[openafs.git] / src / afs / afs_call.c

/*
 * Copyright 2000, International Business Machines Corporation and others.
 * All Rights Reserved.
 *
 * This software has been released under the terms of the IBM Public
 * License.  For details, see the LICENSE file in the top-level source
 * directory or online at http://www.openafs.org/dl/license10.html
 */

#include <afsconfig.h>
#include "afs/param.h"

#if defined(HAVE_LINUX_KTHREAD_RUN) && !defined(UKERNEL)
#  include "h/kthread.h"
#endif

#include "afs/sysincludes.h"    /* Standard vendor system headers */
#include "afsincludes.h"        /* Afs-based standard headers */
#include "afs/afs_stats.h"
#include "rx/rx_globals.h"
#if !defined(UKERNEL)
# if !defined(AFS_LINUX20_ENV)
#  include "net/if.h"
#  ifdef AFS_SGI62_ENV
#   include "h/hashing.h"
#  endif
#  if !defined(AFS_HPUX110_ENV) && !defined(AFS_DARWIN_ENV)
#   include "netinet/in_var.h"
#  endif
# endif
#endif /* !defined(UKERNEL) */
#ifdef AFS_SUN510_ENV
#include "h/ksynch.h"
#include "h/sunddi.h"
#endif
#include <hcrypto/rand.h>

#if defined(AFS_SUN5_ENV) || defined(AFS_AIX_ENV) || defined(AFS_SGI_ENV) || defined(AFS_HPUX_ENV)
#define AFS_MINBUFFERS  100
#else
#define AFS_MINBUFFERS  50
#endif

#if (defined(AFS_SUN5_ENV) || defined(AFS_LINUX26_ENV) || defined(AFS_DARWIN80_ENV)) && !defined(UKERNEL)
/* If AFS_DAEMONOP_ENV is defined, it indicates we run "daemon" AFS syscalls by
 * spawning a kernel thread to do the work, instead of running them in the
 * calling process. */
# define AFS_DAEMONOP_ENV
#endif

struct afsop_cell {
    afs_int32 hosts[AFS_MAXCELLHOSTS];
    char cellName[100];
};

char afs_zeros[AFS_ZEROS];
char afs_rootVolumeName[64] = "";
afs_uint32 rx_bindhost;

#ifdef AFS_SUN510_ENV
ddi_taskq_t *afs_taskq;
krwlock_t afsifinfo_lock;
#endif

afs_int32 afs_initState = 0;
afs_int32 afs_termState = 0;
int afs_cold_shutdown = 0;
char afs_SynchronousCloses = '\0';
static int afs_CB_Running = 0;
static int AFS_Running = 0;
static int afs_CacheInit_Done = 0;
static int afs_Go_Done = 0;
extern struct interfaceAddr afs_cb_interface;
#ifdef RXK_LISTENER_ENV
static int afs_RX_Running = 0;
#endif
static int afs_InitSetup_done = 0;
afs_int32 afs_numcachefiles = -1;
afs_int32 afs_numfilesperdir = -1;
char afs_cachebasedir[1024];
afs_int32 afs_rmtsys_enable = 0;

afs_int32 afs_rx_deadtime = AFS_RXDEADTIME;
afs_int32 afs_rx_harddead = AFS_HARDDEADTIME;
afs_int32 afs_rx_idledead = AFS_IDLEDEADTIME;
afs_int32 afs_rx_idledead_rep = AFS_IDLEDEADTIME_REP;

static int afscall_set_rxpck_received = 0;

extern afs_int32 afs_volume_ttl;

/* From afs_util.c */
extern afs_int32 afs_md5inum;

/* This is code which needs to be called once when the first daemon enters
 * the client. A non-zero return means an error and AFS should not start.
 */
static int
afs_InitSetup(int preallocs)
{
    int code;
    afs_uint32 host;

    if (afs_InitSetup_done)
        return EAGAIN;

#ifdef AFS_SUN510_ENV
    /* Initialize a RW lock for the ifinfo global array */
    rw_init(&afsifinfo_lock, NULL, RW_DRIVER, NULL);

    /* Create a taskq */
    afs_taskq = ddi_taskq_create(NULL, "afs_taskq", 2, TASKQ_DEFAULTPRI, 0);

    osi_StartNetIfPoller();
#endif

#ifndef AFS_NOSTATS
    /*
     * Set up all the AFS statistics variables.  This should be done
     * exactly once, and it should be done here, the first resource-setting
     * routine to be called by the CM/RX.
     */
    afs_InitStats();
#endif /* AFS_NOSTATS */

    memset(afs_zeros, 0, AFS_ZEROS);

    /* start RX */
    if(!afscall_set_rxpck_received)
    rx_extraPackets = AFS_NRXPACKETS;   /* smaller # of packets */

    host = ntohl(rx_bindhost);
    afs_warn("afs: Binding rx to %d.%d.%d.%d:%d\n",
             (host >> 24),
             (host >> 16) & 0xff,
             (host >>  8) & 0xff,
             (host)       & 0xff,
             7001);
    code = rx_InitHost(rx_bindhost, htons(7001));
    if (code) {
        afs_warn("AFS: RX failed to initialize %d).\n", code);
        return code;
    }
    rx_SetRxDeadTime(afs_rx_deadtime);
    /* resource init creates the services */
    afs_ResourceInit(preallocs);

    afs_InitSetup_done = 1;
    afs_osi_Wakeup(&afs_InitSetup_done);

    return code;
}

#ifdef AFS_DAEMONOP_ENV
static int
daemonOp_common(long parm, long parm2, long parm3, long parm4, long parm5,
                long parm6)
{
    int code;
    if (parm == AFSOP_START_RXCALLBACK) {
        if (afs_CB_Running)
            return -1;
# ifdef RXK_LISTENER_ENV
    } else if (parm == AFSOP_RXLISTENER_DAEMON) {
        if (afs_RX_Running)
            return -1;
        afs_RX_Running = 1;
# endif
        code = afs_InitSetup(parm2);
        if (parm3) {
            rx_enablePeerRPCStats();
        }
        if (parm4) {
            rx_enableProcessRPCStats();
        }
        if (code)
            return -1;
    } else if (parm == AFSOP_START_AFS) {
        if (AFS_Running)
            return -1;
    }                           /* other functions don't need setup in the parent */
    return 0;
}
#endif /* AFS_DAEMONOP_ENV */

#if defined(AFS_DARWIN80_ENV)
struct afsd_thread_info {
    unsigned long parm;
};
static int
afsd_thread(int *rock)
{
    struct afsd_thread_info *arg = (struct afsd_thread_info *)rock;
    unsigned long parm = arg->parm;

    switch (parm) {
    case AFSOP_START_RXCALLBACK:
        AFS_GLOCK();
        wakeup(arg);
        afs_CB_Running = 1;
#ifndef RXK_LISTENER_ENV
        afs_initState = AFSOP_START_AFS;
        afs_osi_Wakeup(&afs_initState);
#else
        while (afs_RX_Running != 2)
            afs_osi_Sleep(&afs_RX_Running);
#endif
        afs_RXCallBackServer();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
    case AFSOP_START_AFS:
        AFS_GLOCK();
        wakeup(arg);
        AFS_Running = 1;
        while (afs_initState < AFSOP_START_AFS)
            afs_osi_Sleep(&afs_initState);
        afs_initState = AFSOP_START_BKG;
        afs_osi_Wakeup(&afs_initState);
        afs_Daemon();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
    case AFSOP_START_BKG:
        afs_warn("Install matching afsd! Old background daemons not supported.\n");
        thread_terminate(current_thread());
        break;
    case AFSOP_START_TRUNCDAEMON:
        AFS_GLOCK();
        wakeup(arg);
        while (afs_initState < AFSOP_GO)
            afs_osi_Sleep(&afs_initState);
        afs_CacheTruncateDaemon();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
    case AFSOP_START_CS:
        AFS_GLOCK();
        wakeup(arg);
        afs_CheckServerDaemon();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
    case AFSOP_RXEVENT_DAEMON:
        AFS_GLOCK();
        wakeup(arg);
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        afs_rxevent_daemon();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
#ifdef RXK_LISTENER_ENV
    case AFSOP_RXLISTENER_DAEMON:
        AFS_GLOCK();
        wakeup(arg);
        afs_initState = AFSOP_START_AFS;
        afs_osi_Wakeup(&afs_initState);
        afs_RX_Running = 2;
        afs_osi_Wakeup(&afs_RX_Running);
        afs_osi_RxkRegister();
        rxk_Listener();
        AFS_GUNLOCK();
        thread_terminate(current_thread());
        break;
#endif
    default:
        afs_warn("Unknown op %ld in StartDaemon()\n", (long)parm);
        break;
    }
}

void
afs_DaemonOp(long parm, long parm2, long parm3, long parm4, long parm5,
             long parm6)
{
    struct afsd_thread_info info;
    thread_t thread;
    if (daemonOp_common(parm, parm2, parm3, parm4, parm5, parm6)) {
        return;
    }
    info.parm = parm;
    kernel_thread_start((thread_continue_t)afsd_thread, &info, &thread);
    AFS_GUNLOCK();
    /* we need to wait cause we passed stack pointers around.... */
    msleep(&info, NULL, PVFS, "afs_DaemonOp", NULL);
    AFS_GLOCK();
    thread_deallocate(thread);
}
#endif


#if defined(AFS_LINUX26_ENV)
struct afsd_thread_info {
# if !defined(INIT_WORK_HAS_DATA)
    struct work_struct tq;
# endif
    unsigned long parm;
    struct completion *complete;
};

static int
afsd_thread(void *rock)
{
    struct afsd_thread_info *arg = rock;
    unsigned long parm = arg->parm;
# ifdef SYS_SETPRIORITY_EXPORTED
    int (*sys_setpriority) (int, int, int) = sys_call_table[__NR_setpriority];
# endif
# if !defined(HAVE_LINUX_KTHREAD_RUN)
#  if defined(AFS_LINUX26_ENV)
    daemonize("afsd");
#  else
    daemonize();
#  endif
# endif /* !HAVE_LINUX_KTHREAD_RUN */
                                /* doesn't do much, since we were forked from keventd, but
                                 * does call mm_release, which wakes up our parent (since it
                                 * used CLONE_VFORK) */
# if !defined(AFS_LINUX26_ENV)
    reparent_to_init();
# endif
    afs_osi_MaskSignals();
    switch (parm) {
    case AFSOP_START_RXCALLBACK:
        sprintf(current->comm, "afs_cbstart");
        AFS_GLOCK();
        complete(arg->complete);
        afs_CB_Running = 1;
#if !defined(RXK_LISTENER_ENV)
        afs_initState = AFSOP_START_AFS;
        afs_osi_Wakeup(&afs_initState);
#else
        while (afs_RX_Running != 2)
            afs_osi_Sleep(&afs_RX_Running);
#endif
        sprintf(current->comm, "afs_callback");
        afs_RXCallBackServer();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
    case AFSOP_START_AFS:
        sprintf(current->comm, "afs_afsstart");
        AFS_GLOCK();
        complete(arg->complete);
        AFS_Running = 1;
        while (afs_initState < AFSOP_START_AFS)
            afs_osi_Sleep(&afs_initState);
        afs_initState = AFSOP_START_BKG;
        afs_osi_Wakeup(&afs_initState);
        sprintf(current->comm, "afsd");
        afs_Daemon();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
    case AFSOP_START_BKG:
#ifdef AFS_NEW_BKG
        afs_warn("Install matching afsd! Old background daemons not supported.\n");
#else
        sprintf(current->comm, "afs_bkgstart");
        AFS_GLOCK();
        complete(arg->complete);
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        if (afs_initState < AFSOP_GO) {
            afs_initState = AFSOP_GO;
            afs_osi_Wakeup(&afs_initState);
        }
        sprintf(current->comm, "afs_background");
        afs_BackgroundDaemon();
        AFS_GUNLOCK();
#endif
        complete_and_exit(0, 0);
        break;
    case AFSOP_START_TRUNCDAEMON:
        sprintf(current->comm, "afs_trimstart");
        AFS_GLOCK();
        complete(arg->complete);
        while (afs_initState < AFSOP_GO)
            afs_osi_Sleep(&afs_initState);
        sprintf(current->comm, "afs_cachetrim");
        afs_CacheTruncateDaemon();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
    case AFSOP_START_CS:
        sprintf(current->comm, "afs_checkserver");
        AFS_GLOCK();
        complete(arg->complete);
        afs_CheckServerDaemon();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
    case AFSOP_RXEVENT_DAEMON:
        sprintf(current->comm, "afs_evtstart");
# ifdef SYS_SETPRIORITY_EXPORTED
        sys_setpriority(PRIO_PROCESS, 0, -10);
# else
#  ifdef CURRENT_INCLUDES_NICE
        current->nice = -10;
#  endif
# endif
        AFS_GLOCK();
        complete(arg->complete);
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        sprintf(current->comm, "afs_rxevent");
        afs_rxevent_daemon();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
#ifdef RXK_LISTENER_ENV
    case AFSOP_RXLISTENER_DAEMON:
        sprintf(current->comm, "afs_lsnstart");
# ifdef SYS_SETPRIORITY_EXPORTED
        sys_setpriority(PRIO_PROCESS, 0, -10);
# else
#  ifdef CURRENT_INCLUDES_NICE
        current->nice = -10;
#  endif
# endif
        AFS_GLOCK();
        complete(arg->complete);
        afs_initState = AFSOP_START_AFS;
        afs_osi_Wakeup(&afs_initState);
        afs_RX_Running = 2;
        afs_osi_Wakeup(&afs_RX_Running);
        afs_osi_RxkRegister();
        sprintf(current->comm, "afs_rxlistener");
        rxk_Listener();
        AFS_GUNLOCK();
        complete_and_exit(0, 0);
        break;
#endif
    default:
        afs_warn("Unknown op %ld in StartDaemon()\n", (long)parm);
        break;
    }
    return 0;
}

void
# if defined(AFS_LINUX26_ENV) && !defined(INIT_WORK_HAS_DATA)
afsd_launcher(struct work_struct *work)
# else
afsd_launcher(void *rock)
# endif
{
# if defined(AFS_LINUX26_ENV) && !defined(INIT_WORK_HAS_DATA)
    struct afsd_thread_info *rock = container_of(work, struct afsd_thread_info, tq);
# endif

# if defined(HAVE_LINUX_KTHREAD_RUN)
    if (IS_ERR(kthread_run(afsd_thread, (void *)rock, "afsd"))) {
        afs_warn("kthread_run failed; afs startup will not complete\n");
    }
# else /* !HAVE_LINUX_KTHREAD_RUN */
    if (!kernel_thread(afsd_thread, (void *)rock, CLONE_VFORK | SIGCHLD))
        afs_warn("kernel_thread failed. afs startup will not complete\n");
# endif /* !HAVE_LINUX_KTHREAD_RUN */
}

void
afs_DaemonOp(long parm, long parm2, long parm3, long parm4, long parm5,
             long parm6)
{
    DECLARE_COMPLETION(c);
# if defined(AFS_LINUX26_ENV)
#  if defined(INIT_WORK_HAS_DATA)
    struct work_struct tq;
#  endif
# else
    struct tq_struct tq;
# endif
    struct afsd_thread_info info;
    if (daemonOp_common(parm, parm2, parm3, parm4, parm5, parm6)) {
        return;
    }
    info.complete = &c;
    info.parm = parm;
# if defined(AFS_LINUX26_ENV)
#  if !defined(INIT_WORK_HAS_DATA)
    INIT_WORK(&info.tq, afsd_launcher);
    schedule_work(&info.tq);
#  else
    INIT_WORK(&tq, afsd_launcher, &info);
    schedule_work(&tq);
#  endif
# else
    tq.sync = 0;
    INIT_LIST_HEAD(&tq.list);
    tq.routine = afsd_launcher;
    tq.data = &info;
    schedule_task(&tq);
# endif
    AFS_GUNLOCK();
    /* we need to wait cause we passed stack pointers around.... */
    wait_for_completion(&c);
    AFS_GLOCK();
}
#endif

#ifdef AFS_SUN5_ENV
struct afs_daemonop_args {
    kcondvar_t cv;
    long parm;
};

static void
afsd_thread(struct afs_daemonop_args *args)
{
    long parm = args->parm;

    AFS_GLOCK();
    cv_signal(&args->cv);

    switch (parm) {
    case AFSOP_START_RXCALLBACK:
        if (afs_CB_Running)
            goto out;
        afs_CB_Running = 1;
        while (afs_RX_Running != 2)
            afs_osi_Sleep(&afs_RX_Running);
        afs_RXCallBackServer();
        AFS_GUNLOCK();
        return;
    case AFSOP_START_AFS:
        if (AFS_Running)
            goto out;
        AFS_Running = 1;
        while (afs_initState < AFSOP_START_AFS)
            afs_osi_Sleep(&afs_initState);
        afs_initState = AFSOP_START_BKG;
        afs_osi_Wakeup(&afs_initState);
        afs_Daemon();
        AFS_GUNLOCK();
        return;
    case AFSOP_START_BKG:
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        if (afs_initState < AFSOP_GO) {
            afs_initState = AFSOP_GO;
            afs_osi_Wakeup(&afs_initState);
        }
        afs_BackgroundDaemon();
        AFS_GUNLOCK();
        return;
    case AFSOP_START_TRUNCDAEMON:
        while (afs_initState < AFSOP_GO)
            afs_osi_Sleep(&afs_initState);
        afs_CacheTruncateDaemon();
        AFS_GUNLOCK();
        return;
    case AFSOP_START_CS:
        afs_CheckServerDaemon();
        AFS_GUNLOCK();
        return;
    case AFSOP_RXEVENT_DAEMON:
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        afs_rxevent_daemon();
        AFS_GUNLOCK();
        return;
    case AFSOP_RXLISTENER_DAEMON:
        afs_initState = AFSOP_START_AFS;
        afs_osi_Wakeup(&afs_initState);
        afs_RX_Running = 2;
        afs_osi_Wakeup(&afs_RX_Running);
        afs_osi_RxkRegister();
        rxk_Listener();
        AFS_GUNLOCK();
        return;
    default:
        AFS_GUNLOCK();
        afs_warn("Unknown op %ld in afsd_thread()\n", parm);
        return;
    }
 out:
    AFS_GUNLOCK();
    return;
}

static void
afs_DaemonOp(long parm, long parm2, long parm3, long parm4, long parm5,
             long parm6)
{
    struct afs_daemonop_args args;

    if (daemonOp_common(parm, parm2, parm3, parm4, parm5, parm6)) {
        return;
    }

    args.parm = parm;

    cv_init(&args.cv, "AFS DaemonOp cond var", CV_DEFAULT, NULL);

    if (thread_create(NULL, 0, afsd_thread, &args, 0, &p0, TS_RUN,
        minclsyspri) == NULL) {

        afs_warn("thread_create failed: AFS startup will not complete\n");
    }

    /* we passed &args to the new thread, which is on the stack. wait until
     * it has read the arguments so it doesn't try to read the args after we
     * have returned */
    cv_wait(&args.cv, &afs_global_lock);

    cv_destroy(&args.cv);
}
#endif /* AFS_SUN5_ENV */

#ifdef AFS_SOCKPROXY_ENV
/**
 * Deallocate packets.
 *
 * @param[inout]  a_pktlist  list of packets to be freed
 * @param[in]     a_npkts    number of packets
 */
static void
sockproxy_pkts_free(struct afs_pkt_hdr **a_pktlist, size_t a_npkts)
{
    int pkt_i;
    struct afs_pkt_hdr *pktlist = *a_pktlist;

    if (pktlist == NULL) {
        return;
    }
    *a_pktlist = NULL;

    for (pkt_i = 0; pkt_i < a_npkts; pkt_i++) {
        struct afs_pkt_hdr *pkt = &pktlist[pkt_i];
        afs_osi_Free(pkt->payload, pkt->size);
        pkt->payload = NULL;
    }
    afs_osi_Free(pktlist, a_npkts * sizeof(pktlist[0]));
}

/**
 * Copy packets from user-space.
 *
 * @param[in]   a_uaddr    address of list of packets in user-space
 * @param[out]  a_pktlist  packets copied from user-space
 * @param[in]   a_npkts    number of packets to be copied
 *
 * @return errno error codes.
 */
static int
sockproxy_pkts_copyin(user_addr_t a_uaddr, struct afs_pkt_hdr **a_pktlist,
                      size_t a_npkts)
{
    int code, pkt_i;
    struct afs_pkt_hdr *pktlist_u;
    struct afs_pkt_hdr *pktlist_k = NULL;

    *a_pktlist = NULL;
    if (a_npkts == 0) {
        return 0;
    }
    if (a_npkts > AFS_SOCKPROXY_PKT_MAX) {
        return E2BIG;
    }

    pktlist_u = afs_osi_Alloc(a_npkts * sizeof(pktlist_u[0]));
    if (pktlist_u == NULL) {
        code = ENOMEM;
        goto done;
    }

    pktlist_k = afs_osi_Alloc(a_npkts * sizeof(pktlist_k[0]));
    if (pktlist_k == NULL) {
        code = ENOMEM;
        goto done;
    }
    memset(pktlist_k, 0, a_npkts * sizeof(pktlist_k[0]));

    AFS_COPYIN(a_uaddr, pktlist_u, a_npkts * sizeof(pktlist_u[0]), code);
    if (code != 0) {
        goto done;
    }

    for (pkt_i = 0; pkt_i < a_npkts; pkt_i++) {
        struct afs_pkt_hdr *pkt_k = &pktlist_k[pkt_i];
        struct afs_pkt_hdr *pkt_u = &pktlist_u[pkt_i];

        if (pkt_u->size > AFS_SOCKPROXY_PAYLOAD_MAX) {
            code = E2BIG;
            goto done;
        }
        /*
         * Notice that pkt_u->payload points to a user-space address. When
         * copying the data from pkt_u to pkt_k, make sure that pkt_k->payload
         * points to a valid address in kernel-space.
         */
        *pkt_k = *pkt_u;
        pkt_k->payload = afs_osi_Alloc(pkt_k->size);
        if (pkt_k->payload == NULL) {
            code = ENOMEM;
            goto done;
        }

        AFS_COPYIN((user_addr_t)pkt_u->payload, pkt_k->payload, pkt_k->size,
                   code);
        if (code != 0) {
            goto done;
        }
    }

    *a_pktlist = pktlist_k;
    pktlist_k = NULL;
    code = 0;

 done:
    sockproxy_pkts_free(&pktlist_k, a_npkts);
    afs_osi_Free(pktlist_u, a_npkts * sizeof(pktlist_u[0]));

    return code;
}

/**
 * Copy packets to user-space.
 *
 * @param[in]  a_uaddr    dst address of list of packets in user-space
 * @param[in]  a_pktlist  packets to be copied to user-space
 * @param[in]  a_npkts    number of packets to be copied
 *
 * @return 0 on success; non-zero otherwise.
 */
static int
sockproxy_pkts_copyout(user_addr_t a_uaddr, struct afs_pkt_hdr *a_pktlist,
                       size_t a_npkts)
{
    int code, pkt_i;
    struct afs_pkt_hdr *pktlist_u = NULL;
    struct afs_pkt_hdr *pktlist_k = a_pktlist;

    if (a_npkts == 0) {
        return 0;
    }
    if (a_npkts > AFS_SOCKPROXY_PKT_MAX) {
        return E2BIG;
    }
    if (a_pktlist == NULL) {
        return EINVAL;
    }

    pktlist_u = afs_osi_Alloc(a_npkts * sizeof(pktlist_u[0]));
    if (pktlist_u == NULL) {
        code = ENOMEM;
        goto done;
    }

    AFS_COPYIN(a_uaddr, pktlist_u, a_npkts * sizeof(pktlist_u[0]), code);
    if (code != 0) {
        goto done;
    }

    for (pkt_i = 0; pkt_i < a_npkts; pkt_i++) {
        struct afs_pkt_hdr *pkt_k = &pktlist_k[pkt_i];
        struct afs_pkt_hdr *pkt_u = &pktlist_u[pkt_i];
        void *payload_uaddr;

        if (pkt_k->size > pkt_u->size) {
            code = ENOSPC;
            goto done;
        }

        /* Copy pkt_k -> pkt_u, but preserve pkt_u->payload */
        payload_uaddr = pkt_u->payload;
        *pkt_u = *pkt_k;
        pkt_u->payload = payload_uaddr;

        AFS_COPYOUT(pkt_k->payload, (user_addr_t)pkt_u->payload, pkt_k->size,
                    code);
        if (code != 0) {
            goto done;
        }
    }

    AFS_COPYOUT(pktlist_u, a_uaddr, a_npkts * sizeof(pktlist_u[0]), code);
    if (code != 0) {
        goto done;
    }

 done:
    afs_osi_Free(pktlist_u, a_npkts * sizeof(pktlist_u[0]));
    return code;
}

/**
 * Receive / send packets from / to user-space.
 *
 * @param[in]  a_parm_uspc  afs_uspc_param struct
 * @param[in]  a_parm_pkts  packets to be received / sent
 *
 * @return 0 on success; non-zero otherwise.
 */
static int
sockproxy_handler(user_addr_t a_parm_uspc, user_addr_t a_parm_pkts)
{
    int code;
    size_t orig_npkts, npkts;
    struct afs_uspc_param uspc;

    struct afs_pkt_hdr *pkts_recv;
    struct afs_pkt_hdr *pkts_send;

    AFS_GUNLOCK();

    orig_npkts = 0;
    memset(&uspc, 0, sizeof(uspc));

    pkts_recv = NULL;
    pkts_send = NULL;

    /* get response from user-space */
    AFS_COPYIN(a_parm_uspc, &uspc, sizeof(uspc), code);
    if (code != 0) {
        afs_warn("afs: AFSOP_SOCKPROXY_HANDLER can't read uspc\n");
        goto done;
    }

    npkts = uspc.req.usp.npkts;
    orig_npkts = npkts;

    if (uspc.reqtype == AFS_USPC_SOCKPROXY_RECV && npkts > 0) {
        /* copyin packets in from user-space */
        code = sockproxy_pkts_copyin(a_parm_pkts, &pkts_recv, npkts);
        if (code) {
            afs_warn("afs: AFSOP_SOCKPROXY_HANDLER can't read pkts\n");
            goto done;
        }
    }

    /*
     * send response from user-space (if any) to the rx layer and wait for a
     * new request.
     */
    code = rxk_SockProxyReply(&uspc, pkts_recv, &pkts_send);
    if (code) {
        afs_warn("afs: AFSOP_SOCKPROXY_HANDLER rxk_SockProxyReply failed\n");
        goto done;
    }

    /* send request to user-space process */
    AFS_COPYOUT(&uspc, a_parm_uspc, sizeof(uspc), code);
    if (code) {
        afs_warn("afs: AFSOP_SOCKPROXY_HANDLER can't write uspc\n");
        goto done;
    }

    npkts = uspc.req.usp.npkts;
    if (uspc.reqtype == AFS_USPC_SOCKPROXY_SEND && npkts > 0) {
        /* check if process allocated enough memory to receive the packets */
        if (npkts > orig_npkts) {
            code = ENOSPC;
            goto done;
        }

        /* copyout packets to user-space */
        code = sockproxy_pkts_copyout(a_parm_pkts, pkts_send, npkts);
        if (code != 0) {
            afs_warn("afs: AFSOP_SOCKPROXY_HANDLER can't write pkts\n");
            goto done;
        }
    }
 done:
    sockproxy_pkts_free(&pkts_recv, orig_npkts);
    AFS_GLOCK();

    return code;
}
#endif /* AFS_SOCKPROXY_ENV */

#ifdef AFS_DARWIN100_ENV
# define AFSKPTR(X) k ## X
int
afs_syscall_call(long parm, long parm2, long parm3,
                 long parm4, long parm5, long parm6)
{
    return afs_syscall64_call(CAST_USER_ADDR_T((parm)),
                              CAST_USER_ADDR_T((parm2)),
                              CAST_USER_ADDR_T((parm3)),
                              CAST_USER_ADDR_T((parm4)),
                              CAST_USER_ADDR_T((parm5)),
                              CAST_USER_ADDR_T((parm6)));
}
#else
# define AFSKPTR(X) ((caddr_t)X)
#endif
int
#ifdef AFS_DARWIN100_ENV
afs_syscall64_call(user_addr_t kparm, user_addr_t kparm2, user_addr_t kparm3,
                 user_addr_t kparm4, user_addr_t kparm5, user_addr_t kparm6)
#else
afs_syscall_call(long parm, long parm2, long parm3,
                 long parm4, long parm5, long parm6)
#endif
{
    afs_int32 code = 0;
#if defined(AFS_SGI61_ENV) || defined(AFS_SUN5_ENV) || defined(AFS_DARWIN_ENV) || defined(AFS_XBSD_ENV)
    size_t bufferSize;
#else /* AFS_SGI61_ENV */
    u_int bufferSize;
#endif /* AFS_SGI61_ENV */
#ifdef AFS_DARWIN100_ENV
    /* AFSKPTR macro relies on this name format/mapping */
    afs_uint32 parm = (afs_uint32)kparm;
    afs_uint32 parm2 = (afs_uint32)kparm2;
    afs_uint32 parm3 = (afs_uint32)kparm3;
    afs_uint32 parm4 = (afs_uint32)kparm4;
    afs_uint32 parm5 = (afs_uint32)kparm5;
    afs_uint32 parm6 = (afs_uint32)kparm6;
#endif

    AFS_STATCNT(afs_syscall_call);
    if (
#ifdef  AFS_SUN5_ENV
        !afs_suser(CRED())
#else
        !afs_suser(NULL)
#endif
                    && (parm != AFSOP_GETMTU) && (parm != AFSOP_GETMASK)) {
        /* only root can run this code */
#if defined(AFS_SUN5_ENV) || defined(KERNEL_HAVE_UERROR)
# if defined(KERNEL_HAVE_UERROR)
        setuerror(EACCES);
# endif
        code = EACCES;
#else
        code = EPERM;
#endif
        AFS_GLOCK();
#ifdef AFS_DARWIN80_ENV
        put_vfs_context();
#endif
        goto out;
    }
    AFS_GLOCK();
#ifdef AFS_DARWIN80_ENV
    put_vfs_context();
#endif
#ifdef AFS_DAEMONOP_ENV
# if defined(AFS_NEW_BKG)
    if (parm == AFSOP_BKG_HANDLER) {
        /* if afs_uspc_param grows this should be checked */
        struct afs_uspc_param *mvParam = osi_AllocSmallSpace(AFS_SMALLOCSIZ);
        void *param2;
        void *param1;
        int namebufsz;

        AFS_COPYIN(AFSKPTR(parm2), (caddr_t)mvParam,
                   sizeof(struct afs_uspc_param), code);
        namebufsz = mvParam->bufSz;
        param1 = afs_osi_Alloc(namebufsz);
        osi_Assert(param1 != NULL);
        param2 = afs_osi_Alloc(namebufsz);
        osi_Assert(param2 != NULL);

        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        if (afs_initState < AFSOP_GO) {
            afs_initState = AFSOP_GO;
            afs_osi_Wakeup(&afs_initState);
        }

        code = afs_BackgroundDaemon(mvParam, param1, param2);

        if (!code) {
            mvParam->retval = 0;
            /* for reqs where pointers are strings: */
#  ifdef AFS_DARWIN_ENV
            if (mvParam->reqtype == AFS_USPC_UMV) {
                /* don't copy out random kernel memory */
                AFS_COPYOUT(param2, AFSKPTR(parm4),
                            MIN(namebufsz, strlen((char *)param2)+1), code);
                AFS_COPYOUT(param1, AFSKPTR(parm3),
                            MIN(namebufsz, strlen((char *)param1)+1), code);
            }
#  endif /* AFS_DARWIN_ENV */
            AFS_COPYOUT((caddr_t)mvParam, AFSKPTR(parm2),
                       sizeof(struct afs_uspc_param), code);
        }

        afs_osi_Free(param1, namebufsz);
        afs_osi_Free(param2, namebufsz);
        osi_FreeSmallSpace(mvParam);
    } else
# endif /* AFS_NEW_BKG */
    if (parm < AFSOP_ADDCELL || parm == AFSOP_RXEVENT_DAEMON
        || parm == AFSOP_RXLISTENER_DAEMON) {
        afs_DaemonOp(parm, parm2, parm3, parm4, parm5, parm6);
    }
#else /* !AFS_DAEMONOP_ENV */
    if (parm == AFSOP_START_RXCALLBACK) {
        if (afs_CB_Running)
            goto out;
        afs_CB_Running = 1;
# ifndef RXK_LISTENER_ENV
        code = afs_InitSetup(parm2);
        if (!code)
# endif /* !RXK_LISTENER_ENV */
        {
# ifdef RXK_LISTENER_ENV
            while (afs_RX_Running != 2)
                afs_osi_Sleep(&afs_RX_Running);
# else /* !RXK_LISTENER_ENV */
            if (parm3) {
                rx_enablePeerRPCStats();
            }
            if (parm4) {
                rx_enableProcessRPCStats();
            }
            afs_initState = AFSOP_START_AFS;
            afs_osi_Wakeup(&afs_initState);
# endif /* RXK_LISTENER_ENV */
            afs_osi_Invisible();
            afs_RXCallBackServer();
            afs_osi_Visible();
        }
# ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, code);
# endif /* AFS_SGI_ENV */
    }
# ifdef RXK_LISTENER_ENV
    else if (parm == AFSOP_RXLISTENER_DAEMON) {
        if (afs_RX_Running)
            goto out;
        afs_RX_Running = 1;
        code = afs_InitSetup(parm2);
        if (parm3) {
            rx_enablePeerRPCStats();
        }
        if (parm4) {
            rx_enableProcessRPCStats();
        }
        if (!code) {
            afs_initState = AFSOP_START_AFS;
            afs_osi_Wakeup(&afs_initState);
            afs_osi_Invisible();
            afs_RX_Running = 2;
            afs_osi_Wakeup(&afs_RX_Running);
#  ifndef UKERNEL
            afs_osi_RxkRegister();
#  endif /* !UKERNEL */
            rxk_Listener();
            afs_osi_Visible();
        }
#  ifdef        AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, code);
#  endif /* AFS_SGI_ENV */
    }
# endif /* RXK_LISTENER_ENV */
    else if (parm == AFSOP_START_AFS) {
        /* afs daemon */
        if (AFS_Running)
            goto out;
        AFS_Running = 1;
        while (afs_initState < AFSOP_START_AFS)
            afs_osi_Sleep(&afs_initState);

        afs_initState = AFSOP_START_BKG;
        afs_osi_Wakeup(&afs_initState);
        afs_osi_Invisible();
        afs_Daemon();
        afs_osi_Visible();
# ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, 0);
# endif /* AFS_SGI_ENV */
    } else if (parm == AFSOP_START_CS) {
        afs_osi_Invisible();
        afs_CheckServerDaemon();
        afs_osi_Visible();
# ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, 0);
# endif /* AFS_SGI_ENV */
# ifndef AFS_NEW_BKG
    } else if (parm == AFSOP_START_BKG) {
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        if (afs_initState < AFSOP_GO) {
            afs_initState = AFSOP_GO;
            afs_osi_Wakeup(&afs_initState);
        }
        /* start the bkg daemon */
        afs_osi_Invisible();
#  ifdef AFS_AIX32_ENV
        if (parm2)
            afs_BioDaemon(parm2);
        else
#  endif /* AFS_AIX32_ENV */
            afs_BackgroundDaemon();
        afs_osi_Visible();
#  ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, 0);
#  endif /* AFS_SGI_ENV */
# endif /* ! AFS_NEW_BKG */
    } else if (parm == AFSOP_START_TRUNCDAEMON) {
        while (afs_initState < AFSOP_GO)
            afs_osi_Sleep(&afs_initState);
        /* start the bkg daemon */
        afs_osi_Invisible();
        afs_CacheTruncateDaemon();
        afs_osi_Visible();
# ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, 0);
# endif /* AFS_SGI_ENV */
    }
# if defined(AFS_SUN5_ENV) || defined(RXK_LISTENER_ENV) || defined(RXK_UPCALL_ENV)
    else if (parm == AFSOP_RXEVENT_DAEMON) {
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);
        afs_osi_Invisible();
        afs_rxevent_daemon();
        afs_osi_Visible();
#  ifdef AFS_SGI_ENV
        AFS_GUNLOCK();
        exit(CLD_EXITED, 0);
#  endif /* AFS_SGI_ENV */
    }
# endif /* AFS_SUN5_ENV || RXK_LISTENER_ENV || RXK_UPCALL_ENV */
#endif /* AFS_DAEMONOP_ENV */
    else if (parm == AFSOP_BASIC_INIT) {
        afs_int32 temp;

        while (!afs_InitSetup_done)
            afs_osi_Sleep(&afs_InitSetup_done);

#if defined(AFS_SGI_ENV) || defined(AFS_HPUX_ENV) || defined(AFS_LINUX20_ENV) || defined(AFS_DARWIN_ENV) || defined(AFS_XBSD_ENV) || defined(AFS_SUN5_ENV)
        temp = AFS_MINBUFFERS;  /* Should fix this soon */
#else
        /* number of 2k buffers we could get from all of the buffer space */
        temp = ((afs_bufferpages * NBPG) >> 11);
        temp = temp >> 2;       /* don't take more than 25% (our magic parameter) */
        if (temp < AFS_MINBUFFERS)
            temp = AFS_MINBUFFERS;      /* though we really should have this many */
#endif
        DInit(temp);
        afs_rootFid.Fid.Volume = 0;
        code = 0;
    } else if (parm == AFSOP_BUCKETPCT) {
        /* need to enable this now, will disable again before GO
           if we don't have 100% */
        splitdcache = 1;
        switch (parm2) {
        case 1:
            afs_tpct1 = parm3;
            break;
        case 2:
            afs_tpct2 = parm3;
            break;
        }
    } else if (parm == AFSOP_ADDCELL) {
        /* add a cell.  Parameter 2 is 8 hosts (in net order),  parm 3 is the null-terminated
         * name.  Parameter 4 is the length of the name, including the null.  Parm 5 is the
         * home cell flag (0x1 bit) and the nosuid flag (0x2 bit) */
        struct afsop_cell *tcell = afs_osi_Alloc(sizeof(struct afsop_cell));

        osi_Assert(tcell != NULL);
        code = afs_InitDynroot();
        if (!code) {
            AFS_COPYIN(AFSKPTR(parm2), (caddr_t)tcell->hosts, sizeof(tcell->hosts),
                       code);
        }
        if (!code) {
            if (parm4 > sizeof(tcell->cellName))
                code = EFAULT;
            else {
              AFS_COPYIN(AFSKPTR(parm3), (caddr_t)tcell->cellName, parm4, code);
                if (!code)
                    afs_NewCell(tcell->cellName, tcell->hosts, parm5, NULL, 0,
                                0, 0);
            }
        }
        afs_osi_Free(tcell, sizeof(struct afsop_cell));
    } else if (parm == AFSOP_ADDCELL2) {
        struct afsop_cell *tcell = afs_osi_Alloc(sizeof(struct afsop_cell));
        char *tbuffer = osi_AllocSmallSpace(AFS_SMALLOCSIZ), *lcnamep = 0;
        char *tbuffer1 = osi_AllocSmallSpace(AFS_SMALLOCSIZ);
        int cflags = parm4;

        osi_Assert(tcell != NULL);
        osi_Assert(tbuffer != NULL);
        osi_Assert(tbuffer1 != NULL);
        code = afs_InitDynroot();
        if (!code) {
            AFS_COPYIN(AFSKPTR(parm2), (caddr_t)tcell->hosts, sizeof(tcell->hosts),
                       code);
        }
        if (!code) {
            AFS_COPYINSTR(AFSKPTR(parm3), tbuffer1, AFS_SMALLOCSIZ,
                          &bufferSize, code);
            if (!code) {
                if (parm4 & 4) {
                    AFS_COPYINSTR(AFSKPTR(parm5), tbuffer, AFS_SMALLOCSIZ,
                                  &bufferSize, code);
                    if (!code) {
                        lcnamep = tbuffer;
                        cflags |= CLinkedCell;
                    }
                }
                if (parm4 & 8) {
                    cflags |= CHush;
                }
                if (!code)
                    code =
                        afs_NewCell(tbuffer1, tcell->hosts, cflags, lcnamep,
                                    0, 0, 0);
            }
        }
        afs_osi_Free(tcell, sizeof(struct afsop_cell));
        osi_FreeSmallSpace(tbuffer);
        osi_FreeSmallSpace(tbuffer1);
    } else if (parm == AFSOP_ADDCELLALIAS) {
        /*
         * Call arguments:
         * parm2 is the alias name
         * parm3 is the real cell name
         */
        char *aliasName = osi_AllocSmallSpace(AFS_SMALLOCSIZ);
        char *cellName = osi_AllocSmallSpace(AFS_SMALLOCSIZ);

        code = afs_InitDynroot();
        if (!code) {
            AFS_COPYINSTR(AFSKPTR(parm2), aliasName, AFS_SMALLOCSIZ, &bufferSize,
                          code);
        }
        if (!code)
            AFS_COPYINSTR(AFSKPTR(parm3), cellName, AFS_SMALLOCSIZ,
                          &bufferSize, code);
        if (!code)
            afs_NewCellAlias(aliasName, cellName);
        osi_FreeSmallSpace(aliasName);
        osi_FreeSmallSpace(cellName);
    } else if (parm == AFSOP_SET_THISCELL) {
        /*
         * Call arguments:
         * parm2 is the primary cell name
         */
        char *cell = osi_AllocSmallSpace(AFS_SMALLOCSIZ);

        afs_CellInit();
        AFS_COPYINSTR(AFSKPTR(parm2), cell, AFS_SMALLOCSIZ, &bufferSize, code);
        if (!code)
            afs_SetPrimaryCell(cell);
        osi_FreeSmallSpace(cell);
        if (!code) {
            code = afs_InitDynroot();
        }
    } else if (parm == AFSOP_CACHEINIT) {
        struct afs_cacheParams cparms;

        if (afs_CacheInit_Done)
            goto out;

        AFS_COPYIN(AFSKPTR(parm2), (caddr_t) & cparms, sizeof(cparms), code);
        if (code) {
#if defined(KERNEL_HAVE_UERROR)
            setuerror(code);
            code = -1;
#endif
            goto out;
        }
        afs_CacheInit_Done = 1;
        code = afs_icl_InitLogs();
        if (cparms.setTimeFlag) {
            afs_warn("afs: AFSOP_CACHEINIT setTimeFlag ignored; are you "
                     "running an old afsd?\n");
        }

        code =
            afs_CacheInit(cparms.cacheScaches, cparms.cacheFiles,
                          cparms.cacheBlocks, cparms.cacheDcaches,
                          cparms.cacheVolumes, cparms.chunkSize,
                          cparms.memCacheFlag, cparms.inodes, cparms.users,
                          cparms.dynamic_vcaches);

    } else if (parm == AFSOP_CACHEINODE) {
        ino_t ainode = parm2;
        /* wait for basic init */
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);

#ifdef AFS_DARWIN80_ENV
        get_vfs_context();
#endif
        /* do it by inode */
#ifdef AFS_SGI62_ENV
        ainode = (ainode << 32) | (parm3 & 0xffffffff);
#endif
        code = afs_InitCacheFile(NULL, ainode);
#ifdef AFS_DARWIN80_ENV
        put_vfs_context();
#endif
    } else if (parm == AFSOP_CACHEDIRS) {
        afs_numfilesperdir = parm2;
        afs_osi_Wakeup(&afs_initState);
    } else if (parm == AFSOP_CACHEFILES) {
        afs_numcachefiles = parm2;
        afs_osi_Wakeup(&afs_initState);
    } else if (parm == AFSOP_ROOTVOLUME) {
        /* wait for basic init */
        while (afs_initState < AFSOP_START_BKG)
            afs_osi_Sleep(&afs_initState);

        if (parm2) {
            AFS_COPYINSTR(AFSKPTR(parm2), afs_rootVolumeName,
                          sizeof(afs_rootVolumeName), &bufferSize, code);
            afs_rootVolumeName[sizeof(afs_rootVolumeName) - 1] = 0;
        } else
            code = 0;
    } else if (parm == AFSOP_CACHEFILE || parm == AFSOP_CACHEINFO
               || parm == AFSOP_VOLUMEINFO || parm == AFSOP_CELLINFO) {
        char *tbuffer = osi_AllocSmallSpace(AFS_SMALLOCSIZ);

        code = 0;
        AFS_COPYINSTR(AFSKPTR(parm2), tbuffer, AFS_SMALLOCSIZ, &bufferSize,
                      code);
        if (!code) {
            tbuffer[AFS_SMALLOCSIZ - 1] = '\0'; /* null-terminate the name */
            /* We have the cache dir copied in.  Call the cache init routine */
#ifdef AFS_DARWIN80_ENV
            get_vfs_context();
#endif
            if (parm == AFSOP_CACHEFILE) {
                code = afs_InitCacheFile(tbuffer, 0);
            } else if (parm == AFSOP_CACHEINFO) {
                code = afs_InitCacheInfo(tbuffer);
            } else if (parm == AFSOP_VOLUMEINFO) {
                code = afs_InitVolumeInfo(tbuffer);
            } else if (parm == AFSOP_CELLINFO) {
                code = afs_InitCellInfo(tbuffer);
            }
#ifdef AFS_DARWIN80_ENV
            put_vfs_context();
#endif
        }
        osi_FreeSmallSpace(tbuffer);
    } else if (parm == AFSOP_GO) {
        /* the generic initialization calls come here.  One parameter: should we do the
         * set-time operation on this workstation */
        if (afs_Go_Done)
            goto out;
        afs_Go_Done = 1;
        while (afs_initState < AFSOP_GO)
            afs_osi_Sleep(&afs_initState);
        afs_initState = 101;
        if (parm2) {
            /* parm2 used to set afs_setTime */
            afs_warn("afs: AFSOP_GO setTime flag ignored; are you running an "
                     "old afsd?\n");
        }
        if (afs_tpct1 + afs_tpct2 != 100) {
            afs_tpct1 = 0;
            afs_tpct2 = 0;
            splitdcache = 0;
        } else {
            splitdcache = 1;
        }
        afs_osi_Wakeup(&afs_initState);
#if     (!defined(AFS_NONFSTRANS)) || defined(AFS_AIX_IAUTH_ENV)
        afs_nfsclient_init();
#endif
        if (afs_uuid_create(&afs_cb_interface.uuid) != 0)
            memset(&afs_cb_interface.uuid, 0, sizeof(afsUUID));

#if defined(AFS_SUN5_ENV)
        afs_kstat_init();
#endif

        printf("found %d non-empty cache files (%d%%).\n",
               afs_stats_cmperf.cacheFilesReused,
               (100 * afs_stats_cmperf.cacheFilesReused) /
               (afs_stats_cmperf.cacheNumEntries ? afs_stats_cmperf.
                cacheNumEntries : 1));
    } else if (parm == AFSOP_ADVISEADDR) {
        /* pass in the host address to the rx package */
        int rxbind = 0;
        int refresh = 0;

        afs_int32 count = parm2;
        afs_int32 *buffer =
            afs_osi_Alloc(sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);
        afs_int32 *maskbuffer =
            afs_osi_Alloc(sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);
        afs_int32 *mtubuffer =
            afs_osi_Alloc(sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);
        int i;

        osi_Assert(buffer != NULL);
        osi_Assert(maskbuffer != NULL);
        osi_Assert(mtubuffer != NULL);
        /* This is a refresh */
        if (count & 0x40000000) {
            count &= ~0x40000000;
            /* Can't bind after we start. Fix? */
            count &= ~0x80000000;
            refresh = 1;
        }

        /* Bind, but only if there's only one address configured */
        if ( count & 0x80000000) {
            count &= ~0x80000000;
            if (count == 1)
                rxbind=1;
        }

        if (count > AFS_MAX_INTERFACE_ADDR) {
            code = ENOMEM;
            count = AFS_MAX_INTERFACE_ADDR;
        }

        AFS_COPYIN(AFSKPTR(parm3), (caddr_t)buffer, count * sizeof(afs_int32),
                   code);
        if (parm4 && !code)
            AFS_COPYIN(AFSKPTR(parm4), (caddr_t)maskbuffer,
                       count * sizeof(afs_int32), code);
        if (parm5 && !code)
            AFS_COPYIN(AFSKPTR(parm5), (caddr_t)mtubuffer,
                       count * sizeof(afs_int32), code);

        if (!code) {
            afs_cb_interface.numberOfInterfaces = count;
            for (i = 0; i < count; i++) {
                afs_cb_interface.addr_in[i] = buffer[i];
#ifdef AFS_USERSPACE_IP_ADDR
                /* AFS_USERSPACE_IP_ADDR means we have no way of finding the
                 * machines IP addresses when in the kernel (the in_ifaddr
                 * struct is not available), so we pass the info in at
                 * startup. We also pass in the subnetmask and mtu size. The
                 * subnetmask is used when setting the rank:
                 * afsi_SetServerIPRank(); and the mtu size is used when
                 * finding the best mtu size. rxi_FindIfnet() is replaced
                 * with rxi_Findcbi().
                 */
                afs_cb_interface.subnetmask[i] =
                    (parm4 ? maskbuffer[i] : 0xffffffff);
                afs_cb_interface.mtu[i] = (parm5 ? mtubuffer[i] : htonl(1500));
#endif
            }
            rxi_setaddr(buffer[0]);
            if (!refresh) {
                if (rxbind)
                    rx_bindhost = buffer[0];
                else
                    rx_bindhost = htonl(INADDR_ANY);
            }
        } else {
            refresh = 0;
        }

        afs_osi_Free(buffer, sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);
        afs_osi_Free(maskbuffer, sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);
        afs_osi_Free(mtubuffer, sizeof(afs_int32) * AFS_MAX_INTERFACE_ADDR);

        if (refresh) {
            afs_CheckServers(1, NULL);     /* check down servers */
            afs_CheckServers(0, NULL);     /* check up servers */
        }
    }
    else if (parm == AFSOP_SHUTDOWN) {
        if (afs_globalVFS != 0) {
            afs_warn("AFS isn't unmounted yet! Call aborted\n");
            code = EACCES;
        } else if (parm2 == AFS_COLD) {
            afs_shutdown(AFS_COLD);
        } else {
            afs_shutdown(AFS_WARM);
        }
    } else if (parm == AFSOP_AFS_VFSMOUNT) {
#ifdef  AFS_HPUX_ENV
        vfsmount(parm2, parm3, parm4, parm5);
#else /* defined(AFS_HPUX_ENV) */
# if defined(KERNEL_HAVE_UERROR)
        setuerror(EINVAL);
# else
        code = EINVAL;
# endif
#endif /* defined(AFS_HPUX_ENV) */
    } else if (parm == AFSOP_CLOSEWAIT) {
        afs_SynchronousCloses = 'S';
    } else if (parm == AFSOP_GETMTU) {
        afs_uint32 mtu = 0;
#if     !defined(AFS_SUN5_ENV) && !defined(AFS_LINUX20_ENV)
# ifdef AFS_USERSPACE_IP_ADDR
        afs_int32 i;
        i = rxi_Findcbi(parm2);
        mtu = ((i == -1) ? htonl(1500) : afs_cb_interface.mtu[i]);
# else /* AFS_USERSPACE_IP_ADDR */
        rx_ifnet_t tifnp;
        RX_NET_EPOCH_ENTER();

        tifnp = rxi_FindIfnet(parm2, NULL);     /*  make iterative */
        mtu = (tifnp ? rx_ifnet_mtu(tifnp) : htonl(1500));

        RX_NET_EPOCH_EXIT();
# endif /* else AFS_USERSPACE_IP_ADDR */
#endif /* !AFS_SUN5_ENV */
        if (!code)
            AFS_COPYOUT((caddr_t) & mtu, AFSKPTR(parm3),
                        sizeof(afs_int32), code);
    } else if (parm == AFSOP_GETMASK) { /* parm2 == addr in net order */
        afs_uint32 mask = 0;
#if     !defined(AFS_SUN5_ENV)
# ifdef AFS_USERSPACE_IP_ADDR
        afs_int32 i;
        i = rxi_Findcbi(parm2);
        if (i != -1) {
            mask = afs_cb_interface.subnetmask[i];
        } else {
            code = -1;
        }
# else /* AFS_USERSPACE_IP_ADDR */
        rx_ifnet_t tifnp;
        RX_NET_EPOCH_ENTER();

        tifnp = rxi_FindIfnet(parm2, &mask);    /* make iterative */
        if (!tifnp)
            code = -1;

        RX_NET_EPOCH_EXIT();
# endif /* else AFS_USERSPACE_IP_ADDR */
#endif /* !AFS_SUN5_ENV */
        if (!code)
            AFS_COPYOUT((caddr_t) & mask, AFSKPTR(parm3),
                        sizeof(afs_int32), code);
    }
    else if (parm == AFSOP_AFSDB_HANDLER) {
        int sizeArg = (int)parm4;
        int kmsgLen = sizeArg & 0xffff;
        int cellLen = (sizeArg & 0xffff0000) >> 16;
        afs_int32 *kmsg = afs_osi_Alloc(kmsgLen);
        char *cellname = afs_osi_Alloc(cellLen);

        osi_Assert(kmsg != NULL);
        osi_Assert(cellname != NULL);
#ifndef UKERNEL
        afs_osi_MaskUserLoop();
#endif
        AFS_COPYIN(AFSKPTR(parm2), cellname, cellLen, code);
        AFS_COPYIN(AFSKPTR(parm3), kmsg, kmsgLen, code);
        if (!code) {
            code = afs_AFSDBHandler(cellname, cellLen, kmsg);
            if (*cellname == 1)
                *cellname = 0;
            if (code == -2) {   /* Shutting down? */
                *cellname = 1;
                code = 0;
            }
        }
        if (!code)
            AFS_COPYOUT(cellname, AFSKPTR(parm2), cellLen, code);
        afs_osi_Free(kmsg, kmsgLen);
        afs_osi_Free(cellname, cellLen);
    }
    else if (parm == AFSOP_SET_DYNROOT) {
        code = afs_SetDynrootEnable(parm2);
    } else if (parm == AFSOP_SET_FAKESTAT) {
        if (parm2 >= 0 && parm2 <= 2) {
            afs_fakestat_enable = parm2;
            code = 0;
        } else {
            afs_warn("afs: afsd gave us unknown fakestat value %ld (are afsd "
                     "and libafs running the same version?\n", parm2);
            code = EINVAL;
        }
    } else if (parm == AFSOP_SET_BACKUPTREE) {
        afs_bkvolpref = parm2;
    } else if (parm == AFSOP_SET_RXPCK) {
        rx_extraPackets = parm2;
        afscall_set_rxpck_received = 1;
    } else if (parm == AFSOP_SET_RXMAXMTU) {
        rx_MyMaxSendSize = rx_maxReceiveSizeUser = rx_maxReceiveSize = parm2;
    } else if (parm == AFSOP_SET_RXMAXFRAGS) {
        rxi_nSendFrags = rxi_nRecvFrags = parm2;
    } else if (parm == AFSOP_SET_RMTSYS_FLAG) {
        afs_rmtsys_enable = parm2;
        code = 0;
#ifndef UKERNEL
    } else if (parm == AFSOP_SEED_ENTROPY) {
        unsigned char *seedbuf;

        if (parm3 > 4096) {
            code = EFAULT;
        } else {
            seedbuf = afs_osi_Alloc(parm3);
            AFS_COPYIN(AFSKPTR(parm2), seedbuf, parm3, code);
            RAND_seed(seedbuf, parm3);
            memset(seedbuf, 0, parm3);
            afs_osi_Free(seedbuf, parm3);
        }
#endif
    } else if (parm == AFSOP_SET_INUMCALC) {
        switch (parm2) {
        case AFS_INUMCALC_COMPAT:
            afs_md5inum = 0;
            code = 0;
            break;
        case AFS_INUMCALC_MD5:
            afs_md5inum = 1;
            code = 0;
            break;
        default:
            code = EINVAL;
        }
    } else if (parm == AFSOP_SET_VOLUME_TTL) {
        if ((parm2 < AFS_MIN_VOLUME_TTL) || (parm2 > AFS_MAX_VOLUME_TTL)) {
            code = EFAULT;
        } else {
            afs_volume_ttl = parm2;
            code = 0;
        }
#ifdef AFS_SOCKPROXY_ENV
    } else if (parm == AFSOP_SOCKPROXY_HANDLER) {
        code = sockproxy_handler(AFSKPTR(parm2), AFSKPTR(parm3));
#endif
    } else {
        code = EINVAL;
    }

  out:
    AFS_GUNLOCK();
#ifdef AFS_LINUX20_ENV
    return -code;
#else
    return code;
#endif
}

/*
 * Initstate in the range 0 < x < 100 are early initialization states.
 * Initstate of 100 means a AFSOP_START operation has been done.  After this,
 *  the cache may be initialized.
 * Initstate of 101 means a AFSOP_GO operation has been done.  This operation
 *  is done after all the cache initialization has been done.
 * Initstate of 200 means that the volume has been looked up once, possibly
 *  incorrectly.
 * Initstate of 300 means that the volume has been *successfully* looked up.
 */
int
afs_CheckInit(void)
{
    int code = 0;

    AFS_STATCNT(afs_CheckInit);
    if (afs_initState <= 100)
        code = ENXIO;           /* never finished init phase */
    else if (afs_initState == 101) {    /* init done, wait for afs_daemon */
        while (afs_initState < 200)
            afs_osi_Sleep(&afs_initState);
    } else if (afs_initState == 200)
        code = ETIMEDOUT;       /* didn't find root volume */
    return code;
}

enum afs_shutdown_state afs_shuttingdown = AFS_RUNNING;
void
afs_shutdown(enum afs_shutdown_type cold_flag)
{
    extern short afs_brsDaemons;
    extern afs_int32 afs_CheckServerDaemonStarted;
    extern struct afs_osi_WaitHandle AFS_WaitHandler, AFS_CSWaitHandler;
    extern struct osi_file *afs_cacheInodep;

    AFS_STATCNT(afs_shutdown);
    if (afs_initState == 0) {
        afs_warn("AFS not initialized - not shutting down\n");
      return;
    }

    if (afs_shuttingdown != AFS_RUNNING)
        return;

    afs_cold_shutdown = ((cold_flag == AFS_COLD) ? 1 : 0);

    afs_shuttingdown = AFS_FLUSHING_CB;

    /* Give up all of our callbacks if we can. */
    afs_FlushVCBs(2);

    afs_shuttingdown = AFS_SHUTDOWN;

#if defined(AFS_SUN5_ENV)
    afs_kstat_shutdown();
#endif

    if (afs_cold_shutdown)
        afs_warn("afs: COLD ");
    else
        afs_warn("afs: WARM ");
    afs_warn("shutting down of: vcaches... ");

#if !defined(AFS_FBSD_ENV)
    /* The FBSD afs_unmount() calls vflush(), which reclaims all vnodes
     * on the mountpoint, flushing them in the process.  In the presence
     * of bugs, flushing again here can cause panics. */
    afs_FlushAllVCaches();
#endif

    afs_termState = AFSOP_STOP_BKG;

    afs_warn("BkG... ");
    /* Wake-up afs_brsDaemons so that we don't have to wait for a bkg job! */
    while (afs_termState == AFSOP_STOP_BKG) {
        afs_osi_Wakeup(&afs_brsDaemons);
        afs_osi_Sleep(&afs_termState);
    }

    afs_warn("CB... ");

    afs_termState = AFSOP_STOP_RXCALLBACK;
    rx_WakeupServerProcs();
#ifdef AFS_AIX51_ENV
    shutdown_rxkernel();
#endif
    /* close rx server connections here? */
    while (afs_termState == AFSOP_STOP_RXCALLBACK)
        afs_osi_Sleep(&afs_termState);

    afs_warn("afs... ");
    while (afs_termState == AFSOP_STOP_AFS) {
        afs_osi_CancelWait(&AFS_WaitHandler);
        afs_osi_Sleep(&afs_termState);
    }
    if (afs_CheckServerDaemonStarted) {
        while (afs_termState == AFSOP_STOP_CS) {
            afs_osi_CancelWait(&AFS_CSWaitHandler);
            afs_osi_Sleep(&afs_termState);
        }
    }
    afs_warn("CTrunc... ");
    /* Cancel cache truncate daemon. */
    while (afs_termState == AFSOP_STOP_TRUNCDAEMON) {
        afs_osi_Wakeup((char *)&afs_CacheTruncateDaemon);
        afs_osi_Sleep(&afs_termState);
    }
    afs_warn("AFSDB... ");
    afs_StopAFSDB();
    while (afs_termState == AFSOP_STOP_AFSDB)
        afs_osi_Sleep(&afs_termState);
#if     defined(AFS_SUN5_ENV) || defined(RXK_LISTENER_ENV) || defined(RXK_UPCALL_ENV)
    afs_warn("RxEvent... ");
    /* cancel rx event daemon */
    while (afs_termState == AFSOP_STOP_RXEVENT)
        afs_osi_Sleep(&afs_termState);
# if defined(RXK_LISTENER_ENV)
#  ifndef UKERNEL
    afs_warn("UnmaskRxkSignals... ");
    afs_osi_UnmaskRxkSignals();
#  endif
    /* cancel rx listener */
    afs_warn("RxListener... ");
    osi_StopListener();         /* This closes rx_socket. */
    while (afs_termState == AFSOP_STOP_RXK_LISTENER) {
        afs_warn("Sleep... ");
        afs_osi_Sleep(&afs_termState);
    }
# endif
#endif

#if defined(AFS_SUN510_ENV) || defined(RXK_UPCALL_ENV)
    afs_warn("NetIfPoller... ");
    osi_StopNetIfPoller();
#endif
    rxi_FreeAllPackets();

    afs_termState = AFSOP_STOP_COMPLETE;

#ifdef AFS_AIX51_ENV
    shutdown_daemons();
#endif
    shutdown_CB();
    shutdown_bufferpackage();
    shutdown_cache();
    shutdown_osi();
    /*
     * Close file only after daemons which can write to it are stopped.
     * Need to close before the osinet shutdown to avoid failing check
     * for dangling memory allocations.
     */
    if (afs_cacheInodep) {      /* memcache won't set this */
        osi_UFSClose(afs_cacheInodep);  /* Since we always leave it open */
        afs_cacheInodep = 0;
    }
    /*
     * Shutdown the ICL logs - needed to free allocated memory space and avoid
     * warnings from shutdown_osinet
     */
    shutdown_icl();
    shutdown_osinet();
    shutdown_osifile();
    shutdown_vnodeops();
    shutdown_memcache();
    shutdown_xscache();
#if (!defined(AFS_NONFSTRANS) || defined(AFS_AIX_IAUTH_ENV))
    shutdown_exporter();
    shutdown_nfsclnt();
#endif
    shutdown_afstest();
    shutdown_dynroot();
    shutdown_AFS();
    /* The following hold the cm stats */
    memset(&afs_cmstats, 0, sizeof(struct afs_CMStats));
    memset(&afs_stats_cmperf, 0, sizeof(struct afs_stats_CMPerf));
    memset(&afs_stats_cmfullperf, 0, sizeof(struct afs_stats_CMFullPerf));
    afs_warn(" ALL allocated tables... ");

    afs_shuttingdown = AFS_RUNNING;
    afs_warn("done\n");

    return;                     /* Just kill daemons for now */
}

void
shutdown_afstest(void)
{
    AFS_STATCNT(shutdown_afstest);
    afs_initState = afs_termState = 0;
    AFS_Running = afs_CB_Running = 0;
    afs_CacheInit_Done = afs_Go_Done = 0;
    if (afs_cold_shutdown) {
        *afs_rootVolumeName = 0;
    }
}