#define _GNU_SOURCE
#include <errno.h>
+#include <fcntl.h> /* AT_FOO constants */
#include <ftw.h> /* nftw() et al. */
#include <getopt.h>
-#include <libgen.h> /* dirname() */
-#include <limits.h> /* PATH_MAX */
+#include <libgen.h> /* basename(), dirname() */
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
/**
- * @brief Get the mode bits from the given path.
+ * @brief Get the mode bits from the given file descriptor.
*
- * @param path
- * The path (file or directory) whose mode we want.
+ * @param fd
+ * The file descriptor (which may reference a directory) whose
+ * mode we want.
*
* @return A mode_t (st_mode) structure containing the mode bits.
* See sys/stat.h for details.
*/
-mode_t get_mode(const char* path) {
- if (path == NULL) {
+mode_t get_mode(int fd) {
+ if (fd <= 0) {
errno = ENOENT;
- return -1;
+ return ACL_ERROR;
}
struct stat s;
- int result = stat(path, &s);
+ int result = fstat(fd, &s);
if (result == 0) {
return s.st_mode;
}
else {
- /* errno will be set already by stat() */
+ /* errno will be set already by lstat() */
return result;
}
}
/**
- * @brief Determine whether or not the given path is a regular file.
+ * @brief Determine if the given file descriptor might refer to an
+ * (unsafe) hard link.
+ *
+ * @param fd
+ * The file descriptor whose link count we want to investigate.
+ *
+ * @return true if we are certain that @c fd does not describe a hard
+ * link, and false otherwise. In case of error, false is returned,
+ * because we are not sure that @c fd is not a hard link.
+ */
+bool is_hardlink_safe(int fd) {
+ if (fd <= 0) {
+ return false;
+ }
+ struct stat s;
+ if (fstat(fd, &s) == 0) {
+ return (s.st_nlink == 1 || S_ISDIR(s.st_mode));
+ }
+ else {
+ return false;
+ }
+}
+
+
+/**
+ * @brief Determine whether or not the given file descriptor is for
+ * a regular file.
+ *
+ * @param fd
+ * The file descriptor to test for regular-fileness.
+ *
+ * @return true if @c fd describes a regular file, and false otherwise.
+ */
+bool is_regular_file(int fd) {
+ if (fd <= 0) {
+ return false;
+ }
+
+ struct stat s;
+ if (fstat(fd, &s) == 0) {
+ return S_ISREG(s.st_mode);
+ }
+ else {
+ return false;
+ }
+}
+
+
+
+/**
+ * @brief Determine whether or not the given path is accessible.
*
* @param path
* The path to test.
*
- * @return true if @c path is a regular file, false otherwise.
+ * @return true if @c path is accessible to the current effective
+ * user/group, false otherwise.
*/
-bool is_regular_file(const char* path) {
+bool path_accessible(const char* path) {
if (path == NULL) {
return false;
}
- struct stat s;
- int result = stat(path, &s);
- if (result == 0) {
- return S_ISREG(s.st_mode);
+ /* Test for access using the effective user and group rather than
+ the real one. */
+ int flags = AT_EACCESS;
+
+ /* Don't follow symlinks when checking for a path's existence,
+ since we won't follow them to set its ACLs either. */
+ flags |= AT_SYMLINK_NOFOLLOW;
+
+ /* If the path is relative, interpret it relative to the current
+ working directory (just like the access() system call). */
+ if (faccessat(AT_FDCWD, path, F_OK, flags) == 0) {
+ return true;
}
else {
return false;
*
* @return true if @c path is a directory, false otherwise.
*/
-bool is_directory(const char* path) {
+bool is_path_directory(const char* path) {
if (path == NULL) {
return false;
}
struct stat s;
- int result = stat(path, &s);
- if (result == 0) {
+ if (lstat(path, &s) == 0) {
+ return S_ISDIR(s.st_mode);
+ }
+ else {
+ return false;
+ }
+}
+
+
+/**
+ * @brief Determine whether or not the given file descriptor is for
+ * a directory.
+ *
+ * @param fd
+ * The file descriptor whose directoryness is in question.
+ *
+ * @return true if @c fd describes a directory, and false otherwise.
+ */
+bool is_directory(int fd) {
+ if (fd <= 0) {
+ return false;
+ }
+
+ struct stat s;
+ if (fstat(fd, &s) == 0) {
return S_ISDIR(s.st_mode);
}
else {
acl_entry_t entry) {
acl_tag_t entry_tag;
- int gt_result = acl_get_tag_type(entry, &entry_tag);
- if (gt_result == ACL_ERROR) {
+ if (acl_get_tag_type(entry, &entry_tag) == ACL_ERROR) {
perror("acl_set_entry (acl_get_tag_type)");
return ACL_ERROR;
}
acl_permset_t entry_permset;
- int ps_result = acl_get_permset(entry, &entry_permset);
- if (ps_result == ACL_ERROR) {
+ if (acl_get_permset(entry, &entry_permset) == ACL_ERROR) {
perror("acl_set_entry (acl_get_permset)");
return ACL_ERROR;
}
while (result == ACL_SUCCESS) {
acl_tag_t existing_tag = ACL_UNDEFINED_TAG;
- int tag_result = acl_get_tag_type(existing_entry, &existing_tag);
- if (tag_result == ACL_ERROR) {
+ if (acl_get_tag_type(existing_entry, &existing_tag) == ACL_ERROR) {
perror("set_acl_tag_permset (acl_get_tag_type)");
return ACL_ERROR;
}
match one of them, we're allowed to return ACL_SUCCESS
below and bypass the rest of the function. */
acl_permset_t existing_permset;
- int gep_result = acl_get_permset(existing_entry, &existing_permset);
- if (gep_result == ACL_ERROR) {
+ if (acl_get_permset(existing_entry, &existing_permset) == ACL_ERROR) {
perror("acl_set_entry (acl_get_permset)");
return ACL_ERROR;
}
- int s_result = acl_set_permset(existing_entry, entry_permset);
- if (s_result == ACL_ERROR) {
+ if (acl_set_permset(existing_entry, entry_permset) == ACL_ERROR) {
perror("acl_set_entry (acl_set_permset)");
return ACL_ERROR;
}
ACL. */
acl_entry_t new_entry;
- /* We allocate memory here that we should release! */
- int c_result = acl_create_entry(aclp, &new_entry);
- if (c_result == ACL_ERROR) {
+ /* The acl_create_entry() function can allocate new memory and/or
+ * change the location of the ACL structure entirely. When that
+ * happens, the value pointed to by aclp is updated, which means
+ * that a new acl_t gets "passed out" to our caller, eventually to
+ * be fed to acl_free(). In other words, we should still be freeing
+ * the right thing, even if the value pointed to by aclp changes.
+ */
+ if (acl_create_entry(aclp, &new_entry) == ACL_ERROR) {
perror("acl_set_entry (acl_create_entry)");
return ACL_ERROR;
}
- int st_result = acl_set_tag_type(new_entry, entry_tag);
- if (st_result == ACL_ERROR) {
+ if (acl_set_tag_type(new_entry, entry_tag) == ACL_ERROR) {
perror("acl_set_entry (acl_set_tag_type)");
return ACL_ERROR;
}
- int s_result = acl_set_permset(new_entry, entry_permset);
- if (s_result == ACL_ERROR) {
+ if (acl_set_permset(new_entry, entry_permset) == ACL_ERROR) {
perror("acl_set_entry (acl_set_permset)");
return ACL_ERROR;
}
return ACL_ERROR;
}
- int sq_result = acl_set_qualifier(new_entry, entry_qual);
- if (sq_result == ACL_ERROR) {
+ if (acl_set_qualifier(new_entry, entry_qual) == ACL_ERROR) {
perror("acl_set_entry (acl_set_qualifier)");
return ACL_ERROR;
}
* @brief Determine the number of entries in the given ACL.
*
* @param acl
- * A pointer to an @c acl_t structure.
+ * The ACL to inspect.
*
* @return Either the non-negative number of entries in @c acl, or
* @c ACL_ERROR on error.
*/
-int acl_entry_count(acl_t* acl) {
+int acl_entry_count(acl_t acl) {
acl_entry_t entry;
int entry_count = 0;
- int result = acl_get_entry(*acl, ACL_FIRST_ENTRY, &entry);
+ int result = acl_get_entry(acl, ACL_FIRST_ENTRY, &entry);
while (result == ACL_SUCCESS) {
entry_count++;
- result = acl_get_entry(*acl, ACL_NEXT_ENTRY, &entry);
+ result = acl_get_entry(acl, ACL_NEXT_ENTRY, &entry);
}
if (result == ACL_ERROR) {
* An ACL is minimal if it has fewer than four entries.
*
* @param acl
- * A pointer to an acl_t structure.
+ * The ACL whose minimality is in question.
*
* @return
* - @c ACL_SUCCESS - @c acl is minimal
* - @c ACL_FAILURE - @c acl is not minimal
* - @c ACL_ERROR - Unexpected library error
*/
-int acl_is_minimal(acl_t* acl) {
+int acl_is_minimal(acl_t acl) {
int ec = acl_entry_count(acl);
/**
- * @brief Determine whether the given path has an ACL whose mask
- * denies execute.
+ * @brief Determine whether the given ACL's mask denies execute.
*
- * @param path
- * The path to check.
+ * @param acl
+ * The ACL whose mask we want to check.
*
* @return
- * - @c ACL_SUCCESS - @c path has a mask which denies execute.
- * - @c ACL_FAILURE - The ACL for @c path does not deny execute,
- * or @c path has no extended ACL at all.
+ * - @c ACL_SUCCESS - The @c acl has a mask which denies execute.
+ * - @c ACL_FAILURE - The @c acl has a mask which does not deny execute.
* - @c ACL_ERROR - Unexpected library error.
*/
-int acl_execute_masked(const char* path) {
-
- acl_t acl = acl_get_file(path, ACL_TYPE_ACCESS);
-
- if (acl == (acl_t)NULL) {
- perror("acl_execute_masked (acl_get_file)");
- return ACL_ERROR;
- }
-
- /* Our return value. */
- int result = ACL_FAILURE;
+int acl_execute_masked(acl_t acl) {
acl_entry_t entry;
int ge_result = acl_get_entry(acl, ACL_FIRST_ENTRY, &entry);
while (ge_result == ACL_SUCCESS) {
acl_tag_t tag = ACL_UNDEFINED_TAG;
- int tag_result = acl_get_tag_type(entry, &tag);
- if (tag_result == ACL_ERROR) {
+ if (acl_get_tag_type(entry, &tag) == ACL_ERROR) {
perror("acl_execute_masked (acl_get_tag_type)");
- result = ACL_ERROR;
- goto cleanup;
+ return ACL_ERROR;
}
if (tag == ACL_MASK) {
execute is specified. */
acl_permset_t permset;
- int ps_result = acl_get_permset(entry, &permset);
- if (ps_result == ACL_ERROR) {
+ if (acl_get_permset(entry, &permset) == ACL_ERROR) {
perror("acl_execute_masked (acl_get_permset)");
- result = ACL_ERROR;
- goto cleanup;
+ return ACL_ERROR;
}
int gp_result = acl_get_perm(permset, ACL_EXECUTE);
if (gp_result == ACL_ERROR) {
perror("acl_execute_masked (acl_get_perm)");
- result = ACL_ERROR;
- goto cleanup;
+ return ACL_ERROR;
}
if (gp_result == ACL_FAILURE) {
ge_result = acl_get_entry(acl, ACL_NEXT_ENTRY, &entry);
}
- cleanup:
- acl_free(acl);
- return result;
+ return ACL_FAILURE;
}
+
/**
- * @brief Determine whether @c path is executable (by anyone) or a
+ * @brief Determine whether @c fd is executable (by anyone) or a
* directory.
*
* This is used as part of the heuristic to determine whether or not
- * we should mask the execute bit when inheriting an ACL. If @c path
- * is a directory, the answer is a clear-cut yes. This behavior is
- * modeled after the capital 'X' perms of setfacl.
+ * we should mask the execute bit when inheriting an ACL. If @c fd
+ * describes a directory, the answer is a clear-cut yes. This behavior
+ * is modeled after the capital 'X' perms of setfacl.
*
- * If @c path is a file, we check the @a effective permissions,
+ * If @c fd describes a file, we check the @a effective permissions,
* contrary to what setfacl does.
*
- * @param path
- * The path to check.
+ * @param fd
+ * The file descriptor to check.
*
* @return
- * - @c ACL_SUCCESS - @c path is a directory, or someone has effective
+ * - @c ACL_SUCCESS - @c fd describes a directory, or someone has effective
execute permissions.
- * - @c ACL_FAILURE - @c path is a regular file and nobody can execute
+ * - @c ACL_FAILURE - @c fd describes a regular file and nobody can execute
it.
* - @c ACL_ERROR - Unexpected library error.
*/
-int any_can_execute_or_dir(const char* path) {
+int any_can_execute_or_dir(int fd) {
- if (is_directory(path)) {
+ if (is_directory(fd)) {
/* That was easy... */
return ACL_SUCCESS;
}
- acl_t acl = acl_get_file(path, ACL_TYPE_ACCESS);
+ acl_t acl = acl_get_fd(fd);
if (acl == (acl_t)NULL) {
perror("any_can_execute_or_dir (acl_get_file)");
/* Our return value. */
int result = ACL_FAILURE;
- if (acl_is_minimal(&acl)) {
- mode_t mode = get_mode(path);
+ if (acl_is_minimal(acl)) {
+ mode_t mode = get_mode(fd);
if (mode & (S_IXUSR | S_IXOTH | S_IXGRP)) {
result = ACL_SUCCESS;
goto cleanup;
int ge_result = acl_get_entry(acl, ACL_FIRST_ENTRY, &entry);
while (ge_result == ACL_SUCCESS) {
+ /* The first thing we do is check to see if this is a mask
+ entry. If it is, we skip it entirely. */
+ acl_tag_t tag = ACL_UNDEFINED_TAG;
+
+ if (acl_get_tag_type(entry, &tag) == ACL_ERROR) {
+ perror("any_can_execute_or_dir (acl_get_tag_type)");
+ result = ACL_ERROR;
+ goto cleanup;
+ }
+
+ if (tag == ACL_MASK) {
+ ge_result = acl_get_entry(acl, ACL_NEXT_ENTRY, &entry);
+ continue;
+ }
+
+ /* Ok, so it's not a mask entry. Check the execute perms. */
acl_permset_t permset;
- int ps_result = acl_get_permset(entry, &permset);
- if (ps_result == ACL_ERROR) {
+ if (acl_get_permset(entry, &permset) == ACL_ERROR) {
perror("any_can_execute_or_dir (acl_get_permset)");
result = ACL_ERROR;
goto cleanup;
}
if (gp_result == ACL_SUCCESS) {
- /* Only return one if this execute bit is not masked. */
- if (acl_execute_masked(path) != ACL_SUCCESS) {
+ /* Only return ACL_SUCCESS if this execute bit is not masked. */
+ if (acl_execute_masked(acl) != ACL_SUCCESS) {
result = ACL_SUCCESS;
goto cleanup;
}
/**
- * @brief Inherit the default ACL from @c parent to @c path.
- *
- * The @c parent parameter does not necessarily need to be the parent
- * of @c path, although that will usually be the case. This overwrites
- * any existing default ACL on @c path.
+ * @brief Set @c acl as the default ACL on @c path if it's a directory.
*
- * @param parent
- * The parent directory whose ACL we want to inherit.
+ * This overwrites any existing default ACL on @c path. If no default
+ * ACL exists, then one is created. If @c path is not a directory, we
+ * return ACL_FAILURE but no error is raised.
*
* @param path
- * The target directory whose ACL we wish to overwrite (or create).
+ * The target directory whose ACL we wish to replace or create.
+ *
+ * @param acl
+ * The ACL to set as default on @c path.
*
* @return
- * - @c ACL_SUCCESS - The default ACL was inherited successfully.
- * - @c ACL_FAILURE - Either @c parent or @c path is not a directory.
+ * - @c ACL_SUCCESS - The default ACL was assigned successfully.
+ * - @c ACL_FAILURE - If @c path is not a directory.
* - @c ACL_ERROR - Unexpected library error.
*/
-int inherit_default_acl(const char* path, const char* parent) {
-
- /* Our return value. */
- int result = ACL_SUCCESS;
+int assign_default_acl(const char* path, acl_t acl) {
if (path == NULL) {
errno = ENOENT;
return ACL_ERROR;
}
- if (!is_directory(path) || !is_directory(parent)) {
+ if (!is_path_directory(path)) {
return ACL_FAILURE;
}
- acl_t parent_acl = acl_get_file(parent, ACL_TYPE_DEFAULT);
- if (parent_acl == (acl_t)NULL) {
- perror("inherit_default_acl (acl_get_file)");
- return ACL_ERROR;
- }
-
- acl_t path_acl = acl_dup(parent_acl);
+ /* Our return value; success unless something bad happens. */
+ int result = ACL_SUCCESS;
+ acl_t path_acl = acl_dup(acl);
if (path_acl == (acl_t)NULL) {
- perror("inherit_default_acl (acl_dup)");
- acl_free(parent_acl);
- return ACL_ERROR;
+ perror("assign_default_acl (acl_dup)");
+ return ACL_ERROR; /* Nothing to clean up in this case. */
}
- int sf_result = acl_set_file(path, ACL_TYPE_DEFAULT, path_acl);
- if (sf_result == -1) {
- perror("inherit_default_acl (acl_set_file)");
+ if (acl_set_file(path, ACL_TYPE_DEFAULT, path_acl) == ACL_ERROR) {
+ perror("assign_default_acl (acl_set_file)");
result = ACL_ERROR;
- goto cleanup;
}
- cleanup:
acl_free(path_acl);
return result;
}
/**
- * @brief Remove @c ACL_USER, @c ACL_GROUP, and @c ACL_MASK entries
- * from the given path.
+ * @brief Remove all @c ACL_TYPE_ACCESS entries from the given file
+ * descriptor, leaving the UNIX permission bits.
*
- * @param path
- * The path whose ACLs we want to wipe.
+ * @param fd
+ * The file descriptor whose ACLs we want to wipe.
*
* @return
* - @c ACL_SUCCESS - The ACLs were wiped successfully, or none
* existed in the first place.
* - @c ACL_ERROR - Unexpected library error.
*/
-int wipe_acls(const char* path) {
+int wipe_acls(int fd) {
+ /* Initialize an empty ACL, and then overwrite the one on "fd" with it. */
+ acl_t empty_acl = acl_init(0);
- if (path == NULL) {
- errno = ENOENT;
+ if (empty_acl == (acl_t)NULL) {
+ perror("wipe_acls (acl_init)");
return ACL_ERROR;
}
- acl_t acl = acl_get_file(path, ACL_TYPE_ACCESS);
- if (acl == (acl_t)NULL) {
- perror("wipe_acls (acl_get_file)");
+ if (acl_set_fd(fd, empty_acl) == ACL_ERROR) {
+ perror("wipe_acls (acl_set_fd)");
+ acl_free(empty_acl);
return ACL_ERROR;
}
- /* Our return value. */
- int result = ACL_SUCCESS;
-
- acl_entry_t entry;
- int ge_result = acl_get_entry(acl, ACL_FIRST_ENTRY, &entry);
-
- while (ge_result == ACL_SUCCESS) {
- int d_result = acl_delete_entry(acl, entry);
- if (d_result == ACL_ERROR) {
- perror("wipe_acls (acl_delete_entry)");
- result = ACL_ERROR;
- goto cleanup;
- }
-
- ge_result = acl_get_entry(acl, ACL_NEXT_ENTRY, &entry);
- }
-
- /* Catches the first acl_get_entry as well as the ones at the end of
- the loop. */
- if (ge_result == ACL_ERROR) {
- perror("wipe_acls (acl_get_entry)");
- result = ACL_ERROR;
- goto cleanup;
- }
-
- int sf_result = acl_set_file(path, ACL_TYPE_ACCESS, acl);
- if (sf_result == ACL_ERROR) {
- perror("wipe_acls (acl_set_file)");
- result = ACL_ERROR;
- goto cleanup;
- }
-
- cleanup:
- acl_free(acl);
- return result;
+ acl_free(empty_acl);
+ return ACL_SUCCESS;
}
return ACL_ERROR;
}
- if (!is_regular_file(path) && !is_directory(path)) {
- return ACL_FAILURE;
- }
+ /* Define these next three variables here because we may have to
+ * jump to the cleanup routine which expects them to exist.
+ */
+
+ /* Our return value. */
+ int result = ACL_SUCCESS;
- /* dirname mangles its argument */
- char path_copy[PATH_MAX];
- strncpy(path_copy, path, PATH_MAX-1);
- path_copy[PATH_MAX-1] = 0;
+ /* The default ACL on path's parent directory */
+ acl_t defacl = (acl_t)NULL;
+ /* The file descriptor corresponding to "path" */
+ int fd = 0;
+
+ /* Split "path" into base/dirname parts to be used with openat().
+ * We duplicate the strings involved because dirname/basename mangle
+ * their arguments.
+ */
+ char* path_copy = strdup(path);
+ if (path_copy == NULL) {
+ perror("apply_default_acl (strdup)");
+ return ACL_ERROR;
+ }
char* parent = dirname(path_copy);
- if (!is_directory(parent)) {
- /* Make sure dirname() did what we think it did. */
- return ACL_FAILURE;
+
+ fd = open(path, O_NOFOLLOW);
+ if (fd == -1) {
+ if (errno == ELOOP) {
+ result = ACL_FAILURE; /* hit a symlink */
+ goto cleanup;
+ }
+ else {
+ perror("apply_default_acl (open fd)");
+ result = ACL_ERROR;
+ goto cleanup;
+ }
+ }
+
+
+ /* Refuse to operate on hard links, which can be abused by an
+ * attacker to trick us into changing the ACL on a file we didn't
+ * intend to; namely the "target" of the hard link. There is TOCTOU
+ * race condition here, but the window is as small as possible
+ * between when we open the file descriptor (look above) and when we
+ * fstat it.
+ */
+ if (!is_hardlink_safe(fd)) {
+ result = ACL_FAILURE;
+ goto cleanup;
+ }
+
+ if (!is_regular_file(fd) && !is_directory(fd)) {
+ result = ACL_FAILURE;
+ goto cleanup;
}
/* Default to not masking the exec bit; i.e. applying the default
bool allow_exec = true;
if (!no_exec_mask) {
- int ace_result = any_can_execute_or_dir(path);
+ int ace_result = any_can_execute_or_dir(fd);
if (ace_result == ACL_ERROR) {
perror("apply_default_acl (any_can_execute_or_dir)");
- return ACL_ERROR;
+ result = ACL_ERROR;
+ goto cleanup;
}
allow_exec = (bool)ace_result;
}
- acl_t defacl = acl_get_file(parent, ACL_TYPE_DEFAULT);
+ defacl = acl_get_file(parent, ACL_TYPE_DEFAULT);
if (defacl == (acl_t)NULL) {
perror("apply_default_acl (acl_get_file)");
- return ACL_ERROR;
+ result = ACL_ERROR;
+ goto cleanup;
}
- /* Our return value. */
- int result = ACL_SUCCESS;
-
- int wipe_result = wipe_acls(path);
- if (wipe_result == ACL_ERROR) {
+ if (wipe_acls(fd) == ACL_ERROR) {
perror("apply_default_acl (wipe_acls)");
result = ACL_ERROR;
goto cleanup;
/* Do this after wipe_acls(), otherwise we'll overwrite the wiped
ACL with this one. */
- acl_t acl = acl_get_file(path, ACL_TYPE_ACCESS);
+ acl_t acl = acl_get_fd(fd);
if (acl == (acl_t)NULL) {
- perror("apply_default_acl (acl_get_file)");
- return ACL_ERROR;
+ perror("apply_default_acl (acl_get_fd)");
+ result = ACL_ERROR;
+ goto cleanup;
}
/* If it's a directory, inherit the parent's default. */
- int inherit_result = inherit_default_acl(path, parent);
- if (inherit_result == ACL_ERROR) {
- perror("apply_default_acl (inherit_acls)");
+ if (assign_default_acl(path, defacl) == ACL_ERROR) {
+ perror("apply_default_acl (assign_default_acl)");
result = ACL_ERROR;
goto cleanup;
}
while (ge_result == ACL_SUCCESS) {
acl_tag_t tag = ACL_UNDEFINED_TAG;
- int tag_result = acl_get_tag_type(entry, &tag);
- if (tag_result == ACL_ERROR) {
+ if (acl_get_tag_type(entry, &tag) == ACL_ERROR) {
perror("apply_default_acl (acl_get_tag_type)");
result = ACL_ERROR;
goto cleanup;
/* We've got an entry/tag from the default ACL. Get its permset. */
acl_permset_t permset;
- int ps_result = acl_get_permset(entry, &permset);
- if (ps_result == ACL_ERROR) {
+ if (acl_get_permset(entry, &permset) == ACL_ERROR) {
perror("apply_default_acl (acl_get_permset)");
result = ACL_ERROR;
goto cleanup;
/* The mask doesn't affect acl_user_obj, acl_group_obj (in
minimal ACLs) or acl_other entries, so if execute should be
masked, we have to do it manually. */
- int d_result = acl_delete_perm(permset, ACL_EXECUTE);
- if (d_result == ACL_ERROR) {
+ if (acl_delete_perm(permset, ACL_EXECUTE) == ACL_ERROR) {
perror("apply_default_acl (acl_delete_perm)");
result = ACL_ERROR;
goto cleanup;
}
- int sp_result = acl_set_permset(entry, permset);
- if (sp_result == ACL_ERROR) {
+ if (acl_set_permset(entry, permset) == ACL_ERROR) {
perror("apply_default_acl (acl_set_permset)");
result = ACL_ERROR;
goto cleanup;
}
}
- /* Finally, add the permset to the access ACL. */
- int set_result = acl_set_entry(&acl, entry);
- if (set_result == ACL_ERROR) {
+ /* Finally, add the permset to the access ACL. It's actually
+ * important that we pass in the address of "acl" here, and not
+ * "acl" itself. Why? The call to acl_create_entry() within
+ * acl_set_entry() can allocate new memory for the entry.
+ * Sometimes that can be done in-place, in which case everything
+ * is cool and the new memory gets released when we call
+ * acl_free(acl).
+ *
+ * But occasionally, the whole ACL structure will have to be moved
+ * in order to allocate the extra space. When that happens,
+ * acl_create_entry() modifies the pointer it was passed (in this
+ * case, &acl) to point to the new location. We want to call
+ * acl_free() on the new location, and since acl_free() gets
+ * called right here, we need acl_create_entry() to update the
+ * value of "acl". To do that, it needs the address of "acl".
+ */
+ if (acl_set_entry(&acl, entry) == ACL_ERROR) {
perror("apply_default_acl (acl_set_entry)");
result = ACL_ERROR;
goto cleanup;
goto cleanup;
}
- int sf_result = acl_set_file(path, ACL_TYPE_ACCESS, acl);
- if (sf_result == ACL_ERROR) {
- perror("apply_default_acl (acl_set_file)");
+ if (acl_set_fd(fd, acl) == ACL_ERROR) {
+ perror("apply_default_acl (acl_set_fd)");
result = ACL_ERROR;
goto cleanup;
}
cleanup:
- acl_free(defacl);
+ free(path_copy);
+ if (defacl != (acl_t)NULL) {
+ acl_free(defacl);
+ }
+ if (fd >= 0 && close(fd) == -1) {
+ perror("apply_default_acl (close)");
+ result = ACL_ERROR;
+ }
return result;
}
* The program name to use in the output.
*
*/
-void usage(char* program_name) {
+void usage(const char* program_name) {
printf("Apply any applicable default ACLs to the given files or "
"directories.\n\n");
printf("Usage: %s [flags] <target1> [<target2> [ <target3>...]]\n\n",
int info,
struct FTW *ftw) {
- bool app_result = apply_default_acl(target, false);
- if (app_result) {
+ if (apply_default_acl(target, false)) {
return FTW_CONTINUE;
}
else {
int info,
struct FTW *ftw) {
- bool app_result = apply_default_acl(target, true);
- if (app_result) {
+ if (apply_default_acl(target, true)) {
return FTW_CONTINUE;
}
else {
*/
bool apply_default_acl_recursive(const char *target, bool no_exec_mask) {
- if (!is_directory(target)) {
+ if (!is_path_directory(target)) {
return apply_default_acl(target, no_exec_mask);
}
const char* target = argv[arg_index];
bool reapp_result = false;
+ /* Make sure we can access the given path before we go out of our
+ * way to please it. Doing this check outside of
+ * apply_default_acl() lets us spit out a better error message for
+ * typos, too.
+ */
+ if (!path_accessible(target)) {
+ fprintf(stderr, "%s: %s: No such file or directory\n", argv[0], target);
+ result = EXIT_FAILURE;
+ continue;
+ }
+
if (recursive) {
reapp_result = apply_default_acl_recursive(target, no_exec_mask);
}
else {
- /* It's either normal file, or we're not operating recursively. */
+ /* It's either a normal file, or we're not operating recursively. */
reapp_result = apply_default_acl(target, no_exec_mask);
}
projects / apply-default-acl.git / blobdiff