/*
* $Id$
*/
#define RTEMS_FAST_MUTEX
#ifdef RTEMS_FAST_MUTEX
#define __RTEMS_VIOLATE_KERNEL_VISIBILITY__ 1
#endif
#include <string.h>
#include <stdarg.h>
#include <stdio.h>
#include <errno.h>
#include <rtems.h>
#include <rtems/libio.h>
#include <rtems/error.h>
#include <rtems/rtems_bsdnet.h>
#include <sys/types.h>
#include <sys/param.h>
#include <sys/domain.h>
#include <sys/mbuf.h>
#include <sys/socketvar.h>
#include <sys/socket.h>
#include <sys/sockio.h>
#include <sys/callout.h>
#include <sys/proc.h>
#include <sys/ioctl.h>
#include <net/if.h>
#include <net/route.h>
#include <netinet/in.h>
#include <vm/vm.h>
#include <arpa/inet.h>
#include <net/netisr.h>
#include <net/route.h>
/*
* Sysctl init all.
*/
void sysctl_register_all(void *arg);
/*
* Memory allocation
*/
static int nmbuf = (64 * 1024) / MSIZE;
int nmbclusters = (128 * 1024) / MCLBYTES;
/*
* Socket buffering parameters
*/
unsigned long sb_efficiency = 8;
/*
* Network task synchronization
*/
static rtems_id networkSemaphore;
#ifdef RTEMS_FAST_MUTEX
Semaphore_Control *the_networkSemaphore;
#endif
static rtems_id networkDaemonTid;
static rtems_unsigned32 networkDaemonPriority;
static void networkDaemon (void *task_argument);
/*
* Network timing
*/
int rtems_bsdnet_ticks_per_second;
int rtems_bsdnet_microseconds_per_tick;
/*
* Callout processing
*/
static rtems_interval ticksWhenCalloutsLastChecked;
static struct callout *callfree, calltodo;
/*
* FreeBSD variables
*/
int nfs_diskless_valid;
/*
* BOOTP values
*/
struct in_addr rtems_bsdnet_log_host_address = {0};
struct in_addr rtems_bsdnet_bootp_server_address = {0};
char *rtems_bsdnet_bootp_boot_file_name = 0;
char *rtems_bsdnet_bootp_server_name = 0;
char *rtems_bsdnet_domain_name = 0;
char *rtems_bsdnet_bootp_cmdline = 0;
struct in_addr rtems_bsdnet_nameserver[sizeof rtems_bsdnet_config.name_server /
sizeof rtems_bsdnet_config.name_server[0]];
int rtems_bsdnet_nameserver_count = 0;
struct in_addr rtems_bsdnet_ntpserver[sizeof rtems_bsdnet_config.ntp_server /
sizeof rtems_bsdnet_config.ntp_server[0]];
int rtems_bsdnet_ntpserver_count = 0;
long rtems_bsdnet_timeoffset = 0;
/*
* Perform FreeBSD memory allocation.
* FIXME: This should be modified to keep memory allocation statistics.
*/
#undef malloc
#undef free
extern void *malloc (size_t);
extern void free (void *);
void *
rtems_bsdnet_malloc (unsigned long size, int type, int flags)
{
void *p;
int try = 0;
for (;;) {
p = malloc (size);
if (p || (flags & M_NOWAIT))
return p;
rtems_bsdnet_semaphore_release ();
if (++try >= 30) {
rtems_bsdnet_malloc_starvation();
try = 0;
}
rtems_task_wake_after (rtems_bsdnet_ticks_per_second);
rtems_bsdnet_semaphore_obtain ();
}
}
/*
* Free FreeBSD memory
* FIXME: This should be modified to keep memory allocation statistics.
*/
void
rtems_bsdnet_free (void *addr, int type)
{
free (addr);
}
/*
* Do the initializations required by the BSD code
*/
static int
bsd_init (void)
{
int i;
char *p;
/*
* Set up mbuf cluster data strutures
*/
p = malloc ((nmbclusters*MCLBYTES)+MCLBYTES-1);
if (p == NULL) {
printf ("Can't get network cluster memory.\n");
return -1;
}
p = (char *)(((unsigned long)p + (MCLBYTES-1)) & ~(MCLBYTES-1));
mbutl = (struct mbuf *)p;
for (i = 0; i < nmbclusters; i++) {
((union mcluster *)p)->mcl_next = mclfree;
mclfree = (union mcluster *)p;
p += MCLBYTES;
mbstat.m_clfree++;
}
mbstat.m_clusters = nmbclusters;
mclrefcnt = malloc (nmbclusters);
if (mclrefcnt == NULL) {
printf ("Can't get mbuf cluster reference counts memory.\n");
return -1;
}
memset (mclrefcnt, '\0', nmbclusters);
/*
* Set up mbuf data structures
*/
p = malloc(nmbuf * MSIZE + MSIZE - 1);
p = (char *)(((unsigned int)p + MSIZE - 1) & ~(MSIZE - 1));
if (p == NULL) {
printf ("Can't get network memory.\n");
return -1;
}
for (i = 0; i < nmbuf; i++) {
((struct mbuf *)p)->m_next = mmbfree;
mmbfree = (struct mbuf *)p;
p += MSIZE;
}
mbstat.m_mbufs = nmbuf;
mbstat.m_mtypes[MT_FREE] = nmbuf;
/*
* Set up domains
*/
{
extern struct domain routedomain;
extern struct domain inetdomain;
routedomain.dom_next = domains;
domains = &routedomain;
inetdomain.dom_next = domains;
domains = &inetdomain;
domaininit (NULL);
}
/*
* Setup the sysctl, normally done by a SYSINIT call.
*/
sysctl_register_all(0);
/*
* Set up interfaces
*/
ifinit (NULL);
return 0;
}
/*
* Initialize and start network operations
*/
static int
rtems_bsdnet_initialize (void)
{
rtems_status_code sc;
/*
* Set the priority of all network tasks
*/
if (rtems_bsdnet_config.network_task_priority == 0)
networkDaemonPriority = 100;
else
networkDaemonPriority = rtems_bsdnet_config.network_task_priority;
/*
* Set the memory allocation limits
*/
if (rtems_bsdnet_config.mbuf_bytecount)
nmbuf = rtems_bsdnet_config.mbuf_bytecount / MSIZE;
if (rtems_bsdnet_config.mbuf_cluster_bytecount)
nmbclusters = rtems_bsdnet_config.mbuf_cluster_bytecount / MCLBYTES;
/*
* Create the task-synchronization semaphore
*/
sc = rtems_semaphore_create (rtems_build_name('B', 'S', 'D', 'n'),
0,
RTEMS_PRIORITY |
RTEMS_BINARY_SEMAPHORE |
RTEMS_INHERIT_PRIORITY |
RTEMS_NO_PRIORITY_CEILING |
RTEMS_LOCAL,
0,
&networkSemaphore);
if (sc != RTEMS_SUCCESSFUL) {
printf ("Can't create network seamphore: `%s'\n", rtems_status_text (sc));
return -1;
}
#ifdef RTEMS_FAST_MUTEX
{
Objects_Locations location;
the_networkSemaphore = _Semaphore_Get( networkSemaphore, &location );
_Thread_Enable_dispatch();
}
#endif
/*
* Compute clock tick conversion factors
*/
rtems_clock_get (RTEMS_CLOCK_GET_TICKS_PER_SECOND, &rtems_bsdnet_ticks_per_second);
if (rtems_bsdnet_ticks_per_second <= 0)
rtems_bsdnet_ticks_per_second = 1;
rtems_bsdnet_microseconds_per_tick = 1000000 / rtems_bsdnet_ticks_per_second;
/*
* Ensure that `seconds' is greater than 0
*/
while (rtems_bsdnet_seconds_since_boot() == 0)
rtems_task_wake_after(1);
/*
* Set up BSD-style sockets
*/
if (bsd_init () < 0)
return -1;
/*
* Start network daemon
*/
networkDaemonTid = rtems_bsdnet_newproc ("ntwk", 4096, networkDaemon, NULL);
/*
* Let other network tasks begin
*/
rtems_bsdnet_semaphore_release ();
return 0;
}
/*
* Obtain network mutex
*/
void
rtems_bsdnet_semaphore_obtain (void)
{
#ifdef RTEMS_FAST_MUTEX
ISR_Level level;
_ISR_Disable (level);
_CORE_mutex_Seize (
&the_networkSemaphore->Core_control.mutex,
networkSemaphore,
1, /* wait */
0, /* forever */
level
);
if (_Thread_Executing->Wait.return_code)
rtems_panic ("Can't obtain network semaphore\n");
#else
rtems_status_code sc;
sc = rtems_semaphore_obtain (networkSemaphore, RTEMS_WAIT, RTEMS_NO_TIMEOUT);
if (sc != RTEMS_SUCCESSFUL)
rtems_panic ("Can't obtain network semaphore: `%s'\n", rtems_status_text (sc));
#endif
}
/*
* Release network mutex
*/
void
rtems_bsdnet_semaphore_release (void)
{
#ifdef RTEMS_FAST_MUTEX
int i;
_Thread_Disable_dispatch();
i = _CORE_mutex_Surrender (
&the_networkSemaphore->Core_control.mutex,
networkSemaphore,
NULL
);
_Thread_Enable_dispatch();
if (i)
rtems_panic ("Can't release network semaphore\n");
#else
rtems_status_code sc;
sc = rtems_semaphore_release (networkSemaphore);
if (sc != RTEMS_SUCCESSFUL)
rtems_panic ("Can't release network semaphore: `%s'\n", rtems_status_text (sc));
#endif
}
/*
* Wait for something to happen to a socket buffer
*/
int
sbwait(sb)
struct sockbuf *sb;
{
rtems_event_set events;
rtems_id tid;
rtems_status_code sc;
/*
* Soak up any pending events.
* The sleep/wakeup synchronization in the FreeBSD
* kernel has no memory.
*/
rtems_event_receive (SBWAIT_EVENT, RTEMS_EVENT_ANY | RTEMS_NO_WAIT, RTEMS_NO_TIMEOUT, &events);
/*
* Set this task as the target of the wakeup operation.
*/
rtems_task_ident (RTEMS_SELF, 0, &tid);
sb->sb_sel.si_pid = tid;
/*
* Show that socket is waiting
*/
sb->sb_flags |= SB_WAIT;
/*
* Release the network semaphore.
*/
rtems_bsdnet_semaphore_release ();
/*
* Wait for the wakeup event.
*/
sc = rtems_event_receive (SBWAIT_EVENT, RTEMS_EVENT_ANY | RTEMS_WAIT, sb->sb_timeo, &events);
/*
* Reobtain the network semaphore.
*/
rtems_bsdnet_semaphore_obtain ();
/*
* Return the status of the wait.
*/
switch (sc) {
case RTEMS_SUCCESSFUL: return 0;
case RTEMS_TIMEOUT: return EWOULDBLOCK;
default: return ENXIO;
}
}
/*
* Wake up the task waiting on a socket buffer.
*/
void
sowakeup(so, sb)
register struct socket *so;
register struct sockbuf *sb;
{
if (sb->sb_flags & SB_WAIT) {
sb->sb_flags &= ~SB_WAIT;
rtems_event_send (sb->sb_sel.si_pid, SBWAIT_EVENT);
}
if (sb->sb_wakeup) {
(*sb->sb_wakeup) (so, sb->sb_wakeuparg);
}
}
/*
* For now, a socket can be used by only one task at a time.
*/
int
sb_lock(sb)
register struct sockbuf *sb;
{
rtems_panic ("Socket buffer is already in use.");
return 0;
}
void
wakeup (void *p)
{
rtems_panic ("Wakeup called");
}
/*
* Wait for a connection/disconnection event.
*/
int
soconnsleep (struct socket *so)
{
rtems_event_set events;
rtems_id tid;
rtems_status_code sc;
/*
* Soak up any pending events.
* The sleep/wakeup synchronization in the FreeBSD
* kernel has no memory.
*/
rtems_event_receive (SOSLEEP_EVENT, RTEMS_EVENT_ANY | RTEMS_NO_WAIT, RTEMS_NO_TIMEOUT, &events);
/*
* Set this task as the target of the wakeup operation.
*/
if (so->so_pgid)
rtems_panic ("Another task is already sleeping on that socket");
rtems_task_ident (RTEMS_SELF, 0, &tid);
so->so_pgid = tid;
/*
* Wait for the wakeup event.
*/
sc = rtems_bsdnet_event_receive (SOSLEEP_EVENT, RTEMS_EVENT_ANY | RTEMS_WAIT, so->so_rcv.sb_timeo, &events);
/*
* Relinquish ownership of the socket.
*/
so->so_pgid = 0;
switch (sc) {
case RTEMS_SUCCESSFUL: return 0;
case RTEMS_TIMEOUT: return EWOULDBLOCK;
default: return ENXIO;
}
}
/*
* Wake up a task waiting for a connection/disconnection to complete.
*/
void
soconnwakeup (struct socket *so)
{
if (so->so_pgid)
rtems_event_send (so->so_pgid, SOSLEEP_EVENT);
}
/*
* Send an event to the network daemon.
* This corresponds to sending a software interrupt in the BSD kernel.
*/
void
rtems_bsdnet_schednetisr (int n)
{
rtems_event_send (networkDaemonTid, 1 << n);
}
/*
* The network daemon
* This provides a context to run BSD software interrupts
*/
static void
networkDaemon (void *task_argument)
{
rtems_status_code sc;
rtems_event_set events;
rtems_interval now;
int ticksPassed;
unsigned32 timeout;
struct callout *c;
for (;;) {
c = calltodo.c_next;
if (c)
timeout = c->c_time;
else
timeout = RTEMS_NO_TIMEOUT;
sc = rtems_bsdnet_event_receive (NETISR_EVENTS,
RTEMS_EVENT_ANY | RTEMS_WAIT,
timeout,
&events);
if ( sc == RTEMS_SUCCESSFUL ) {
if (events & NETISR_IP_EVENT)
ipintr ();
if (events & NETISR_ARP_EVENT)
arpintr ();
}
rtems_clock_get (RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, &now);
ticksPassed = now - ticksWhenCalloutsLastChecked;
if (ticksPassed != 0) {
ticksWhenCalloutsLastChecked = now;
c = calltodo.c_next;
if (c) {
c->c_time -= ticksPassed;
while ((c = calltodo.c_next) != NULL && c->c_time <= 0) {
void *arg;
void (*func) (void *);
func = c->c_func;
arg = c->c_arg;
calltodo.c_next = c->c_next;
c->c_next = callfree;
callfree = c;
(*func)(arg);
}
}
}
}
}
/*
* Structure passed to task-start stub
*/
struct newtask {
void (*entry)(void *);
void *arg;
};
/*
* Task-start stub
*/
static void
taskEntry (rtems_task_argument arg)
{
struct newtask t;
/*
* Pick up task information and free
* the memory allocated to pass the
* information to this task.
*/
t = *(struct newtask *)arg;
free ((struct newtask *)arg);
/*
* Enter the competition for the network semaphore
*/
rtems_bsdnet_semaphore_obtain ();
/*
* Enter the task
*/
(*t.entry)(t.arg);
rtems_panic ("Network task returned!\n");
}
/*
* Start a network task
*/
rtems_id
rtems_bsdnet_newproc (char *name, int stacksize, void(*entry)(void *), void *arg)
{
struct newtask *t;
char nm[4];
rtems_id tid;
rtems_status_code sc;
strncpy (nm, name, 4);
sc = rtems_task_create (rtems_build_name(nm[0], nm[1], nm[2], nm[3]),
networkDaemonPriority,
stacksize,
RTEMS_PREEMPT|RTEMS_NO_TIMESLICE|RTEMS_NO_ASR|RTEMS_INTERRUPT_LEVEL(0),
RTEMS_NO_FLOATING_POINT|RTEMS_LOCAL,
&tid);
if (sc != RTEMS_SUCCESSFUL)
rtems_panic ("Can't create network daemon `%s': `%s'\n", name, rtems_status_text (sc));
/*
* Set up task arguments
*/
t = malloc (sizeof *t);
t->entry = entry;
t->arg = arg;
/*
* Start the task
*/
sc = rtems_task_start (tid, taskEntry, (rtems_task_argument)t);
if (sc != RTEMS_SUCCESSFUL)
rtems_panic ("Can't start network daemon `%s': `%s'\n", name, rtems_status_text (sc));
/*
* Let our caller know the i.d. of the new task
*/
return tid;
}
rtems_status_code rtems_bsdnet_event_receive (
rtems_event_set event_in,
rtems_option option_set,
rtems_interval ticks,
rtems_event_set *event_out)
{
rtems_status_code sc;
rtems_bsdnet_semaphore_release ();
sc = rtems_event_receive (event_in, option_set, ticks, event_out);
rtems_bsdnet_semaphore_obtain ();
return sc;
}
/*
* Return time since startup
*/
void
microtime (struct timeval *t)
{
rtems_interval now;
rtems_clock_get (RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, &now);
t->tv_sec = now / rtems_bsdnet_ticks_per_second;
t->tv_usec = (now % rtems_bsdnet_ticks_per_second) * rtems_bsdnet_microseconds_per_tick;
}
unsigned long
rtems_bsdnet_seconds_since_boot (void)
{
rtems_interval now;
rtems_clock_get (RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, &now);
return now / rtems_bsdnet_ticks_per_second;
}
/*
* Fake random number generator
*/
unsigned long
rtems_bsdnet_random (void)
{
rtems_interval now;
rtems_clock_get (RTEMS_CLOCK_GET_TICKS_SINCE_BOOT, &now);
return (now * 99991);
}
/*
* Callout list processing
*/
void
timeout(void (*ftn)(void *), void *arg, int ticks)
{
register struct callout *new, *p, *t;
if (ticks <= 0)
ticks = 1;
/* Fill in the next free callout structure. */
if (callfree == NULL) {
callfree = malloc (sizeof *callfree);
if (callfree == NULL)
rtems_panic ("No memory for timeout table entry");
callfree->c_next = NULL;
}
new = callfree;
callfree = new->c_next;
new->c_arg = arg;
new->c_func = ftn;
/*
* The time for each event is stored as a difference from the time
* of the previous event on the queue. Walk the queue, correcting
* the ticks argument for queue entries passed. Correct the ticks
* value for the queue entry immediately after the insertion point
* as well. Watch out for negative c_time values; these represent
* overdue events.
*/
for (p = &calltodo;
(t = p->c_next) != NULL && ticks > t->c_time; p = t)
if (t->c_time > 0)
ticks -= t->c_time;
new->c_time = ticks;
if (t != NULL)
t->c_time -= ticks;
/* Insert the new entry into the queue. */
p->c_next = new;
new->c_next = t;
}
/*
* Ticks till specified time
* XXX: This version worries only about seconds, but that's good
* enough for the way the network code uses this routine.
*/
int
hzto(struct timeval *tv)
{
long diff = tv->tv_sec - rtems_bsdnet_seconds_since_boot();
if (diff <= 0)
return 1;
return diff * rtems_bsdnet_ticks_per_second;
}
/*
* Kernel debugging
*/
int rtems_bsdnet_log_priority;
void
rtems_bsdnet_log (int priority, const char *fmt, ...)
{
va_list args;
if (priority & rtems_bsdnet_log_priority) {
va_start (args, fmt);
vprintf (fmt, args);
va_end (args);
}
}
/*
* IP header checksum routine for processors which don't have an inline version
*/
u_int
in_cksum_hdr (const void *ip)
{
rtems_unsigned32 sum;
const rtems_unsigned16 *sp;
int i;
sum = 0;
sp = (rtems_unsigned16 *)ip;
for (i = 0 ; i < 10 ; i++)
sum += *sp++;
while (sum > 0xFFFF)
sum = (sum & 0xffff) + (sum >> 16);
return ~sum & 0xFFFF;
}
/*
* Manipulate routing tables
*/
int rtems_bsdnet_rtrequest (
int req,
struct sockaddr *dst,
struct sockaddr *gateway,
struct sockaddr *netmask,
int flags,
struct rtentry **net_nrt)
{
int error;
rtems_bsdnet_semaphore_obtain ();
error = rtrequest (req, dst, gateway, netmask, flags, net_nrt);
rtems_bsdnet_semaphore_release ();
if (error) {
errno = error;
return -1;
}
return 0;
}
static int
rtems_bsdnet_setup (void)
{
struct rtems_bsdnet_ifconfig *ifp;
short flags;
struct sockaddr_in address;
struct sockaddr_in netmask;
struct sockaddr_in broadcast;
struct sockaddr_in gateway;
int i;
extern char *strdup (const char *cp);
/*
* Set local parameters
*/
if (rtems_bsdnet_config.hostname)
sethostname (rtems_bsdnet_config.hostname,
strlen (rtems_bsdnet_config.hostname));
if (rtems_bsdnet_config.domainname)
rtems_bsdnet_domain_name =
strdup (rtems_bsdnet_config.domainname);
if (rtems_bsdnet_config.log_host)
rtems_bsdnet_log_host_address.s_addr =
inet_addr (rtems_bsdnet_config.log_host);
for (i = 0 ; i < sizeof rtems_bsdnet_config.name_server /
sizeof rtems_bsdnet_config.name_server[0] ; i++) {
if (!rtems_bsdnet_config.name_server[i])
break;
rtems_bsdnet_nameserver[rtems_bsdnet_nameserver_count++].s_addr
= inet_addr (rtems_bsdnet_config.name_server[i]);
}
for (i = 0 ; i < sizeof rtems_bsdnet_config.ntp_server /
sizeof rtems_bsdnet_config.ntp_server[0] ; i++) {
if (!rtems_bsdnet_config.ntp_server[i])
break;
rtems_bsdnet_ntpserver[rtems_bsdnet_ntpserver_count++].s_addr
= inet_addr (rtems_bsdnet_config.ntp_server[i]);
}
/*
* Configure interfaces
*/
for (ifp = rtems_bsdnet_config.ifconfig ; ifp ; ifp = ifp->next) {
if (ifp->ip_address == NULL)
continue;
/*
* Bring interface up
*/
flags = IFF_UP;
if (rtems_bsdnet_ifconfig (ifp->name, SIOCSIFFLAGS, &flags) < 0) {
printf ("Can't bring %s up: %s\n", ifp->name, strerror (errno));
continue;
}
/*
* Set interface netmask
*/
memset (&netmask, '\0', sizeof netmask);
netmask.sin_len = sizeof netmask;
netmask.sin_family = AF_INET;
netmask.sin_addr.s_addr = inet_addr (ifp->ip_netmask);
if (rtems_bsdnet_ifconfig (ifp->name, SIOCSIFNETMASK, &netmask) < 0) {
printf ("Can't set %s netmask: %s\n", ifp->name, strerror (errno));
continue;
}
/*
* Set interface address
*/
memset (&address, '\0', sizeof address);
address.sin_len = sizeof address;
address.sin_family = AF_INET;
address.sin_addr.s_addr = inet_addr (ifp->ip_address);
if (rtems_bsdnet_ifconfig (ifp->name, SIOCSIFADDR, &address) < 0) {
printf ("Can't set %s address: %s\n", ifp->name, strerror (errno));
continue;
}
/*
* Set interface broadcast address if the interface has the
* broadcast flag set.
*/
if (rtems_bsdnet_ifconfig (ifp->name, SIOCGIFFLAGS, &flags) < 0) {
printf ("Can't read %s flags: %s\n", ifp->name, strerror (errno));
continue;
}
if (flags & IFF_BROADCAST) {
memset (&broadcast, '\0', sizeof broadcast);
broadcast.sin_len = sizeof broadcast;
broadcast.sin_family = AF_INET;
broadcast.sin_addr.s_addr =
address.sin_addr.s_addr | ~netmask.sin_addr.s_addr;
if (rtems_bsdnet_ifconfig (ifp->name, SIOCSIFBRDADDR, &broadcast) < 0) {
struct in_addr in_addr;
char buf[20];
in_addr.s_addr = broadcast.sin_addr.s_addr;
if (!inet_ntop(AF_INET, &in_addr, buf, sizeof(buf)))
strcpy(buf,"?.?.?.?");
printf ("Can't set %s broadcast address %s: %s\n",
ifp->name, buf, strerror (errno));
}
}
}
/*
* Set default route
*/
if (rtems_bsdnet_config.gateway) {
address.sin_addr.s_addr = INADDR_ANY;
netmask.sin_addr.s_addr = INADDR_ANY;
memset (&gateway, '\0', sizeof gateway);
gateway.sin_len = sizeof gateway;
gateway.sin_family = AF_INET;
gateway.sin_addr.s_addr = inet_addr (rtems_bsdnet_config.gateway);
if (rtems_bsdnet_rtrequest (
RTM_ADD,
(struct sockaddr *)&address,
(struct sockaddr *)&gateway,
(struct sockaddr *)&netmask,
(RTF_UP | RTF_GATEWAY | RTF_STATIC), NULL) < 0) {
printf ("Can't set default route: %s\n", strerror (errno));
return -1;
}
}
return 0;
}
/*
* Initialize the network
*/
int
rtems_bsdnet_initialize_network (void)
{
struct rtems_bsdnet_ifconfig *ifp;
/*
* Start network tasks.
* Initialize BSD network data structures.
*/
if (rtems_bsdnet_initialize () < 0)
return -1;
/*
* Attach interfaces
*/
for (ifp = rtems_bsdnet_config.ifconfig ; ifp ; ifp = ifp->next) {
rtems_bsdnet_attach (ifp);
}
/*
* Bring up the network
*/
if (rtems_bsdnet_setup () < 0)
return -1;
if (rtems_bsdnet_config.bootp)
(*rtems_bsdnet_config.bootp)();
return 0;
}
/*
* Attach a network interface.
*/
void rtems_bsdnet_attach (struct rtems_bsdnet_ifconfig *ifp)
{
if (ifp) {
rtems_bsdnet_semaphore_obtain ();
(ifp->attach)(ifp, 1);
rtems_bsdnet_semaphore_release ();
}
}
/*
* Detach a network interface.
*/
void rtems_bsdnet_detach (struct rtems_bsdnet_ifconfig *ifp)
{
if (ifp) {
rtems_bsdnet_semaphore_obtain ();
(ifp->attach)(ifp, 0);
rtems_bsdnet_semaphore_release ();
}
}
/*
* Interface Configuration.
*/
int rtems_bsdnet_ifconfig (const char *ifname, unsigned32 cmd, void *param)
{
int s, r = 0;
struct ifreq ifreq;
/*
* Configure interfaces
*/
s = socket (AF_INET, SOCK_DGRAM, 0);
if (s < 0)
return -1;
strncpy (ifreq.ifr_name, ifname, IFNAMSIZ);
rtems_bsdnet_semaphore_obtain ();
switch (cmd) {
case SIOCSIFADDR:
case SIOCSIFNETMASK:
memcpy (&ifreq.ifr_addr, param, sizeof (struct sockaddr));
r = ioctl (s, cmd, &ifreq);
break;
case OSIOCGIFADDR:
case SIOCGIFADDR:
case OSIOCGIFNETMASK:
case SIOCGIFNETMASK:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
memcpy (param, &ifreq.ifr_addr, sizeof (struct sockaddr));
break;
case SIOCGIFFLAGS:
case SIOCSIFFLAGS:
if ((r = ioctl (s, SIOCGIFFLAGS, &ifreq)) < 0)
break;
if (cmd == SIOCGIFFLAGS) {
*((short*) param) = ifreq.ifr_flags;
break;
}
ifreq.ifr_flags |= *((short*) param);
r = ioctl (s, SIOCSIFFLAGS, &ifreq);
break;
case SIOCSIFDSTADDR:
memcpy (&ifreq.ifr_dstaddr, param, sizeof (struct sockaddr));
r = ioctl (s, cmd, &ifreq);
break;
case OSIOCGIFDSTADDR:
case SIOCGIFDSTADDR:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
memcpy (param, &ifreq.ifr_dstaddr, sizeof (struct sockaddr));
break;
case SIOCSIFBRDADDR:
memcpy (&ifreq.ifr_broadaddr, param, sizeof (struct sockaddr));
r = ioctl (s, cmd, &ifreq);
break;
case OSIOCGIFBRDADDR:
case SIOCGIFBRDADDR:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
memcpy (param, &ifreq.ifr_broadaddr, sizeof (struct sockaddr));
break;
case SIOCSIFMETRIC:
ifreq.ifr_metric = *((int*) param);
r = ioctl (s, cmd, &ifreq);
break;
case SIOCGIFMETRIC:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
*((int*) param) = ifreq.ifr_metric;
break;
case SIOCSIFMTU:
ifreq.ifr_mtu = *((int*) param);
r = ioctl (s, cmd, &ifreq);
break;
case SIOCGIFMTU:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
*((int*) param) = ifreq.ifr_mtu;
break;
case SIOCSIFPHYS:
ifreq.ifr_phys = *((int*) param);
r = ioctl (s, cmd, &ifreq);
break;
case SIOCGIFPHYS:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
*((int*) param) = ifreq.ifr_phys;
break;
case SIOCSIFMEDIA:
ifreq.ifr_media = *((int*) param);
r = ioctl (s, cmd, &ifreq);
break;
case SIOCGIFMEDIA:
if ((r = ioctl (s, cmd, &ifreq)) < 0)
break;
*((int*) param) = ifreq.ifr_media;
break;
case SIOCAIFADDR:
case SIOCDIFADDR:
r = ioctl(s, cmd, (struct freq *) param);
break;
default:
errno = EOPNOTSUPP;
r = -1;
break;
}
rtems_bsdnet_semaphore_release ();
close (s);
return r;
}
/*
* Parse a network driver name into a name and a unit number
*/
int
rtems_bsdnet_parse_driver_name (const struct rtems_bsdnet_ifconfig *config, char **namep)
{
const char *cp = config->name;
char c;
int unitNumber = 0;
if (cp == NULL) {
printf ("No network driver name.\n");
return -1;
}
while ((c = *cp++) != '\0') {
if ((c >= '0') && (c <= '9')) {
int len = cp - config->name;
if ((len < 2) || (len > 50))
break;
for (;;) {
unitNumber = (unitNumber * 10) + (c - '0');
c = *cp++;
if (c == '\0') {
char *unitName = malloc (len);
if (unitName == NULL) {
printf ("No memory.\n");
return -1;
}
strncpy (unitName, config->name, len - 1);
unitName[len-1] = '\0';
*namep = unitName;
return unitNumber;
}
if ((c < '0') || (c > '9'))
break;
}
break;
}
}
printf ("Bad network driver name `%s'.\n", config->name);
return -1;
}
/*
* Handle requests for more network memory
* XXX: Another possibility would be to use a semaphore here with
* a release in the mbuf free macro. I have chosen this `polling'
* approach because:
* 1) It is simpler.
* 2) It adds no complexity to the free macro.
* 3) Running out of mbufs should be a rare
* condition -- predeployment testing of
* an application should indicate the
* required mbuf pool size.
* XXX: Should there be a panic if a task is stuck in the loop for
* more than a minute or so?
*/
int
m_mballoc (int nmb, int nowait)
{
if (nowait)
return 0;
m_reclaim ();
if (mmbfree == NULL) {
int try = 0;
int print_limit = 30 * rtems_bsdnet_ticks_per_second;
mbstat.m_wait++;
for (;;) {
rtems_bsdnet_semaphore_release ();
rtems_task_wake_after (1);
rtems_bsdnet_semaphore_obtain ();
if (mmbfree)
break;
if (++try >= print_limit) {
printf ("Still waiting for mbuf.\n");
try = 0;
}
}
}
else {
mbstat.m_drops++;
}
return 1;
}
int
m_clalloc(ncl, nowait)
{
if (nowait)
return 0;
m_reclaim ();
if (mclfree == NULL) {
int try = 0;
int print_limit = 30 * rtems_bsdnet_ticks_per_second;
mbstat.m_wait++;
for (;;) {
rtems_bsdnet_semaphore_release ();
rtems_task_wake_after (1);
rtems_bsdnet_semaphore_obtain ();
if (mclfree)
break;
if (++try >= print_limit) {
printf ("Still waiting for mbuf cluster.\n");
try = 0;
}
}
}
else {
mbstat.m_drops++;
}
return 1;
}