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|
/* Sock functions
Copyright (C) 1995 Free Software Foundation, Inc.
Written by Miles Bader <miles@gnu.ai.mit.edu>
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2, or (at
your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
#include <string.h> /* For bzero() */
#include <cthreads.h>
#include <hurd/pipe.h>
#include "sock.h"
#include "sserver.h"
/* ---------------------------------------------------------------- */
/* Returns the pipe that SOCK is reading from in PIPE, locked and with an
additional reference, or an error saying why it's not possible. In the
case where the read should signal EOF, EPIPE is returned. SOCK mustn't be
locked. */
error_t
sock_acquire_read_pipe (struct sock *sock, struct pipe **pipe)
{
error_t err = 0;
mutex_lock (&sock->lock);
*pipe = sock->read_pipe;
if (*pipe != NULL)
/* SOCK may have a read pipe even before it's connected, so make
sure it really is. */
if ( !(sock->pipe_class->flags & PIPE_CLASS_CONNECTIONLESS)
&& !(sock->flags & SOCK_CONNECTED))
err = ENOTCONN;
else
pipe_acquire_reader (*pipe);
else if (sock->flags & SOCK_SHUTDOWN_READ)
/* Reading on a socket with the read-half shutdown always acts as if the
pipe were at eof, even if the socket isn't connected yet [at least in
netbsd]. */
err = EPIPE;
else
err = ENOTCONN;
mutex_unlock (&sock->lock);
return err;
}
/* Returns the pipe that SOCK is writing to in PIPE, locked and with an
additional reference, or an error saying why it's not possible. SOCK
mustn't be locked. */
error_t
sock_acquire_write_pipe (struct sock *sock, struct pipe **pipe)
{
error_t err = 0;
mutex_lock (&sock->lock);
*pipe = sock->write_pipe;
if (*pipe != NULL)
pipe_acquire_writer (*pipe); /* Do this before unlocking the sock! */
else if (sock->flags & SOCK_SHUTDOWN_WRITE)
/* Writing on a socket with the write-half shutdown always acts as if the
pipe were broken, even if the socket isn't connected yet [at least in
netbsd]. */
err = EPIPE;
else if (sock->pipe_class->flags & PIPE_CLASS_CONNECTIONLESS)
/* Connectionless protocols give a different error when unconnected. */
err = EDESTADDRREQ;
else
err = ENOTCONN;
mutex_unlock (&sock->lock);
return err;
}
/* ---------------------------------------------------------------- */
/* Return a new socket with the given pipe class in SOCK. */
error_t
sock_create (struct pipe_class *pipe_class, struct sock **sock)
{
error_t err;
static unsigned next_sock_id = 0;
struct sock *new = malloc (sizeof (struct sock));
if (new == NULL)
return ENOMEM;
/* A socket always has a read pipe (this is just to avoid some annoyance in
sock_connect), so create it here. */
err = pipe_create (pipe_class, &new->read_pipe);
if (err)
{
free (new);
return err;
}
pipe_add_reader (new->read_pipe);
new->refs = 0;
new->flags = 0;
new->write_pipe = NULL;
new->id = next_sock_id++;
new->listen_queue = NULL;
new->connect_queue = NULL;
new->pipe_class = pipe_class;
new->addr = NULL;
bzero (&new->change_time, sizeof (new->change_time));
mutex_init (&new->lock);
*sock = new;
return 0;
}
/* Free SOCK, assuming there are no more handle on it. */
void
sock_free (struct sock *sock)
{
sock_shutdown (sock, SOCK_SHUTDOWN_READ | SOCK_SHUTDOWN_WRITE);
free (sock);
}
/* Free a sock derefed too far. */
void
_sock_norefs (struct sock *sock)
{
/* A sock should never have an address when it has 0 refs, as the
address should hold a reference to the sock! */
assert (sock->addr == NULL);
mutex_unlock (&sock->lock); /* Unlock so sock_free can do stuff. */
sock_free (sock);
}
/* ---------------------------------------------------------------- */
/* Return a new socket largely copied from TEMPLATE. */
error_t
sock_clone (struct sock *template, struct sock **sock)
{
error_t err = sock_create (template->pipe_class, sock);
if (err)
return err;
/* Copy some properties from TEMPLATE. */
(*sock)->flags = template->flags & ~SOCK_CONNECTED;
return 0;
}
/* ---------------------------------------------------------------- */
struct port_class *sock_user_port_class;
/* Get rid of a user reference to a socket. */
static void
sock_user_clean (void *vuser)
{
struct sock_user *user = vuser;
sock_deref (user->sock);
}
/* Return a new user port on SOCK in PORT. */
error_t
sock_create_port (struct sock *sock, mach_port_t *port)
{
struct sock_user *user =
ports_allocate_port (sock_port_bucket,
sizeof (struct sock_user), sock_user_port_class);
if (!user)
return ENOMEM;
ensure_sock_server ();
mutex_lock (&sock->lock);
sock->refs++;
mutex_unlock (&sock->lock);
user->sock = sock;
*port = ports_get_right (user);
ports_port_deref (user); /* We only want one ref, for the send right. */
return 0;
}
/* ---------------------------------------------------------------- */
/* Address manipulation. */
struct addr
{
struct port_info pi;
struct sock *sock;
struct mutex lock;
};
struct port_class *addr_port_class;
/* Get rid of ADDR's socket's reference to it, in preparation for ADDR going
away. */
static void
addr_unbind (void *vaddr)
{
struct sock *sock;
struct addr *addr = vaddr;
mutex_lock (&addr->lock);
sock = addr->sock;
if (sock)
{
mutex_lock (&sock->lock);
sock->addr = NULL;
addr->sock = NULL;
ports_port_deref_weak (addr);
mutex_unlock (&sock->lock);
sock_deref (sock);
}
mutex_unlock (&addr->lock);
}
/* Cleanup after the address ADDR, which is going away... */
static void
addr_clean (void *vaddr)
{
struct addr *addr = vaddr;
/* ADDR should never have a socket bound to it at this point, as it should
have been removed by addr_unbind dropping the socket's weak reference
it. */
assert (addr->sock == NULL);
}
/* Return a new address, not connected to any socket yet, ADDR. */
inline error_t
addr_create (struct addr **addr)
{
*addr =
ports_allocate_port (sock_port_bucket,
sizeof (struct addr), addr_port_class);
if (! *addr)
return ENOMEM;
ensure_sock_server ();
(*addr)->sock = NULL;
mutex_init (&(*addr)->lock);
return 0;
}
/* Bind SOCK to ADDR. */
error_t
sock_bind (struct sock *sock, struct addr *addr)
{
error_t err = 0;
struct addr *old_addr;
mutex_lock (&addr->lock);
mutex_lock (&sock->lock);
old_addr = sock->addr;
if (addr && old_addr)
err = EINVAL; /* SOCK already bound. */
else if (addr && addr->sock)
err = EADDRINUSE; /* Something else already bound ADDR. */
else if (addr)
addr->sock = sock; /* First binding for SOCK. */
else
old_addr->sock = NULL; /* Unbinding SOCK. */
if (!err)
sock->addr = addr;
if (addr)
sock->refs++;
if (old_addr)
{
/* Note that we don't have to worry about SOCK's ref count going to zero
because whoever's calling us should be holding a ref somehow. */
sock->refs--;
assert (sock->refs > 0); /* But make sure... */
}
mutex_unlock (&sock->lock);
mutex_unlock (&addr->lock);
return err;
}
/* Returns SOCK's addr, with an additional reference, fabricating one if
necessary. SOCK should be locked. */
static inline error_t
ensure_addr (struct sock *sock, struct addr **addr)
{
error_t err = 0;
if (! sock->addr)
{
err = addr_create (&sock->addr);
if (!err)
{
sock->addr->sock = sock;
sock->refs++;
ports_port_ref_weak (sock->addr);
}
}
else
ports_port_ref (sock->addr);
if (!err)
*addr = sock->addr;
return err;
}
/* Returns the socket bound to ADDR in SOCK, or EADDRNOTAVAIL. The returned
sock will have one reference added to it. */
error_t
addr_get_sock (struct addr *addr, struct sock **sock)
{
mutex_lock (&addr->lock);
*sock = addr->sock;
if (*sock)
(*sock)->refs++;
mutex_unlock (&addr->lock);
return *sock ? 0 : EADDRNOTAVAIL;
}
/* Returns SOCK's address in ADDR, with an additional reference added. If
SOCK doesn't currently have an address, one is fabricated first. */
error_t
sock_get_addr (struct sock *sock, struct addr **addr)
{
error_t err;
mutex_lock (&sock->lock);
err = ensure_addr (sock, addr);
mutex_unlock (&sock->lock);
return err; /* XXX */
}
/* ---------------------------------------------------------------- */
/* We hold this lock before we lock two sockets at once, to prevent someone
else trying to lock the same two sockets in the reverse order, resulting
in a deadlock. */
static struct mutex socket_pair_lock;
/* Connect SOCK1 and SOCK2. */
error_t
sock_connect (struct sock *sock1, struct sock *sock2)
{
error_t err = 0;
/* In the case of a connectionless protocol, an already-connected socket may
be reconnected, so save the old destination for later disposal. */
struct pipe *old_sock1_write_pipe = NULL;
struct addr *old_sock1_write_addr = NULL;
void connect (struct sock *wr, struct sock *rd)
{
if (!( (wr->flags & SOCK_SHUTDOWN_WRITE)
|| (rd->flags & SOCK_SHUTDOWN_READ)))
{
struct pipe *pipe = rd->read_pipe;
assert (pipe); /* Since SOCK_SHUTDOWN_READ isn't set. */
pipe_add_writer (pipe);
wr->write_pipe = pipe;
}
}
if (sock1->pipe_class != sock2->pipe_class)
/* Incompatible socket types. */
return EOPNOTSUPP; /* XXX?? */
mutex_lock (&socket_pair_lock);
mutex_lock (&sock1->lock);
if (sock1 != sock2)
/* If SOCK1 == SOCK2, then we get a fifo! */
mutex_lock (&sock2->lock);
if ((sock1->flags & SOCK_CONNECTED) || (sock2->flags & SOCK_CONNECTED))
/* An already-connected socket. */
err = EISCONN;
else
{
old_sock1_write_pipe = sock1->write_pipe;
old_sock1_write_addr = sock1->write_addr;
/* Always make the forward connection. */
connect (sock1, sock2);
/* Only make the reverse for connection-oriented protocols. */
if (! (sock1->pipe_class->flags & PIPE_CLASS_CONNECTIONLESS))
{
sock1->flags |= SOCK_CONNECTED;
if (sock1 != sock2)
{
connect (sock2, sock1);
sock2->flags |= SOCK_CONNECTED;
}
}
}
if (sock1 != sock2)
mutex_unlock (&sock2->lock);
mutex_unlock (&sock1->lock);
mutex_unlock (&socket_pair_lock);
if (old_sock1_write_pipe)
{
pipe_remove_writer (old_sock1_write_pipe);
ports_port_deref (old_sock1_write_addr);
}
return err;
}
/* ---------------------------------------------------------------- */
/* Shutdown either the read or write halves of SOCK, depending on whether the
SOCK_SHUTDOWN_READ or SOCK_SHUTDOWN_WRITE flags are set in FLAGS. */
void
sock_shutdown (struct sock *sock, unsigned flags)
{
unsigned old_flags;
mutex_lock (&sock->lock);
old_flags = sock->flags;
sock->flags |= flags;
if (flags & SOCK_SHUTDOWN_READ && !(old_flags & SOCK_SHUTDOWN_READ))
/* Shutdown the read half. */
{
struct pipe *pipe = sock->read_pipe;
if (pipe != NULL)
{
sock->read_pipe = NULL;
/* Unlock SOCK here, as we may subsequently wake up other threads. */
mutex_unlock (&sock->lock);
pipe_remove_reader (pipe);
}
else
mutex_unlock (&sock->lock);
}
if (flags & SOCK_SHUTDOWN_WRITE && !(old_flags & SOCK_SHUTDOWN_WRITE))
/* Shutdown the write half. */
{
struct pipe *pipe = sock->write_pipe;
if (pipe != NULL)
{
sock->write_pipe = NULL;
/* Unlock SOCK here, as we may subsequently wake up other threads. */
mutex_unlock (&sock->lock);
pipe_remove_writer (pipe);
}
else
mutex_unlock (&sock->lock);
}
else
mutex_unlock (&sock->lock);
}
/* ---------------------------------------------------------------- */
error_t
sock_global_init ()
{
sock_port_bucket = ports_create_bucket ();
sock_user_port_class = ports_create_class (sock_user_clean, NULL);
addr_port_class = ports_create_class (addr_clean, addr_unbind);
return 0;
}
/* Try to shutdown any active sockets, returning EBUSY if we can't. */
error_t
sock_global_shutdown ()
{
int num_ports = ports_count_bucket (sock_port_bucket);
ports_enable_bucket (sock_port_bucket);
return (num_ports == 0 ? 0 : EBUSY);
}
|