespace ID"); } ret = read(pipefd[0], &ub_id, sizeof(ub_id)); close(pipefd[0]); if (ret != sizeof(ub_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read user_B namespace ID"); } /* Construct file handles from namespace IDs */ ua_handle = (struct file_handle *)ua_buf; ua_handle->handle_bytes = sizeof(struct nsfs_file_handle); ua_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ua_fh = (struct nsfs_file_handle *)ua_handle->f_handle; ua_fh->ns_id = ua_id; ua_fh->ns_type = 0; ua_fh->ns_inum = 0; ub_handle = (struct file_handle *)ub_buf; ub_handle->handle_bytes = sizeof(struct nsfs_file_handle); ub_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ub_fh = (struct nsfs_file_handle *)ub_handle->f_handle; ub_fh->ns_id = ub_id; ub_fh->ns_type = 0; ub_fh->ns_inum = 0; /* Open user_B before child exits */ int ub_fd = open_by_handle_at(FD_NSFS_ROOT, ub_handle, O_RDONLY); if (ub_fd < 0) { waitpid(pid, NULL, 0); SKIP(return, "Failed to open user_B"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* With user_B active, user_A should also be active */ TH_LOG("Testing user_A active when child user_B is active"); int ua_fd = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_GE(ua_fd, 0); /* Close user_B */ TH_LOG("Closing user_B"); close(ub_fd); /* user_A should remain active (we hold direct ref) */ int ua_fd2 = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_GE(ua_fd2, 0); close(ua_fd2); /* Close user_A - should become inactive */ TH_LOG("Closing user_A - should become inactive"); close(ua_fd); ua_fd = open_by_handle_at(FD_NSFS_ROOT, ua_handle, O_RDONLY); ASSERT_LT(ua_fd, 0); } /* * Test different namespace types (net, uts, ipc) all contributing * active references to the same owning user namespace. */ TEST(ns_mixed_types_same_owner) { struct file_handle *user_handle, *net_handle, *uts_handle; int ret, pipefd[2]; pid_t pid; int status; __u64 u_id, n_id, ut_id; char u_buf[sizeof(*user_handle) + MAX_HANDLE_SZ]; char n_buf[sizeof(*net_handle) + MAX_HANDLE_SZ]; char ut_buf[sizeof(*uts_handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { close(pipefd[0]); if (setup_userns() < 0) { close(pipefd[1]); exit(1); } int u_fd = open("/proc/self/ns/user", O_RDONLY); if (u_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(u_fd, NS_GET_ID, &u_id) < 0) { close(u_fd); close(pipefd[1]); exit(1); } close(u_fd); if (unshare(CLONE_NEWNET) < 0) { close(pipefd[1]); exit(1); } int n_fd = open("/proc/self/ns/net", O_RDONLY); if (n_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(n_fd, NS_GET_ID, &n_id) < 0) { close(n_fd); close(pipefd[1]); exit(1); } close(n_fd); if (unshare(CLONE_NEWUTS) < 0) { close(pipefd[1]); exit(1); } int ut_fd = open("/proc/self/ns/uts", O_RDONLY); if (ut_fd < 0) { close(pipefd[1]); exit(1); } if (ioctl(ut_fd, NS_GET_ID, &ut_id) < 0) { close(ut_fd); close(pipefd[1]); exit(1); } close(ut_fd); /* Send all namespace IDs */ write(pipefd[1], &u_id, sizeof(u_id)); write(pipefd[1], &n_id, sizeof(n_id)); write(pipefd[1], &ut_id, sizeof(ut_id)); close(pipefd[1]); exit(0); } close(pipefd[1]); /* Read all three namespace IDs - fixed size, no parsing needed */ ret = read(pipefd[0], &u_id, sizeof(u_id)); if (ret != sizeof(u_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user namespace ID"); } ret = read(pipefd[0], &n_id, sizeof(n_id)); if (ret != sizeof(n_id)) { close(pipefd[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read network namespace ID"); } ret = read(pipefd[0], &ut_id, sizeof(ut_id)); close(pipefd[0]); if (ret != sizeof(ut_id)) { waitpid(pid, NULL, 0); SKIP(return, "Failed to read UTS namespace ID"); } /* Construct file handles from namespace IDs */ user_handle = (struct file_handle *)u_buf; user_handle->handle_bytes = sizeof(struct nsfs_file_handle); user_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *u_fh = (struct nsfs_file_handle *)user_handle->f_handle; u_fh->ns_id = u_id; u_fh->ns_type = 0; u_fh->ns_inum = 0; net_handle = (struct file_handle *)n_buf; net_handle->handle_bytes = sizeof(struct nsfs_file_handle); net_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *n_fh = (struct nsfs_file_handle *)net_handle->f_handle; n_fh->ns_id = n_id; n_fh->ns_type = 0; n_fh->ns_inum = 0; uts_handle = (struct file_handle *)ut_buf; uts_handle->handle_bytes = sizeof(struct nsfs_file_handle); uts_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *ut_fh = (struct nsfs_file_handle *)uts_handle->f_handle; ut_fh->ns_id = ut_id; ut_fh->ns_type = 0; ut_fh->ns_inum = 0; /* Open both non-user namespaces */ int n_fd = open_by_handle_at(FD_NSFS_ROOT, net_handle, O_RDONLY); int ut_fd = open_by_handle_at(FD_NSFS_ROOT, uts_handle, O_RDONLY); if (n_fd < 0 || ut_fd < 0) { if (n_fd >= 0) close(n_fd); if (ut_fd >= 0) close(ut_fd); waitpid(pid, NULL, 0); SKIP(return, "Failed to open namespaces"); } waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); ASSERT_EQ(WEXITSTATUS(status), 0); /* User namespace should be active (2 active children) */ TH_LOG("Both net and uts active - user ns should be active"); int u_fd = open_by_handle_at(FD_NSFS_ROOT, user_handle, O_RDONLY); ASSERT_GE(u_fd, 0); close(u_fd); /* Close net - user ns should STILL be active (uts still active) */ TH_LOG("Closing net - user ns should still be active"); close(n_fd); u_fd = open_by_handle_at(FD_NSFS_ROOT, user_handle, O_RDONLY); ASSERT_GE(u_fd, 0); close(u_fd); /* Close uts - user ns should become inactive */ TH_LOG("Closing uts - user ns should become inactive"); close(ut_fd); u_fd = open_by_handle_at(FD_NSFS_ROOT, user_handle, O_RDONLY); ASSERT_LT(u_fd, 0); } /* Thread test helpers and structures */ struct thread_ns_info { __u64 ns_id; int pipefd; int syncfd_read; int syncfd_write; int exit_code; }; static void *thread_create_namespace(void *arg) { struct thread_ns_info *info = (struct thread_ns_info *)arg; int ret; /* Create new network namespace */ ret = unshare(CLONE_NEWNET); if (ret < 0) { info->exit_code = 1; return NULL; } /* Get namespace ID */ int fd = open("/proc/thread-self/ns/net", O_RDONLY); if (fd < 0) { info->exit_code = 2; return NULL; } ret = ioctl(fd, NS_GET_ID, &info->ns_id); close(fd); if (ret < 0) { info->exit_code = 3; return NULL; } /* Send namespace ID to main thread */ if (write(info->pipefd, &info->ns_id, sizeof(info->ns_id)) != sizeof(info->ns_id)) { info->exit_code = 4; return NULL; } /* Wait for signal to exit */ char sync_byte; if (read(info->syncfd_read, &sync_byte, 1) != 1) { info->exit_code = 5; return NULL; } info->exit_code = 0; return NULL; } /* * Test that namespace becomes inactive after thread exits. * This verifies active reference counting works with threads, not just processes. */ TEST(thread_ns_inactive_after_exit) { pthread_t thread; struct thread_ns_info info; struct file_handle *handle; int pipefd[2]; int syncpipe[2]; int ret; char sync_byte; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); ASSERT_EQ(pipe(syncpipe), 0); info.pipefd = pipefd[1]; info.syncfd_read = syncpipe[0]; info.syncfd_write = -1; info.exit_code = -1; /* Create thread that will create a namespace */ ret = pthread_create(&thread, NULL, thread_create_namespace, &info); ASSERT_EQ(ret, 0); /* Read namespace ID from thread */ __u64 ns_id; ret = read(pipefd[0], &ns_id, sizeof(ns_id)); if (ret != sizeof(ns_id)) { sync_byte = 'X'; write(syncpipe[1], &sync_byte, 1); pthread_join(thread, NULL); close(pipefd[0]); close(pipefd[1]); close(syncpipe[0]); close(syncpipe[1]); SKIP(return, "Failed to read namespace ID from thread"); } TH_LOG("Thread created namespace with ID %llu", (unsigned long long)ns_id); /* Construct file handle */ handle = (struct file_handle *)buf; handle->handle_bytes = sizeof(struct nsfs_file_handle); handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *fh = (struct nsfs_file_handle *)handle->f_handle; fh->ns_id = ns_id; fh->ns_type = 0; fh->ns_inum = 0; /* Namespace should be active while thread is alive */ TH_LOG("Attempting to open namespace while thread is alive (should succeed)"); int nsfd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_GE(nsfd, 0); close(nsfd); /* Signal thread to exit */ TH_LOG("Signaling thread to exit"); sync_byte = 'X'; ASSERT_EQ(write(syncpipe[1], &sync_byte, 1), 1); close(syncpipe[1]); /* Wait for thread to exit */ ASSERT_EQ(pthread_join(thread, NULL), 0); close(pipefd[0]); close(pipefd[1]); close(syncpipe[0]); if (info.exit_code != 0) SKIP(return, "Thread failed to create namespace"); TH_LOG("Thread exited, namespace should be inactive"); /* Namespace should now be inactive */ nsfd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(nsfd, 0); /* Should fail with ENOENT (inactive) or ESTALE (gone) */ TH_LOG("Namespace inactive as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* * Test that a namespace remains active while a thread holds an fd to it. * Even after the thread exits, the namespace should remain active as long as * another thread holds a file descriptor to it. */ TEST(thread_ns_fd_keeps_active) { pthread_t thread; struct thread_ns_info info; struct file_handle *handle; int pipefd[2]; int syncpipe[2]; int ret; char sync_byte; char buf[sizeof(*handle) + MAX_HANDLE_SZ]; ASSERT_EQ(pipe(pipefd), 0); ASSERT_EQ(pipe(syncpipe), 0); info.pipefd = pipefd[1]; info.syncfd_read = syncpipe[0]; info.syncfd_write = -1; info.exit_code = -1; /* Create thread that will create a namespace */ ret = pthread_create(&thread, NULL, thread_create_namespace, &info); ASSERT_EQ(ret, 0); /* Read namespace ID from thread */ __u64 ns_id; ret = read(pipefd[0], &ns_id, sizeof(ns_id)); if (ret != sizeof(ns_id)) { sync_byte = 'X'; write(syncpipe[1], &sync_byte, 1); pthread_join(thread, NULL); close(pipefd[0]); close(pipefd[1]); close(syncpipe[0]); close(syncpipe[1]); SKIP(return, "Failed to read namespace ID from thread"); } TH_LOG("Thread created namespace with ID %llu", (unsigned long long)ns_id); /* Construct file handle */ handle = (struct file_handle *)buf; handle->handle_bytes = sizeof(struct nsfs_file_handle); handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *fh = (struct nsfs_file_handle *)handle->f_handle; fh->ns_id = ns_id; fh->ns_type = 0; fh->ns_inum = 0; /* Open namespace while thread is alive */ TH_LOG("Opening namespace while thread is alive"); int nsfd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_GE(nsfd, 0); /* Signal thread to exit */ TH_LOG("Signaling thread to exit"); sync_byte = 'X'; write(syncpipe[1], &sync_byte, 1); close(syncpipe[1]); /* Wait for thread to exit */ pthread_join(thread, NULL); close(pipefd[0]); close(pipefd[1]); close(syncpipe[0]); if (info.exit_code != 0) { close(nsfd); SKIP(return, "Thread failed to create namespace"); } TH_LOG("Thread exited, but main thread holds fd - namespace should remain active"); /* Namespace should still be active because we hold an fd */ int nsfd2 = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_GE(nsfd2, 0); /* Verify it's the same namespace */ struct stat st1, st2; ASSERT_EQ(fstat(nsfd, &st1), 0); ASSERT_EQ(fstat(nsfd2, &st2), 0); ASSERT_EQ(st1.st_ino, st2.st_ino); close(nsfd2); TH_LOG("Closing fd - namespace should become inactive"); close(nsfd); /* Now namespace should be inactive */ nsfd = open_by_handle_at(FD_NSFS_ROOT, handle, O_RDONLY); ASSERT_LT(nsfd, 0); /* Should fail with ENOENT (inactive) or ESTALE (gone) */ TH_LOG("Namespace inactive as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); } /* Structure for thread data in subprocess */ struct thread_sleep_data { int syncfd_read; }; static void *thread_sleep_and_wait(void *arg) { struct thread_sleep_data *data = (struct thread_sleep_data *)arg; char sync_byte; /* Wait for signal to exit - read will unblock when pipe is closed */ (void)read(data->syncfd_read, &sync_byte, 1); return NULL; } /* * Test that namespaces become inactive after subprocess with multiple threads exits. * Create a subprocess that unshares user and network namespaces, then creates two * threads that share those namespaces. Verify that after all threads and subprocess * exit, the namespaces are no longer listed by listns() and cannot be opened by * open_by_handle_at(). */ TEST(thread_subprocess_ns_inactive_after_all_exit) { int pipefd[2]; int sv[2]; pid_t pid; int status; __u64 user_id, net_id; struct file_handle *user_handle, *net_handle; char user_buf[sizeof(*user_handle) + MAX_HANDLE_SZ]; char net_buf[sizeof(*net_handle) + MAX_HANDLE_SZ]; char sync_byte; int ret; ASSERT_EQ(pipe(pipefd), 0); ASSERT_EQ(socketpair(AF_UNIX, SOCK_STREAM, 0, sv), 0); pid = fork(); ASSERT_GE(pid, 0); if (pid == 0) { /* Child process */ close(pipefd[0]); close(sv[0]); /* Create user namespace with mappings */ if (setup_userns() < 0) { fprintf(stderr, "Child: setup_userns() failed: %s\n", strerror(errno)); close(pipefd[1]); close(sv[1]); exit(1); } fprintf(stderr, "Child: setup_userns() succeeded\n"); /* Get user namespace ID */ int user_fd = open("/proc/self/ns/user", O_RDONLY); if (user_fd < 0) { fprintf(stderr, "Child: open(/proc/self/ns/user) failed: %s\n", strerror(errno)); close(pipefd[1]); close(sv[1]); exit(1); } if (ioctl(user_fd, NS_GET_ID, &user_id) < 0) { fprintf(stderr, "Child: ioctl(NS_GET_ID) for user ns failed: %s\n", strerror(errno)); close(user_fd); close(pipefd[1]); close(sv[1]); exit(1); } close(user_fd); fprintf(stderr, "Child: user ns ID = %llu\n", (unsigned long long)user_id); /* Unshare network namespace */ if (unshare(CLONE_NEWNET) < 0) { fprintf(stderr, "Child: unshare(CLONE_NEWNET) failed: %s\n", strerror(errno)); close(pipefd[1]); close(sv[1]); exit(1); } fprintf(stderr, "Child: unshare(CLONE_NEWNET) succeeded\n"); /* Get network namespace ID */ int net_fd = open("/proc/self/ns/net", O_RDONLY); if (net_fd < 0) { fprintf(stderr, "Child: open(/proc/self/ns/net) failed: %s\n", strerror(errno)); close(pipefd[1]); close(sv[1]); exit(1); } if (ioctl(net_fd, NS_GET_ID, &net_id) < 0) { fprintf(stderr, "Child: ioctl(NS_GET_ID) for net ns failed: %s\n", strerror(errno)); close(net_fd); close(pipefd[1]); close(sv[1]); exit(1); } close(net_fd); fprintf(stderr, "Child: net ns ID = %llu\n", (unsigned long long)net_id); /* Send namespace IDs to parent */ if (write(pipefd[1], &user_id, sizeof(user_id)) != sizeof(user_id)) { fprintf(stderr, "Child: write(user_id) failed: %s\n", strerror(errno)); exit(1); } if (write(pipefd[1], &net_id, sizeof(net_id)) != sizeof(net_id)) { fprintf(stderr, "Child: write(net_id) failed: %s\n", strerror(errno)); exit(1); } close(pipefd[1]); fprintf(stderr, "Child: sent namespace IDs to parent\n"); /* Create two threads that share the namespaces */ pthread_t thread1, thread2; struct thread_sleep_data data; data.syncfd_read = sv[1]; int ret_thread = pthread_create(&thread1, NULL, thread_sleep_and_wait, &data); if (ret_thread != 0) { fprintf(stderr, "Child: pthread_create(thread1) failed: %s\n", strerror(ret_thread)); close(sv[1]); exit(1); } fprintf(stderr, "Child: created thread1\n"); ret_thread = pthread_create(&thread2, NULL, thread_sleep_and_wait, &data); if (ret_thread != 0) { fprintf(stderr, "Child: pthread_create(thread2) failed: %s\n", strerror(ret_thread)); close(sv[1]); pthread_cancel(thread1); exit(1); } fprintf(stderr, "Child: created thread2\n"); /* Wait for threads to complete - they will unblock when parent writes */ fprintf(stderr, "Child: waiting for threads to exit\n"); pthread_join(thread1, NULL); fprintf(stderr, "Child: thread1 exited\n"); pthread_join(thread2, NULL); fprintf(stderr, "Child: thread2 exited\n"); close(sv[1]); /* Exit - namespaces should become inactive */ fprintf(stderr, "Child: all threads joined, exiting with success\n"); exit(0); } /* Parent process */ close(pipefd[1]); close(sv[1]); TH_LOG("Parent: waiting to read namespace IDs from child"); /* Read namespace IDs from child */ ret = read(pipefd[0], &user_id, sizeof(user_id)); if (ret != sizeof(user_id)) { TH_LOG("Parent: failed to read user_id, ret=%d, errno=%s", ret, strerror(errno)); close(pipefd[0]); sync_byte = 'X'; (void)write(sv[0], &sync_byte, 1); close(sv[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read user namespace ID from child"); } ret = read(pipefd[0], &net_id, sizeof(net_id)); close(pipefd[0]); if (ret != sizeof(net_id)) { TH_LOG("Parent: failed to read net_id, ret=%d, errno=%s", ret, strerror(errno)); sync_byte = 'X'; (void)write(sv[0], &sync_byte, 1); close(sv[0]); waitpid(pid, NULL, 0); SKIP(return, "Failed to read network namespace ID from child"); } TH_LOG("Child created user ns %llu and net ns %llu with 2 threads", (unsigned long long)user_id, (unsigned long long)net_id); /* Construct file handles */ user_handle = (struct file_handle *)user_buf; user_handle->handle_bytes = sizeof(struct nsfs_file_handle); user_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *user_fh = (struct nsfs_file_handle *)user_handle->f_handle; user_fh->ns_id = user_id; user_fh->ns_type = 0; user_fh->ns_inum = 0; net_handle = (struct file_handle *)net_buf; net_handle->handle_bytes = sizeof(struct nsfs_file_handle); net_handle->handle_type = FILEID_NSFS; struct nsfs_file_handle *net_fh = (struct nsfs_file_handle *)net_handle->f_handle; net_fh->ns_id = net_id; net_fh->ns_type = 0; net_fh->ns_inum = 0; /* Verify namespaces are active while subprocess and threads are alive */ TH_LOG("Verifying namespaces are active while subprocess with threads is running"); int user_fd = open_by_handle_at(FD_NSFS_ROOT, user_handle, O_RDONLY); ASSERT_GE(user_fd, 0); int net_fd = open_by_handle_at(FD_NSFS_ROOT, net_handle, O_RDONLY); ASSERT_GE(net_fd, 0); close(user_fd); close(net_fd); /* Also verify they appear in listns() */ TH_LOG("Verifying namespaces appear in listns() while active"); struct ns_id_req req = { .size = sizeof(struct ns_id_req), .spare = 0, .ns_id = 0, .ns_type = CLONE_NEWUSER, .spare2 = 0, .user_ns_id = 0, }; __u64 ns_ids[256]; int nr_ids = sys_listns(&req, ns_ids, 256, 0); if (nr_ids < 0) { TH_LOG("listns() not available, skipping listns verification"); } else { /* Check if user_id is in the list */ int found_user = 0; for (int i = 0; i < nr_ids; i++) { if (ns_ids[i] == user_id) { found_user = 1; break; } } ASSERT_TRUE(found_user); TH_LOG("User namespace found in listns() as expected"); /* Check network namespace */ req.ns_type = CLONE_NEWNET; nr_ids = sys_listns(&req, ns_ids, 256, 0); if (nr_ids >= 0) { int found_net = 0; for (int i = 0; i < nr_ids; i++) { if (ns_ids[i] == net_id) { found_net = 1; break; } } ASSERT_TRUE(found_net); TH_LOG("Network namespace found in listns() as expected"); } } /* Signal threads to exit */ TH_LOG("Signaling threads to exit"); sync_byte = 'X'; /* Write two bytes - one for each thread */ ASSERT_EQ(write(sv[0], &sync_byte, 1), 1); ASSERT_EQ(write(sv[0], &sync_byte, 1), 1); close(sv[0]); /* Wait for child process to exit */ waitpid(pid, &status, 0); ASSERT_TRUE(WIFEXITED(status)); if (WEXITSTATUS(status) != 0) { TH_LOG("Child process failed with exit code %d", WEXITSTATUS(status)); SKIP(return, "Child process failed"); } TH_LOG("Subprocess and all threads have exited successfully"); /* Verify namespaces are now inactive - open_by_handle_at should fail */ TH_LOG("Verifying namespaces are inactive after subprocess and threads exit"); user_fd = open_by_handle_at(FD_NSFS_ROOT, user_handle, O_RDONLY); ASSERT_LT(user_fd, 0); TH_LOG("User namespace inactive as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); net_fd = open_by_handle_at(FD_NSFS_ROOT, net_handle, O_RDONLY); ASSERT_LT(net_fd, 0); TH_LOG("Network namespace inactive as expected: %s (errno=%d)", strerror(errno), errno); ASSERT_TRUE(errno == ENOENT || errno == ESTALE); /* Verify namespaces do NOT appear in listns() */ TH_LOG("Verifying namespaces do NOT appear in listns() when inactive"); memset(&req, 0, sizeof(req)); req.size = sizeof(struct ns_id_req); req.ns_type = CLONE_NEWUSER; nr_ids = sys_listns(&req, ns_ids, 256, 0); if (nr_ids >= 0) { int found_user = 0; for (int i = 0; i < nr_ids; i++) { if (ns_ids[i] == user_id) { found_user = 1; break; } } ASSERT_FALSE(found_user); TH_LOG("User namespace correctly not listed in listns()"); /* Check network namespace */ req.ns_type = CLONE_NEWNET; nr_ids = sys_listns(&req, ns_ids, 256, 0); if (nr_ids >= 0) { int found_net = 0; for (int i = 0; i < nr_ids; i++) { if (ns_ids[i] == net_id) { found_net = 1; break; } } ASSERT_FALSE(found_net); TH_LOG("Network namespace correctly not listed in listns()"); } } } TEST_HARNESS_MAIN