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INTRO(2) FreeBSD System Calls Manual INTRO(2)
NAME
intro - introduction to system calls and error numbers
LIBRARY
Standard C Library (libc, -lc)
SYNOPSIS
#include <errno.h>
DESCRIPTION
This section provides an overview of the system calls, their error
returns, and other common definitions and concepts.
RETURN VALUES
Nearly all of the system calls provide an error number referenced via the
external identifier errno. This identifier is defined in <sys/errno.h>
as
extern int * __error();
#define errno (* __error())
The __error() function returns a pointer to a field in the thread
specific structure for threads other than the initial thread. For the
initial thread and non-threaded processes, __error() returns a pointer to
a global errno variable that is compatible with the previous definition.
When a system call detects an error, it returns an integer value
indicating failure (usually -1) and sets the variable errno accordingly.
(This allows interpretation of the failure on receiving a -1 and to take
action accordingly.) Successful calls never set errno; once set, it
remains until another error occurs. It should only be examined after an
error. Note that a number of system calls overload the meanings of these
error numbers, and that the meanings must be interpreted according to the
type and circumstances of the call.
The following is a complete list of the errors and their names as given
in <sys/errno.h>.
0 Undefined error: 0. Not used.
1 EPERM Operation not permitted. An attempt was made to perform an
operation limited to processes with appropriate privileges or to
the owner of a file or other resources.
2 ENOENT No such file or directory. A component of a specified pathname
did not exist, or the pathname was an empty string.
3 ESRCH No such process. No process could be found corresponding to that
specified by the given process ID.
4 EINTR Interrupted system call. An asynchronous signal (such as SIGINT
or SIGQUIT) was caught by the process during the execution of an
interruptible function. If the signal handler performs a normal
return, the interrupted system call will seem to have returned
the error condition.
5 EIO Input/output error. Some physical input or output error occurred.
example, a tape drive is not online or no disk pack is loaded on
a drive.
7 E2BIG Argument list too long. The number of bytes used for the argument
and environment list of the new process exceeded the current
limit (NCARGS in <sys/param.h>).
8 ENOEXEC Exec format error. A request was made to execute a file that,
although it has the appropriate permissions, was not in the
format required for an executable file.
9 EBADF Bad file descriptor. A file descriptor argument was out of range,
referred to no open file, or a read (write) request was made to a
file that was only open for writing (reading).
10 ECHILD No child processes. A wait(2) or waitpid(2) function was
executed by a process that had no existing or unwaited-for child
processes.
11 EDEADLK Resource deadlock avoided. An attempt was made to lock a
system resource that would have resulted in a deadlock situation.
12 ENOMEM Cannot allocate memory. The new process image required more
memory than was allowed by the hardware or by system-imposed
memory management constraints. A lack of swap space is normally
temporary; however, a lack of core is not. Soft limits may be
increased to their corresponding hard limits.
13 EACCES Permission denied. An attempt was made to access a file in a
way forbidden by its file access permissions.
14 EFAULT Bad address. The system detected an invalid address in
attempting to use an argument of a call.
15 ENOTBLK Block device required. A block device operation was attempted
on a non-block device or file.
16 EBUSY Device busy. An attempt to use a system resource which was in
use at the time in a manner which would have conflicted with the
request.
17 EEXIST File exists. An existing file was mentioned in an inappropriate
context, for instance, as the new link name in a link(2) system
call.
18 EXDEV Cross-device link. A hard link to a file on another file system
was attempted.
19 ENODEV Operation not supported by device. An attempt was made to apply
an inappropriate function to a device, for example, trying to
read a write-only device such as a printer.
20 ENOTDIR Not a directory. A component of the specified pathname
existed, but it was not a directory, when a directory was
expected.
21 EISDIR Is a directory. An attempt was made to open a directory with
write mode specified.
24 EMFILE Too many open files. Maximum number of file descriptors
allowable in the process has been reached and requests for an
open cannot be satisfied until at least one has been closed. The
getdtablesize(2) system call will obtain the current limit.
25 ENOTTY Inappropriate ioctl for device. A control function (see
ioctl(2)) was attempted for a file or special device for which
the operation was inappropriate.
26 ETXTBSY Text file busy. The new process was a pure procedure (shared
text) file which was open for writing by another process, or
while the pure procedure file was being executed an open(2) call
requested write access.
27 EFBIG File too large. The size of a file exceeded the maximum.
28 ENOSPC No space left on device. A write(2) to an ordinary file, the
creation of a directory or symbolic link, or the creation of a
directory entry failed because no more disk blocks were available
on the file system, or the allocation of an inode for a newly
created file failed because no more inodes were available on the
file system.
29 ESPIPE Illegal seek. An lseek(2) system call was issued on a socket,
pipe or FIFO.
30 EROFS Read-only file system. An attempt was made to modify a file or
directory on a file system that was read-only at the time.
31 EMLINK Too many links. Maximum allowable hard links to a single file
has been exceeded (limit of 32767 hard links per file).
32 EPIPE Broken pipe. A write on a pipe, socket or FIFO for which there
is no process to read the data.
33 EDOM Numerical argument out of domain. A numerical input argument was
outside the defined domain of the mathematical function.
34 ERANGE Result too large. A numerical result of the function was too
large to fit in the available space (perhaps exceeded precision).
35 EAGAIN Resource temporarily unavailable. This is a temporary condition
and later calls to the same routine may complete normally.
36 EINPROGRESS Operation now in progress. An operation that takes a long
time to complete (such as a connect(2)) was attempted on a non-
blocking object (see fcntl(2)).
37 EALREADY Operation already in progress. An operation was attempted on
a non-blocking object that already had an operation in progress.
38 ENOTSOCK Socket operation on non-socket. Self-explanatory.
39 EDESTADDRREQ Destination address required. A required address was
omitted from an operation on a socket.
40 EMSGSIZE Message too long. A message sent on a socket was larger than
the internal message buffer or some other network limit.
specified in a getsockopt(2) or setsockopt(2) call.
43 EPROTONOSUPPORT Protocol not supported. The protocol has not been
configured into the system or no implementation for it exists.
44 ESOCKTNOSUPPORT Socket type not supported. The support for the socket
type has not been configured into the system or no implementation
for it exists.
45 EOPNOTSUPP Operation not supported. The attempted operation is not
supported for the type of object referenced. Usually this occurs
when a file descriptor refers to a file or socket that cannot
support this operation, for example, trying to accept a
connection on a datagram socket.
46 EPFNOSUPPORT Protocol family not supported. The protocol family has
not been configured into the system or no implementation for it
exists.
47 EAFNOSUPPORT Address family not supported by protocol family. An
address incompatible with the requested protocol was used. For
example, you should not necessarily expect to be able to use NS
addresses with ARPA Internet protocols.
48 EADDRINUSE Address already in use. Only one usage of each address is
normally permitted.
49 EADDRNOTAVAIL Can't assign requested address. Normally results from an
attempt to create a socket with an address not on this machine.
50 ENETDOWN Network is down. A socket operation encountered a dead
network.
51 ENETUNREACH Network is unreachable. A socket operation was attempted
to an unreachable network.
52 ENETRESET Network dropped connection on reset. The host you were
connected to crashed and rebooted.
53 ECONNABORTED Software caused connection abort. A connection abort was
caused internal to your host machine.
54 ECONNRESET Connection reset by peer. A connection was forcibly closed
by a peer. This normally results from a loss of the connection
on the remote socket due to a timeout or a reboot.
55 ENOBUFS No buffer space available. An operation on a socket or pipe
was not performed because the system lacked sufficient buffer
space or because a queue was full.
56 EISCONN Socket is already connected. A connect(2) request was made on
an already connected socket; or, a sendto(2) or sendmsg(2)
request on a connected socket specified a destination when
already connected.
57 ENOTCONN Socket is not connected. An request to send or receive data
was disallowed because the socket was not connected and (when
sending on a datagram socket) no address was supplied.
communication protocol.)
61 ECONNREFUSED Connection refused. No connection could be made because
the target machine actively refused it. This usually results
from trying to connect to a service that is inactive on the
foreign host.
62 ELOOP Too many levels of symbolic links. A path name lookup involved
more than 32 (MAXSYMLINKS) symbolic links.
63 ENAMETOOLONG File name too long. A component of a path name exceeded
{NAME_MAX} characters, or an entire path name exceeded {PATH_MAX}
characters. (See also the description of _PC_NO_TRUNC in
pathconf(2).)
64 EHOSTDOWN Host is down. A socket operation failed because the
destination host was down.
65 EHOSTUNREACH No route to host. A socket operation was attempted to an
unreachable host.
66 ENOTEMPTY Directory not empty. A directory with entries other than `.'
and `..' was supplied to a remove directory or rename call.
67 EPROCLIM Too many processes.
68 EUSERS Too many users. The quota system ran out of table entries.
69 EDQUOT Disc quota exceeded. A write(2) to an ordinary file, the
creation of a directory or symbolic link, or the creation of a
directory entry failed because the user's quota of disk blocks
was exhausted, or the allocation of an inode for a newly created
file failed because the user's quota of inodes was exhausted.
70 ESTALE Stale NFS file handle. An attempt was made to access an open
file (on an NFS file system) which is now unavailable as
referenced by the file descriptor. This may indicate the file
was deleted on the NFS server or some other catastrophic event
occurred.
72 EBADRPC RPC struct is bad. Exchange of RPC information was
unsuccessful.
73 ERPCMISMATCH RPC version wrong. The version of RPC on the remote peer
is not compatible with the local version.
74 EPROGUNAVAIL RPC prog. not avail. The requested program is not
registered on the remote host.
75 EPROGMISMATCH Program version wrong. The requested version of the
program is not available on the remote host (RPC).
76 EPROCUNAVAIL Bad procedure for program. An RPC call was attempted for
a procedure which does not exist in the remote program.
77 ENOLCK No locks available. A system-imposed limit on the number of
simultaneous file locks was reached.
78 ENOSYS Function not implemented. Attempted a system call that is not
81 ENEEDAUTH Need authenticator. An authentication ticket must be
obtained before the given NFS file system may be mounted.
82 EIDRM Identifier removed. An IPC identifier was removed while the
current process was waiting on it.
83 ENOMSG No message of desired type. An IPC message queue does not
contain a message of the desired type, or a message catalog does
not contain the requested message.
84 EOVERFLOW Value too large to be stored in data type. A numerical
result of the function was too large to be stored in the caller
provided space.
85 ECANCELED Operation canceled. The scheduled operation was canceled.
86 EILSEQ Illegal byte sequence. While decoding a multibyte character the
function came along an invalid or an incomplete sequence of bytes
or the given wide character is invalid.
87 ENOATTR Attribute not found. The specified extended attribute does not
exist.
88 EDOOFUS Programming error. A function or API is being abused in a way
which could only be detected at run-time.
89 EBADMSG Bad message. A corrupted message was detected.
90 EMULTIHOP Multihop attempted. This error code is unused, but present
for compatibility with other systems.
91 ENOLINK Link has been severed. This error code is unused, but present
for compatibility with other systems.
92 EPROTO Protocol error. A device or socket encountered an unrecoverable
protocol error.
93 ENOTCAPABLE Capabilities insufficient. An operation on a capability
file descriptor requires greater privilege than the capability
allows.
94 ECAPMODE Not permitted in capability mode. The system call or
operation is not permitted for capability mode processes.
95 ENOTRECOVERABLE State not recoverable. The state protected by a robust
mutex is not recoverable.
96 EOWNERDEAD Previous owner died. The owner of a robust mutex terminated
while holding the mutex lock.
97 EINTEGRITY Integrity check failed. An integrity check such as a check-
hash or a cross-correlation failed. The integrity error falls in
the kernel I/O stack between EINVAL that identifies errors in
parameters to a system call and EIO that identifies errors with
the underlying storage media. It is typically raised by
intermediate kernel layers such as a filesystem or an in-kernel
GEOM subsystem when they detect inconsistencies. Uses include
allowing the mount(8) command to return a different exit value to
Parent process ID
A new process is created by a currently active process (see
fork(2)). The parent process ID of a process is initially the
process ID of its creator. If the creating process exits, the
parent process ID of each child is set to the ID of the calling
process's reaper (see procctl(2)), normally init(8).
Process Group
Each active process is a member of a process group that is
identified by a non-negative integer called the process group ID.
This is the process ID of the group leader. This grouping
permits the signaling of related processes (see termios(4)) and
the job control mechanisms of csh(1).
Session
A session is a set of one or more process groups. A session is
created by a successful call to setsid(2), which causes the
caller to become the only member of the only process group in the
new session.
Session leader
A process that has created a new session by a successful call to
setsid(2), is known as a session leader. Only a session leader
may acquire a terminal as its controlling terminal (see
termios(4)).
Controlling process
A session leader with a controlling terminal is a controlling
process.
Controlling terminal
A terminal that is associated with a session is known as the
controlling terminal for that session and its members.
Terminal Process Group ID
A terminal may be acquired by a session leader as its controlling
terminal. Once a terminal is associated with a session, any of
the process groups within the session may be placed into the
foreground by setting the terminal process group ID to the ID of
the process group. This facility is used to arbitrate between
multiple jobs contending for the same terminal; (see csh(1) and
tty(4)).
Orphaned Process Group
A process group is considered to be orphaned if it is not under
the control of a job control shell. More precisely, a process
group is orphaned when none of its members has a parent process
that is in the same session as the group, but is in a different
process group. Note that when a process exits, the parent
process for its children is normally changed to be init(8), which
is in a separate session. Not all members of an orphaned process
group are necessarily orphaned processes (those whose creating
process has exited). The process group of a session leader is
orphaned by definition.
Real User ID and Real Group ID
Each user on the system is identified by a positive integer
termed the real user ID.
initialized from the equivalent attributes of the process that
created it.
Effective User Id, Effective Group Id, and Group Access List
Access to system resources is governed by two values: the
effective user ID, and the group access list. The first member
of the group access list is also known as the effective group ID.
(In POSIX.1, the group access list is known as the set of
supplementary group IDs, and it is unspecified whether the
effective group ID is a member of the list.)
The effective user ID and effective group ID are initially the
process's real user ID and real group ID respectively. Either
may be modified through execution of a set-user-ID or set-group-
ID file (possibly by one its ancestors) (see execve(2)). By
convention, the effective group ID (the first member of the group
access list) is duplicated, so that the execution of a set-group-
ID program does not result in the loss of the original (real)
group ID.
The group access list is a set of group IDs used only in
determining resource accessibility. Access checks are performed
as described below in ``File Access Permissions''.
Saved Set User ID and Saved Set Group ID
When a process executes a new file, the effective user ID is set
to the owner of the file if the file is set-user-ID, and the
effective group ID (first element of the group access list) is
set to the group of the file if the file is set-group-ID. The
effective user ID of the process is then recorded as the saved
set-user-ID, and the effective group ID of the process is
recorded as the saved set-group-ID. These values may be used to
regain those values as the effective user or group ID after
reverting to the real ID (see setuid(2)). (In POSIX.1, the saved
set-user-ID and saved set-group-ID are optional, and are used in
setuid and setgid, but this does not work as desired for the
super-user.)
Super-user
A process is recognized as a super-user process and is granted
special privileges if its effective user ID is 0.
Descriptor
An integer assigned by the system when a file is referenced by
open(2) or dup(2), or when a socket is created by pipe(2),
socket(2) or socketpair(2), which uniquely identifies an access
path to that file or socket from a given process or any of its
children.
File Name
Names consisting of up to {NAME_MAX} characters may be used to
name an ordinary file, special file, or directory.
These characters may be arbitrary eight-bit values, excluding NUL
(ASCII 0) and the `/' character (slash, ASCII 47).
Note that it is generally unwise to use `*', `?', `[' or `]' as
part of file names because of the special meaning attached to
these characters by the shell.
If a path name begins with a slash, the path search begins at the
root directory. Otherwise, the search begins from the current
working directory. A slash by itself names the root directory.
An empty pathname refers to the current directory.
Directory
A directory is a special type of file that contains entries that
are references to other files. Directory entries are called
links. By convention, a directory contains at least two links,
`.' and `..', referred to as dot and dot-dot respectively. Dot
refers to the directory itself and dot-dot refers to its parent
directory.
Root Directory and Current Working Directory
Each process has associated with it a concept of a root directory
and a current working directory for the purpose of resolving path
name searches. A process's root directory need not be the root
directory of the root file system.
File Access Permissions
Every file in the file system has a set of access permissions.
These permissions are used in determining whether a process may
perform a requested operation on the file (such as opening a file
for writing). Access permissions are established at the time a
file is created. They may be changed at some later time through
the chmod(2) call.
File access is broken down according to whether a file may be:
read, written, or executed. Directory files use the execute
permission to control if the directory may be searched.
File access permissions are interpreted by the system as they
apply to three different classes of users: the owner of the file,
those users in the file's group, anyone else. Every file has an
independent set of access permissions for each of these classes.
When an access check is made, the system decides if permission
should be granted by checking the access information applicable
to the caller.
Read, write, and execute/search permissions on a file are granted
to a process if:
The process's effective user ID is that of the super-user.
(Note: even the super-user cannot execute a non-executable file.)
The process's effective user ID matches the user ID of the owner
of the file and the owner permissions allow the access.
The process's effective user ID does not match the user ID of the
owner of the file, and either the process's effective group ID
matches the group ID of the file, or the group ID of the file is
in the process's group access list, and the group permissions
allow the access.
Neither the effective user ID nor effective group ID and group
access list of the process match the corresponding user ID and
group ID of the file, but the permissions for ``other users''
allow access.
Sockets are typed according to their communications properties.
These properties include whether messages sent and received at a
socket require the name of the partner, whether communication is
reliable, the format used in naming message recipients, etc.
Each instance of the system supports some collection of socket
types; consult socket(2) for more information about the types
available and their properties.
Each instance of the system supports some number of sets of
communications protocols. Each protocol set supports addresses
of a certain format. An Address Family is the set of addresses
for a specific group of protocols. Each socket has an address
chosen from the address family in which the socket was created.
SEE ALSO
intro(3), perror(3)
FreeBSD 14.0-RELEASE-p11 September 8, 2016 FreeBSD 14.0-RELEASE-p11