/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Copyright (c) 1983, 1984, 1985, 1986, 1987, 1988, 1989 AT&T * All Rights Reserved */ /* * Portions of this source code were derived from Berkeley 4.3 BSD * under license from the Regents of the University of California. */ /* * Implements a kernel based, client side RPC over Connection Oriented * Transports (COTS). */ /* * Much of this file has been re-written to let NFS work better over slow * transports. A description follows. * * One of the annoying things about kRPC/COTS is that it will temporarily * create more than one connection between a client and server. This * happens because when a connection is made, the end-points entry in the * linked list of connections (headed by cm_hd), is removed so that other * threads don't mess with it. Went ahead and bit the bullet by keeping * the endpoint on the connection list and introducing state bits, * condition variables etc. to the connection entry data structure (struct * cm_xprt). * * Here is a summary of the changes to cm-xprt: * * x_ctime is the timestamp of when the endpoint was last * connected or disconnected. If an end-point is ever disconnected * or re-connected, then any outstanding RPC request is presumed * lost, telling clnt_cots_kcallit that it needs to re-send the * request, not just wait for the original request's reply to * arrive. * * x_thread flag which tells us if a thread is doing a connection attempt. * * x_waitdis flag which tells us we are waiting a disconnect ACK. * * x_needdis flag which tells us we need to send a T_DISCONN_REQ * to kill the connection. * * x_needrel flag which tells us we need to send a T_ORDREL_REQ to * gracefully close the connection. * * #defined bitmasks for the all the b_* bits so that more * efficient (and at times less clumsy) masks can be used to * manipulated state in cases where multiple bits have to * set/cleared/checked in the same critical section. * * x_conn_cv and x_dis-_cv are new condition variables to let * threads knows when the connection attempt is done, and to let * the connecting thread know when the disconnect handshake is * done. * * Added the CONN_HOLD() macro so that all reference holds have the same * look and feel. * * In the private (cku_private) portion of the client handle, * * cku_flags replaces the cku_sent a boolean. cku_flags keeps * track of whether a request as been sent, and whether the * client's handles call record is on the dispatch list (so that * the reply can be matched by XID to the right client handle). * The idea of CKU_ONQUEUE is that we can exit clnt_cots_kcallit() * and still have the response find the right client handle so * that the retry of CLNT_CALL() gets the result. Testing, found * situations where if the timeout was increased, performance * degraded. This was due to us hitting a window where the thread * was back in rfscall() (probably printing server not responding) * while the response came back but no place to put it. * * cku_ctime is just a cache of x_ctime. If they match, * clnt_cots_kcallit() won't to send a retry (unless the maximum * receive count limit as been reached). If the don't match, then * we assume the request has been lost, and a retry of the request * is needed. * * cku_recv_attempts counts the number of receive count attempts * after one try is sent on the wire. * * Added the clnt_delay() routine so that interruptible and * noninterruptible delays are possible. * * CLNT_MIN_TIMEOUT has been bumped to 10 seconds from 3. This is used to * control how long the client delays before returned after getting * ECONNREFUSED. At 3 seconds, 8 client threads per mount really does bash * a server that may be booting and not yet started nfsd. * * CLNT_MAXRECV_WITHOUT_RETRY is a new macro (value of 3) (with a tunable) * Why don't we just wait forever (receive an infinite # of times)? * Because the server may have rebooted. More insidious is that some * servers (ours) will drop NFS/TCP requests in some cases. This is bad, * but it is a reality. * * The case of a server doing orderly release really messes up the * client's recovery, especially if the server's TCP implementation is * buggy. It was found was that the kRPC/COTS client was breaking some * TPI rules, such as not waiting for the acknowledgement of a * T_DISCON_REQ (hence the added case statements T_ERROR_ACK, T_OK_ACK and * T_DISCON_REQ in clnt_dispatch_notifyall()). * * One of things that we've seen is that a kRPC TCP endpoint goes into * TIMEWAIT and a thus a reconnect takes a long time to satisfy because * that the TIMEWAIT state takes a while to finish. If a server sends a * T_ORDREL_IND, there is little point in an RPC client doing a * T_ORDREL_REQ, because the RPC request isn't going to make it (the * server is saying that it won't accept any more data). So kRPC was * changed to send a T_DISCON_REQ when we get a T_ORDREL_IND. So now the * connection skips the TIMEWAIT state and goes straight to a bound state * that kRPC can quickly switch to connected. * * Code that issues TPI request must use waitforack() to wait for the * corresponding ack (assuming there is one) in any future modifications. * This works around problems that may be introduced by breaking TPI rules * (by submitting new calls before earlier requests have been acked) in the * case of a signal or other early return. waitforack() depends on * clnt_dispatch_notifyconn() to issue the wakeup when the ack * arrives, so adding new TPI calls may require corresponding changes * to clnt_dispatch_notifyconn(). Presently, the timeout period is based on * CLNT_MIN_TIMEOUT which is 10 seconds. If you modify this value, be sure * not to set it too low or TPI ACKS will be lost. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define COTS_DEFAULT_ALLOCSIZE 2048 #define WIRE_HDR_SIZE 20 /* serialized call header, sans proc number */ #define MSG_OFFSET 128 /* offset of call into the mblk */ const char *kinet_ntop6(uchar_t *, char *, size_t); static int clnt_cots_ksettimers(CLIENT *, struct rpc_timers *, struct rpc_timers *, int, void(*)(int, int, caddr_t), caddr_t, uint32_t); static enum clnt_stat clnt_cots_kcallit(CLIENT *, rpcproc_t, xdrproc_t, caddr_t, xdrproc_t, caddr_t, struct timeval); static void clnt_cots_kabort(CLIENT *); static void clnt_cots_kerror(CLIENT *, struct rpc_err *); static bool_t clnt_cots_kfreeres(CLIENT *, xdrproc_t, caddr_t); static void clnt_cots_kdestroy(CLIENT *); static bool_t clnt_cots_kcontrol(CLIENT *, int, char *); /* List of transports managed by the connection manager. */ struct cm_xprt { TIUSER *x_tiptr; /* transport handle */ queue_t *x_wq; /* send queue */ clock_t x_time; /* last time we handed this xprt out */ clock_t x_ctime; /* time we went to CONNECTED */ int x_tidu_size; /* TIDU size of this transport */ union { struct { unsigned int #ifdef _BIT_FIELDS_HTOL b_closing: 1, /* we've sent a ord rel on this conn */ b_dead: 1, /* transport is closed or disconn */ b_doomed: 1, /* too many conns, let this go idle */ b_connected: 1, /* this connection is connected */ b_ordrel: 1, /* do an orderly release? */ b_thread: 1, /* thread doing connect */ b_waitdis: 1, /* waiting for disconnect ACK */ b_needdis: 1, /* need T_DISCON_REQ */ b_needrel: 1, /* need T_ORDREL_REQ */ b_early_disc: 1, /* got a T_ORDREL_IND or T_DISCON_IND */ /* disconnect during connect */ b_pad: 22; #endif #ifdef _BIT_FIELDS_LTOH b_pad: 22, b_early_disc: 1, /* got a T_ORDREL_IND or T_DISCON_IND */ /* disconnect during connect */ b_needrel: 1, /* need T_ORDREL_REQ */ b_needdis: 1, /* need T_DISCON_REQ */ b_waitdis: 1, /* waiting for disconnect ACK */ b_thread: 1, /* thread doing connect */ b_ordrel: 1, /* do an orderly release? */ b_connected: 1, /* this connection is connected */ b_doomed: 1, /* too many conns, let this go idle */ b_dead: 1, /* transport is closed or disconn */ b_closing: 1; /* we've sent a ord rel on this conn */ #endif } bit; unsigned int word; #define x_closing x_state.bit.b_closing #define x_dead x_state.bit.b_dead #define x_doomed x_state.bit.b_doomed #define x_connected x_state.bit.b_connected #define x_ordrel x_state.bit.b_ordrel #define x_thread x_state.bit.b_thread #define x_waitdis x_state.bit.b_waitdis #define x_needdis x_state.bit.b_needdis #define x_needrel x_state.bit.b_needrel #define x_early_disc x_state.bit.b_early_disc #define x_state_flags x_state.word #define X_CLOSING 0x80000000 #define X_DEAD 0x40000000 #define X_DOOMED 0x20000000 #define X_CONNECTED 0x10000000 #define X_ORDREL 0x08000000 #define X_THREAD 0x04000000 #define X_WAITDIS 0x02000000 #define X_NEEDDIS 0x01000000 #define X_NEEDREL 0x00800000 #define X_EARLYDISC 0x00400000 #define X_BADSTATES (X_CLOSING | X_DEAD | X_DOOMED) } x_state; int x_ref; /* number of users of this xprt */ int x_family; /* address family of transport */ dev_t x_rdev; /* device number of transport */ struct cm_xprt *x_next; struct netbuf x_server; /* destination address */ struct netbuf x_src; /* src address (for retries) */ kmutex_t x_lock; /* lock on this entry */ kcondvar_t x_cv; /* to signal when can be closed */ kcondvar_t x_conn_cv; /* to signal when connection attempt */ /* is complete */ kstat_t *x_ksp; kcondvar_t x_dis_cv; /* to signal when disconnect attempt */ /* is complete */ zoneid_t x_zoneid; /* zone this xprt belongs to */ }; typedef struct cm_kstat_xprt { kstat_named_t x_wq; kstat_named_t x_server; kstat_named_t x_family; kstat_named_t x_rdev; kstat_named_t x_time; kstat_named_t x_state; kstat_named_t x_ref; kstat_named_t x_port; } cm_kstat_xprt_t; static cm_kstat_xprt_t cm_kstat_template = { { "write_queue", KSTAT_DATA_UINT32 }, { "server", KSTAT_DATA_STRING }, { "addr_family", KSTAT_DATA_UINT32 }, { "device", KSTAT_DATA_UINT32 }, { "time_stamp", KSTAT_DATA_UINT32 }, { "status", KSTAT_DATA_UINT32 }, { "ref_count", KSTAT_DATA_INT32 }, { "port", KSTAT_DATA_UINT32 }, }; /* * The inverse of this is connmgr_release(). */ #define CONN_HOLD(Cm_entry) {\ mutex_enter(&(Cm_entry)->x_lock); \ (Cm_entry)->x_ref++; \ mutex_exit(&(Cm_entry)->x_lock); \ } /* * Private data per rpc handle. This structure is allocated by * clnt_cots_kcreate, and freed by clnt_cots_kdestroy. */ typedef struct cku_private_s { CLIENT cku_client; /* client handle */ calllist_t cku_call; /* for dispatching calls */ struct rpc_err cku_err; /* error status */ struct netbuf cku_srcaddr; /* source address for retries */ int cku_addrfmly; /* for binding port */ struct netbuf cku_addr; /* remote address */ dev_t cku_device; /* device to use */ uint_t cku_flags; #define CKU_ONQUEUE 0x1 #define CKU_SENT 0x2 bool_t cku_progress; /* for CLSET_PROGRESS */ uint32_t cku_xid; /* current XID */ clock_t cku_ctime; /* time stamp of when */ /* connection was created */ uint_t cku_recv_attempts; XDR cku_outxdr; /* xdr routine for output */ XDR cku_inxdr; /* xdr routine for input */ char cku_rpchdr[WIRE_HDR_SIZE + 4]; /* pre-serialized rpc header */ uint_t cku_outbuflen; /* default output mblk length */ struct cred *cku_cred; /* credentials */ bool_t cku_nodelayonerr; /* for CLSET_NODELAYONERR */ int cku_useresvport; /* Use reserved port */ struct rpc_cots_client *cku_stats; /* stats for zone */ } cku_private_t; static struct cm_xprt *connmgr_wrapconnect(struct cm_xprt *, const struct timeval *, struct netbuf *, int, struct netbuf *, struct rpc_err *, bool_t, bool_t, cred_t *); static bool_t connmgr_connect(struct cm_xprt *, queue_t *, struct netbuf *, int, calllist_t *, int *, bool_t reconnect, const struct timeval *, bool_t, cred_t *); static void *connmgr_opt_getoff(mblk_t *mp, t_uscalar_t offset, t_uscalar_t length, uint_t align_size); static bool_t connmgr_setbufsz(calllist_t *e, queue_t *wq, cred_t *cr); static bool_t connmgr_getopt_int(queue_t *wq, int level, int name, int *val, calllist_t *e, cred_t *cr); static bool_t connmgr_setopt_int(queue_t *wq, int level, int name, int val, calllist_t *e, cred_t *cr); static bool_t connmgr_setopt(queue_t *, int, int, calllist_t *, cred_t *cr); static void connmgr_sndrel(struct cm_xprt *); static void connmgr_snddis(struct cm_xprt *); static void connmgr_close(struct cm_xprt *); static void connmgr_release(struct cm_xprt *); static struct cm_xprt *connmgr_wrapget(struct netbuf *, const struct timeval *, cku_private_t *); static struct cm_xprt *connmgr_get(struct netbuf *, const struct timeval *, struct netbuf *, int, struct netbuf *, struct rpc_err *, dev_t, bool_t, int, cred_t *); static void connmgr_cancelconn(struct cm_xprt *); static enum clnt_stat connmgr_cwait(struct cm_xprt *, const struct timeval *, bool_t); static void connmgr_dis_and_wait(struct cm_xprt *); static int clnt_dispatch_send(queue_t *, mblk_t *, calllist_t *, uint_t, uint_t); static int clnt_delay(clock_t, bool_t); static int waitforack(calllist_t *, t_scalar_t, const struct timeval *, bool_t); /* * Operations vector for TCP/IP based RPC */ static struct clnt_ops tcp_ops = { clnt_cots_kcallit, /* do rpc call */ clnt_cots_kabort, /* abort call */ clnt_cots_kerror, /* return error status */ clnt_cots_kfreeres, /* free results */ clnt_cots_kdestroy, /* destroy rpc handle */ clnt_cots_kcontrol, /* the ioctl() of rpc */ clnt_cots_ksettimers, /* set retry timers */ }; static int rpc_kstat_instance = 0; /* keeps the current instance */ /* number for the next kstat_create */ static struct cm_xprt *cm_hd = NULL; static kmutex_t connmgr_lock; /* for connection mngr's list of transports */ extern kmutex_t clnt_max_msg_lock; static calllist_t *clnt_pending = NULL; extern kmutex_t clnt_pending_lock; static int clnt_cots_hash_size = DEFAULT_HASH_SIZE; static call_table_t *cots_call_ht; static const struct rpc_cots_client { kstat_named_t rccalls; kstat_named_t rcbadcalls; kstat_named_t rcbadxids; kstat_named_t rctimeouts; kstat_named_t rcnewcreds; kstat_named_t rcbadverfs; kstat_named_t rctimers; kstat_named_t rccantconn; kstat_named_t rcnomem; kstat_named_t rcintrs; } cots_rcstat_tmpl = { { "calls", KSTAT_DATA_UINT64 }, { "badcalls", KSTAT_DATA_UINT64 }, { "badxids", KSTAT_DATA_UINT64 }, { "timeouts", KSTAT_DATA_UINT64 }, { "newcreds", KSTAT_DATA_UINT64 }, { "badverfs", KSTAT_DATA_UINT64 }, { "timers", KSTAT_DATA_UINT64 }, { "cantconn", KSTAT_DATA_UINT64 }, { "nomem", KSTAT_DATA_UINT64 }, { "interrupts", KSTAT_DATA_UINT64 } }; #define COTSRCSTAT_INCR(p, x) \ atomic_add_64(&(p)->x.value.ui64, 1) #define CLNT_MAX_CONNS 1 /* concurrent connections between clnt/srvr */ int clnt_max_conns = CLNT_MAX_CONNS; #define CLNT_MIN_TIMEOUT 10 /* seconds to wait after we get a */ /* connection reset */ #define CLNT_MIN_CONNTIMEOUT 5 /* seconds to wait for a connection */ int clnt_cots_min_tout = CLNT_MIN_TIMEOUT; int clnt_cots_min_conntout = CLNT_MIN_CONNTIMEOUT; /* * Limit the number of times we will attempt to receive a reply without * re-sending a response. */ #define CLNT_MAXRECV_WITHOUT_RETRY 3 uint_t clnt_cots_maxrecv = CLNT_MAXRECV_WITHOUT_RETRY; uint_t *clnt_max_msg_sizep; void (*clnt_stop_idle)(queue_t *wq); #define ptoh(p) (&((p)->cku_client)) #define htop(h) ((cku_private_t *)((h)->cl_private)) /* * Times to retry */ #define REFRESHES 2 /* authentication refreshes */ /* * The following is used to determine the global default behavior for * COTS when binding to a local port. * * If the value is set to 1 the default will be to select a reserved * (aka privileged) port, if the value is zero the default will be to * use non-reserved ports. Users of kRPC may override this by using * CLNT_CONTROL() and CLSET_BINDRESVPORT. */ int clnt_cots_do_bindresvport = 1; static zone_key_t zone_cots_key; /* * Defaults TCP send and receive buffer size for RPC connections. * These values can be tuned by /etc/system. */ int rpc_send_bufsz = 1024*1024; int rpc_recv_bufsz = 1024*1024; /* * To use system-wide default for TCP send and receive buffer size, * use /etc/system to set rpc_default_tcp_bufsz to 1: * * set rpcmod:rpc_default_tcp_bufsz=1 */ int rpc_default_tcp_bufsz = 0; /* * We need to do this after all kernel threads in the zone have exited. */ /* ARGSUSED */ static void clnt_zone_destroy(zoneid_t zoneid, void *unused) { struct cm_xprt **cmp; struct cm_xprt *cm_entry; struct cm_xprt *freelist = NULL; mutex_enter(&connmgr_lock); cmp = &cm_hd; while ((cm_entry = *cmp) != NULL) { if (cm_entry->x_zoneid == zoneid) { *cmp = cm_entry->x_next; cm_entry->x_next = freelist; freelist = cm_entry; } else { cmp = &cm_entry->x_next; } } mutex_exit(&connmgr_lock); while ((cm_entry = freelist) != NULL) { freelist = cm_entry->x_next; connmgr_close(cm_entry); } } int clnt_cots_kcreate(dev_t dev, struct netbuf *addr, int family, rpcprog_t prog, rpcvers_t vers, uint_t max_msgsize, cred_t *cred, CLIENT **ncl) { CLIENT *h; cku_private_t *p; struct rpc_msg call_msg; struct rpcstat *rpcstat; RPCLOG(8, "clnt_cots_kcreate: prog %u\n", prog); rpcstat = zone_getspecific(rpcstat_zone_key, rpc_zone()); ASSERT(rpcstat != NULL); /* Allocate and intialize the client handle. */ p = kmem_zalloc(sizeof (*p), KM_SLEEP); h = ptoh(p); h->cl_private = (caddr_t)p; h->cl_auth = authkern_create(); h->cl_ops = &tcp_ops; cv_init(&p->cku_call.call_cv, NULL, CV_DEFAULT, NULL); mutex_init(&p->cku_call.call_lock, NULL, MUTEX_DEFAULT, NULL); /* * If the current sanity check size in rpcmod is smaller * than the size needed, then increase the sanity check. */ if (max_msgsize != 0 && clnt_max_msg_sizep != NULL && max_msgsize > *clnt_max_msg_sizep) { mutex_enter(&clnt_max_msg_lock); if (max_msgsize > *clnt_max_msg_sizep) *clnt_max_msg_sizep = max_msgsize; mutex_exit(&clnt_max_msg_lock); } p->cku_outbuflen = COTS_DEFAULT_ALLOCSIZE; /* Preserialize the call message header */ call_msg.rm_xid = 0; call_msg.rm_direction = CALL; call_msg.rm_call.cb_rpcvers = RPC_MSG_VERSION; call_msg.rm_call.cb_prog = prog; call_msg.rm_call.cb_vers = vers; xdrmem_create(&p->cku_outxdr, p->cku_rpchdr, WIRE_HDR_SIZE, XDR_ENCODE); if (!xdr_callhdr(&p->cku_outxdr, &call_msg)) { RPCLOG0(1, "clnt_cots_kcreate - Fatal header serialization " "error\n"); auth_destroy(h->cl_auth); kmem_free(p, sizeof (cku_private_t)); RPCLOG0(1, "clnt_cots_kcreate: create failed error EINVAL\n"); return (EINVAL); /* XXX */ } /* * The zalloc initialized the fields below. * p->cku_xid = 0; * p->cku_flags = 0; * p->cku_srcaddr.len = 0; * p->cku_srcaddr.maxlen = 0; */ p->cku_cred = cred; p->cku_device = dev; p->cku_addrfmly = family; p->cku_addr.buf = kmem_zalloc(addr->maxlen, KM_SLEEP); p->cku_addr.maxlen = addr->maxlen; p->cku_addr.len = addr->len; bcopy(addr->buf, p->cku_addr.buf, addr->len); p->cku_stats = rpcstat->rpc_cots_client; p->cku_useresvport = -1; /* value is has not been set */ *ncl = h; return (0); } /*ARGSUSED*/ static void clnt_cots_kabort(CLIENT *h) { } /* * Return error info on this handle. */ static void clnt_cots_kerror(CLIENT *h, struct rpc_err *err) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); *err = p->cku_err; } static bool_t clnt_cots_kfreeres(CLIENT *h, xdrproc_t xdr_res, caddr_t res_ptr) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); XDR *xdrs; xdrs = &(p->cku_outxdr); xdrs->x_op = XDR_FREE; return ((*xdr_res)(xdrs, res_ptr)); } static bool_t clnt_cots_kcontrol(CLIENT *h, int cmd, char *arg) { cku_private_t *p = htop(h); switch (cmd) { case CLSET_PROGRESS: p->cku_progress = TRUE; return (TRUE); case CLSET_XID: if (arg == NULL) return (FALSE); p->cku_xid = *((uint32_t *)arg); return (TRUE); case CLGET_XID: if (arg == NULL) return (FALSE); *((uint32_t *)arg) = p->cku_xid; return (TRUE); case CLSET_NODELAYONERR: if (arg == NULL) return (FALSE); if (*((bool_t *)arg) == TRUE) { p->cku_nodelayonerr = TRUE; return (TRUE); } if (*((bool_t *)arg) == FALSE) { p->cku_nodelayonerr = FALSE; return (TRUE); } return (FALSE); case CLGET_NODELAYONERR: if (arg == NULL) return (FALSE); *((bool_t *)arg) = p->cku_nodelayonerr; return (TRUE); case CLSET_BINDRESVPORT: if (arg == NULL) return (FALSE); if (*(int *)arg != 1 && *(int *)arg != 0) return (FALSE); p->cku_useresvport = *(int *)arg; return (TRUE); case CLGET_BINDRESVPORT: if (arg == NULL) return (FALSE); *(int *)arg = p->cku_useresvport; return (TRUE); default: return (FALSE); } } /* * Destroy rpc handle. Frees the space used for output buffer, * private data, and handle structure. */ static void clnt_cots_kdestroy(CLIENT *h) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); calllist_t *call = &p->cku_call; RPCLOG(8, "clnt_cots_kdestroy h: %p\n", (void *)h); RPCLOG(8, "clnt_cots_kdestroy h: xid=0x%x\n", p->cku_xid); if (p->cku_flags & CKU_ONQUEUE) { RPCLOG(64, "clnt_cots_kdestroy h: removing call for xid 0x%x " "from dispatch list\n", p->cku_xid); call_table_remove(call); } if (call->call_reply) freemsg(call->call_reply); cv_destroy(&call->call_cv); mutex_destroy(&call->call_lock); kmem_free(p->cku_srcaddr.buf, p->cku_srcaddr.maxlen); kmem_free(p->cku_addr.buf, p->cku_addr.maxlen); kmem_free(p, sizeof (*p)); } static int clnt_cots_pulls; #define RM_HDR_SIZE 4 /* record mark header size */ /* * Call remote procedure. */ static enum clnt_stat clnt_cots_kcallit(CLIENT *h, rpcproc_t procnum, xdrproc_t xdr_args, caddr_t argsp, xdrproc_t xdr_results, caddr_t resultsp, struct timeval wait) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); calllist_t *call = &p->cku_call; XDR *xdrs; struct rpc_msg reply_msg; mblk_t *mp; #ifdef RPCDEBUG clock_t time_sent; #endif struct netbuf *retryaddr; struct cm_xprt *cm_entry = NULL; queue_t *wq; int len, waitsecs, max_waitsecs; int mpsize; int refreshes = REFRESHES; int interrupted; int tidu_size; enum clnt_stat status; struct timeval cwait; bool_t delay_first = FALSE; clock_t ticks; RPCLOG(2, "clnt_cots_kcallit, procnum %u\n", procnum); COTSRCSTAT_INCR(p->cku_stats, rccalls); RPCLOG(2, "clnt_cots_kcallit: wait.tv_sec: %ld\n", wait.tv_sec); RPCLOG(2, "clnt_cots_kcallit: wait.tv_usec: %ld\n", wait.tv_usec); /* * Bug ID 1240234: * Look out for zero length timeouts. We don't want to * wait zero seconds for a connection to be established. */ if (wait.tv_sec < clnt_cots_min_conntout) { cwait.tv_sec = clnt_cots_min_conntout; cwait.tv_usec = 0; RPCLOG(8, "clnt_cots_kcallit: wait.tv_sec (%ld) too low,", wait.tv_sec); RPCLOG(8, " setting to: %d\n", clnt_cots_min_conntout); } else { cwait = wait; } call_again: if (cm_entry) { connmgr_release(cm_entry); cm_entry = NULL; } mp = NULL; /* * If the call is not a retry, allocate a new xid and cache it * for future retries. * Bug ID 1246045: * Treat call as a retry for purposes of binding the source * port only if we actually attempted to send anything on * the previous call. */ if (p->cku_xid == 0) { p->cku_xid = alloc_xid(); call->call_zoneid = rpc_zoneid(); /* * We need to ASSERT here that our xid != 0 because this * determines whether or not our call record gets placed on * the hash table or the linked list. By design, we mandate * that RPC calls over cots must have xid's != 0, so we can * ensure proper management of the hash table. */ ASSERT(p->cku_xid != 0); retryaddr = NULL; p->cku_flags &= ~CKU_SENT; if (p->cku_flags & CKU_ONQUEUE) { RPCLOG(8, "clnt_cots_kcallit: new call, dequeuing old" " one (%p)\n", (void *)call); call_table_remove(call); p->cku_flags &= ~CKU_ONQUEUE; RPCLOG(64, "clnt_cots_kcallit: removing call from " "dispatch list because xid was zero (now 0x%x)\n", p->cku_xid); } if (call->call_reply != NULL) { freemsg(call->call_reply); call->call_reply = NULL; } } else if (p->cku_srcaddr.buf == NULL || p->cku_srcaddr.len == 0) { retryaddr = NULL; } else if (p->cku_flags & CKU_SENT) { retryaddr = &p->cku_srcaddr; } else { /* * Bug ID 1246045: Nothing was sent, so set retryaddr to * NULL and let connmgr_get() bind to any source port it * can get. */ retryaddr = NULL; } RPCLOG(64, "clnt_cots_kcallit: xid = 0x%x", p->cku_xid); RPCLOG(64, " flags = 0x%x\n", p->cku_flags); p->cku_err.re_status = RPC_TIMEDOUT; p->cku_err.re_errno = p->cku_err.re_terrno = 0; cm_entry = connmgr_wrapget(retryaddr, &cwait, p); if (cm_entry == NULL) { RPCLOG(1, "clnt_cots_kcallit: can't connect status %s\n", clnt_sperrno(p->cku_err.re_status)); /* * The reasons why we fail to create a connection are * varied. In most cases we don't want the caller to * immediately retry. This could have one or more * bad effects. This includes flooding the net with * connect requests to ports with no listener; a hard * kernel loop due to all the "reserved" TCP ports being * in use. */ delay_first = TRUE; /* * Even if we end up returning EINTR, we still count a * a "can't connect", because the connection manager * might have been committed to waiting for or timing out on * a connection. */ COTSRCSTAT_INCR(p->cku_stats, rccantconn); switch (p->cku_err.re_status) { case RPC_INTR: p->cku_err.re_errno = EINTR; /* * No need to delay because a UNIX signal(2) * interrupted us. The caller likely won't * retry the CLNT_CALL() and even if it does, * we assume the caller knows what it is doing. */ delay_first = FALSE; break; case RPC_TIMEDOUT: p->cku_err.re_errno = ETIMEDOUT; /* * No need to delay because timed out already * on the connection request and assume that the * transport time out is longer than our minimum * timeout, or least not too much smaller. */ delay_first = FALSE; break; case RPC_SYSTEMERROR: case RPC_TLIERROR: /* * We want to delay here because a transient * system error has a better chance of going away * if we delay a bit. If it's not transient, then * we don't want end up in a hard kernel loop * due to retries. */ ASSERT(p->cku_err.re_errno != 0); break; case RPC_CANTCONNECT: /* * RPC_CANTCONNECT is set on T_ERROR_ACK which * implies some error down in the TCP layer or * below. If cku_nodelayonerror is set then we * assume the caller knows not to try too hard. */ RPCLOG0(8, "clnt_cots_kcallit: connection failed,"); RPCLOG0(8, " re_status=RPC_CANTCONNECT,"); RPCLOG(8, " re_errno=%d,", p->cku_err.re_errno); RPCLOG(8, " cku_nodelayonerr=%d", p->cku_nodelayonerr); if (p->cku_nodelayonerr == TRUE) delay_first = FALSE; p->cku_err.re_errno = EIO; break; case RPC_XPRTFAILED: /* * We want to delay here because we likely * got a refused connection. */ if (p->cku_err.re_errno == 0) p->cku_err.re_errno = EIO; RPCLOG(1, "clnt_cots_kcallit: transport failed: %d\n", p->cku_err.re_errno); break; default: /* * We delay here because it is better to err * on the side of caution. If we got here then * status could have been RPC_SUCCESS, but we * know that we did not get a connection, so * force the rpc status to RPC_CANTCONNECT. */ p->cku_err.re_status = RPC_CANTCONNECT; p->cku_err.re_errno = EIO; break; } if (delay_first == TRUE) ticks = clnt_cots_min_tout * drv_usectohz(1000000); goto cots_done; } /* * If we've never sent any request on this connection (send count * is zero, or the connection has been reset), cache the * the connection's create time and send a request (possibly a retry) */ if ((p->cku_flags & CKU_SENT) == 0 || p->cku_ctime != cm_entry->x_ctime) { p->cku_ctime = cm_entry->x_ctime; } else if ((p->cku_flags & CKU_SENT) && (p->cku_flags & CKU_ONQUEUE) && (call->call_reply != NULL || p->cku_recv_attempts < clnt_cots_maxrecv)) { /* * If we've sent a request and our call is on the dispatch * queue and we haven't made too many receive attempts, then * don't re-send, just receive. */ p->cku_recv_attempts++; goto read_again; } /* * Now we create the RPC request in a STREAMS message. We have to do * this after the call to connmgr_get so that we have the correct * TIDU size for the transport. */ tidu_size = cm_entry->x_tidu_size; len = MSG_OFFSET + MAX(tidu_size, RM_HDR_SIZE + WIRE_HDR_SIZE); while ((mp = allocb(len, BPRI_MED)) == NULL) { if (strwaitbuf(len, BPRI_MED)) { p->cku_err.re_status = RPC_SYSTEMERROR; p->cku_err.re_errno = ENOSR; COTSRCSTAT_INCR(p->cku_stats, rcnomem); goto cots_done; } } xdrs = &p->cku_outxdr; xdrmblk_init(xdrs, mp, XDR_ENCODE, tidu_size); mpsize = MBLKSIZE(mp); ASSERT(mpsize >= len); ASSERT(mp->b_rptr == mp->b_datap->db_base); /* * If the size of mblk is not appreciably larger than what we * asked, then resize the mblk to exactly len bytes. The reason for * this: suppose len is 1600 bytes, the tidu is 1460 bytes * (from TCP over ethernet), and the arguments to the RPC require * 2800 bytes. Ideally we want the protocol to render two * ~1400 byte segments over the wire. However if allocb() gives us a 2k * mblk, and we allocate a second mblk for the remainder, the protocol * module may generate 3 segments over the wire: * 1460 bytes for the first, 448 (2048 - 1600) for the second, and * 892 for the third. If we "waste" 448 bytes in the first mblk, * the XDR encoding will generate two ~1400 byte mblks, and the * protocol module is more likely to produce properly sized segments. */ if ((mpsize >> 1) <= len) mp->b_rptr += (mpsize - len); /* * Adjust b_rptr to reserve space for the non-data protocol headers * any downstream modules might like to add, and for the * record marking header. */ mp->b_rptr += (MSG_OFFSET + RM_HDR_SIZE); if (h->cl_auth->ah_cred.oa_flavor != RPCSEC_GSS) { /* Copy in the preserialized RPC header information. */ bcopy(p->cku_rpchdr, mp->b_rptr, WIRE_HDR_SIZE); /* Use XDR_SETPOS() to set the b_wptr to past the RPC header. */ XDR_SETPOS(xdrs, (uint_t)(mp->b_rptr - mp->b_datap->db_base + WIRE_HDR_SIZE)); ASSERT((mp->b_wptr - mp->b_rptr) == WIRE_HDR_SIZE); /* Serialize the procedure number and the arguments. */ if ((!XDR_PUTINT32(xdrs, (int32_t *)&procnum)) || (!AUTH_MARSHALL(h->cl_auth, xdrs, p->cku_cred)) || (!(*xdr_args)(xdrs, argsp))) { p->cku_err.re_status = RPC_CANTENCODEARGS; p->cku_err.re_errno = EIO; goto cots_done; } (*(uint32_t *)(mp->b_rptr)) = p->cku_xid; } else { uint32_t *uproc = (uint32_t *)&p->cku_rpchdr[WIRE_HDR_SIZE]; IXDR_PUT_U_INT32(uproc, procnum); (*(uint32_t *)(&p->cku_rpchdr[0])) = p->cku_xid; /* Use XDR_SETPOS() to set the b_wptr. */ XDR_SETPOS(xdrs, (uint_t)(mp->b_rptr - mp->b_datap->db_base)); /* Serialize the procedure number and the arguments. */ if (!AUTH_WRAP(h->cl_auth, p->cku_rpchdr, WIRE_HDR_SIZE+4, xdrs, xdr_args, argsp)) { p->cku_err.re_status = RPC_CANTENCODEARGS; p->cku_err.re_errno = EIO; goto cots_done; } } RPCLOG(2, "clnt_cots_kcallit: connected, sending call, tidu_size %d\n", tidu_size); wq = cm_entry->x_wq; waitsecs = 0; dispatch_again: status = clnt_dispatch_send(wq, mp, call, p->cku_xid, (p->cku_flags & CKU_ONQUEUE)); if ((status == RPC_CANTSEND) && (call->call_reason == ENOBUFS)) { /* * QFULL condition, allow some time for queue to drain * and try again. Give up after waiting for all timeout * specified for the call, or zone is going away. */ max_waitsecs = wait.tv_sec ? wait.tv_sec : clnt_cots_min_tout; if ((waitsecs++ < max_waitsecs) && !(zone_status_get(curproc->p_zone) >= ZONE_IS_SHUTTING_DOWN)) { /* wait 1 sec for queue to drain */ if (clnt_delay(drv_usectohz(1000000), h->cl_nosignal) == EINTR) { p->cku_err.re_errno = EINTR; p->cku_err.re_status = RPC_INTR; goto cots_done; } /* and try again */ goto dispatch_again; } p->cku_err.re_status = status; p->cku_err.re_errno = call->call_reason; DTRACE_PROBE(krpc__e__clntcots__kcallit__cantsend); goto cots_done; } if (waitsecs) { /* adjust timeout to account for time wait to send */ wait.tv_sec -= waitsecs; if (wait.tv_sec < 0) { /* pick up reply on next retry */ wait.tv_sec = 0; } DTRACE_PROBE2(clnt_cots__sendwait, CLIENT *, h, int, waitsecs); } RPCLOG(64, "clnt_cots_kcallit: sent call for xid 0x%x\n", (uint_t)p->cku_xid); p->cku_flags = (CKU_ONQUEUE|CKU_SENT); p->cku_recv_attempts = 1; #ifdef RPCDEBUG time_sent = lbolt; #endif /* * Wait for a reply or a timeout. If there is no error or timeout, * (both indicated by call_status), call->call_reply will contain * the RPC reply message. */ read_again: mutex_enter(&call->call_lock); interrupted = 0; if (call->call_status == RPC_TIMEDOUT) { /* * Indicate that the lwp is not to be stopped while waiting * for this network traffic. This is to avoid deadlock while * debugging a process via /proc and also to avoid recursive * mutex_enter()s due to NFS page faults while stopping * (NFS holds locks when it calls here). */ clock_t cv_wait_ret; clock_t timout; clock_t oldlbolt; klwp_t *lwp = ttolwp(curthread); if (lwp != NULL) lwp->lwp_nostop++; oldlbolt = lbolt; timout = wait.tv_sec * drv_usectohz(1000000) + drv_usectohz(wait.tv_usec) + oldlbolt; /* * Iterate until the call_status is changed to something * other that RPC_TIMEDOUT, or if cv_timedwait_sig() returns * something <=0 zero. The latter means that we timed * out. */ if (h->cl_nosignal) while ((cv_wait_ret = cv_timedwait(&call->call_cv, &call->call_lock, timout)) > 0 && call->call_status == RPC_TIMEDOUT) ; else while ((cv_wait_ret = cv_timedwait_sig( &call->call_cv, &call->call_lock, timout)) > 0 && call->call_status == RPC_TIMEDOUT) ; switch (cv_wait_ret) { case 0: /* * If we got out of the above loop with * cv_timedwait_sig() returning 0, then we were * interrupted regardless what call_status is. */ interrupted = 1; break; case -1: /* cv_timedwait_sig() timed out */ break; default: /* * We were cv_signaled(). If we didn't * get a successful call_status and returned * before time expired, delay up to clnt_cots_min_tout * seconds so that the caller doesn't immediately * try to call us again and thus force the * same condition that got us here (such * as a RPC_XPRTFAILED due to the server not * listening on the end-point. */ if (call->call_status != RPC_SUCCESS) { clock_t curlbolt; clock_t diff; curlbolt = ddi_get_lbolt(); ticks = clnt_cots_min_tout * drv_usectohz(1000000); diff = curlbolt - oldlbolt; if (diff < ticks) { delay_first = TRUE; if (diff > 0) ticks -= diff; } } break; } if (lwp != NULL) lwp->lwp_nostop--; } /* * Get the reply message, if any. This will be freed at the end * whether or not an error occurred. */ mp = call->call_reply; call->call_reply = NULL; /* * call_err is the error info when the call is on dispatch queue. * cku_err is the error info returned to the caller. * Sync cku_err with call_err for local message processing. */ status = call->call_status; p->cku_err = call->call_err; mutex_exit(&call->call_lock); if (status != RPC_SUCCESS) { switch (status) { case RPC_TIMEDOUT: if (interrupted) { COTSRCSTAT_INCR(p->cku_stats, rcintrs); p->cku_err.re_status = RPC_INTR; p->cku_err.re_errno = EINTR; RPCLOG(1, "clnt_cots_kcallit: xid 0x%x", p->cku_xid); RPCLOG(1, "signal interrupted at %ld", lbolt); RPCLOG(1, ", was sent at %ld\n", time_sent); } else { COTSRCSTAT_INCR(p->cku_stats, rctimeouts); p->cku_err.re_errno = ETIMEDOUT; RPCLOG(1, "clnt_cots_kcallit: timed out at %ld", lbolt); RPCLOG(1, ", was sent at %ld\n", time_sent); } break; case RPC_XPRTFAILED: if (p->cku_err.re_errno == 0) p->cku_err.re_errno = EIO; RPCLOG(1, "clnt_cots_kcallit: transport failed: %d\n", p->cku_err.re_errno); break; case RPC_SYSTEMERROR: ASSERT(p->cku_err.re_errno); RPCLOG(1, "clnt_cots_kcallit: system error: %d\n", p->cku_err.re_errno); break; default: p->cku_err.re_status = RPC_SYSTEMERROR; p->cku_err.re_errno = EIO; RPCLOG(1, "clnt_cots_kcallit: error: %s\n", clnt_sperrno(status)); break; } if (p->cku_err.re_status != RPC_TIMEDOUT) { if (p->cku_flags & CKU_ONQUEUE) { call_table_remove(call); p->cku_flags &= ~CKU_ONQUEUE; } RPCLOG(64, "clnt_cots_kcallit: non TIMEOUT so xid 0x%x " "taken off dispatch list\n", p->cku_xid); if (call->call_reply) { freemsg(call->call_reply); call->call_reply = NULL; } } else if (wait.tv_sec != 0) { /* * We've sent the request over TCP and so we have * every reason to believe it will get * delivered. In which case returning a timeout is not * appropriate. */ if (p->cku_progress == TRUE && p->cku_recv_attempts < clnt_cots_maxrecv) { p->cku_err.re_status = RPC_INPROGRESS; } } goto cots_done; } xdrs = &p->cku_inxdr; xdrmblk_init(xdrs, mp, XDR_DECODE, 0); reply_msg.rm_direction = REPLY; reply_msg.rm_reply.rp_stat = MSG_ACCEPTED; reply_msg.acpted_rply.ar_stat = SUCCESS; reply_msg.acpted_rply.ar_verf = _null_auth; /* * xdr_results will be done in AUTH_UNWRAP. */ reply_msg.acpted_rply.ar_results.where = NULL; reply_msg.acpted_rply.ar_results.proc = xdr_void; if (xdr_replymsg(xdrs, &reply_msg)) { enum clnt_stat re_status; _seterr_reply(&reply_msg, &p->cku_err); re_status = p->cku_err.re_status; if (re_status == RPC_SUCCESS) { /* * Reply is good, check auth. */ if (!AUTH_VALIDATE(h->cl_auth, &reply_msg.acpted_rply.ar_verf)) { COTSRCSTAT_INCR(p->cku_stats, rcbadverfs); RPCLOG0(1, "clnt_cots_kcallit: validation " "failure\n"); freemsg(mp); (void) xdr_rpc_free_verifier(xdrs, &reply_msg); mutex_enter(&call->call_lock); if (call->call_reply == NULL) call->call_status = RPC_TIMEDOUT; mutex_exit(&call->call_lock); goto read_again; } else if (!AUTH_UNWRAP(h->cl_auth, xdrs, xdr_results, resultsp)) { RPCLOG0(1, "clnt_cots_kcallit: validation " "failure (unwrap)\n"); p->cku_err.re_status = RPC_CANTDECODERES; p->cku_err.re_errno = EIO; } } else { /* set errno in case we can't recover */ if (re_status != RPC_VERSMISMATCH && re_status != RPC_AUTHERROR && re_status != RPC_PROGVERSMISMATCH) p->cku_err.re_errno = EIO; if (re_status == RPC_AUTHERROR) { /* * Maybe our credential need to be refreshed */ if (cm_entry) { /* * There is the potential that the * cm_entry has/will be marked dead, * so drop the connection altogether, * force REFRESH to establish new * connection. */ connmgr_cancelconn(cm_entry); cm_entry = NULL; } if ((refreshes > 0) && AUTH_REFRESH(h->cl_auth, &reply_msg, p->cku_cred)) { refreshes--; (void) xdr_rpc_free_verifier(xdrs, &reply_msg); freemsg(mp); mp = NULL; if (p->cku_flags & CKU_ONQUEUE) { call_table_remove(call); p->cku_flags &= ~CKU_ONQUEUE; } RPCLOG(64, "clnt_cots_kcallit: AUTH_ERROR, xid" " 0x%x removed off dispatch list\n", p->cku_xid); if (call->call_reply) { freemsg(call->call_reply); call->call_reply = NULL; } COTSRCSTAT_INCR(p->cku_stats, rcbadcalls); COTSRCSTAT_INCR(p->cku_stats, rcnewcreds); goto call_again; } /* * We have used the client handle to * do an AUTH_REFRESH and the RPC status may * be set to RPC_SUCCESS; Let's make sure to * set it to RPC_AUTHERROR. */ p->cku_err.re_status = RPC_AUTHERROR; /* * Map recoverable and unrecoverable * authentication errors to appropriate errno */ switch (p->cku_err.re_why) { case AUTH_TOOWEAK: /* * This could be a failure where the * server requires use of a reserved * port, check and optionally set the * client handle useresvport trying * one more time. Next go round we * fall out with the tooweak error. */ if (p->cku_useresvport != 1) { p->cku_useresvport = 1; p->cku_xid = 0; (void) xdr_rpc_free_verifier (xdrs, &reply_msg); freemsg(mp); goto call_again; } /* FALLTHRU */ case AUTH_BADCRED: case AUTH_BADVERF: case AUTH_INVALIDRESP: case AUTH_FAILED: case RPCSEC_GSS_NOCRED: case RPCSEC_GSS_FAILED: p->cku_err.re_errno = EACCES; break; case AUTH_REJECTEDCRED: case AUTH_REJECTEDVERF: default: p->cku_err.re_errno = EIO; break; } RPCLOG(1, "clnt_cots_kcallit : authentication" " failed with RPC_AUTHERROR of type %d\n", (int)p->cku_err.re_why); } } } else { /* reply didn't decode properly. */ p->cku_err.re_status = RPC_CANTDECODERES; p->cku_err.re_errno = EIO; RPCLOG0(1, "clnt_cots_kcallit: decode failure\n"); } (void) xdr_rpc_free_verifier(xdrs, &reply_msg); if (p->cku_flags & CKU_ONQUEUE) { call_table_remove(call); p->cku_flags &= ~CKU_ONQUEUE; } RPCLOG(64, "clnt_cots_kcallit: xid 0x%x taken off dispatch list", p->cku_xid); RPCLOG(64, " status is %s\n", clnt_sperrno(p->cku_err.re_status)); cots_done: if (cm_entry) connmgr_release(cm_entry); if (mp != NULL) freemsg(mp); if ((p->cku_flags & CKU_ONQUEUE) == 0 && call->call_reply) { freemsg(call->call_reply); call->call_reply = NULL; } if (p->cku_err.re_status != RPC_SUCCESS) { RPCLOG0(1, "clnt_cots_kcallit: tail-end failure\n"); COTSRCSTAT_INCR(p->cku_stats, rcbadcalls); } /* * No point in delaying if the zone is going away. */ if (delay_first == TRUE && !(zone_status_get(curproc->p_zone) >= ZONE_IS_SHUTTING_DOWN)) { if (clnt_delay(ticks, h->cl_nosignal) == EINTR) { p->cku_err.re_errno = EINTR; p->cku_err.re_status = RPC_INTR; } } return (p->cku_err.re_status); } /* * Kinit routine for cots. This sets up the correct operations in * the client handle, as the handle may have previously been a clts * handle, and clears the xid field so there is no way a new call * could be mistaken for a retry. It also sets in the handle the * information that is passed at create/kinit time but needed at * call time, as cots creates the transport at call time - device, * address of the server, protocol family. */ void clnt_cots_kinit(CLIENT *h, dev_t dev, int family, struct netbuf *addr, int max_msgsize, cred_t *cred) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); calllist_t *call = &p->cku_call; h->cl_ops = &tcp_ops; if (p->cku_flags & CKU_ONQUEUE) { call_table_remove(call); p->cku_flags &= ~CKU_ONQUEUE; RPCLOG(64, "clnt_cots_kinit: removing call for xid 0x%x from" " dispatch list\n", p->cku_xid); } if (call->call_reply != NULL) { freemsg(call->call_reply); call->call_reply = NULL; } call->call_bucket = NULL; call->call_hash = 0; /* * We don't clear cku_flags here, because clnt_cots_kcallit() * takes care of handling the cku_flags reset. */ p->cku_xid = 0; p->cku_device = dev; p->cku_addrfmly = family; p->cku_cred = cred; if (p->cku_addr.maxlen < addr->len) { if (p->cku_addr.maxlen != 0 && p->cku_addr.buf != NULL) kmem_free(p->cku_addr.buf, p->cku_addr.maxlen); p->cku_addr.buf = kmem_zalloc(addr->maxlen, KM_SLEEP); p->cku_addr.maxlen = addr->maxlen; } p->cku_addr.len = addr->len; bcopy(addr->buf, p->cku_addr.buf, addr->len); /* * If the current sanity check size in rpcmod is smaller * than the size needed, then increase the sanity check. */ if (max_msgsize != 0 && clnt_max_msg_sizep != NULL && max_msgsize > *clnt_max_msg_sizep) { mutex_enter(&clnt_max_msg_lock); if (max_msgsize > *clnt_max_msg_sizep) *clnt_max_msg_sizep = max_msgsize; mutex_exit(&clnt_max_msg_lock); } } /* * ksettimers is a no-op for cots, with the exception of setting the xid. */ /* ARGSUSED */ static int clnt_cots_ksettimers(CLIENT *h, struct rpc_timers *t, struct rpc_timers *all, int minimum, void (*feedback)(int, int, caddr_t), caddr_t arg, uint32_t xid) { /* LINTED pointer alignment */ cku_private_t *p = htop(h); if (xid) p->cku_xid = xid; COTSRCSTAT_INCR(p->cku_stats, rctimers); return (0); } extern void rpc_poptimod(struct vnode *); extern int kstr_push(struct vnode *, char *); int conn_kstat_update(kstat_t *ksp, int rw) { struct cm_xprt *cm_entry; struct cm_kstat_xprt *cm_ksp_data; uchar_t *b; char *fbuf; if (rw == KSTAT_WRITE) return (EACCES); if (ksp == NULL || ksp->ks_private == NULL) return (EIO); cm_entry = (struct cm_xprt *)ksp->ks_private; cm_ksp_data = (struct cm_kstat_xprt *)ksp->ks_data; cm_ksp_data->x_wq.value.ui32 = (uint32_t)(uintptr_t)cm_entry->x_wq; cm_ksp_data->x_family.value.ui32 = cm_entry->x_family; cm_ksp_data->x_rdev.value.ui32 = (uint32_t)cm_entry->x_rdev; cm_ksp_data->x_time.value.ui32 = cm_entry->x_time; cm_ksp_data->x_ref.value.ui32 = cm_entry->x_ref; cm_ksp_data->x_state.value.ui32 = cm_entry->x_state_flags; if (cm_entry->x_server.buf) { fbuf = cm_ksp_data->x_server.value.str.addr.ptr; if (cm_entry->x_family == AF_INET && cm_entry->x_server.len == sizeof (struct sockaddr_in)) { struct sockaddr_in *sa; sa = (struct sockaddr_in *) cm_entry->x_server.buf; b = (uchar_t *)&sa->sin_addr; (void) sprintf(fbuf, "%03d.%03d.%03d.%03d", b[0] & 0xFF, b[1] & 0xFF, b[2] & 0xFF, b[3] & 0xFF); cm_ksp_data->x_port.value.ui32 = (uint32_t)sa->sin_port; } else if (cm_entry->x_family == AF_INET6 && cm_entry->x_server.len >= sizeof (struct sockaddr_in6)) { /* extract server IP address & port */ struct sockaddr_in6 *sin6; sin6 = (struct sockaddr_in6 *)cm_entry->x_server.buf; (void) kinet_ntop6((uchar_t *)&sin6->sin6_addr, fbuf, INET6_ADDRSTRLEN); cm_ksp_data->x_port.value.ui32 = sin6->sin6_port; } else { struct sockaddr_in *sa; sa = (struct sockaddr_in *)cm_entry->x_server.buf; b = (uchar_t *)&sa->sin_addr; (void) sprintf(fbuf, "%03d.%03d.%03d.%03d", b[0] & 0xFF, b[1] & 0xFF, b[2] & 0xFF, b[3] & 0xFF); } KSTAT_NAMED_STR_BUFLEN(&cm_ksp_data->x_server) = strlen(fbuf) + 1; } return (0); } /* * We want a version of delay which is interruptible by a UNIX signal * Return EINTR if an interrupt occured. */ static int clnt_delay(clock_t ticks, bool_t nosignal) { if (nosignal == TRUE) { delay(ticks); return (0); } return (delay_sig(ticks)); } /* * Wait for a connection until a timeout, or until we are * signalled that there has been a connection state change. */ static enum clnt_stat connmgr_cwait(struct cm_xprt *cm_entry, const struct timeval *waitp, bool_t nosignal) { bool_t interrupted; clock_t timout, cv_stat; enum clnt_stat clstat; unsigned int old_state; ASSERT(MUTEX_HELD(&connmgr_lock)); /* * We wait for the transport connection to be made, or an * indication that it could not be made. */ clstat = RPC_TIMEDOUT; interrupted = FALSE; old_state = cm_entry->x_state_flags; /* * Now loop until cv_timedwait{_sig} returns because of * a signal(0) or timeout(-1) or cv_signal(>0). But it may be * cv_signalled for various other reasons too. So loop * until there is a state change on the connection. */ timout = waitp->tv_sec * drv_usectohz(1000000) + drv_usectohz(waitp->tv_usec) + lbolt; if (nosignal) { while ((cv_stat = cv_timedwait(&cm_entry->x_conn_cv, &connmgr_lock, timout)) > 0 && cm_entry->x_state_flags == old_state) ; } else { while ((cv_stat = cv_timedwait_sig(&cm_entry->x_conn_cv, &connmgr_lock, timout)) > 0 && cm_entry->x_state_flags == old_state) ; if (cv_stat == 0) /* got intr signal? */ interrupted = TRUE; } if ((cm_entry->x_state_flags & (X_BADSTATES|X_CONNECTED)) == X_CONNECTED) { clstat = RPC_SUCCESS; } else { if (interrupted == TRUE) clstat = RPC_INTR; RPCLOG(1, "connmgr_cwait: can't connect, error: %s\n", clnt_sperrno(clstat)); } return (clstat); } /* * Primary interface for how RPC grabs a connection. */ static struct cm_xprt * connmgr_wrapget( struct netbuf *retryaddr, const struct timeval *waitp, cku_private_t *p) { struct cm_xprt *cm_entry; cm_entry = connmgr_get(retryaddr, waitp, &p->cku_addr, p->cku_addrfmly, &p->cku_srcaddr, &p->cku_err, p->cku_device, p->cku_client.cl_nosignal, p->cku_useresvport, p->cku_cred); if (cm_entry == NULL) { /* * Re-map the call status to RPC_INTR if the err code is * EINTR. This can happen if calls status is RPC_TLIERROR. * However, don't re-map if signalling has been turned off. * XXX Really need to create a separate thread whenever * there isn't an existing connection. */ if (p->cku_err.re_errno == EINTR) { if (p->cku_client.cl_nosignal == TRUE) p->cku_err.re_errno = EIO; else p->cku_err.re_status = RPC_INTR; } } return (cm_entry); } /* * Obtains a transport to the server specified in addr. If a suitable transport * does not already exist in the list of cached transports, a new connection * is created, connected, and added to the list. The connection is for sending * only - the reply message may come back on another transport connection. * * To implement round-robin load balancing with multiple client connections, * the last entry on the list is always selected. Once the entry is selected * it's re-inserted to the head of the list. */ static struct cm_xprt * connmgr_get( struct netbuf *retryaddr, const struct timeval *waitp, /* changed to a ptr to converse stack */ struct netbuf *destaddr, int addrfmly, struct netbuf *srcaddr, struct rpc_err *rpcerr, dev_t device, bool_t nosignal, int useresvport, cred_t *cr) { struct cm_xprt *cm_entry; struct cm_xprt *lru_entry; struct cm_xprt **cmp, **prev; queue_t *wq; TIUSER *tiptr; int i; int retval; int tidu_size; bool_t connected; zoneid_t zoneid = rpc_zoneid(); /* * If the call is not a retry, look for a transport entry that * goes to the server of interest. */ mutex_enter(&connmgr_lock); if (retryaddr == NULL) { use_new_conn: i = 0; cm_entry = lru_entry = NULL; prev = cmp = &cm_hd; while ((cm_entry = *cmp) != NULL) { ASSERT(cm_entry != cm_entry->x_next); /* * Garbage collect conections that are marked * for needs disconnect. */ if (cm_entry->x_needdis) { CONN_HOLD(cm_entry); connmgr_dis_and_wait(cm_entry); connmgr_release(cm_entry); /* * connmgr_lock could have been * dropped for the disconnect * processing so start over. */ goto use_new_conn; } /* * Garbage collect the dead connections that have * no threads working on them. */ if ((cm_entry->x_state_flags & (X_DEAD|X_THREAD)) == X_DEAD) { mutex_enter(&cm_entry->x_lock); if (cm_entry->x_ref != 0) { /* * Currently in use. * Cleanup later. */ cmp = &cm_entry->x_next; mutex_exit(&cm_entry->x_lock); continue; } mutex_exit(&cm_entry->x_lock); *cmp = cm_entry->x_next; mutex_exit(&connmgr_lock); connmgr_close(cm_entry); mutex_enter(&connmgr_lock); goto use_new_conn; } if ((cm_entry->x_state_flags & X_BADSTATES) == 0 && cm_entry->x_zoneid == zoneid && cm_entry->x_rdev == device && destaddr->len == cm_entry->x_server.len && bcmp(destaddr->buf, cm_entry->x_server.buf, destaddr->len) == 0) { /* * If the matching entry isn't connected, * attempt to reconnect it. */ if (cm_entry->x_connected == FALSE) { /* * We don't go through trying * to find the least recently * used connected because * connmgr_reconnect() briefly * dropped the connmgr_lock, * allowing a window for our * accounting to be messed up. * In any case, a re-connected * connection is as good as * a LRU connection. */ return (connmgr_wrapconnect(cm_entry, waitp, destaddr, addrfmly, srcaddr, rpcerr, TRUE, nosignal, cr)); } i++; /* keep track of the last entry */ lru_entry = cm_entry; prev = cmp; } cmp = &cm_entry->x_next; } if (i > clnt_max_conns) { RPCLOG(8, "connmgr_get: too many conns, dooming entry" " %p\n", (void *)lru_entry->x_tiptr); lru_entry->x_doomed = TRUE; goto use_new_conn; } /* * If we are at the maximum number of connections to * the server, hand back the least recently used one. */ if (i == clnt_max_conns) { /* * Copy into the handle the source address of * the connection, which we will use in case of * a later retry. */ if (srcaddr->len != lru_entry->x_src.len) { if (srcaddr->len > 0) kmem_free(srcaddr->buf, srcaddr->maxlen); srcaddr->buf = kmem_zalloc( lru_entry->x_src.len, KM_SLEEP); srcaddr->maxlen = srcaddr->len = lru_entry->x_src.len; } bcopy(lru_entry->x_src.buf, srcaddr->buf, srcaddr->len); RPCLOG(2, "connmgr_get: call going out on %p\n", (void *)lru_entry); lru_entry->x_time = lbolt; CONN_HOLD(lru_entry); if ((i > 1) && (prev != &cm_hd)) { /* * remove and re-insert entry at head of list. */ *prev = lru_entry->x_next; lru_entry->x_next = cm_hd; cm_hd = lru_entry; } mutex_exit(&connmgr_lock); return (lru_entry); } } else { /* * This is the retry case (retryaddr != NULL). Retries must * be sent on the same source port as the original call. */ /* * Walk the list looking for a connection with a source address * that matches the retry address. */ start_retry_loop: cmp = &cm_hd; while ((cm_entry = *cmp) != NULL) { ASSERT(cm_entry != cm_entry->x_next); /* * determine if this connection matches the passed * in retry address. If it does not match, advance * to the next element on the list. */ if (zoneid != cm_entry->x_zoneid || device != cm_entry->x_rdev || retryaddr->len != cm_entry->x_src.len || bcmp(retryaddr->buf, cm_entry->x_src.buf, retryaddr->len) != 0) { cmp = &cm_entry->x_next; continue; } /* * Garbage collect conections that are marked * for needs disconnect. */ if (cm_entry->x_needdis) { CONN_HOLD(cm_entry); connmgr_dis_and_wait(cm_entry); connmgr_release(cm_entry); /* * connmgr_lock could have been * dropped for the disconnect * processing so start over. */ goto start_retry_loop; } /* * Garbage collect the dead connections that have * no threads working on them. */ if ((cm_entry->x_state_flags & (X_DEAD|X_THREAD)) == X_DEAD) { mutex_enter(&cm_entry->x_lock); if (cm_entry->x_ref != 0) { /* * Currently in use. * Cleanup later. */ cmp = &cm_entry->x_next; mutex_exit(&cm_entry->x_lock); continue; } mutex_exit(&cm_entry->x_lock); *cmp = cm_entry->x_next; mutex_exit(&connmgr_lock); connmgr_close(cm_entry); mutex_enter(&connmgr_lock); goto start_retry_loop; } /* * Sanity check: if the connection with our source * port is going to some other server, something went * wrong, as we never delete connections (i.e. release * ports) unless they have been idle. In this case, * it is probably better to send the call out using * a new source address than to fail it altogether, * since that port may never be released. */ if (destaddr->len != cm_entry->x_server.len || bcmp(destaddr->buf, cm_entry->x_server.buf, destaddr->len) != 0) { RPCLOG(1, "connmgr_get: tiptr %p" " is going to a different server" " with the port that belongs" " to us!\n", (void *)cm_entry->x_tiptr); retryaddr = NULL; goto use_new_conn; } /* * If the connection of interest is not connected and we * can't reconnect it, then the server is probably * still down. Return NULL to the caller and let it * retry later if it wants to. We have a delay so the * machine doesn't go into a tight retry loop. If the * entry was already connected, or the reconnected was * successful, return this entry. */ if (cm_entry->x_connected == FALSE) { return (connmgr_wrapconnect(cm_entry, waitp, destaddr, addrfmly, NULL, rpcerr, TRUE, nosignal, cr)); } else { CONN_HOLD(cm_entry); cm_entry->x_time = lbolt; mutex_exit(&connmgr_lock); RPCLOG(2, "connmgr_get: found old " "transport %p for retry\n", (void *)cm_entry); return (cm_entry); } } /* * We cannot find an entry in the list for this retry. * Either the entry has been removed temporarily to be * reconnected by another thread, or the original call * got a port but never got connected, * and hence the transport never got put in the * list. Fall through to the "create new connection" code - * the former case will fail there trying to rebind the port, * and the later case (and any other pathological cases) will * rebind and reconnect and not hang the client machine. */ RPCLOG0(8, "connmgr_get: no entry in list for retry\n"); } /* * Set up a transport entry in the connection manager's list. */ cm_entry = (struct cm_xprt *) kmem_zalloc(sizeof (struct cm_xprt), KM_SLEEP); cm_entry->x_server.buf = kmem_zalloc(destaddr->len, KM_SLEEP); bcopy(destaddr->buf, cm_entry->x_server.buf, destaddr->len); cm_entry->x_server.len = cm_entry->x_server.maxlen = destaddr->len; cm_entry->x_state_flags = X_THREAD; cm_entry->x_ref = 1; cm_entry->x_family = addrfmly; cm_entry->x_rdev = device; cm_entry->x_zoneid = zoneid; mutex_init(&cm_entry->x_lock, NULL, MUTEX_DEFAULT, NULL); cv_init(&cm_entry->x_cv, NULL, CV_DEFAULT, NULL); cv_init(&cm_entry->x_conn_cv, NULL, CV_DEFAULT, NULL); cv_init(&cm_entry->x_dis_cv, NULL, CV_DEFAULT, NULL); /* * Note that we add this partially initialized entry to the * connection list. This is so that we don't have connections to * the same server. * * Note that x_src is not initialized at this point. This is because * retryaddr might be NULL in which case x_src is whatever * t_kbind/bindresvport gives us. If another thread wants a * connection to the same server, seemingly we have an issue, but we * don't. If the other thread comes in with retryaddr == NULL, then it * will never look at x_src, and it will end up waiting in * connmgr_cwait() for the first thread to finish the connection * attempt. If the other thread comes in with retryaddr != NULL, then * that means there was a request sent on a connection, in which case * the the connection should already exist. Thus the first thread * never gets here ... it finds the connection it its server in the * connection list. * * But even if theory is wrong, in the retryaddr != NULL case, the 2nd * thread will skip us because x_src.len == 0. */ cm_entry->x_next = cm_hd; cm_hd = cm_entry; mutex_exit(&connmgr_lock); /* * Either we didn't find an entry to the server of interest, or we * don't have the maximum number of connections to that server - * create a new connection. */ RPCLOG0(8, "connmgr_get: creating new connection\n"); rpcerr->re_status = RPC_TLIERROR; i = t_kopen(NULL, device, FREAD|FWRITE|FNDELAY, &tiptr, zone_kcred()); if (i) { RPCLOG(1, "connmgr_get: can't open cots device, error %d\n", i); rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } rpc_poptimod(tiptr->fp->f_vnode); if (i = strioctl(tiptr->fp->f_vnode, I_PUSH, (intptr_t)"rpcmod", 0, K_TO_K, kcred, &retval)) { RPCLOG(1, "connmgr_get: can't push cots module, %d\n", i); (void) t_kclose(tiptr, 1); rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } if (i = strioctl(tiptr->fp->f_vnode, RPC_CLIENT, 0, 0, K_TO_K, kcred, &retval)) { RPCLOG(1, "connmgr_get: can't set client status with cots " "module, %d\n", i); (void) t_kclose(tiptr, 1); rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } mutex_enter(&connmgr_lock); wq = tiptr->fp->f_vnode->v_stream->sd_wrq->q_next; cm_entry->x_wq = wq; mutex_exit(&connmgr_lock); if (i = strioctl(tiptr->fp->f_vnode, I_PUSH, (intptr_t)"timod", 0, K_TO_K, kcred, &retval)) { RPCLOG(1, "connmgr_get: can't push timod, %d\n", i); (void) t_kclose(tiptr, 1); rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } /* * If the caller has not specified reserved port usage then * take the system default. */ if (useresvport == -1) useresvport = clnt_cots_do_bindresvport; if ((useresvport || retryaddr != NULL) && (addrfmly == AF_INET || addrfmly == AF_INET6)) { bool_t alloc_src = FALSE; if (srcaddr->len != destaddr->len) { kmem_free(srcaddr->buf, srcaddr->maxlen); srcaddr->buf = kmem_zalloc(destaddr->len, KM_SLEEP); srcaddr->maxlen = destaddr->len; srcaddr->len = destaddr->len; alloc_src = TRUE; } if ((i = bindresvport(tiptr, retryaddr, srcaddr, TRUE)) != 0) { (void) t_kclose(tiptr, 1); RPCLOG(1, "connmgr_get: couldn't bind, retryaddr: " "%p\n", (void *)retryaddr); /* * 1225408: If we allocated a source address, then it * is either garbage or all zeroes. In that case * we need to clear srcaddr. */ if (alloc_src == TRUE) { kmem_free(srcaddr->buf, srcaddr->maxlen); srcaddr->maxlen = srcaddr->len = 0; srcaddr->buf = NULL; } rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } } else { if ((i = t_kbind(tiptr, NULL, NULL)) != 0) { RPCLOG(1, "clnt_cots_kcreate: t_kbind: %d\n", i); (void) t_kclose(tiptr, 1); rpcerr->re_errno = i; connmgr_cancelconn(cm_entry); return (NULL); } } { /* * Keep the kernel stack lean. Don't move this call * declaration to the top of this function because a * call is declared in connmgr_wrapconnect() */ calllist_t call; bzero(&call, sizeof (call)); cv_init(&call.call_cv, NULL, CV_DEFAULT, NULL); /* * This is a bound end-point so don't close it's stream. */ connected = connmgr_connect(cm_entry, wq, destaddr, addrfmly, &call, &tidu_size, FALSE, waitp, nosignal, cr); *rpcerr = call.call_err; cv_destroy(&call.call_cv); } mutex_enter(&connmgr_lock); /* * Set up a transport entry in the connection manager's list. */ cm_entry->x_src.buf = kmem_zalloc(srcaddr->len, KM_SLEEP); bcopy(srcaddr->buf, cm_entry->x_src.buf, srcaddr->len); cm_entry->x_src.len = cm_entry->x_src.maxlen = srcaddr->len; cm_entry->x_tiptr = tiptr; cm_entry->x_time = lbolt; if (tiptr->tp_info.servtype == T_COTS_ORD) cm_entry->x_ordrel = TRUE; else cm_entry->x_ordrel = FALSE; cm_entry->x_tidu_size = tidu_size; if (cm_entry->x_early_disc) { /* * We need to check if a disconnect request has come * while we are connected, if so, then we need to * set rpcerr->re_status appropriately before returning * NULL to caller. */ if (rpcerr->re_status == RPC_SUCCESS) rpcerr->re_status = RPC_XPRTFAILED; cm_entry->x_connected = FALSE; } else cm_entry->x_connected = connected; /* * There could be a discrepancy here such that * x_early_disc is TRUE yet connected is TRUE as well * and the connection is actually connected. In that case * lets be conservative and declare the connection as not * connected. */ cm_entry->x_early_disc = FALSE; cm_entry->x_needdis = (cm_entry->x_connected == FALSE); cm_entry->x_ctime = lbolt; /* * Notify any threads waiting that the connection attempt is done. */ cm_entry->x_thread = FALSE; cv_broadcast(&cm_entry->x_conn_cv); if (cm_entry->x_connected == FALSE) { mutex_exit(&connmgr_lock); connmgr_release(cm_entry); return (NULL); } mutex_exit(&connmgr_lock); return (cm_entry); } /* * Keep the cm_xprt entry on the connecton list when making a connection. This * is to prevent multiple connections to a slow server from appearing. * We use the bit field x_thread to tell if a thread is doing a connection * which keeps other interested threads from messing with connection. * Those other threads just wait if x_thread is set. * * If x_thread is not set, then we do the actual work of connecting via * connmgr_connect(). * * mutex convention: called with connmgr_lock held, returns with it released. */ static struct cm_xprt * connmgr_wrapconnect( struct cm_xprt *cm_entry, const struct timeval *waitp, struct netbuf *destaddr, int addrfmly, struct netbuf *srcaddr, struct rpc_err *rpcerr, bool_t reconnect, bool_t nosignal, cred_t *cr) { ASSERT(MUTEX_HELD(&connmgr_lock)); /* * Hold this entry as we are about to drop connmgr_lock. */ CONN_HOLD(cm_entry); /* * If there is a thread already making a connection for us, then * wait for it to complete the connection. */ if (cm_entry->x_thread == TRUE) { rpcerr->re_status = connmgr_cwait(cm_entry, waitp, nosignal); if (rpcerr->re_status != RPC_SUCCESS) { mutex_exit(&connmgr_lock); connmgr_release(cm_entry); return (NULL); } } else { bool_t connected; calllist_t call; cm_entry->x_thread = TRUE; while (cm_entry->x_needrel == TRUE) { cm_entry->x_needrel = FALSE; connmgr_sndrel(cm_entry); delay(drv_usectohz(1000000)); mutex_enter(&connmgr_lock); } /* * If we need to send a T_DISCON_REQ, send one. */ connmgr_dis_and_wait(cm_entry); mutex_exit(&connmgr_lock); bzero(&call, sizeof (call)); cv_init(&call.call_cv, NULL, CV_DEFAULT, NULL); connected = connmgr_connect(cm_entry, cm_entry->x_wq, destaddr, addrfmly, &call, &cm_entry->x_tidu_size, reconnect, waitp, nosignal, cr); *rpcerr = call.call_err; cv_destroy(&call.call_cv); mutex_enter(&connmgr_lock); if (cm_entry->x_early_disc) { /* * We need to check if a disconnect request has come * while we are connected, if so, then we need to * set rpcerr->re_status appropriately before returning * NULL to caller. */ if (rpcerr->re_status == RPC_SUCCESS) rpcerr->re_status = RPC_XPRTFAILED; cm_entry->x_connected = FALSE; } else cm_entry->x_connected = connected; /* * There could be a discrepancy here such that * x_early_disc is TRUE yet connected is TRUE as well * and the connection is actually connected. In that case * lets be conservative and declare the connection as not * connected. */ cm_entry->x_early_disc = FALSE; cm_entry->x_needdis = (cm_entry->x_connected == FALSE); /* * connmgr_connect() may have given up before the connection * actually timed out. So ensure that before the next * connection attempt we do a disconnect. */ cm_entry->x_ctime = lbolt; cm_entry->x_thread = FALSE; cv_broadcast(&cm_entry->x_conn_cv); if (cm_entry->x_connected == FALSE) { mutex_exit(&connmgr_lock); connmgr_release(cm_entry); return (NULL); } } if (srcaddr != NULL) { /* * Copy into the handle the * source address of the * connection, which we will use * in case of a later retry. */ if (srcaddr->len != cm_entry->x_src.len) { if (srcaddr->maxlen > 0) kmem_free(srcaddr->buf, srcaddr->maxlen); srcaddr->buf = kmem_zalloc(cm_entry->x_src.len, KM_SLEEP); srcaddr->maxlen = srcaddr->len = cm_entry->x_src.len; } bcopy(cm_entry->x_src.buf, srcaddr->buf, srcaddr->len); } cm_entry->x_time = lbolt; mutex_exit(&connmgr_lock); return (cm_entry); } /* * If we need to send a T_DISCON_REQ, send one. */ static void connmgr_dis_and_wait(struct cm_xprt *cm_entry) { ASSERT(MUTEX_HELD(&connmgr_lock)); for (;;) { while (cm_entry->x_needdis == TRUE) { RPCLOG(8, "connmgr_dis_and_wait: need " "T_DISCON_REQ for connection 0x%p\n", (void *)cm_entry); cm_entry->x_needdis = FALSE; cm_entry->x_waitdis = TRUE; connmgr_snddis(cm_entry); mutex_enter(&connmgr_lock); } if (cm_entry->x_waitdis == TRUE) { clock_t curlbolt; clock_t timout; RPCLOG(8, "connmgr_dis_and_wait waiting for " "T_DISCON_REQ's ACK for connection %p\n", (void *)cm_entry); curlbolt = ddi_get_lbolt(); timout = clnt_cots_min_conntout * drv_usectohz(1000000) + curlbolt; /* * The TPI spec says that the T_DISCON_REQ * will get acknowledged, but in practice * the ACK may never get sent. So don't * block forever. */ (void) cv_timedwait(&cm_entry->x_dis_cv, &connmgr_lock, timout); } /* * If we got the ACK, break. If we didn't, * then send another T_DISCON_REQ. */ if (cm_entry->x_waitdis == FALSE) { break; } else { RPCLOG(8, "connmgr_dis_and_wait: did" "not get T_DISCON_REQ's ACK for " "connection %p\n", (void *)cm_entry); cm_entry->x_needdis = TRUE; } } } static void connmgr_cancelconn(struct cm_xprt *cm_entry) { /* * Mark the connection table entry as dead; the next thread that * goes through connmgr_release() will notice this and deal with it. */ mutex_enter(&connmgr_lock); cm_entry->x_dead = TRUE; /* * Notify any threads waiting for the connection that it isn't * going to happen. */ cm_entry->x_thread = FALSE; cv_broadcast(&cm_entry->x_conn_cv); mutex_exit(&connmgr_lock); connmgr_release(cm_entry); } static void connmgr_close(struct cm_xprt *cm_entry) { mutex_enter(&cm_entry->x_lock); while (cm_entry->x_ref != 0) { /* * Must be a noninterruptible wait. */ cv_wait(&cm_entry->x_cv, &cm_entry->x_lock); } if (cm_entry->x_tiptr != NULL) (void) t_kclose(cm_entry->x_tiptr, 1); mutex_exit(&cm_entry->x_lock); if (cm_entry->x_ksp != NULL) { mutex_enter(&connmgr_lock); cm_entry->x_ksp->ks_private = NULL; mutex_exit(&connmgr_lock); /* * Must free the buffer we allocated for the * server address in the update function */ if (((struct cm_kstat_xprt *)(cm_entry->x_ksp->ks_data))-> x_server.value.str.addr.ptr != NULL) kmem_free(((struct cm_kstat_xprt *)(cm_entry->x_ksp-> ks_data))->x_server.value.str.addr.ptr, INET6_ADDRSTRLEN); kmem_free(cm_entry->x_ksp->ks_data, cm_entry->x_ksp->ks_data_size); kstat_delete(cm_entry->x_ksp); } mutex_destroy(&cm_entry->x_lock); cv_destroy(&cm_entry->x_cv); cv_destroy(&cm_entry->x_conn_cv); cv_destroy(&cm_entry->x_dis_cv); if (cm_entry->x_server.buf != NULL) kmem_free(cm_entry->x_server.buf, cm_entry->x_server.maxlen); if (cm_entry->x_src.buf != NULL) kmem_free(cm_entry->x_src.buf, cm_entry->x_src.maxlen); kmem_free(cm_entry, sizeof (struct cm_xprt)); } /* * Called by KRPC after sending the call message to release the connection * it was using. */ static void connmgr_release(struct cm_xprt *cm_entry) { mutex_enter(&cm_entry->x_lock); cm_entry->x_ref--; if (cm_entry->x_ref == 0) cv_signal(&cm_entry->x_cv); mutex_exit(&cm_entry->x_lock); } /* * Set TCP receive and xmit buffer size for RPC connections. */ static bool_t connmgr_setbufsz(calllist_t *e, queue_t *wq, cred_t *cr) { int ok = FALSE; int val; if (rpc_default_tcp_bufsz) return (FALSE); /* * Only set new buffer size if it's larger than the system * default buffer size. If smaller buffer size is needed * then use /etc/system to set rpc_default_tcp_bufsz to 1. */ ok = connmgr_getopt_int(wq, SOL_SOCKET, SO_RCVBUF, &val, e, cr); if ((ok == TRUE) && (val < rpc_send_bufsz)) { ok = connmgr_setopt_int(wq, SOL_SOCKET, SO_RCVBUF, rpc_send_bufsz, e, cr); DTRACE_PROBE2(krpc__i__connmgr_rcvbufsz, int, ok, calllist_t *, e); } ok = connmgr_getopt_int(wq, SOL_SOCKET, SO_SNDBUF, &val, e, cr); if ((ok == TRUE) && (val < rpc_recv_bufsz)) { ok = connmgr_setopt_int(wq, SOL_SOCKET, SO_SNDBUF, rpc_recv_bufsz, e, cr); DTRACE_PROBE2(krpc__i__connmgr_sndbufsz, int, ok, calllist_t *, e); } return (TRUE); } /* * Given an open stream, connect to the remote. Returns true if connected, * false otherwise. */ static bool_t connmgr_connect( struct cm_xprt *cm_entry, queue_t *wq, struct netbuf *addr, int addrfmly, calllist_t *e, int *tidu_ptr, bool_t reconnect, const struct timeval *waitp, bool_t nosignal, cred_t *cr) { mblk_t *mp; struct T_conn_req *tcr; struct T_info_ack *tinfo; int interrupted, error; int tidu_size, kstat_instance; /* if it's a reconnect, flush any lingering data messages */ if (reconnect) (void) putctl1(wq, M_FLUSH, FLUSHRW); /* * Note: if the receiver uses SCM_UCRED/getpeerucred the pid will * appear as -1. */ mp = allocb_cred(sizeof (*tcr) + addr->len, cr, NOPID); if (mp == NULL) { /* * This is unfortunate, but we need to look up the stats for * this zone to increment the "memory allocation failed" * counter. curproc->p_zone is safe since we're initiating a * connection and not in some strange streams context. */ struct rpcstat *rpcstat; rpcstat = zone_getspecific(rpcstat_zone_key, rpc_zone()); ASSERT(rpcstat != NULL); RPCLOG0(1, "connmgr_connect: cannot alloc mp for " "sending conn request\n"); COTSRCSTAT_INCR(rpcstat->rpc_cots_client, rcnomem); e->call_status = RPC_SYSTEMERROR; e->call_reason = ENOSR; return (FALSE); } /* Set TCP buffer size for RPC connections if needed */ if (addrfmly == AF_INET || addrfmly == AF_INET6) (void) connmgr_setbufsz(e, wq, cr); mp->b_datap->db_type = M_PROTO; tcr = (struct T_conn_req *)mp->b_rptr; bzero(tcr, sizeof (*tcr)); tcr->PRIM_type = T_CONN_REQ; tcr->DEST_length = addr->len; tcr->DEST_offset = sizeof (struct T_conn_req); mp->b_wptr = mp->b_rptr + sizeof (*tcr); bcopy(addr->buf, mp->b_wptr, tcr->DEST_length); mp->b_wptr += tcr->DEST_length; RPCLOG(8, "connmgr_connect: sending conn request on queue " "%p", (void *)wq); RPCLOG(8, " call %p\n", (void *)wq); /* * We use the entry in the handle that is normally used for * waiting for RPC replies to wait for the connection accept. */ if (clnt_dispatch_send(wq, mp, e, 0, 0) != RPC_SUCCESS) { DTRACE_PROBE(krpc__e__connmgr__connect__cantsend); freemsg(mp); return (FALSE); } mutex_enter(&clnt_pending_lock); /* * We wait for the transport connection to be made, or an * indication that it could not be made. */ interrupted = 0; /* * waitforack should have been called with T_OK_ACK, but the * present implementation needs to be passed T_INFO_ACK to * work correctly. */ error = waitforack(e, T_INFO_ACK, waitp, nosignal); if (error == EINTR) interrupted = 1; if (zone_status_get(curproc->p_zone) >= ZONE_IS_EMPTY) { /* * No time to lose; we essentially have been signaled to * quit. */ interrupted = 1; } #ifdef RPCDEBUG if (error == ETIME) RPCLOG0(8, "connmgr_connect: giving up " "on connection attempt; " "clnt_dispatch notifyconn " "diagnostic 'no one waiting for " "connection' should not be " "unexpected\n"); #endif if (e->call_prev) e->call_prev->call_next = e->call_next; else clnt_pending = e->call_next; if (e->call_next) e->call_next->call_prev = e->call_prev; mutex_exit(&clnt_pending_lock); if (e->call_status != RPC_SUCCESS || error != 0) { if (interrupted) e->call_status = RPC_INTR; else if (error == ETIME) e->call_status = RPC_TIMEDOUT; else if (error == EPROTO) { e->call_status = RPC_SYSTEMERROR; e->call_reason = EPROTO; } RPCLOG(8, "connmgr_connect: can't connect, status: " "%s\n", clnt_sperrno(e->call_status)); if (e->call_reply) { freemsg(e->call_reply); e->call_reply = NULL; } return (FALSE); } /* * The result of the "connection accept" is a T_info_ack * in the call_reply field. */ ASSERT(e->call_reply != NULL); mp = e->call_reply; e->call_reply = NULL; tinfo = (struct T_info_ack *)mp->b_rptr; tidu_size = tinfo->TIDU_size; tidu_size -= (tidu_size % BYTES_PER_XDR_UNIT); if (tidu_size > COTS_DEFAULT_ALLOCSIZE || (tidu_size <= 0)) tidu_size = COTS_DEFAULT_ALLOCSIZE; *tidu_ptr = tidu_size; freemsg(mp); /* * Set up the pertinent options. NODELAY is so the transport doesn't * buffer up RPC messages on either end. This may not be valid for * all transports. Failure to set this option is not cause to * bail out so we return success anyway. Note that lack of NODELAY * or some other way to flush the message on both ends will cause * lots of retries and terrible performance. */ if (addrfmly == AF_INET || addrfmly == AF_INET6) { (void) connmgr_setopt(wq, IPPROTO_TCP, TCP_NODELAY, e, cr); if (e->call_status == RPC_XPRTFAILED) return (FALSE); } /* * Since we have a connection, we now need to figure out if * we need to create a kstat. If x_ksp is not NULL then we * are reusing a connection and so we do not need to create * another kstat -- lets just return. */ if (cm_entry->x_ksp != NULL) return (TRUE); /* * We need to increment rpc_kstat_instance atomically to prevent * two kstats being created with the same instance. */ kstat_instance = atomic_add_32_nv((uint32_t *)&rpc_kstat_instance, 1); if ((cm_entry->x_ksp = kstat_create_zone("unix", kstat_instance, "rpc_cots_connections", "rpc", KSTAT_TYPE_NAMED, (uint_t)(sizeof (cm_kstat_xprt_t) / sizeof (kstat_named_t)), KSTAT_FLAG_VIRTUAL, cm_entry->x_zoneid)) == NULL) { return (TRUE); } cm_entry->x_ksp->ks_lock = &connmgr_lock; cm_entry->x_ksp->ks_private = cm_entry; cm_entry->x_ksp->ks_data_size = ((INET6_ADDRSTRLEN * sizeof (char)) + sizeof (cm_kstat_template)); cm_entry->x_ksp->ks_data = kmem_alloc(cm_entry->x_ksp->ks_data_size, KM_SLEEP); bcopy(&cm_kstat_template, cm_entry->x_ksp->ks_data, cm_entry->x_ksp->ks_data_size); ((struct cm_kstat_xprt *)(cm_entry->x_ksp->ks_data))-> x_server.value.str.addr.ptr = kmem_alloc(INET6_ADDRSTRLEN, KM_SLEEP); cm_entry->x_ksp->ks_update = conn_kstat_update; kstat_install(cm_entry->x_ksp); return (TRUE); } /* * Verify that the specified offset falls within the mblk and * that the resulting pointer is aligned. * Returns NULL if not. * * code from fs/sockfs/socksubr.c */ static void * connmgr_opt_getoff(mblk_t *mp, t_uscalar_t offset, t_uscalar_t length, uint_t align_size) { uintptr_t ptr1, ptr2; ASSERT(mp && mp->b_wptr >= mp->b_rptr); ptr1 = (uintptr_t)mp->b_rptr + offset; ptr2 = (uintptr_t)ptr1 + length; if (ptr1 < (uintptr_t)mp->b_rptr || ptr2 > (uintptr_t)mp->b_wptr) { return (NULL); } if ((ptr1 & (align_size - 1)) != 0) { return (NULL); } return ((void *)ptr1); } static bool_t connmgr_getopt_int(queue_t *wq, int level, int name, int *val, calllist_t *e, cred_t *cr) { mblk_t *mp; struct opthdr *opt, *opt_res; struct T_optmgmt_req *tor; struct T_optmgmt_ack *opt_ack; struct timeval waitp; int error; mp = allocb_cred(sizeof (struct T_optmgmt_req) + sizeof (struct opthdr) + sizeof (int), cr, NOPID); if (mp == NULL) return (FALSE); mp->b_datap->db_type = M_PROTO; tor = (struct T_optmgmt_req *)(mp->b_rptr); tor->PRIM_type = T_SVR4_OPTMGMT_REQ; tor->MGMT_flags = T_CURRENT; tor->OPT_length = sizeof (struct opthdr) + sizeof (int); tor->OPT_offset = sizeof (struct T_optmgmt_req); opt = (struct opthdr *)(mp->b_rptr + sizeof (struct T_optmgmt_req)); opt->level = level; opt->name = name; opt->len = sizeof (int); mp->b_wptr += sizeof (struct T_optmgmt_req) + sizeof (struct opthdr) + sizeof (int); /* * We will use this connection regardless * of whether or not the option is readable. */ if (clnt_dispatch_send(wq, mp, e, 0, 0) != RPC_SUCCESS) { DTRACE_PROBE(krpc__e__connmgr__getopt__cantsend); freemsg(mp); return (FALSE); } mutex_enter(&clnt_pending_lock); waitp.tv_sec = clnt_cots_min_conntout; waitp.tv_usec = 0; error = waitforack(e, T_OPTMGMT_ACK, &waitp, 1); if (e->call_prev) e->call_prev->call_next = e->call_next; else clnt_pending = e->call_next; if (e->call_next) e->call_next->call_prev = e->call_prev; mutex_exit(&clnt_pending_lock); /* get reply message */ mp = e->call_reply; e->call_reply = NULL; if ((!mp) || (e->call_status != RPC_SUCCESS) || (error != 0)) { DTRACE_PROBE4(krpc__e__connmgr_getopt, int, name, int, e->call_status, int, error, mblk_t *, mp); if (mp) freemsg(mp); return (FALSE); } opt_ack = (struct T_optmgmt_ack *)mp->b_rptr; opt_res = (struct opthdr *)connmgr_opt_getoff(mp, opt_ack->OPT_offset, opt_ack->OPT_length, __TPI_ALIGN_SIZE); if (!opt_res) { DTRACE_PROBE4(krpc__e__connmgr_optres, mblk_t *, mp, int, name, int, opt_ack->OPT_offset, int, opt_ack->OPT_length); freemsg(mp); return (FALSE); } *val = *(int *)&opt_res[1]; DTRACE_PROBE2(connmgr_getopt__ok, int, name, int, *val); freemsg(mp); return (TRUE); } /* * Called by connmgr_connect to set an option on the new stream. */ static bool_t connmgr_setopt_int(queue_t *wq, int level, int name, int val, calllist_t *e, cred_t *cr) { mblk_t *mp; struct opthdr *opt; struct T_optmgmt_req *tor; struct timeval waitp; int error; mp = allocb_cred(sizeof (struct T_optmgmt_req) + sizeof (struct opthdr) + sizeof (int), cr, NOPID); if (mp == NULL) { RPCLOG0(1, "connmgr_setopt: cannot alloc mp for option " "request\n"); return (FALSE); } mp->b_datap->db_type = M_PROTO; tor = (struct T_optmgmt_req *)(mp->b_rptr); tor->PRIM_type = T_SVR4_OPTMGMT_REQ; tor->MGMT_flags = T_NEGOTIATE; tor->OPT_length = sizeof (struct opthdr) + sizeof (int); tor->OPT_offset = sizeof (struct T_optmgmt_req); opt = (struct opthdr *)(mp->b_rptr + sizeof (struct T_optmgmt_req)); opt->level = level; opt->name = name; opt->len = sizeof (int); *(int *)((char *)opt + sizeof (*opt)) = val; mp->b_wptr += sizeof (struct T_optmgmt_req) + sizeof (struct opthdr) + sizeof (int); /* * We will use this connection regardless * of whether or not the option is settable. */ if (clnt_dispatch_send(wq, mp, e, 0, 0) != RPC_SUCCESS) { DTRACE_PROBE(krpc__e__connmgr__setopt__cantsend); freemsg(mp); return (FALSE); } mutex_enter(&clnt_pending_lock); waitp.tv_sec = clnt_cots_min_conntout; waitp.tv_usec = 0; error = waitforack(e, T_OPTMGMT_ACK, &waitp, 1); if (e->call_prev) e->call_prev->call_next = e->call_next; else clnt_pending = e->call_next; if (e->call_next) e->call_next->call_prev = e->call_prev; mutex_exit(&clnt_pending_lock); if (e->call_reply != NULL) { freemsg(e->call_reply); e->call_reply = NULL; } if (e->call_status != RPC_SUCCESS || error != 0) { RPCLOG(1, "connmgr_setopt: can't set option: %d\n", name); return (FALSE); } RPCLOG(8, "connmgr_setopt: successfully set option: %d\n", name); return (TRUE); } static bool_t connmgr_setopt(queue_t *wq, int level, int name, calllist_t *e, cred_t *cr) { return (connmgr_setopt_int(wq, level, name, 1, e, cr)); } #ifdef DEBUG /* * This is a knob to let us force code coverage in allocation failure * case. */ static int connmgr_failsnd; #define CONN_SND_ALLOC(Size, Pri) \ ((connmgr_failsnd-- > 0) ? NULL : allocb(Size, Pri)) #else #define CONN_SND_ALLOC(Size, Pri) allocb(Size, Pri) #endif /* * Sends an orderly release on the specified queue. * Entered with connmgr_lock. Exited without connmgr_lock */ static void connmgr_sndrel(struct cm_xprt *cm_entry) { struct T_ordrel_req *torr; mblk_t *mp; queue_t *q = cm_entry->x_wq; ASSERT(MUTEX_HELD(&connmgr_lock)); mp = CONN_SND_ALLOC(sizeof (struct T_ordrel_req), BPRI_LO); if (mp == NULL) { cm_entry->x_needrel = TRUE; mutex_exit(&connmgr_lock); RPCLOG(1, "connmgr_sndrel: cannot alloc mp for sending ordrel " "to queue %p\n", (void *)q); return; } mutex_exit(&connmgr_lock); mp->b_datap->db_type = M_PROTO; torr = (struct T_ordrel_req *)(mp->b_rptr); torr->PRIM_type = T_ORDREL_REQ; mp->b_wptr = mp->b_rptr + sizeof (struct T_ordrel_req); RPCLOG(8, "connmgr_sndrel: sending ordrel to queue %p\n", (void *)q); put(q, mp); } /* * Sends an disconnect on the specified queue. * Entered with connmgr_lock. Exited without connmgr_lock */ static void connmgr_snddis(struct cm_xprt *cm_entry) { struct T_discon_req *tdis; mblk_t *mp; queue_t *q = cm_entry->x_wq; ASSERT(MUTEX_HELD(&connmgr_lock)); mp = CONN_SND_ALLOC(sizeof (*tdis), BPRI_LO); if (mp == NULL) { cm_entry->x_needdis = TRUE; mutex_exit(&connmgr_lock); RPCLOG(1, "connmgr_snddis: cannot alloc mp for sending discon " "to queue %p\n", (void *)q); return; } mutex_exit(&connmgr_lock); mp->b_datap->db_type = M_PROTO; tdis = (struct T_discon_req *)mp->b_rptr; tdis->PRIM_type = T_DISCON_REQ; mp->b_wptr = mp->b_rptr + sizeof (*tdis); RPCLOG(8, "connmgr_snddis: sending discon to queue %p\n", (void *)q); put(q, mp); } /* * Sets up the entry for receiving replies, and calls rpcmod's write put proc * (through put) to send the call. */ static int clnt_dispatch_send(queue_t *q, mblk_t *mp, calllist_t *e, uint_t xid, uint_t queue_flag) { ASSERT(e != NULL); e->call_status = RPC_TIMEDOUT; /* optimistic, eh? */ e->call_reason = 0; e->call_wq = q; e->call_xid = xid; e->call_notified = FALSE; if (!canput(q)) { e->call_status = RPC_CANTSEND; e->call_reason = ENOBUFS; return (RPC_CANTSEND); } /* * If queue_flag is set then the calllist_t is already on the hash * queue. In this case just send the message and return. */ if (queue_flag) { put(q, mp); return (RPC_SUCCESS); } /* * Set up calls for RPC requests (with XID != 0) on the hash * queue for fast lookups and place other calls (i.e. * connection management) on the linked list. */ if (xid != 0) { RPCLOG(64, "clnt_dispatch_send: putting xid 0x%x on " "dispatch list\n", xid); e->call_hash = call_hash(xid, clnt_cots_hash_size); e->call_bucket = &cots_call_ht[e->call_hash]; call_table_enter(e); } else { mutex_enter(&clnt_pending_lock); if (clnt_pending) clnt_pending->call_prev = e; e->call_next = clnt_pending; e->call_prev = NULL; clnt_pending = e; mutex_exit(&clnt_pending_lock); } put(q, mp); return (RPC_SUCCESS); } /* * Called by rpcmod to notify a client with a clnt_pending call that its reply * has arrived. If we can't find a client waiting for this reply, we log * the error and return. */ bool_t clnt_dispatch_notify(mblk_t *mp, zoneid_t zoneid) { calllist_t *e = NULL; call_table_t *chtp; uint32_t xid; uint_t hash; if ((IS_P2ALIGNED(mp->b_rptr, sizeof (uint32_t))) && (mp->b_wptr - mp->b_rptr) >= sizeof (xid)) xid = *((uint32_t *)mp->b_rptr); else { int i = 0; unsigned char *p = (unsigned char *)&xid; unsigned char *rptr; mblk_t *tmp = mp; /* * Copy the xid, byte-by-byte into xid. */ while (tmp) { rptr = tmp->b_rptr; while (rptr < tmp->b_wptr) { *p++ = *rptr++; if (++i >= sizeof (xid)) goto done_xid_copy; } tmp = tmp->b_cont; } /* * If we got here, we ran out of mblk space before the * xid could be copied. */ ASSERT(tmp == NULL && i < sizeof (xid)); RPCLOG0(1, "clnt_dispatch_notify: message less than size of xid\n"); return (FALSE); } done_xid_copy: hash = call_hash(xid, clnt_cots_hash_size); chtp = &cots_call_ht[hash]; /* call_table_find returns with the hash bucket locked */ call_table_find(chtp, xid, e); if (e != NULL) { /* * Found thread waiting for this reply */ mutex_enter(&e->call_lock); /* * verify that the reply is coming in on * the same zone that it was sent from. */ if (e->call_zoneid != zoneid) { mutex_exit(&e->call_lock); mutex_exit(&chtp->ct_lock); RPCLOG0(1, "clnt_dispatch_notify: incorrect zoneid\n"); return (FALSE); } if (e->call_reply) /* * This can happen under the following scenario: * clnt_cots_kcallit() times out on the response, * rfscall() repeats the CLNT_CALL() with * the same xid, clnt_cots_kcallit() sends the retry, * thereby putting the clnt handle on the pending list, * the first response arrives, signalling the thread * in clnt_cots_kcallit(). Before that thread is * dispatched, the second response arrives as well, * and clnt_dispatch_notify still finds the handle on * the pending list, with call_reply set. So free the * old reply now. * * It is also possible for a response intended for * an RPC call with a different xid to reside here. * This can happen if the thread that owned this * client handle prior to the current owner bailed * out and left its call record on the dispatch * queue. A window exists where the response can * arrive before the current owner dispatches its * RPC call. * * In any case, this is the very last point where we * can safely check the call_reply field before * placing the new response there. */ freemsg(e->call_reply); e->call_reply = mp; e->call_status = RPC_SUCCESS; e->call_notified = TRUE; cv_signal(&e->call_cv); mutex_exit(&e->call_lock); mutex_exit(&chtp->ct_lock); return (TRUE); } else { zone_t *zone; struct rpcstat *rpcstat; mutex_exit(&chtp->ct_lock); RPCLOG(65, "clnt_dispatch_notify: no caller for reply 0x%x\n", xid); /* * This is unfortunate, but we need to lookup the zone so we * can increment its "rcbadxids" counter. */ zone = zone_find_by_id(zoneid); if (zone == NULL) { /* * The zone went away... */ return (FALSE); } rpcstat = zone_getspecific(rpcstat_zone_key, zone); if (zone_status_get(zone) >= ZONE_IS_SHUTTING_DOWN) { /* * Not interested */ zone_rele(zone); return (FALSE); } COTSRCSTAT_INCR(rpcstat->rpc_cots_client, rcbadxids); zone_rele(zone); } return (FALSE); } /* * Called by rpcmod when a non-data indication arrives. The ones in which we * are interested are connection indications and options acks. We dispatch * based on the queue the indication came in on. If we are not interested in * what came in, we return false to rpcmod, who will then pass it upstream. */ bool_t clnt_dispatch_notifyconn(queue_t *q, mblk_t *mp) { calllist_t *e; int type; ASSERT((q->q_flag & QREADR) == 0); type = ((union T_primitives *)mp->b_rptr)->type; RPCLOG(8, "clnt_dispatch_notifyconn: prim type: [%s]\n", rpc_tpiprim2name(type)); mutex_enter(&clnt_pending_lock); for (e = clnt_pending; /* NO CONDITION */; e = e->call_next) { if (e == NULL) { mutex_exit(&clnt_pending_lock); RPCLOG(1, "clnt_dispatch_notifyconn: no one waiting " "for connection on queue 0x%p\n", (void *)q); return (FALSE); } if (e->call_wq == q) break; } switch (type) { case T_CONN_CON: /* * The transport is now connected, send a T_INFO_REQ to get * the tidu size. */ mutex_exit(&clnt_pending_lock); ASSERT(mp->b_datap->db_lim - mp->b_datap->db_base >= sizeof (struct T_info_req)); mp->b_rptr = mp->b_datap->db_base; ((union T_primitives *)mp->b_rptr)->type = T_INFO_REQ; mp->b_wptr = mp->b_rptr + sizeof (struct T_info_req); mp->b_datap->db_type = M_PCPROTO; put(q, mp); return (TRUE); case T_INFO_ACK: case T_OPTMGMT_ACK: e->call_status = RPC_SUCCESS; e->call_reply = mp; e->call_notified = TRUE; cv_signal(&e->call_cv); break; case T_ERROR_ACK: e->call_status = RPC_CANTCONNECT; e->call_reply = mp; e->call_notified = TRUE; cv_signal(&e->call_cv); break; case T_OK_ACK: /* * Great, but we are really waiting for a T_CONN_CON */ freemsg(mp); break; default: mutex_exit(&clnt_pending_lock); RPCLOG(1, "clnt_dispatch_notifyconn: bad type %d\n", type); return (FALSE); } mutex_exit(&clnt_pending_lock); return (TRUE); } /* * Called by rpcmod when the transport is (or should be) going away. Informs * all callers waiting for replies and marks the entry in the connection * manager's list as unconnected, and either closing (close handshake in * progress) or dead. */ void clnt_dispatch_notifyall(queue_t *q, int32_t msg_type, int32_t reason) { calllist_t *e; call_table_t *ctp; struct cm_xprt *cm_entry; int have_connmgr_lock; int i; ASSERT((q->q_flag & QREADR) == 0); RPCLOG(1, "clnt_dispatch_notifyall on queue %p", (void *)q); RPCLOG(1, " received a notifcation prim type [%s]", rpc_tpiprim2name(msg_type)); RPCLOG(1, " and reason %d\n", reason); /* * Find the transport entry in the connection manager's list, close * the transport and delete the entry. In the case where rpcmod's * idle timer goes off, it sends us a T_ORDREL_REQ, indicating we * should gracefully close the connection. */ have_connmgr_lock = 1; mutex_enter(&connmgr_lock); for (cm_entry = cm_hd; cm_entry; cm_entry = cm_entry->x_next) { ASSERT(cm_entry != cm_entry->x_next); if (cm_entry->x_wq == q) { ASSERT(MUTEX_HELD(&connmgr_lock)); ASSERT(have_connmgr_lock == 1); switch (msg_type) { case T_ORDREL_REQ: if (cm_entry->x_dead) { RPCLOG(1, "idle timeout on dead " "connection: %p\n", (void *)cm_entry); if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); break; } /* * Only mark the connection as dead if it is * connected and idle. * An unconnected connection has probably * gone idle because the server is down, * and when it comes back up there will be * retries that need to use that connection. */ if (cm_entry->x_connected || cm_entry->x_doomed) { if (cm_entry->x_ordrel) { if (cm_entry->x_closing == TRUE) { /* * The connection is * obviously wedged due * to a bug or problem * with the transport. * Mark it as dead. * Otherwise we can * leak connections. */ cm_entry->x_dead = TRUE; mutex_exit( &connmgr_lock); have_connmgr_lock = 0; if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); break; } cm_entry->x_closing = TRUE; connmgr_sndrel(cm_entry); have_connmgr_lock = 0; } else { cm_entry->x_dead = TRUE; mutex_exit(&connmgr_lock); have_connmgr_lock = 0; if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); } } else { /* * We don't mark the connection * as dead, but we turn off the * idle timer. */ mutex_exit(&connmgr_lock); have_connmgr_lock = 0; if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); RPCLOG(1, "clnt_dispatch_notifyall:" " ignoring timeout from rpcmod" " (q %p) because we are not " " connected\n", (void *)q); } break; case T_ORDREL_IND: /* * If this entry is marked closing, then we are * completing a close handshake, and the * connection is dead. Otherwise, the server is * trying to close. Since the server will not * be sending any more RPC replies, we abort * the connection, including flushing * any RPC requests that are in-transit. * In either case, mark the entry as dead so * that it can be closed by the connection * manager's garbage collector. */ cm_entry->x_dead = TRUE; if (cm_entry->x_closing) { mutex_exit(&connmgr_lock); have_connmgr_lock = 0; if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); } else { /* * if we're getting a disconnect * before we've finished our * connect attempt, mark it for * later processing */ if (cm_entry->x_thread) cm_entry->x_early_disc = TRUE; else cm_entry->x_connected = FALSE; cm_entry->x_waitdis = TRUE; connmgr_snddis(cm_entry); have_connmgr_lock = 0; } break; case T_ERROR_ACK: case T_OK_ACK: cm_entry->x_waitdis = FALSE; cv_signal(&cm_entry->x_dis_cv); mutex_exit(&connmgr_lock); return; case T_DISCON_REQ: if (cm_entry->x_thread) cm_entry->x_early_disc = TRUE; else cm_entry->x_connected = FALSE; cm_entry->x_waitdis = TRUE; connmgr_snddis(cm_entry); have_connmgr_lock = 0; break; case T_DISCON_IND: default: /* * if we're getting a disconnect before * we've finished our connect attempt, * mark it for later processing */ if (cm_entry->x_closing) { cm_entry->x_dead = TRUE; mutex_exit(&connmgr_lock); have_connmgr_lock = 0; if (clnt_stop_idle != NULL) (*clnt_stop_idle)(q); } else { if (cm_entry->x_thread) { cm_entry->x_early_disc = TRUE; } else { cm_entry->x_dead = TRUE; cm_entry->x_connected = FALSE; } } break; } break; } } if (have_connmgr_lock) mutex_exit(&connmgr_lock); if (msg_type == T_ERROR_ACK || msg_type == T_OK_ACK) { RPCLOG(1, "clnt_dispatch_notifyall: (wq %p) could not find " "connmgr entry for discon ack\n", (void *)q); return; } /* * Then kick all the clnt_pending calls out of their wait. There * should be no clnt_pending calls in the case of rpcmod's idle * timer firing. */ for (i = 0; i < clnt_cots_hash_size; i++) { ctp = &cots_call_ht[i]; mutex_enter(&ctp->ct_lock); for (e = ctp->ct_call_next; e != (calllist_t *)ctp; e = e->call_next) { if (e->call_wq == q && e->call_notified == FALSE) { RPCLOG(1, "clnt_dispatch_notifyall for queue %p ", (void *)q); RPCLOG(1, "aborting clnt_pending call %p\n", (void *)e); if (msg_type == T_DISCON_IND) e->call_reason = reason; e->call_notified = TRUE; e->call_status = RPC_XPRTFAILED; cv_signal(&e->call_cv); } } mutex_exit(&ctp->ct_lock); } mutex_enter(&clnt_pending_lock); for (e = clnt_pending; e; e = e->call_next) { /* * Only signal those RPC handles that haven't been * signalled yet. Otherwise we can get a bogus call_reason. * This can happen if thread A is making a call over a * connection. If the server is killed, it will cause * reset, and reason will default to EIO as a result of * a T_ORDREL_IND. Thread B then attempts to recreate * the connection but gets a T_DISCON_IND. If we set the * call_reason code for all threads, then if thread A * hasn't been dispatched yet, it will get the wrong * reason. The bogus call_reason can make it harder to * discriminate between calls that fail because the * connection attempt failed versus those where the call * may have been executed on the server. */ if (e->call_wq == q && e->call_notified == FALSE) { RPCLOG(1, "clnt_dispatch_notifyall for queue %p ", (void *)q); RPCLOG(1, " aborting clnt_pending call %p\n", (void *)e); if (msg_type == T_DISCON_IND) e->call_reason = reason; e->call_notified = TRUE; /* * Let the caller timeout, else he will retry * immediately. */ e->call_status = RPC_XPRTFAILED; /* * We used to just signal those threads * waiting for a connection, (call_xid = 0). * That meant that threads waiting for a response * waited till their timeout expired. This * could be a long time if they've specified a * maximum timeout. (2^31 - 1). So we * Signal all threads now. */ cv_signal(&e->call_cv); } } mutex_exit(&clnt_pending_lock); } /*ARGSUSED*/ /* * after resuming a system that's been suspended for longer than the * NFS server's idle timeout (svc_idle_timeout for Solaris 2), rfscall() * generates "NFS server X not responding" and "NFS server X ok" messages; * here we reset inet connections to cause a re-connect and avoid those * NFS messages. see 4045054 */ boolean_t connmgr_cpr_reset(void *arg, int code) { struct cm_xprt *cxp; if (code == CB_CODE_CPR_CHKPT) return (B_TRUE); if (mutex_tryenter(&connmgr_lock) == 0) return (B_FALSE); for (cxp = cm_hd; cxp; cxp = cxp->x_next) { if ((cxp->x_family == AF_INET || cxp->x_family == AF_INET6) && cxp->x_connected == TRUE) { if (cxp->x_thread) cxp->x_early_disc = TRUE; else cxp->x_connected = FALSE; cxp->x_needdis = TRUE; } } mutex_exit(&connmgr_lock); return (B_TRUE); } void clnt_cots_stats_init(zoneid_t zoneid, struct rpc_cots_client **statsp) { *statsp = (struct rpc_cots_client *)rpcstat_zone_init_common(zoneid, "unix", "rpc_cots_client", (const kstat_named_t *)&cots_rcstat_tmpl, sizeof (cots_rcstat_tmpl)); } void clnt_cots_stats_fini(zoneid_t zoneid, struct rpc_cots_client **statsp) { rpcstat_zone_fini_common(zoneid, "unix", "rpc_cots_client"); kmem_free(*statsp, sizeof (cots_rcstat_tmpl)); } void clnt_cots_init(void) { mutex_init(&connmgr_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&clnt_pending_lock, NULL, MUTEX_DEFAULT, NULL); if (clnt_cots_hash_size < DEFAULT_MIN_HASH_SIZE) clnt_cots_hash_size = DEFAULT_MIN_HASH_SIZE; cots_call_ht = call_table_init(clnt_cots_hash_size); zone_key_create(&zone_cots_key, NULL, NULL, clnt_zone_destroy); } void clnt_cots_fini(void) { (void) zone_key_delete(zone_cots_key); } /* * Wait for TPI ack, returns success only if expected ack is received * within timeout period. */ static int waitforack(calllist_t *e, t_scalar_t ack_prim, const struct timeval *waitp, bool_t nosignal) { union T_primitives *tpr; clock_t timout; int cv_stat = 1; ASSERT(MUTEX_HELD(&clnt_pending_lock)); while (e->call_reply == NULL) { if (waitp != NULL) { timout = waitp->tv_sec * drv_usectohz(MICROSEC) + drv_usectohz(waitp->tv_usec) + lbolt; if (nosignal) cv_stat = cv_timedwait(&e->call_cv, &clnt_pending_lock, timout); else cv_stat = cv_timedwait_sig(&e->call_cv, &clnt_pending_lock, timout); } else { if (nosignal) cv_wait(&e->call_cv, &clnt_pending_lock); else cv_stat = cv_wait_sig(&e->call_cv, &clnt_pending_lock); } if (cv_stat == -1) return (ETIME); if (cv_stat == 0) return (EINTR); /* * if we received an error from the server and we know a reply * is not going to be sent, do not wait for the full timeout, * return now. */ if (e->call_status == RPC_XPRTFAILED) return (e->call_reason); } tpr = (union T_primitives *)e->call_reply->b_rptr; if (tpr->type == ack_prim) return (0); /* Success */ if (tpr->type == T_ERROR_ACK) { if (tpr->error_ack.TLI_error == TSYSERR) return (tpr->error_ack.UNIX_error); else return (t_tlitosyserr(tpr->error_ack.TLI_error)); } return (EPROTO); /* unknown or unexpected primitive */ }