1ACCESS(2) Linux Programmer's Manual ACCESS(2)
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6 access, faccessat, faccessat2 - check user's permissions for a file
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9 #include <unistd.h>
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11 int access(const char *pathname, int mode);
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13 #include <fcntl.h> /* Definition of AT_* constants */
14 #include <unistd.h>
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16 int faccessat(int dirfd, const char *pathname, int mode, int flags);
17 /* But see C library/kernel differences, below */
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19 #include <fcntl.h> /* Definition of AT_* constants */
20 #include <sys/syscall.h> /* Definition of SYS_* constants */
21 #include <unistd.h>
22
23 int syscall(SYS_faccessat2,
24 int dirfd, const char *pathname, int mode, int flags);
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26 Feature Test Macro Requirements for glibc (see feature_test_macros(7)):
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28 faccessat():
29 Since glibc 2.10:
30 _POSIX_C_SOURCE >= 200809L
31 Before glibc 2.10:
32 _ATFILE_SOURCE
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35 access() checks whether the calling process can access the file path‐
36 name. If pathname is a symbolic link, it is dereferenced.
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38 The mode specifies the accessibility check(s) to be performed, and is
39 either the value F_OK, or a mask consisting of the bitwise OR of one or
40 more of R_OK, W_OK, and X_OK. F_OK tests for the existence of the
41 file. R_OK, W_OK, and X_OK test whether the file exists and grants
42 read, write, and execute permissions, respectively.
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44 The check is done using the calling process's real UID and GID, rather
45 than the effective IDs as is done when actually attempting an operation
46 (e.g., open(2)) on the file. Similarly, for the root user, the check
47 uses the set of permitted capabilities rather than the set of effective
48 capabilities; and for non-root users, the check uses an empty set of
49 capabilities.
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51 This allows set-user-ID programs and capability-endowed programs to
52 easily determine the invoking user's authority. In other words, ac‐
53 cess() does not answer the "can I read/write/execute this file?" ques‐
54 tion. It answers a slightly different question: "(assuming I'm a se‐
55 tuid binary) can the user who invoked me read/write/execute this
56 file?", which gives set-user-ID programs the possibility to prevent ma‐
57 licious users from causing them to read files which users shouldn't be
58 able to read.
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60 If the calling process is privileged (i.e., its real UID is zero), then
61 an X_OK check is successful for a regular file if execute permission is
62 enabled for any of the file owner, group, or other.
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64 faccessat()
65 faccessat() operates in exactly the same way as access(), except for
66 the differences described here.
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68 If the pathname given in pathname is relative, then it is interpreted
69 relative to the directory referred to by the file descriptor dirfd
70 (rather than relative to the current working directory of the calling
71 process, as is done by access() for a relative pathname).
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73 If pathname is relative and dirfd is the special value AT_FDCWD, then
74 pathname is interpreted relative to the current working directory of
75 the calling process (like access()).
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77 If pathname is absolute, then dirfd is ignored.
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79 flags is constructed by ORing together zero or more of the following
80 values:
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82 AT_EACCESS
83 Perform access checks using the effective user and group IDs.
84 By default, faccessat() uses the real IDs (like access()).
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86 AT_SYMLINK_NOFOLLOW
87 If pathname is a symbolic link, do not dereference it: instead
88 return information about the link itself.
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90 See openat(2) for an explanation of the need for faccessat().
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92 faccessat2()
93 The description of faccessat() given above corresponds to POSIX.1 and
94 to the implementation provided by glibc. However, the glibc implemen‐
95 tation was an imperfect emulation (see BUGS) that papered over the fact
96 that the raw Linux faccessat() system call does not have a flags argu‐
97 ment. To allow for a proper implementation, Linux 5.8 added the fac‐
98 cessat2() system call, which supports the flags argument and allows a
99 correct implementation of the faccessat() wrapper function.
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102 On success (all requested permissions granted, or mode is F_OK and the
103 file exists), zero is returned. On error (at least one bit in mode
104 asked for a permission that is denied, or mode is F_OK and the file
105 does not exist, or some other error occurred), -1 is returned, and er‐
106 rno is set to indicate the error.
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109 EACCES The requested access would be denied to the file, or search per‐
110 mission is denied for one of the directories in the path prefix
111 of pathname. (See also path_resolution(7).)
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113 EBADF (faccessat()) pathname is relative but dirfd is neither AT_FDCWD
114 (faccessat()) nor a valid file descriptor.
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116 EFAULT pathname points outside your accessible address space.
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118 EINVAL mode was incorrectly specified.
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120 EINVAL (faccessat()) Invalid flag specified in flags.
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122 EIO An I/O error occurred.
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124 ELOOP Too many symbolic links were encountered in resolving pathname.
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126 ENAMETOOLONG
127 pathname is too long.
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129 ENOENT A component of pathname does not exist or is a dangling symbolic
130 link.
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132 ENOMEM Insufficient kernel memory was available.
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134 ENOTDIR
135 A component used as a directory in pathname is not, in fact, a
136 directory.
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138 ENOTDIR
139 (faccessat()) pathname is relative and dirfd is a file descrip‐
140 tor referring to a file other than a directory.
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142 EROFS Write permission was requested for a file on a read-only
143 filesystem.
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145 ETXTBSY
146 Write access was requested to an executable which is being exe‐
147 cuted.
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150 faccessat() was added to Linux in kernel 2.6.16; library support was
151 added to glibc in version 2.4.
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153 faccessat2() was added to Linux in version 5.8.
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156 access(): SVr4, 4.3BSD, POSIX.1-2001, POSIX.1-2008.
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158 faccessat(): POSIX.1-2008.
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160 faccessat2(): Linux-specific.
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163 Warning: Using these calls to check if a user is authorized to, for ex‐
164 ample, open a file before actually doing so using open(2) creates a se‐
165 curity hole, because the user might exploit the short time interval be‐
166 tween checking and opening the file to manipulate it. For this reason,
167 the use of this system call should be avoided. (In the example just
168 described, a safer alternative would be to temporarily switch the
169 process's effective user ID to the real ID and then call open(2).)
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171 access() always dereferences symbolic links. If you need to check the
172 permissions on a symbolic link, use faccessat() with the flag AT_SYM‐
173 LINK_NOFOLLOW.
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175 These calls return an error if any of the access types in mode is de‐
176 nied, even if some of the other access types in mode are permitted.
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178 If the calling process has appropriate privileges (i.e., is superuser),
179 POSIX.1-2001 permits an implementation to indicate success for an X_OK
180 check even if none of the execute file permission bits are set. Linux
181 does not do this.
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183 A file is accessible only if the permissions on each of the directories
184 in the path prefix of pathname grant search (i.e., execute) access. If
185 any directory is inaccessible, then the access() call fails, regardless
186 of the permissions on the file itself.
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188 Only access bits are checked, not the file type or contents. There‐
189 fore, if a directory is found to be writable, it probably means that
190 files can be created in the directory, and not that the directory can
191 be written as a file. Similarly, a DOS file may be reported as exe‐
192 cutable, but the execve(2) call will still fail.
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194 These calls may not work correctly on NFSv2 filesystems with UID map‐
195 ping enabled, because UID mapping is done on the server and hidden from
196 the client, which checks permissions. (NFS versions 3 and higher per‐
197 form the check on the server.) Similar problems can occur to FUSE
198 mounts.
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200 C library/kernel differences
201 The raw faccessat() system call takes only the first three arguments.
202 The AT_EACCESS and AT_SYMLINK_NOFOLLOW flags are actually implemented
203 within the glibc wrapper function for faccessat(). If either of these
204 flags is specified, then the wrapper function employs fstatat(2) to de‐
205 termine access permissions, but see BUGS.
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207 Glibc notes
208 On older kernels where faccessat() is unavailable (and when the AT_EAC‐
209 CESS and AT_SYMLINK_NOFOLLOW flags are not specified), the glibc wrap‐
210 per function falls back to the use of access(). When pathname is a
211 relative pathname, glibc constructs a pathname based on the symbolic
212 link in /proc/self/fd that corresponds to the dirfd argument.
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215 Because the Linux kernel's faccessat() system call does not support a
216 flags argument, the glibc faccessat() wrapper function provided in
217 glibc 2.32 and earlier emulates the required functionality using a com‐
218 bination of the faccessat() system call and fstatat(2). However, this
219 emulation does not take ACLs into account. Starting with glibc 2.33,
220 the wrapper function avoids this bug by making use of the faccessat2()
221 system call where it is provided by the underlying kernel.
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223 In kernel 2.4 (and earlier) there is some strangeness in the handling
224 of X_OK tests for superuser. If all categories of execute permission
225 are disabled for a nondirectory file, then the only access() test that
226 returns -1 is when mode is specified as just X_OK; if R_OK or W_OK is
227 also specified in mode, then access() returns 0 for such files. Early
228 2.6 kernels (up to and including 2.6.3) also behaved in the same way as
229 kernel 2.4.
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231 In kernels before 2.6.20, these calls ignored the effect of the
232 MS_NOEXEC flag if it was used to mount(2) the underlying filesystem.
233 Since kernel 2.6.20, the MS_NOEXEC flag is honored.
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236 chmod(2), chown(2), open(2), setgid(2), setuid(2), stat(2), euidac‐
237 cess(3), credentials(7), path_resolution(7), symlink(7)
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240 This page is part of release 5.13 of the Linux man-pages project. A
241 description of the project, information about reporting bugs, and the
242 latest version of this page, can be found at
243 https://www.kernel.org/doc/man-pages/.
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247Linux 2021-08-27 ACCESS(2)