/* * This protocol is compatible with UDP's packet format. * It could be done over UDP if need be. */ #include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" #include "ip.h" #define DEBUG 0 #define DPRINT if(DEBUG)print #define SEQDIFF(a,b) ( (a)>=(b)?\ (a)-(b):\ 0xffffffffUL-((b)-(a)) ) #define INSEQ(a,start,end) ( (start)<=(end)?\ ((a)>(start)&&(a)<=(end)):\ ((a)>(start)||(a)<=(end)) ) #define UNACKED(r) SEQDIFF(r->sndseq, r->ackrcvd) #define NEXTSEQ(a) ( (a)+1 == 0 ? 1 : (a)+1 ) enum { UDP_HDRSIZE = 20, /* pseudo header + udp header */ UDP_PHDRSIZE = 12, /* pseudo header */ UDP_RHDRSIZE = 36, /* pseudo header + udp header + rudp header */ UDP_IPHDR = 8, /* ip header */ IP_UDPPROTO = 254, UDP_USEAD7 = 52, UDP_USEAD6 = 36, UDP_USEAD4 = 12, Rudprxms = 200, Rudptickms = 50, Rudpmaxxmit = 10, Maxunacked = 100, }; #define Hangupgen 0xffffffff /* used only in hangup messages */ typedef struct Udphdr Udphdr; struct Udphdr { /* ip header */ uchar vihl; /* Version and header length */ uchar tos; /* Type of service */ uchar length[2]; /* packet length */ uchar id[2]; /* Identification */ uchar frag[2]; /* Fragment information */ /* pseudo header starts here */ uchar Unused; uchar udpproto; /* Protocol */ uchar udpplen[2]; /* Header plus data length */ uchar udpsrc[4]; /* Ip source */ uchar udpdst[4]; /* Ip destination */ /* udp header */ uchar udpsport[2]; /* Source port */ uchar udpdport[2]; /* Destination port */ uchar udplen[2]; /* data length */ uchar udpcksum[2]; /* Checksum */ }; typedef struct Rudphdr Rudphdr; struct Rudphdr { /* ip header */ uchar vihl; /* Version and header length */ uchar tos; /* Type of service */ uchar length[2]; /* packet length */ uchar id[2]; /* Identification */ uchar frag[2]; /* Fragment information */ /* pseudo header starts here */ uchar Unused; uchar udpproto; /* Protocol */ uchar udpplen[2]; /* Header plus data length */ uchar udpsrc[4]; /* Ip source */ uchar udpdst[4]; /* Ip destination */ /* udp header */ uchar udpsport[2]; /* Source port */ uchar udpdport[2]; /* Destination port */ uchar udplen[2]; /* data length (includes rudp header) */ uchar udpcksum[2]; /* Checksum */ /* rudp header */ uchar relseq[4]; /* id of this packet (or 0) */ uchar relsgen[4]; /* generation/time stamp */ uchar relack[4]; /* packet being acked (or 0) */ uchar relagen[4]; /* generation/time stamp */ }; /* * one state structure per destination */ typedef struct Reliable Reliable; struct Reliable { Ref; Reliable *next; uchar addr[IPaddrlen]; /* always V6 when put here */ ushort port; Block *unacked; /* unacked msg list */ Block *unackedtail; /* and its tail */ int timeout; /* time since first unacked msg sent */ int xmits; /* number of times first unacked msg sent */ ulong sndseq; /* next packet to be sent */ ulong sndgen; /* and its generation */ ulong rcvseq; /* last packet received */ ulong rcvgen; /* and its generation */ ulong acksent; /* last ack sent */ ulong ackrcvd; /* last msg for which ack was rcvd */ /* flow control */ QLock lock; Rendez vous; int blocked; }; /* MIB II counters */ typedef struct Rudpstats Rudpstats; struct Rudpstats { ulong rudpInDatagrams; ulong rudpNoPorts; ulong rudpInErrors; ulong rudpOutDatagrams; }; typedef struct Rudppriv Rudppriv; struct Rudppriv { Ipht ht; /* MIB counters */ Rudpstats ustats; /* non-MIB stats */ ulong csumerr; /* checksum errors */ ulong lenerr; /* short packet */ ulong rxmits; /* # of retransmissions */ ulong orders; /* # of out of order pkts */ /* keeping track of the ack kproc */ int ackprocstarted; QLock apl; }; static ulong generation = 0; static Rendez rend; /* * protocol specific part of Conv */ typedef struct Rudpcb Rudpcb; struct Rudpcb { QLock; uchar headers; uchar randdrop; Reliable *r; }; /* * local functions */ void relsendack(Conv*, Reliable*, int); int reliput(Conv*, Block*, uchar*, ushort); Reliable *relstate(Rudpcb*, uchar*, ushort, char*); void relput(Reliable*); void relforget(Conv *, uchar*, int, int); void relackproc(void *); void relackq(Reliable *, Block*); void relhangup(Conv *, Reliable*); void relrexmit(Conv *, Reliable*); void relput(Reliable*); void rudpkick(void *x); static void rudpstartackproc(Proto *rudp) { Rudppriv *rpriv; char kpname[KNAMELEN]; rpriv = rudp->priv; if(rpriv->ackprocstarted == 0){ qlock(&rpriv->apl); if(rpriv->ackprocstarted == 0){ sprint(kpname, "#I%drudpack", rudp->f->dev); kproc(kpname, relackproc, rudp); rpriv->ackprocstarted = 1; } qunlock(&rpriv->apl); } } static char* rudpconnect(Conv *c, char **argv, int argc) { char *e; Rudppriv *upriv; upriv = c->p->priv; rudpstartackproc(c->p); e = Fsstdconnect(c, argv, argc); Fsconnected(c, e); iphtadd(&upriv->ht, c); return e; } static int rudpstate(Conv *c, char *state, int n) { Rudpcb *ucb; Reliable *r; int m; m = snprint(state, n, "%s", c->inuse?"Open":"Closed"); ucb = (Rudpcb*)c->ptcl; qlock(ucb); for(r = ucb->r; r; r = r->next) m += snprint(state+m, n-m, " %I/%ld", r->addr, UNACKED(r)); qunlock(ucb); return m; } static char* rudpannounce(Conv *c, char** argv, int argc) { char *e; Rudppriv *upriv; upriv = c->p->priv; rudpstartackproc(c->p); e = Fsstdannounce(c, argv, argc); if(e != nil) return e; Fsconnected(c, nil); iphtadd(&upriv->ht, c); return nil; } static void rudpcreate(Conv *c) { c->rq = qopen(64*1024, Qmsg, 0, 0); c->wq = qopen(64*1024, Qkick, rudpkick, c); } static void rudpclose(Conv *c) { Rudpcb *ucb; Reliable *r, *nr; Rudppriv *upriv; upriv = c->p->priv; iphtrem(&upriv->ht, c); /* force out any delayed acks */ ucb = (Rudpcb*)c->ptcl; qlock(ucb); for(r = ucb->r; r; r = r->next){ if(r->acksent != r->rcvseq) relsendack(c, r, 0); } qunlock(ucb); qclose(c->rq); qclose(c->wq); qclose(c->eq); ipmove(c->laddr, IPnoaddr); ipmove(c->raddr, IPnoaddr); c->lport = 0; c->rport = 0; ucb->headers = 0; ucb->randdrop = 0; qlock(ucb); for(r = ucb->r; r; r = nr){ if(r->acksent != r->rcvseq) relsendack(c, r, 0); nr = r->next; relhangup(c, r); relput(r); } ucb->r = 0; qunlock(ucb); } /* * randomly don't send packets */ static void doipoput(Conv *c, Fs *f, Block *bp, int x, int ttl, int tos) { Rudpcb *ucb; ucb = (Rudpcb*)c->ptcl; if(ucb->randdrop && nrand(100) < ucb->randdrop) freeblist(bp); else ipoput4(f, bp, x, ttl, tos, nil); } int flow(void *v) { Reliable *r = v; return UNACKED(r) <= Maxunacked; } void rudpkick(void *x) { Conv *c = x; Udphdr *uh; ushort rport; uchar laddr[IPaddrlen], raddr[IPaddrlen]; Block *bp; Rudpcb *ucb; Rudphdr *rh; Reliable *r; int dlen, ptcllen; Rudppriv *upriv; Fs *f; upriv = c->p->priv; f = c->p->f; netlog(c->p->f, Logrudp, "rudp: kick\n"); bp = qget(c->wq); if(bp == nil) return; ucb = (Rudpcb*)c->ptcl; switch(ucb->headers) { case 7: /* get user specified addresses */ bp = pullupblock(bp, UDP_USEAD7); if(bp == nil) return; ipmove(raddr, bp->rp); bp->rp += IPaddrlen; ipmove(laddr, bp->rp); bp->rp += IPaddrlen; /* pick interface closest to dest */ if(ipforme(f, laddr) != Runi) findlocalip(f, laddr, raddr); bp->rp += IPaddrlen; /* Ignore ifc address */ rport = nhgets(bp->rp); bp->rp += 2+2; /* Ignore local port */ break; case 6: /* OBS */ /* get user specified addresses */ bp = pullupblock(bp, UDP_USEAD6); if(bp == nil) return; ipmove(raddr, bp->rp); bp->rp += IPaddrlen; ipmove(laddr, bp->rp); bp->rp += IPaddrlen; /* pick interface closest to dest */ if(ipforme(f, laddr) != Runi) findlocalip(f, laddr, raddr); rport = nhgets(bp->rp); bp->rp += 4; /* Igonore local port */ break; default: ipmove(raddr, c->raddr); ipmove(laddr, c->laddr); rport = c->rport; break; } dlen = blocklen(bp); /* Make space to fit rudp & ip header */ bp = padblock(bp, UDP_IPHDR+UDP_RHDRSIZE); if(bp == nil) return; uh = (Udphdr *)(bp->rp); uh->vihl = IP_VER4; rh = (Rudphdr*)uh; ptcllen = dlen + (UDP_RHDRSIZE-UDP_PHDRSIZE); uh->Unused = 0; uh->udpproto = IP_UDPPROTO; uh->frag[0] = 0; uh->frag[1] = 0; hnputs(uh->udpplen, ptcllen); switch(ucb->headers){ case 6: /* OBS */ case 7: v6tov4(uh->udpdst, raddr); hnputs(uh->udpdport, rport); v6tov4(uh->udpsrc, laddr); break; default: v6tov4(uh->udpdst, c->raddr); hnputs(uh->udpdport, c->rport); if(ipcmp(c->laddr, IPnoaddr) == 0) findlocalip(f, c->laddr, c->raddr); v6tov4(uh->udpsrc, c->laddr); break; } hnputs(uh->udpsport, c->lport); hnputs(uh->udplen, ptcllen); uh->udpcksum[0] = 0; uh->udpcksum[1] = 0; qlock(ucb); r = relstate(ucb, raddr, rport, "kick"); r->sndseq = NEXTSEQ(r->sndseq); hnputl(rh->relseq, r->sndseq); hnputl(rh->relsgen, r->sndgen); hnputl(rh->relack, r->rcvseq); /* ACK last rcvd packet */ hnputl(rh->relagen, r->rcvgen); if(r->rcvseq != r->acksent) r->acksent = r->rcvseq; hnputs(uh->udpcksum, ptclcsum(bp, UDP_IPHDR, dlen+UDP_RHDRSIZE)); relackq(r, bp); qunlock(ucb); upriv->ustats.rudpOutDatagrams++; DPRINT("sent: %lud/%lud, %lud/%lud\n", r->sndseq, r->sndgen, r->rcvseq, r->rcvgen); doipoput(c, f, bp, 0, c->ttl, c->tos); if(waserror()) { relput(r); qunlock(&r->lock); nexterror(); } /* flow control of sorts */ qlock(&r->lock); if(UNACKED(r) > Maxunacked){ r->blocked = 1; sleep(&r->vous, flow, r); r->blocked = 0; } qunlock(&r->lock); relput(r); poperror(); } void rudpiput(Proto *rudp, Ipifc *ifc, Block *bp) { int len, olen, ottl; Udphdr *uh; Conv *c; Rudpcb *ucb; uchar raddr[IPaddrlen], laddr[IPaddrlen]; ushort rport, lport; Rudppriv *upriv; Fs *f; uchar *p; upriv = rudp->priv; f = rudp->f; upriv->ustats.rudpInDatagrams++; uh = (Udphdr*)(bp->rp); /* Put back pseudo header for checksum * (remember old values for icmpnoconv()) */ ottl = uh->Unused; uh->Unused = 0; len = nhgets(uh->udplen); olen = nhgets(uh->udpplen); hnputs(uh->udpplen, len); v4tov6(raddr, uh->udpsrc); v4tov6(laddr, uh->udpdst); lport = nhgets(uh->udpdport); rport = nhgets(uh->udpsport); if(nhgets(uh->udpcksum)) { if(ptclcsum(bp, UDP_IPHDR, len+UDP_PHDRSIZE)) { upriv->ustats.rudpInErrors++; upriv->csumerr++; netlog(f, Logrudp, "rudp: checksum error %I\n", raddr); DPRINT("rudp: checksum error %I\n", raddr); freeblist(bp); return; } } qlock(rudp); c = iphtlook(&upriv->ht, raddr, rport, laddr, lport); if(c == nil){ /* no converstation found */ upriv->ustats.rudpNoPorts++; qunlock(rudp); netlog(f, Logudp, "udp: no conv %I!%d -> %I!%d\n", raddr, rport, laddr, lport); uh->Unused = ottl; hnputs(uh->udpplen, olen); icmpnoconv(f, bp); freeblist(bp); return; } ucb = (Rudpcb*)c->ptcl; qlock(ucb); qunlock(rudp); if(reliput(c, bp, raddr, rport) < 0){ qunlock(ucb); freeb(bp); return; } /* * Trim the packet down to data size */ len -= (UDP_RHDRSIZE-UDP_PHDRSIZE); bp = trimblock(bp, UDP_IPHDR+UDP_RHDRSIZE, len); if(bp == nil) { netlog(f, Logrudp, "rudp: len err %I.%d -> %I.%d\n", raddr, rport, laddr, lport); DPRINT("rudp: len err %I.%d -> %I.%d\n", raddr, rport, laddr, lport); upriv->lenerr++; return; } netlog(f, Logrudpmsg, "rudp: %I.%d -> %I.%d l %d\n", raddr, rport, laddr, lport, len); switch(ucb->headers){ case 7: /* pass the src address */ bp = padblock(bp, UDP_USEAD7); p = bp->rp; ipmove(p, raddr); p += IPaddrlen; ipmove(p, laddr); p += IPaddrlen; ipmove(p, ifc->lifc->local); p += IPaddrlen; hnputs(p, rport); p += 2; hnputs(p, lport); break; case 6: /* OBS */ /* pass the src address */ bp = padblock(bp, UDP_USEAD6); p = bp->rp; ipmove(p, raddr); p += IPaddrlen; ipmove(p, ipforme(f, laddr)==Runi ? laddr : ifc->lifc->local); p += IPaddrlen; hnputs(p, rport); p += 2; hnputs(p, lport); break; default: /* connection oriented rudp */ if(ipcmp(c->raddr, IPnoaddr) == 0){ /* save the src address in the conversation */ ipmove(c->raddr, raddr); c->rport = rport; /* reply with the same ip address (if not broadcast) */ if(ipforme(f, laddr) == Runi) ipmove(c->laddr, laddr); else v4tov6(c->laddr, ifc->lifc->local); } break; } if(bp->next) bp = concatblock(bp); if(qfull(c->rq)) { netlog(f, Logrudp, "rudp: qfull %I.%d -> %I.%d\n", raddr, rport, laddr, lport); freeblist(bp); } else qpass(c->rq, bp); qunlock(ucb); } static char *rudpunknown = "unknown rudp ctl request"; char* rudpctl(Conv *c, char **f, int n) { Rudpcb *ucb; uchar ip[IPaddrlen]; int x; ucb = (Rudpcb*)c->ptcl; if(n < 1) return rudpunknown; if(strcmp(f[0], "headers++4") == 0){ ucb->headers = 7; /* new headers format */ return nil; } else if(strcmp(f[0], "headers") == 0){ /* OBS */ ucb->headers = 6; return nil; } else if(strcmp(f[0], "hangup") == 0){ if(n < 3) return "bad syntax"; parseip(ip, f[1]); x = atoi(f[2]); qlock(ucb); relforget(c, ip, x, 1); qunlock(ucb); return nil; } else if(strcmp(f[0], "randdrop") == 0){ x = 10; /* default is 10% */ if(n > 1) x = atoi(f[1]); if(x > 100 || x < 0) return "illegal rudp drop rate"; ucb->randdrop = x; return nil; } return rudpunknown; } void rudpadvise(Proto *rudp, Block *bp, char *msg) { Udphdr *h; uchar source[IPaddrlen], dest[IPaddrlen]; ushort psource, pdest; Conv *s, **p; h = (Udphdr*)(bp->rp); v4tov6(dest, h->udpdst); v4tov6(source, h->udpsrc); psource = nhgets(h->udpsport); pdest = nhgets(h->udpdport); /* Look for a connection */ for(p = rudp->conv; *p; p++) { s = *p; if(s->rport == pdest) if(s->lport == psource) if(ipcmp(s->raddr, dest) == 0) if(ipcmp(s->laddr, source) == 0){ qhangup(s->rq, msg); qhangup(s->wq, msg); break; } } freeblist(bp); } int rudpstats(Proto *rudp, char *buf, int len) { Rudppriv *upriv; upriv = rudp->priv; return snprint(buf, len, "%lud %lud %lud %lud %lud %lud\n", upriv->ustats.rudpInDatagrams, upriv->ustats.rudpNoPorts, upriv->ustats.rudpInErrors, upriv->ustats.rudpOutDatagrams, upriv->rxmits, upriv->orders); } void rudpinit(Fs *fs) { Proto *rudp; rudp = smalloc(sizeof(Proto)); rudp->priv = smalloc(sizeof(Rudppriv)); rudp->name = "rudp"; rudp->connect = rudpconnect; rudp->announce = rudpannounce; rudp->ctl = rudpctl; rudp->state = rudpstate; rudp->create = rudpcreate; rudp->close = rudpclose; rudp->rcv = rudpiput; rudp->advise = rudpadvise; rudp->stats = rudpstats; rudp->ipproto = IP_UDPPROTO; rudp->nc = 16; rudp->ptclsize = sizeof(Rudpcb); Fsproto(fs, rudp); } /*********************************************/ /* Here starts the reliable helper functions */ /*********************************************/ /* * Enqueue a copy of an unacked block for possible retransmissions */ void relackq(Reliable *r, Block *bp) { Block *np; np = copyblock(bp, blocklen(bp)); if(r->unacked) r->unackedtail->list = np; else { /* restart timer */ r->timeout = 0; r->xmits = 1; r->unacked = np; } r->unackedtail = np; np->list = nil; } /* * retransmit unacked blocks */ void relackproc(void *a) { Rudpcb *ucb; Proto *rudp; Reliable *r; Conv **s, *c; rudp = (Proto *)a; loop: tsleep(&up->sleep, return0, 0, Rudptickms); for(s = rudp->conv; *s; s++) { c = *s; ucb = (Rudpcb*)c->ptcl; qlock(ucb); for(r = ucb->r; r; r = r->next) { if(r->unacked != nil){ r->timeout += Rudptickms; if(r->timeout > Rudprxms*r->xmits) relrexmit(c, r); } if(r->acksent != r->rcvseq) relsendack(c, r, 0); } qunlock(ucb); } goto loop; } /* * get the state record for a conversation */ Reliable* relstate(Rudpcb *ucb, uchar *addr, ushort port, char *from) { Reliable *r, **l; l = &ucb->r; for(r = *l; r; r = *l){ if(memcmp(addr, r->addr, IPaddrlen) == 0 && port == r->port) break; l = &r->next; } /* no state for this addr/port, create some */ if(r == nil){ while(generation == 0) generation = rand(); DPRINT("from %s new state %lud for %I!%ud\n", from, generation, addr, port); r = smalloc(sizeof(Reliable)); memmove(r->addr, addr, IPaddrlen); r->port = port; r->unacked = 0; if(generation == Hangupgen) generation++; r->sndgen = generation++; r->sndseq = 0; r->ackrcvd = 0; r->rcvgen = 0; r->rcvseq = 0; r->acksent = 0; r->xmits = 0; r->timeout = 0; r->ref = 0; incref(r); /* one reference for being in the list */ *l = r; } incref(r); return r; } void relput(Reliable *r) { if(decref(r) == 0) free(r); } /* * forget a Reliable state */ void relforget(Conv *c, uchar *ip, int port, int originator) { Rudpcb *ucb; Reliable *r, **l; ucb = (Rudpcb*)c->ptcl; l = &ucb->r; for(r = *l; r; r = *l){ if(ipcmp(ip, r->addr) == 0 && port == r->port){ *l = r->next; if(originator) relsendack(c, r, 1); relhangup(c, r); relput(r); /* remove from the list */ break; } l = &r->next; } } /* * process a rcvd reliable packet. return -1 if not to be passed to user process, * 0 therwise. * * called with ucb locked. */ int reliput(Conv *c, Block *bp, uchar *addr, ushort port) { Block *nbp; Rudpcb *ucb; Rudppriv *upriv; Udphdr *uh; Reliable *r; Rudphdr *rh; ulong seq, ack, sgen, agen, ackreal; int rv = -1; /* get fields */ uh = (Udphdr*)(bp->rp); rh = (Rudphdr*)uh; seq = nhgetl(rh->relseq); sgen = nhgetl(rh->relsgen); ack = nhgetl(rh->relack); agen = nhgetl(rh->relagen); upriv = c->p->priv; ucb = (Rudpcb*)c->ptcl; r = relstate(ucb, addr, port, "input"); DPRINT("rcvd %lud/%lud, %lud/%lud, r->sndgen = %lud\n", seq, sgen, ack, agen, r->sndgen); /* if acking an incorrect generation, ignore */ if(ack && agen != r->sndgen) goto out; /* Look for a hangup */ if(sgen == Hangupgen) { if(agen == r->sndgen) relforget(c, addr, port, 0); goto out; } /* make sure we're not talking to a new remote side */ if(r->rcvgen != sgen){ if(seq != 0 && seq != 1) goto out; /* new connection */ if(r->rcvgen != 0){ DPRINT("new con r->rcvgen = %lud, sgen = %lud\n", r->rcvgen, sgen); relhangup(c, r); } r->rcvgen = sgen; } /* dequeue acked packets */ if(ack && agen == r->sndgen){ ackreal = 0; while(r->unacked != nil && INSEQ(ack, r->ackrcvd, r->sndseq)){ nbp = r->unacked; r->unacked = nbp->list; DPRINT("%lud/%lud acked, r->sndgen = %lud\n", ack, agen, r->sndgen); freeb(nbp); r->ackrcvd = NEXTSEQ(r->ackrcvd); ackreal = 1; } /* flow control */ if(UNACKED(r) < Maxunacked/8 && r->blocked) wakeup(&r->vous); /* * retransmit next packet if the acked packet * was transmitted more than once */ if(ackreal && r->unacked != nil){ r->timeout = 0; if(r->xmits > 1){ r->xmits = 1; relrexmit(c, r); } } } /* no message or input queue full */ if(seq == 0 || qfull(c->rq)) goto out; /* refuse out of order delivery */ if(seq != NEXTSEQ(r->rcvseq)){ relsendack(c, r, 0); /* tell him we got it already */ upriv->orders++; DPRINT("out of sequence %lud not %lud\n", seq, NEXTSEQ(r->rcvseq)); goto out; } r->rcvseq = seq; rv = 0; out: relput(r); return rv; } void relsendack(Conv *c, Reliable *r, int hangup) { Udphdr *uh; Block *bp; Rudphdr *rh; int ptcllen; Fs *f; bp = allocb(UDP_IPHDR + UDP_RHDRSIZE); if(bp == nil) return; bp->wp += UDP_IPHDR + UDP_RHDRSIZE; f = c->p->f; uh = (Udphdr *)(bp->rp); uh->vihl = IP_VER4; rh = (Rudphdr*)uh; ptcllen = (UDP_RHDRSIZE-UDP_PHDRSIZE); uh->Unused = 0; uh->udpproto = IP_UDPPROTO; uh->frag[0] = 0; uh->frag[1] = 0; hnputs(uh->udpplen, ptcllen); v6tov4(uh->udpdst, r->addr); hnputs(uh->udpdport, r->port); hnputs(uh->udpsport, c->lport); if(ipcmp(c->laddr, IPnoaddr) == 0) findlocalip(f, c->laddr, c->raddr); v6tov4(uh->udpsrc, c->laddr); hnputs(uh->udplen, ptcllen); if(hangup) hnputl(rh->relsgen, Hangupgen); else hnputl(rh->relsgen, r->sndgen); hnputl(rh->relseq, 0); hnputl(rh->relagen, r->rcvgen); hnputl(rh->relack, r->rcvseq); if(r->acksent < r->rcvseq) r->acksent = r->rcvseq; uh->udpcksum[0] = 0; uh->udpcksum[1] = 0; hnputs(uh->udpcksum, ptclcsum(bp, UDP_IPHDR, UDP_RHDRSIZE)); DPRINT("sendack: %lud/%lud, %lud/%lud\n", 0L, r->sndgen, r->rcvseq, r->rcvgen); doipoput(c, f, bp, 0, c->ttl, c->tos); } /* * called with ucb locked (and c locked if user initiated close) */ void relhangup(Conv *c, Reliable *r) { int n; Block *bp; char hup[ERRMAX]; n = snprint(hup, sizeof(hup), "hangup %I!%d", r->addr, r->port); qproduce(c->eq, hup, n); /* * dump any unacked outgoing messages */ for(bp = r->unacked; bp != nil; bp = r->unacked){ r->unacked = bp->list; bp->list = nil; freeb(bp); } r->rcvgen = 0; r->rcvseq = 0; r->acksent = 0; if(generation == Hangupgen) generation++; r->sndgen = generation++; r->sndseq = 0; r->ackrcvd = 0; r->xmits = 0; r->timeout = 0; wakeup(&r->vous); } /* * called with ucb locked */ void relrexmit(Conv *c, Reliable *r) { Rudppriv *upriv; Block *np; Fs *f; upriv = c->p->priv; f = c->p->f; r->timeout = 0; if(r->xmits++ > Rudpmaxxmit){ relhangup(c, r); return; } upriv->rxmits++; np = copyblock(r->unacked, blocklen(r->unacked)); DPRINT("rxmit r->ackrvcd+1 = %lud\n", r->ackrcvd+1); doipoput(c, f, np, 0, c->ttl, c->tos); }