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/*

 *  $Id: rtems_glue.c,v 1.2 2001-09-27 12:02:00 chris Exp $

 */

#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>

/*

 * 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;

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;

struct in_addr rtems_bsdnet_bootp_server_address;

char *rtems_bsdnet_bootp_boot_file_name;

char *rtems_bsdnet_bootp_server_name;

char *rtems_bsdnet_domain_name;

struct in_addr rtems_bsdnet_nameserver[sizeof rtems_bsdnet_config.name_server /

                        sizeof rtems_bsdnet_config.name_server[0]];

int rtems_bsdnet_nameserver_count;

struct in_addr rtems_bsdnet_ntpserver[sizeof rtems_bsdnet_config.ntp_server /

                        sizeof rtems_bsdnet_config.ntp_server[0]];

int rtems_bsdnet_ntpserver_count;

long rtems_bsdnet_timeoffset;

/*

 * 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) {

                        printf ("rtems_bsdnet_malloc still waiting.\n");

                        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);

        p = (char *)(((unsigned long)p + (MCLBYTES-1)) & ~(MCLBYTES-1));

        if (p == NULL) {

                printf ("Can't get network cluster memory.\n");

                return -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);

        }

        /*

         * 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_FIFO |

                                                RTEMS_BINARY_SEMAPHORE |

                                                RTEMS_NO_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;

        }

        /*

         * 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

         */

        rtems_task_wake_after (rtems_bsdnet_ticks_per_second);

        /*

         * 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)

{

        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));

}

/*

 * Release network mutex

 */

void

rtems_bsdnet_semaphore_release (void)

{

        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));

                                                                                }

/*

 * 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_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;

                rtems_bsdnet_event_receive (NETISR_EVENTS,

                                                RTEMS_EVENT_ANY | RTEMS_WAIT,

                                                timeout,

                                                &events);

                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,