SOCKET(9) | Kernel Developer's Manual | SOCKET(9) |
socket
— kernel
socket interface
#include
<sys/socket.h>
#include <sys/socketvar.h>
void
soabort
(struct
socket *so);
int
soaccept
(struct
socket *so, struct
sockaddr **nam);
int
socheckuid
(struct
socket *so, uid_t
uid);
int
sobind
(struct
socket *so, struct
sockaddr *nam, struct
thread *td);
void
soclose
(struct
socket *so);
int
soconnect
(struct
socket *so, struct
sockaddr *nam, struct
thread *td);
int
socreate
(int dom,
struct socket **aso, int type,
int proto, struct ucred *cred,
struct thread *td);
int
sodisconnect
(struct
socket *so);
void
sodtor_set
(struct socket *so,
void (*func)(struct socket *));
struct sockaddr *
sodupsockaddr
(const
struct sockaddr *sa, int
mflags);
void
sofree
(struct
socket *so);
void
sohasoutofband
(struct
socket *so);
int
solisten
(struct
socket *so, int
backlog, struct thread
*td);
void
solisten_proto
(struct
socket *so, int
backlog);
int
solisten_proto_check
(struct
socket *so);
struct socket *
sonewconn
(struct
socket *head, int
connstatus);
int
sopoll
(struct socket *so,
int events, struct ucred
*active_cred, struct thread *td);
int
sopoll_generic
(struct socket
*so, int events, struct ucred
*active_cred, struct thread *td);
int
soreceive
(struct socket *so,
struct sockaddr **psa, struct uio
*uio, struct mbuf **mp0, struct
mbuf **controlp, int *flagsp);
int
soreceive_stream
(struct socket
*so, struct sockaddr **paddr,
struct uio *uio, struct mbuf
**mp0, struct mbuf **controlp,
int *flagsp);
int
soreceive_dgram
(struct socket
*so, struct sockaddr **paddr,
struct uio *uio, struct mbuf
**mp0, struct mbuf **controlp,
int *flagsp);
int
soreceive_generic
(struct socket
*so, struct sockaddr **paddr,
struct uio *uio, struct mbuf
**mp0, struct mbuf **controlp,
int *flagsp);
int
soreserve
(struct
socket *so, u_long
sndcc, u_long
rcvcc);
void
sorflush
(struct
socket *so);
int
sosend
(struct socket *so,
struct sockaddr *addr, struct uio
*uio, struct mbuf *top, struct
mbuf *control, int flags, struct
thread *td);
int
sosend_dgram
(struct socket *so,
struct sockaddr *addr, struct uio
*uio, struct mbuf *top, struct
mbuf *control, int flags, struct
thread *td);
int
sosend_generic
(struct socket
*so, struct sockaddr *addr,
struct uio *uio, struct mbuf
*top, struct mbuf *control, int
flags, struct thread *td);
int
soshutdown
(struct
socket *so, int
how);
void
sotoxsocket
(struct
socket *so, struct
xsocket *xso);
void
soupcall_clear
(struct
socket *so, int
which);
void
soupcall_set
(struct socket *so,
int which, int (*func)(struct socket
*, void *, int), void *arg);
void
sowakeup
(struct
socket *so, struct
sockbuf *sb);
#include
<sys/sockopt.h>
int
sosetopt
(struct
socket *so, struct
sockopt *sopt);
int
sogetopt
(struct
socket *so, struct
sockopt *sopt);
int
sooptcopyin
(struct
sockopt *sopt, void
*buf, size_t len,
size_t minlen);
int
sooptcopyout
(struct
sockopt *sopt, const void
*buf, size_t
len);
The kernel socket
programming interface
permits in-kernel consumers to interact with local and network socket
objects in a manner similar to that permitted using the
socket(2) user API. These interfaces are appropriate for
use by distributed file systems and other network-aware kernel services.
While the user API operates on file descriptors, the kernel interfaces
operate directly on struct socket pointers. Some
portions of the kernel API exist only to implement the user API, and are not
expected to be used by kernel code. The portions of the socket API used by
socket consumers and implementations of network protocols will differ; some
routines are only useful for protocol implementors.
Except where otherwise indicated, socket
functions may sleep, and are not appropriate for use in an
ithread(9) context or while holding non-sleepable kernel
locks.
A new socket may be created using
socreate
().
As with socket(2), arguments specify the requested domain,
type, and protocol via dom,
type, and proto. The socket is
returned via aso on success. In addition, the
credential used to authorize operations associated with the socket will be
passed via cred (and will be cached for the lifetime
of the socket), and the thread performing the operation via
td.
Warning:
authorization of the socket creation operation will be performed using the
thread credential for some protocols (such as raw sockets).
Sockets may be closed and freed using
soclose
(),
which has similar semantics to close(2).
In certain circumstances, it is appropriate to
destroy a socket without waiting for it to disconnect, for which
soabort
()
is used. This is only appropriate for incoming connections which are in a
partially connected state. It must be called on an unreferenced socket, by
the thread which removed the socket from its listen queue, to prevent races.
It will call into protocol code, so no socket locks may be held over the
call. The caller of soabort
() is responsible for
setting the VNET context. The normal path to freeing a socket is
sofree
(),
which handles reference counting on the socket. It should be called whenever
a reference is released, and also whenever reference flags are cleared in
socket or protocol code. Calls to sofree
() should
not be made from outside the socket layer; outside callers should use
soclose
() instead.
The
sobind
()
function is equivalent to the bind(2) system call, and
binds the socket so to the address
nam. The operation would be authorized using the
credential on thread td.
The
soconnect
()
function is equivalent to the connect(2) system call, and
initiates a connection on the socket so to the address
nam. The operation will be authorized using the
credential on thread td. Unlike the user system call,
soconnect
() returns immediately; the caller may
msleep(9) on so->so_timeo while
holding the socket mutex and waiting for the
SS_ISCONNECTING
flag to clear or
so->so_error to become non-zero. If
soconnect
() fails, the caller must manually clear
the SS_ISCONNECTING
flag.
A call to
sodisconnect
()
disconnects the socket without closing it.
The
soshutdown
()
function is equivalent to the shutdown(2) system call, and
causes part or all of a connection on a socket to be closed down.
Sockets are transitioned from non-listening status
to listening with
solisten
().
The sogetopt
() function is equivalent to
the getsockopt(2) system call, and retrieves a socket
option on socket so. The
sosetopt
() function is equivalent to the
setsockopt(2) system call, and sets a socket option on
socket so.
The second argument in both
sogetopt
()
and
sosetopt
()
is the sopt pointer to a struct
sopt describing the socket option operation. The caller-allocated
structure must be zeroed, and then have its fields initialized to specify
socket option operation arguments:
SOPT_SET
or
SOPT_GET
depending on whether this is a get or set
operation.SOL_SOCKET
.In order for the owner of a socket to be notified when the socket
is ready to send or receive data, an upcall may be registered on the socket.
The upcall is a function that will be called by the socket framework when a
socket buffer associated with the given socket is ready for reading or
writing.
soupcall_set
()
is used to register a socket upcall. The function func
is registered, and the pointer arg will be passed as
its second argument when it is called by the framework. The possible values
for which are SO_RCV
and
SO_SND
, which register upcalls for receive and send
events, respectively. The upcall function
func
()
must return either SU_OK
or
SU_ISCONNECTED
, depending on whether or not a call
to soisconnected should be made by the socket framework
after the upcall returns. The upcall func cannot call
soisconnected itself due to lock ordering with the socket
buffer lock. Only SO_RCV
upcalls should return
SU_ISCONNECTED
. When a
SO_RCV
upcall returns
SU_ISCONNECTED
, the upcall will be removed from the
socket.
Upcalls are removed from their socket by
soupcall_clear
().
The which argument again specifies whether the sending
or receiving upcall is to be cleared, with SO_RCV
or
SO_SND
.
A kernel system can use the
sodtor_set
()
function to set a destructor for a socket. The destructor is called when the
socket is is about to be freed. The destructor is called before the protocol
detach routine. The destructor can serve as a callback to initiate
additional cleanup actions.
The
soreceive
()
function is equivalent to the recvmsg(2) system call, and
attempts to receive bytes of data from the socket so,
optionally blocking awaiting for data if none is ready to read. Data may be
retrieved directly to kernel or user memory via the
uio argument, or as an mbuf chain returned to the
caller via mp0, avoiding a data copy. The
uio must always be non-NULL
.
If mp0 is non-NULL
, only the
uio_resid of uio is used. The
caller may optionally retrieve a socket address on a protocol with the
PR_ADDR
capability by providing storage via
non-NULL
psa argument. The
caller may optionally retrieve control data mbufs via a
non-NULL
controlp argument.
Optional flags may be passed to soreceive
() via a
non-NULL
flagsp argument, and
use the same flag name space as the recvmsg(2) system
call.
The
sosend
()
function is equivalent to the sendmsg(2) system call, and
attempts to send bytes of data via the socket so,
optionally blocking if data cannot be immediately sent. Data may be sent
directly from kernel or user memory via the uio
argument, or as an mbuf chain via top, avoiding a data
copy. Only one of the uio or top
pointers may be non-NULL
. An optional destination
address may be specified via a non-NULL
addr argument, which may result in an implicit connect
if supported by the protocol. The caller may optionally send control data
mbufs via a non-NULL
control
argument. Flags may be passed to sosend
() using the
flags argument, and use the same flag name space as
the sendmsg(2) system call.
Kernel callers running in ithread(9) context, or
with a mutex held, will wish to use non-blocking sockets and pass the
MSG_DONTWAIT
flag in order to prevent these
functions from sleeping.
A socket can be queried for readability, writability,
out-of-band data, or end-of-file using
sopoll
().
The possible values for events are as for
poll(2), with symbolic values
POLLIN
, POLLPRI
,
POLLOUT
, POLLRDNORM
,
POLLWRNORM
, POLLRDBAND
, and
POLLINGEOF
taken from
<sys/poll.h>
.
Calls to
soaccept
()
pass through to the protocol's accept routine to accept an incoming
connection.
The uid of a socket's credential may be compared against a
uid with
socheckuid
().
A copy of an existing struct
sockaddr may be made using
sodupsockaddr
().
Protocol implementations notify the socket
layer of the arrival of out-of-band data using
sohasoutofband
(),
so that the socket layer can notify socket consumers of the available
data.
An “external-format” version of a
struct socket can be created using
sotoxsocket
(),
suitable for isolating user code from changes in the kernel structure.
Protocols must supply an implementation for
solisten
(); such protocol implementations can call
back into the socket layer using
solisten_proto_check
()
and
solisten_proto
()
to check and set the socket-layer listen state. These callbacks are provided
so that the protocol implementation can order the socket layer and protocol
locks as necessary. Protocols must supply an implementation of
soreceive
(); the functions
soreceive_stream
(),
soreceive_dgram
(),
and
soreceive_generic
()
are supplied for use by such implementations.
Protocol implementations can use
sonewconn
()
to create a socket and attach protocol state to that socket. This can be
used to create new sockets available for soaccept
()
on a listen socket. The returned socket has a reference count of zero.
Protocols must supply an implementation for
sopoll
();
sopoll_generic
()
is provided for the use by protocol implementations.
The functions
sosend_dgram
()
and
sosend_generic
()
are supplied to assist in protocol implementations of
sosend
().
When a protocol creates a new socket structure, it
is necessary to reserve socket buffer space for that socket, by calling
soreserve
().
The rough inverse of this reservation is performed by
sorflush
(),
which is called automatically by the socket framework.
When a protocol needs to wake up threads waiting for
the socket to become ready to read or write, variants of
sowakeup
()
are used. The sowakeup
() function should not be
called directly by protocol code, instead use the wrappers
sorwakeup
(),
sorwakeup_locked
(),
sowwakeup
(),
and
sowwakeup_locked
()
for readers and writers, with the corresponding socket buffer lock not
already locked, or already held, respectively.
The functions
sooptcopyin
()
and
sooptcopyout
()
are useful for transferring struct sockopt data
between user and kernel code.
bind(2), close(2), connect(2), getsockopt(2), recv(2), send(2), setsockopt(2), shutdown(2), socket(2), ng_ksocket(4), ithread(9), msleep(9), ucred(9)
The socket(2) system call appeared in 4.2BSD. This manual page was introduced in FreeBSD 7.0.
This manual page was written by Robert
Watson and
Benjamin Kaduk.
The use of explicitly passed credentials, credentials hung from
explicitly passed threads, the credential on
curthread
, and the cached credential from socket
creation time is inconsistent, and may lead to unexpected behaviour. It is
possible that several of the td arguments should be
cred arguments, or simply not be present at all.
The caller may need to manually clear
SS_ISCONNECTING
if
soconnect
() returns an error.
The MSG_DONTWAIT
flag is not implemented
for sosend
(), and may not always work with
soreceive
() when zero copy sockets are enabled.
This manual page does not describe how to register socket upcalls or monitor a socket for readability/writability without using blocking I/O.
The soref
() and
sorele
() functions are not described, and in most
cases should not be used, due to confusing and potentially incorrect
interactions when sorele
() is last called after
soclose
().
October 18, 2018 | Debian |