/* * Copyright (c) 1998 Luigi Rizzo * * Redistribution and use in source forms, with and without modification, * are permitted provided that this entire comment appears intact. * * Redistribution in binary form may occur without any restrictions. * Obviously, it would be nice if you gave credit where credit is due * but requiring it would be too onerous. * * This software is provided ``AS IS'' without any warranties of any kind. * * $Id: ip_dummynet.c 1.2 1998/08/21 15:01:13 luigi Exp $ */ /* * This module implements IP dummynet, a bandwidth limiter/delay emulator * used in conjunction with the ipfw package. * * Changes: * * 980821: changed conventions in the queueing logic * packets passed from dummynet to ip_in/out are prepended with * a vestigial mbuf type MT_DUMMYNET which contains a pointer * to the matching rule. * ip_input/output will extract the parameters, free the vestigial mbuf, * and do the processing. * * 980519: fixed behaviour when deleting rules. * 980518: added splimp()/splx() to protect against races * 980513: initial release */ /* include files marked with XXX are probably not needed */ #include #include #include #include #include /* XXX */ #include #include #include #include #include #include #include #include #include #include #include #include #ifdef BRIDGE #include /* for struct arpcom */ #include #endif static struct dn_pipe *all_pipes = NULL ; /* list of all pipes */ static int dn_debug = 0 ; /* verbose */ static int dn_calls = 0 ; /* number of calls */ static int dn_idle = 1; #ifdef SYSCTL_NODE SYSCTL_NODE(_net_inet_ip, OID_AUTO, dummynet, CTLFLAG_RW, 0, "Dummynet"); SYSCTL_INT(_net_inet_ip_dummynet, OID_AUTO, debug, CTLFLAG_RW, &dn_debug, 0, ""); SYSCTL_INT(_net_inet_ip_dummynet, OID_AUTO, calls, CTLFLAG_RD, &dn_calls, 0, ""); SYSCTL_INT(_net_inet_ip_dummynet, OID_AUTO, idle, CTLFLAG_RD, &dn_idle, 0, ""); #endif static int ip_dn_ctl(int optname, struct mbuf **mm); static void dummynet(void); static void dn_restart(void); static void dn_move(struct dn_pipe *pipe, int immediate); /* * the following is needed when deleting a pipe, because rules can * hold references to the pipe. */ extern LIST_HEAD (ip_fw_head, ip_fw_chain) ip_fw_chain; /* * invoked to reschedule the periodic task if necessary. * Should only be called when dn_idle = 1 ; */ static void dn_restart() { struct dn_pipe *pipe; if (!dn_idle) return; for (pipe = all_pipes ; pipe ; pipe = pipe->next ) { /* if there any pipe that needs work, restart */ if (pipe->r.head || pipe->p.head || pipe->numbytes < 0 ) { dn_idle = 0; timeout(dummynet, (caddr_t)NULL, 1); return ; } } } /* * move packets from R-queue to P-queue */ static void dn_move(struct dn_pipe *pipe, int immediate) { struct dn_pkt *tmp, *pkt; /* * consistency check, should catch new pipes which are * not initialized properly. */ if ( pipe->p.head == NULL && pipe->ticks_from_last_insert != pipe->delay) { printf("Warning, empty pipe and delay %d (should be %a)d\n", pipe->ticks_from_last_insert, pipe->delay); pipe->ticks_from_last_insert = pipe->delay; } /* this ought to go in dn_dequeue() */ if (!immediate && pipe->ticks_from_last_insert < pipe->delay) pipe->ticks_from_last_insert++; if ( pkt = pipe->r.head ) { /* * Move at most numbytes bytes from src and move to dst. * delay is set to ticks_from_last_insert, which * is reset after the first insertion; */ while ( pkt ) { struct ip *ip=mtod(pkt->dn_m, struct ip *); /* * queue limitation: pass packets down if the len is * such that the pkt would go out before the next tick. */ if (pipe->bandwidth) { if (pipe->numbytes < ip->ip_len) break; pipe->numbytes -= ip->ip_len; } pipe->r_len--; /* elements in queue */ pipe->r_len_bytes -= ip->ip_len ; /* * to add delay jitter, must act here. A lower value * (bounded to 0) means lower delay. */ pkt->delay = pipe->ticks_from_last_insert; pipe->ticks_from_last_insert = 0; /* compensate the decrement done next in dn_dequeue */ if (!immediate && pkt->delay >0 && pipe->p.head==NULL) pkt->delay++; if (pipe->p.head == NULL) pipe->p.head = pkt; else (struct dn_pkt *)pipe->p.tail->dn_next = pkt; pipe->p.tail = pkt; pkt = (struct dn_pkt *)pkt->dn_next; pipe->p.tail->dn_next = NULL; } pipe->r.head = pkt; /*** XXX just a sanity check */ if ( ( pkt == NULL && pipe->r_len != 0) || ( pkt != NULL && pipe->r_len == 0) ) printf("-- Warning, pipe head %x len %d\n", pkt, pipe->r_len); } /* * deliver packets downstream after the delay in the P-queue. */ if (pipe->p.head == NULL) return; if (!immediate) pipe->p.head->delay--; while ( (pkt = pipe->p.head) && pkt->delay < 1) { /* * first unlink, then call procedures since ip_input() * can result in a call to ip_output cnd viceversa, * thus causing nested calls */ pipe->p.head = (struct dn_pkt *) pkt->dn_next ; /* * the trick to avoid flow-id settings here is to prepend a * vestigial mbuf to the packet, with the following values: * m_type = MT_DUMMYNET * m_next = the actual mbuf to be processed by ip_input/output * m_data = the matching rule * The vestigial element is the same memory area used by * the dn_pkt, and IS FREED IN ip_input/ip_output. IT IS * NOT A REAL MBUF, just a block of memory acquired with malloc(). */ switch (pkt->dn_dir) { case DN_TO_IP_OUT: { struct rtentry *tmp_rt = pkt->ro.ro_rt ; (void)ip_output((struct mbuf *)pkt, (struct mbuf *)pkt->ifp, &(pkt->ro), pkt->dn_hlen, NULL); if (tmp_rt) tmp_rt->rt_refcnt--; /* XXX return a reference count */ } break ; case DN_TO_IP_IN : ip_input((struct mbuf *)pkt) ; break ; #ifdef BRIDGE case DN_TO_BDG_FWD : bdg_forward((struct mbuf **)&pkt, pkt->ifp); break ; #endif default: printf("dummynet: bad switch %d!\n", pkt->dn_dir); m_freem(pkt->dn_m); FREE(pkt, M_IPFW); break ; } } } /* * this is the periodic task that moves packets between the R- * and the P- queue */ void dummynet() { struct dn_pipe *p ; int s ; dn_calls++ ; for (p = all_pipes ; p ; p = p->next ) { /* * Increment the amount of data that can be sent. However, * don't do that if the channel is idle * (r.head == NULL && numbytes >= bandwidth). * This bug fix is from tim shepard (shep@bbn.com) */ s = splimp(); if (p->r.head != NULL || p->numbytes < p->bandwidth ) p->numbytes += p->bandwidth ; dn_move(p, 0); /* is it really 0 (also below) ? */ splx(s); } /* * finally, if some queue has data, restart the timer. */ dn_idle = 1; dn_restart(); } /* * dummynet hook for packets. * input and output use the same code, so i use bit 16 in the pipe * number to chose the direction: 1 for output packets, 0 for input. * for input, only m is significant. For output, also the others. */ int dummynet_io(int pipe_nr, int dir, struct mbuf *m, struct ifnet *ifp, struct route *ro, int hlen, struct ip_fw_chain *rule) { struct dn_pkt *pkt; struct dn_pipe *pipe; struct ip *ip=mtod(m, struct ip *); int s=splimp(); pipe_nr &= 0xffff ; /* * locate pipe. First time is expensive, next have direct access. */ if ( (pipe = rule->rule->pipe_ptr) == NULL ) { for (pipe=all_pipes; pipe && pipe->pipe_nr !=pipe_nr; pipe=pipe->next) ; if (pipe == NULL) { splx(s); if (dn_debug) printf("warning, pkt for no pipe %d\n", pipe_nr); m_freem(m); return 0 ; } else rule->rule->pipe_ptr = pipe ; } /* * should i drop ? * This section implements random packet drop. */ if ( (pipe->plr && random() < pipe->plr) || (pipe->queue_size && pipe->r_len >= pipe->queue_size) || (pipe->queue_size_bytes && ip->ip_len + pipe->r_len_bytes > pipe->queue_size_bytes) || (pkt = (struct dn_pkt *)malloc(sizeof (*pkt), M_IPFW, M_NOWAIT) ) == NULL ) { splx(s); if (dn_debug) printf("-- dummynet: drop from pipe %d, have %d pks, %d bytes\n", pipe_nr, pipe->r_len, pipe->r_len_bytes); pipe->r_drops++ ; m_freem(m); return 0 ; /* XXX error */ } /* build and enqueue packet */ pkt->hdr.mh_type = MT_DUMMYNET ; (struct ip_fw_chain *)pkt->hdr.mh_data = rule ; pkt->dn_next = NULL; pkt->dn_m = m; pkt->dn_dir = dir ; pkt->delay = 0; pkt->ifp = ifp; if (dir == DN_TO_IP_OUT) { pkt->ro = *ro; /* XXX copied! */ if (ro->ro_rt) ro->ro_rt->rt_refcnt++ ; /* XXX */ } pkt->dn_hlen = hlen; if (pipe->r.head == NULL) pipe->r.head = pkt; else (struct dn_pkt *)pipe->r.tail->dn_next = pkt; pipe->r.tail = pkt; pipe->r_len++; pipe->r_len_bytes += ip->ip_len ; /* * here we could implement RED if we like to */ if (pipe->r.head == pkt) { /* process immediately */ dn_move(pipe, 1); } splx(s); if (dn_idle) dn_restart(); return 0; } /* * dispose all packets queued on a pipe */ static void purge_pipe(struct dn_pipe *pipe) { struct dn_pkt *pkt, *n ; struct rtentry *tmp_rt ; for (pkt = pipe->r.head ; pkt ; ) { if (tmp_rt = pkt->ro.ro_rt ) tmp_rt->rt_refcnt--; /* XXX return a reference count */ m_freem(pkt->dn_m); n = pkt ; pkt = (struct dn_pkt *)pkt->dn_next ; free(n, M_IPFW) ; } for (pkt = pipe->p.head ; pkt ; ) { if (tmp_rt = pkt->ro.ro_rt ) tmp_rt->rt_refcnt--; /* XXX return a reference count */ m_freem(pkt->dn_m); n = pkt ; pkt = (struct dn_pkt *)pkt->dn_next ; free(n, M_IPFW) ; } } /* * delete all pipes returning memory */ static void dummynet_flush() { struct dn_pipe *q, *p = all_pipes ; int s = splnet() ; all_pipes = NULL ; splx(s) ; /* * purge all queued pkts and delete all pipes */ for ( ; p ; ) { purge_pipe(p); q = p ; p = p->next ; free(q, M_IPFW); } } extern struct ip_fw_chain *ip_fw_default_rule ; /* * when a firewall rule is deleted, scan all pipes and remove the flow-id * from packets matching this rule. */ void dn_rule_delete(void *r) { struct dn_pipe *q, *p = all_pipes ; for ( p= all_pipes ; p ; p = p->next ) { struct dn_pkt *x ; for (x = p->r.head ; x ; x = (struct dn_pkt *)x->dn_next ) if (x->hdr.mh_data == r) x->hdr.mh_data = (void *)ip_fw_default_rule ; for (x = p->p.head ; x ; x = (struct dn_pkt *)x->dn_next ) if (x->hdr.mh_data == r) x->hdr.mh_data = (void *)ip_fw_default_rule ; } } /* * handler for the various dummynet socket options * (get, flush, config, del) */ static int ip_dn_ctl(int optname, struct mbuf **mm) { struct mbuf *m ; if (optname == IP_DUMMYNET_GET) { struct dn_pipe *p = all_pipes ; *mm = m = m_get(M_WAIT, MT_SOOPTS); m->m_len = 0 ; m->m_next = NULL ; for (; p ; p = p->next ) { struct dn_pipe *q = mtod(m,struct dn_pipe *) ; memcpy( m->m_data, p, sizeof(*p) ); /* * return bw and delay in bits/s and ms, respectively */ q->bandwidth *= (8*hz) ; q->delay = (q->delay * 1000) / hz ; m->m_len = sizeof(*p) ; m->m_next = m_get(M_WAIT, MT_SOOPTS); m = m->m_next ; m->m_len = 0 ; } return 0 ; } if (securelevel > 2) { /* like in the firewall code... */ if (m) (void)m_free(m); return (EPERM) ; } m = *mm ; if (optname == IP_DUMMYNET_FLUSH) { dummynet_flush() ; if (m) (void)m_free(m); return 0 ; } if (!m) /* need an argument for the following */ return (EINVAL); if (optname == IP_DUMMYNET_CONFIGURE) { struct dn_pipe *p = mtod(m,struct dn_pipe *) ; struct dn_pipe *x, *a, *b ; if (m->m_len != sizeof (*p) ) { printf("dn_pipe Invalid length, %d instead of %d\n", m->m_len, sizeof(*p) ); (void)m_free(m); return (EINVAL); } /* * The config program passes parameters as follows: * bandwidth = bits/second (0 = no limits); * must be translated in bytes/tick. * delay = ms * must be translated in ticks. * queue_size = slots (0 = no limit) * queue_size_bytes = bytes (0 = no limit) * only one can be set, must be bound-checked */ if ( p->bandwidth > 0 ) { p->bandwidth = p->bandwidth / 8 / hz ; if (p->bandwidth == 0) /* too little does not make sense! */ p->bandwidth = 10 ; } p->delay = ( p->delay * hz ) / 1000 ; if (p->queue_size == 0 && p->queue_size_bytes == 0) p->queue_size = 100 ; if (p->queue_size != 0 ) /* buffers are prevailing */ p->queue_size_bytes = 0 ; if (p->queue_size > 100) p->queue_size = 100 ; if (p->queue_size_bytes > 1024*1024) p->queue_size_bytes = 1024*1024 ; #if 0 printf("ip_dn: config pipe %d %d bit/s %d ms %d bufs\n", p->pipe_nr, p->bandwidth * 8 * hz , p->delay * 1000 / hz , p->queue_size); #endif for (a = NULL , b = all_pipes ; b && b->pipe_nr < p->pipe_nr ; a = b , b = b->next) ; if (b && b->pipe_nr == p->pipe_nr) { /* XXX should spl and flush old pipe... */ b->bandwidth = p->bandwidth ; b->delay = p->delay ; b->ticks_from_last_insert = p->delay ; b->queue_size = p->queue_size ; b->queue_size_bytes = p->queue_size_bytes ; b->plr = p->plr ; } else { int s ; x = malloc(sizeof(struct dn_pipe), M_IPFW, M_DONTWAIT) ; if (x == NULL) { printf("ip_dummynet.c: sorry no memory\n"); return (ENOSPC) ; } bzero(x, sizeof(*x) ); x->bandwidth = p->bandwidth ; x->delay = p->delay ; x->ticks_from_last_insert = p->delay ; x->pipe_nr = p->pipe_nr ; x->queue_size = p->queue_size ; x->queue_size_bytes = p->queue_size_bytes ; x->plr = p->plr ; s = splnet() ; x->next = b ; if (a == NULL) all_pipes = x ; else a->next = x ; splx(s); } (void)m_free(m); return 0 ; } if (optname == IP_DUMMYNET_DEL) { struct dn_pipe *p = mtod(m,struct dn_pipe *) ; struct dn_pipe *x, *a, *b ; for (a = NULL , b = all_pipes ; b && b->pipe_nr < p->pipe_nr ; a = b , b = b->next) ; if (b && b->pipe_nr == p->pipe_nr) { /* found pipe */ int s = splnet() ; struct ip_fw_chain *chain = ip_fw_chain.lh_first; if (a == NULL) all_pipes = b->next ; else a->next = b->next ; /* * remove references to this pipe from the ip_fw rules. */ for (; chain; chain = chain->chain.le_next) { register struct ip_fw *const f = chain->rule; if (f->pipe_ptr == b) f->pipe_ptr = NULL ; } splx(s); purge_pipe(b); /* remove pkts from here */ free(b, M_IPFW); } } return 0 ; } void ip_dn_init(void) { printf("DUMMYNET initialized (980901) -- size dn_pkt %d\n", sizeof(struct dn_pkt)); all_pipes = NULL ; ip_dn_ctl_ptr = ip_dn_ctl; } #ifdef DUMMYNET_MODULE #include #include #include MOD_MISC(dummynet); static ip_dn_ctl_t *old_dn_ctl_ptr ; static int dummynet_load(struct lkm_table *lkmtp, int cmd) { int s=splnet(); old_dn_ctl_ptr = ip_dn_ctl_ptr; ip_dn_init(); splx(s); return 0; } static int dummynet_unload(struct lkm_table *lkmtp, int cmd) { int s=splnet(); ip_dn_ctl_ptr = old_dn_ctl_ptr; splx(s); dummynet_flush(); printf("DUMMYNET unloaded\n"); return 0; } int dummynet_mod(struct lkm_table *lkmtp, int cmd, int ver) { DISPATCH(lkmtp, cmd, ver, dummynet_load, dummynet_unload, lkm_nullcmd); } #endif