/* * Copyright (c) 1990,1994 Regents of The University of Michigan. * All Rights Reserved. See COPYRIGHT. * * $DragonFly: src/sys/netproto/atalk/ddp_usrreq.c,v 1.9 2005/06/10 22:43:58 dillon Exp $ */ #include #include #include #include #include #include #include #include #include #include #include #include #include "at.h" #include "at_var.h" #include "ddp_var.h" #include "at_extern.h" static void at_pcbdisconnect( struct ddpcb *ddp ); static void at_sockaddr(struct ddpcb *ddp, struct sockaddr **addr); static int at_pcbsetaddr(struct ddpcb *ddp, struct sockaddr *addr, struct thread *td); static int at_pcbconnect(struct ddpcb *ddp, struct sockaddr *addr, struct thread *td); static void at_pcbdetach(struct socket *so, struct ddpcb *ddp); static int at_pcballoc(struct socket *so); struct ddpcb *ddp_ports[ ATPORT_LAST ]; struct ddpcb *ddpcb = NULL; static u_long ddp_sendspace = DDP_MAXSZ; /* Max ddp size + 1 (ddp_type) */ static u_long ddp_recvspace = 10 * ( 587 + sizeof( struct sockaddr_at )); static int ddp_attach(struct socket *so, int proto, struct pru_attach_info *ai) { struct ddpcb *ddp; int error = 0; ddp = sotoddpcb( so ); if ( ddp != NULL ) { return( EINVAL); } crit_enter(); error = at_pcballoc( so ); crit_exit(); if (error) { return (error); } return (soreserve( so, ddp_sendspace, ddp_recvspace, ai->sb_rlimit )); } static int ddp_detach(struct socket *so) { struct ddpcb *ddp; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } crit_enter(); at_pcbdetach( so, ddp ); crit_exit(); return(0); } static int ddp_bind(struct socket *so, struct sockaddr *nam, struct thread *td) { struct ddpcb *ddp; int error = 0; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } crit_enter(); error = at_pcbsetaddr(ddp, nam, td); crit_exit(); return (error); } static int ddp_connect(struct socket *so, struct sockaddr *nam, struct thread *td) { struct ddpcb *ddp; int error = 0; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } if ( ddp->ddp_fsat.sat_port != ATADDR_ANYPORT ) { return(EISCONN); } crit_enter(); error = at_pcbconnect( ddp, nam, td ); crit_exit(); if ( error == 0 ) soisconnected( so ); return(error); } static int ddp_disconnect(struct socket *so) { struct ddpcb *ddp; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } if ( ddp->ddp_fsat.sat_addr.s_node == ATADDR_ANYNODE ) { return(ENOTCONN); } crit_enter(); at_pcbdisconnect( ddp ); ddp->ddp_fsat.sat_addr.s_node = ATADDR_ANYNODE; crit_exit(); soisdisconnected( so ); return(0); } static int ddp_shutdown(struct socket *so) { struct ddpcb *ddp; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } socantsendmore( so ); return(0); } static int ddp_send(struct socket *so, int flags, struct mbuf *m, struct sockaddr *addr, struct mbuf *control, struct thread *td) { struct ddpcb *ddp; int error = 0; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return(EINVAL); } if ( control && control->m_len ) { return(EINVAL); } if ( addr ) { if ( ddp->ddp_fsat.sat_port != ATADDR_ANYPORT ) { return(EISCONN); } crit_enter(); error = at_pcbconnect(ddp, addr, td); crit_exit(); if ( error ) { return(error); } } else { if ( ddp->ddp_fsat.sat_port == ATADDR_ANYPORT ) { return(ENOTCONN); } } crit_enter(); error = ddp_output( m, so ); if ( addr ) { at_pcbdisconnect( ddp ); } crit_exit(); return(error); } static int ddp_abort(struct socket *so) { struct ddpcb *ddp; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return(EINVAL); } soisdisconnected( so ); crit_enter(); at_pcbdetach( so, ddp ); crit_exit(); return(0); } static void at_sockaddr(struct ddpcb *ddp, struct sockaddr **addr) { *addr = dup_sockaddr((struct sockaddr *)&ddp->ddp_lsat); } static int at_pcbsetaddr(struct ddpcb *ddp, struct sockaddr *addr, struct thread *td) { struct sockaddr_at lsat, *sat; struct at_ifaddr *aa; struct ddpcb *ddpp; if ( ddp->ddp_lsat.sat_port != ATADDR_ANYPORT ) { /* shouldn't be bound */ return( EINVAL ); } if (addr != 0) { /* validate passed address */ sat = (struct sockaddr_at *)addr; if (sat->sat_family != AF_APPLETALK) { return(EAFNOSUPPORT); } if ( sat->sat_addr.s_node != ATADDR_ANYNODE || sat->sat_addr.s_net != ATADDR_ANYNET ) { for ( aa = at_ifaddr; aa; aa = aa->aa_next ) { if (( sat->sat_addr.s_net == AA_SAT( aa )->sat_addr.s_net ) && ( sat->sat_addr.s_node == AA_SAT( aa )->sat_addr.s_node )) { break; } } if ( !aa ) { return( EADDRNOTAVAIL ); } } if ( sat->sat_port != ATADDR_ANYPORT ) { if ( sat->sat_port < ATPORT_FIRST || sat->sat_port >= ATPORT_LAST ) { return( EINVAL ); } if ( sat->sat_port < ATPORT_RESERVED && suser(td) ) { return( EACCES ); } } } else { bzero( (caddr_t)&lsat, sizeof( struct sockaddr_at )); lsat.sat_len = sizeof(struct sockaddr_at); lsat.sat_addr.s_node = ATADDR_ANYNODE; lsat.sat_addr.s_net = ATADDR_ANYNET; lsat.sat_family = AF_APPLETALK; sat = &lsat; } if ( sat->sat_addr.s_node == ATADDR_ANYNODE && sat->sat_addr.s_net == ATADDR_ANYNET ) { if ( at_ifaddr == NULL ) { return( EADDRNOTAVAIL ); } sat->sat_addr = AA_SAT( at_ifaddr )->sat_addr; } ddp->ddp_lsat = *sat; /* * Choose port. */ if ( sat->sat_port == ATADDR_ANYPORT ) { for ( sat->sat_port = ATPORT_RESERVED; sat->sat_port < ATPORT_LAST; sat->sat_port++ ) { if ( ddp_ports[ sat->sat_port - 1 ] == 0 ) { break; } } if ( sat->sat_port == ATPORT_LAST ) { return( EADDRNOTAVAIL ); } ddp->ddp_lsat.sat_port = sat->sat_port; ddp_ports[ sat->sat_port - 1 ] = ddp; } else { for ( ddpp = ddp_ports[ sat->sat_port - 1 ]; ddpp; ddpp = ddpp->ddp_pnext ) { if ( ddpp->ddp_lsat.sat_addr.s_net == sat->sat_addr.s_net && ddpp->ddp_lsat.sat_addr.s_node == sat->sat_addr.s_node ) { break; } } if ( ddpp != NULL ) { return( EADDRINUSE ); } ddp->ddp_pnext = ddp_ports[ sat->sat_port - 1 ]; ddp_ports[ sat->sat_port - 1 ] = ddp; if ( ddp->ddp_pnext ) { ddp->ddp_pnext->ddp_pprev = ddp; } } return( 0 ); } static int at_pcbconnect(struct ddpcb *ddp, struct sockaddr *addr, struct thread *td) { struct sockaddr_at *sat = (struct sockaddr_at *)addr; struct route *ro; struct at_ifaddr *aa = 0; struct ifnet *ifp; u_short hintnet = 0, net; if (sat->sat_family != AF_APPLETALK) { return(EAFNOSUPPORT); } /* * Under phase 2, network 0 means "the network". We take "the * network" to mean the network the control block is bound to. * If the control block is not bound, there is an error. */ if ( sat->sat_addr.s_net == ATADDR_ANYNET && sat->sat_addr.s_node != ATADDR_ANYNODE ) { if ( ddp->ddp_lsat.sat_port == ATADDR_ANYPORT ) { return( EADDRNOTAVAIL ); } hintnet = ddp->ddp_lsat.sat_addr.s_net; } ro = &ddp->ddp_route; /* * If we've got an old route for this pcb, check that it is valid. * If we've changed our address, we may have an old "good looking" * route here. Attempt to detect it. */ if ( ro->ro_rt ) { if ( hintnet ) { net = hintnet; } else { net = sat->sat_addr.s_net; } aa = 0; if ((ifp = ro->ro_rt->rt_ifp) != NULL) { for ( aa = at_ifaddr; aa; aa = aa->aa_next ) { if ( aa->aa_ifp == ifp && ntohs( net ) >= ntohs( aa->aa_firstnet ) && ntohs( net ) <= ntohs( aa->aa_lastnet )) { break; } } } if ( aa == NULL || ( satosat( &ro->ro_dst )->sat_addr.s_net != ( hintnet ? hintnet : sat->sat_addr.s_net ) || satosat( &ro->ro_dst )->sat_addr.s_node != sat->sat_addr.s_node )) { RTFREE( ro->ro_rt ); ro->ro_rt = (struct rtentry *)0; } } /* * If we've got no route for this interface, try to find one. */ if ( ro->ro_rt == (struct rtentry *)0 || ro->ro_rt->rt_ifp == (struct ifnet *)0 ) { ro->ro_dst.sa_len = sizeof( struct sockaddr_at ); ro->ro_dst.sa_family = AF_APPLETALK; if ( hintnet ) { satosat( &ro->ro_dst )->sat_addr.s_net = hintnet; } else { satosat( &ro->ro_dst )->sat_addr.s_net = sat->sat_addr.s_net; } satosat( &ro->ro_dst )->sat_addr.s_node = sat->sat_addr.s_node; rtalloc( ro ); } /* * Make sure any route that we have has a valid interface. */ aa = 0; if ( ro->ro_rt && ( ifp = ro->ro_rt->rt_ifp )) { for ( aa = at_ifaddr; aa; aa = aa->aa_next ) { if ( aa->aa_ifp == ifp ) { break; } } } if ( aa == 0 ) { return( ENETUNREACH ); } ddp->ddp_fsat = *sat; if ( ddp->ddp_lsat.sat_port == ATADDR_ANYPORT ) { return(at_pcbsetaddr(ddp, (struct sockaddr *)0, td)); } return( 0 ); } static void at_pcbdisconnect( struct ddpcb *ddp ) { ddp->ddp_fsat.sat_addr.s_net = ATADDR_ANYNET; ddp->ddp_fsat.sat_addr.s_node = ATADDR_ANYNODE; ddp->ddp_fsat.sat_port = ATADDR_ANYPORT; } static int at_pcballoc( struct socket *so ) { struct ddpcb *ddp; MALLOC(ddp, struct ddpcb *, sizeof *ddp, M_PCB, M_WAITOK); bzero(ddp, sizeof *ddp); ddp->ddp_lsat.sat_port = ATADDR_ANYPORT; ddp->ddp_next = ddpcb; ddp->ddp_prev = NULL; ddp->ddp_pprev = NULL; ddp->ddp_pnext = NULL; if (ddpcb) { ddpcb->ddp_prev = ddp; } ddpcb = ddp; ddp->ddp_socket = so; so->so_pcb = (caddr_t)ddp; return(0); } static void at_pcbdetach( struct socket *so, struct ddpcb *ddp) { soisdisconnected( so ); so->so_pcb = 0; sofree( so ); /* remove ddp from ddp_ports list */ if ( ddp->ddp_lsat.sat_port != ATADDR_ANYPORT && ddp_ports[ ddp->ddp_lsat.sat_port - 1 ] != NULL ) { if ( ddp->ddp_pprev != NULL ) { ddp->ddp_pprev->ddp_pnext = ddp->ddp_pnext; } else { ddp_ports[ ddp->ddp_lsat.sat_port - 1 ] = ddp->ddp_pnext; } if ( ddp->ddp_pnext != NULL ) { ddp->ddp_pnext->ddp_pprev = ddp->ddp_pprev; } } if ( ddp->ddp_route.ro_rt ) { rtfree( ddp->ddp_route.ro_rt ); } if ( ddp->ddp_prev ) { ddp->ddp_prev->ddp_next = ddp->ddp_next; } else { ddpcb = ddp->ddp_next; } if ( ddp->ddp_next ) { ddp->ddp_next->ddp_prev = ddp->ddp_prev; } FREE(ddp, M_PCB); } /* * For the moment, this just find the pcb with the correct local address. * In the future, this will actually do some real searching, so we can use * the sender's address to do de-multiplexing on a single port to many * sockets (pcbs). */ struct ddpcb * ddp_search( struct sockaddr_at *from, struct sockaddr_at *to, struct at_ifaddr *aa) { struct ddpcb *ddp; /* * Check for bad ports. */ if ( to->sat_port < ATPORT_FIRST || to->sat_port >= ATPORT_LAST ) { return( NULL ); } /* * Make sure the local address matches the sent address. What about * the interface? */ for ( ddp = ddp_ports[ to->sat_port - 1 ]; ddp; ddp = ddp->ddp_pnext ) { /* XXX should we handle 0.YY? */ /* XXXX.YY to socket on destination interface */ if ( to->sat_addr.s_net == ddp->ddp_lsat.sat_addr.s_net && to->sat_addr.s_node == ddp->ddp_lsat.sat_addr.s_node ) { break; } /* 0.255 to socket on receiving interface */ if ( to->sat_addr.s_node == ATADDR_BCAST && ( to->sat_addr.s_net == 0 || to->sat_addr.s_net == ddp->ddp_lsat.sat_addr.s_net ) && ddp->ddp_lsat.sat_addr.s_net == AA_SAT( aa )->sat_addr.s_net ) { break; } /* XXXX.0 to socket on destination interface */ if ( to->sat_addr.s_net == aa->aa_firstnet && to->sat_addr.s_node == 0 && ntohs( ddp->ddp_lsat.sat_addr.s_net ) >= ntohs( aa->aa_firstnet ) && ntohs( ddp->ddp_lsat.sat_addr.s_net ) <= ntohs( aa->aa_lastnet )) { break; } } return( ddp ); } static int at_setpeeraddr(struct socket *so, struct sockaddr **nam) { return(EOPNOTSUPP); } static int at_setsockaddr(struct socket *so, struct sockaddr **nam) { struct ddpcb *ddp; ddp = sotoddpcb( so ); if ( ddp == NULL ) { return( EINVAL); } at_sockaddr( ddp, nam ); return(0); } void ddp_init(void ) { netisr_register(NETISR_ATALK1, cpu0_portfn, at1intr); netisr_register(NETISR_ATALK2, cpu0_portfn, at2intr); netisr_register(NETISR_AARP, cpu0_portfn, aarpintr); } #if 0 static void ddp_clean(void ) { struct ddpcb *ddp; for ( ddp = ddpcb; ddp; ddp = ddp->ddp_next ) { at_pcbdetach( ddp->ddp_socket, ddp ); } } #endif struct pr_usrreqs ddp_usrreqs = { ddp_abort, pru_accept_notsupp, ddp_attach, ddp_bind, ddp_connect, pru_connect2_notsupp, at_control, ddp_detach, ddp_disconnect, pru_listen_notsupp, at_setpeeraddr, pru_rcvd_notsupp, pru_rcvoob_notsupp, ddp_send, pru_sense_null, ddp_shutdown, at_setsockaddr, sosend, soreceive, sopoll };