/* * ng_btsocket_rfcomm.c * * Copyright (c) 2001-2003 Maksim Yevmenkin * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $Id: ng_btsocket_rfcomm.c,v 1.28 2003/09/14 23:29:06 max Exp $ * $FreeBSD$ */ #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 /* MALLOC define */ #ifdef NG_SEPARATE_MALLOC MALLOC_DEFINE(M_NETGRAPH_BTSOCKET_RFCOMM, "netgraph_btsocks_rfcomm", "Netgraph Bluetooth RFCOMM sockets"); #else #define M_NETGRAPH_BTSOCKET_RFCOMM M_NETGRAPH #endif /* NG_SEPARATE_MALLOC */ /* Debug */ #define NG_BTSOCKET_RFCOMM_INFO \ if (ng_btsocket_rfcomm_debug_level >= NG_BTSOCKET_INFO_LEVEL) \ printf #define NG_BTSOCKET_RFCOMM_WARN \ if (ng_btsocket_rfcomm_debug_level >= NG_BTSOCKET_WARN_LEVEL) \ printf #define NG_BTSOCKET_RFCOMM_ERR \ if (ng_btsocket_rfcomm_debug_level >= NG_BTSOCKET_ERR_LEVEL) \ printf #define NG_BTSOCKET_RFCOMM_ALERT \ if (ng_btsocket_rfcomm_debug_level >= NG_BTSOCKET_ALERT_LEVEL) \ printf #define ALOT 0x7fff /* Local prototypes */ static void ng_btsocket_rfcomm_upcall (struct socket *so, void *arg, int waitflag); static void ng_btsocket_rfcomm_sessions_task (void *ctx, int pending); static void ng_btsocket_rfcomm_session_task (ng_btsocket_rfcomm_session_p s); #define ng_btsocket_rfcomm_task_wakeup() \ taskqueue_enqueue(taskqueue_swi_giant, &ng_btsocket_rfcomm_task) static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_connect_ind (ng_btsocket_rfcomm_session_p s, int channel); static void ng_btsocket_rfcomm_connect_cfm (ng_btsocket_rfcomm_session_p s); static int ng_btsocket_rfcomm_session_create (ng_btsocket_rfcomm_session_p *sp, struct socket *l2so, bdaddr_p src, bdaddr_p dst, struct thread *td); static int ng_btsocket_rfcomm_session_accept (ng_btsocket_rfcomm_session_p s0); static int ng_btsocket_rfcomm_session_connect (ng_btsocket_rfcomm_session_p s); static int ng_btsocket_rfcomm_session_receive (ng_btsocket_rfcomm_session_p s); static int ng_btsocket_rfcomm_session_send (ng_btsocket_rfcomm_session_p s); static void ng_btsocket_rfcomm_session_clean (ng_btsocket_rfcomm_session_p s); static void ng_btsocket_rfcomm_session_process_pcb (ng_btsocket_rfcomm_session_p s); static ng_btsocket_rfcomm_session_p ng_btsocket_rfcomm_session_by_addr (bdaddr_p src, bdaddr_p dst); static int ng_btsocket_rfcomm_receive_frame (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_sabm (ng_btsocket_rfcomm_session_p s, int dlci); static int ng_btsocket_rfcomm_receive_disc (ng_btsocket_rfcomm_session_p s, int dlci); static int ng_btsocket_rfcomm_receive_ua (ng_btsocket_rfcomm_session_p s, int dlci); static int ng_btsocket_rfcomm_receive_dm (ng_btsocket_rfcomm_session_p s, int dlci); static int ng_btsocket_rfcomm_receive_uih (ng_btsocket_rfcomm_session_p s, int dlci, int pf, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_mcc (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_test (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_fc (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_msc (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_rpn (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_rls (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static int ng_btsocket_rfcomm_receive_pn (ng_btsocket_rfcomm_session_p s, struct mbuf *m0); static void ng_btsocket_rfcomm_set_pn (ng_btsocket_rfcomm_pcb_p pcb, u_int8_t cr, u_int8_t flow_control, u_int8_t credits, u_int16_t mtu); static int ng_btsocket_rfcomm_send_command (ng_btsocket_rfcomm_session_p s, u_int8_t type, u_int8_t dlci); static int ng_btsocket_rfcomm_send_uih (ng_btsocket_rfcomm_session_p s, u_int8_t address, u_int8_t pf, u_int8_t credits, struct mbuf *data); static int ng_btsocket_rfcomm_send_msc (ng_btsocket_rfcomm_pcb_p pcb); static int ng_btsocket_rfcomm_send_pn (ng_btsocket_rfcomm_pcb_p pcb); static int ng_btsocket_rfcomm_send_credits (ng_btsocket_rfcomm_pcb_p pcb); static int ng_btsocket_rfcomm_pcb_send (ng_btsocket_rfcomm_pcb_p pcb, int limit); static int ng_btsocket_rfcomm_pcb_kill (ng_btsocket_rfcomm_pcb_p pcb, int error); static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_by_channel (bdaddr_p src, int channel); static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_by_dlci (ng_btsocket_rfcomm_session_p s, int dlci); static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_listener (bdaddr_p src, int channel); static void ng_btsocket_rfcomm_timeout (ng_btsocket_rfcomm_pcb_p pcb); static void ng_btsocket_rfcomm_untimeout (ng_btsocket_rfcomm_pcb_p pcb); static void ng_btsocket_rfcomm_process_timeout (void *xpcb); static struct mbuf * ng_btsocket_rfcomm_prepare_packet (struct sockbuf *sb, int length); /* Globals */ extern int ifqmaxlen; static u_int32_t ng_btsocket_rfcomm_debug_level; static u_int32_t ng_btsocket_rfcomm_timo; struct task ng_btsocket_rfcomm_task; static LIST_HEAD(, ng_btsocket_rfcomm_session) ng_btsocket_rfcomm_sessions; static struct mtx ng_btsocket_rfcomm_sessions_mtx; static LIST_HEAD(, ng_btsocket_rfcomm_pcb) ng_btsocket_rfcomm_sockets; static struct mtx ng_btsocket_rfcomm_sockets_mtx; /* Sysctl tree */ SYSCTL_DECL(_net_bluetooth_rfcomm_sockets); SYSCTL_NODE(_net_bluetooth_rfcomm_sockets, OID_AUTO, stream, CTLFLAG_RW, 0, "Bluetooth STREAM RFCOMM sockets family"); SYSCTL_INT(_net_bluetooth_rfcomm_sockets_stream, OID_AUTO, debug_level, CTLFLAG_RW, &ng_btsocket_rfcomm_debug_level, NG_BTSOCKET_INFO_LEVEL, "Bluetooth STREAM RFCOMM sockets debug level"); SYSCTL_INT(_net_bluetooth_rfcomm_sockets_stream, OID_AUTO, timeout, CTLFLAG_RW, &ng_btsocket_rfcomm_timo, 60, "Bluetooth STREAM RFCOMM sockets timeout"); /***************************************************************************** ***************************************************************************** ** RFCOMM CRC ***************************************************************************** *****************************************************************************/ static u_int8_t ng_btsocket_rfcomm_crc_table[256] = { 0x00, 0x91, 0xe3, 0x72, 0x07, 0x96, 0xe4, 0x75, 0x0e, 0x9f, 0xed, 0x7c, 0x09, 0x98, 0xea, 0x7b, 0x1c, 0x8d, 0xff, 0x6e, 0x1b, 0x8a, 0xf8, 0x69, 0x12, 0x83, 0xf1, 0x60, 0x15, 0x84, 0xf6, 0x67, 0x38, 0xa9, 0xdb, 0x4a, 0x3f, 0xae, 0xdc, 0x4d, 0x36, 0xa7, 0xd5, 0x44, 0x31, 0xa0, 0xd2, 0x43, 0x24, 0xb5, 0xc7, 0x56, 0x23, 0xb2, 0xc0, 0x51, 0x2a, 0xbb, 0xc9, 0x58, 0x2d, 0xbc, 0xce, 0x5f, 0x70, 0xe1, 0x93, 0x02, 0x77, 0xe6, 0x94, 0x05, 0x7e, 0xef, 0x9d, 0x0c, 0x79, 0xe8, 0x9a, 0x0b, 0x6c, 0xfd, 0x8f, 0x1e, 0x6b, 0xfa, 0x88, 0x19, 0x62, 0xf3, 0x81, 0x10, 0x65, 0xf4, 0x86, 0x17, 0x48, 0xd9, 0xab, 0x3a, 0x4f, 0xde, 0xac, 0x3d, 0x46, 0xd7, 0xa5, 0x34, 0x41, 0xd0, 0xa2, 0x33, 0x54, 0xc5, 0xb7, 0x26, 0x53, 0xc2, 0xb0, 0x21, 0x5a, 0xcb, 0xb9, 0x28, 0x5d, 0xcc, 0xbe, 0x2f, 0xe0, 0x71, 0x03, 0x92, 0xe7, 0x76, 0x04, 0x95, 0xee, 0x7f, 0x0d, 0x9c, 0xe9, 0x78, 0x0a, 0x9b, 0xfc, 0x6d, 0x1f, 0x8e, 0xfb, 0x6a, 0x18, 0x89, 0xf2, 0x63, 0x11, 0x80, 0xf5, 0x64, 0x16, 0x87, 0xd8, 0x49, 0x3b, 0xaa, 0xdf, 0x4e, 0x3c, 0xad, 0xd6, 0x47, 0x35, 0xa4, 0xd1, 0x40, 0x32, 0xa3, 0xc4, 0x55, 0x27, 0xb6, 0xc3, 0x52, 0x20, 0xb1, 0xca, 0x5b, 0x29, 0xb8, 0xcd, 0x5c, 0x2e, 0xbf, 0x90, 0x01, 0x73, 0xe2, 0x97, 0x06, 0x74, 0xe5, 0x9e, 0x0f, 0x7d, 0xec, 0x99, 0x08, 0x7a, 0xeb, 0x8c, 0x1d, 0x6f, 0xfe, 0x8b, 0x1a, 0x68, 0xf9, 0x82, 0x13, 0x61, 0xf0, 0x85, 0x14, 0x66, 0xf7, 0xa8, 0x39, 0x4b, 0xda, 0xaf, 0x3e, 0x4c, 0xdd, 0xa6, 0x37, 0x45, 0xd4, 0xa1, 0x30, 0x42, 0xd3, 0xb4, 0x25, 0x57, 0xc6, 0xb3, 0x22, 0x50, 0xc1, 0xba, 0x2b, 0x59, 0xc8, 0xbd, 0x2c, 0x5e, 0xcf }; /* CRC */ static u_int8_t ng_btsocket_rfcomm_crc(u_int8_t *data, int length) { u_int8_t crc = 0xff; while (length --) crc = ng_btsocket_rfcomm_crc_table[crc ^ *data++]; return (crc); } /* ng_btsocket_rfcomm_crc */ /* FCS on 2 bytes */ static u_int8_t ng_btsocket_rfcomm_fcs2(u_int8_t *data) { return (0xff - ng_btsocket_rfcomm_crc(data, 2)); } /* ng_btsocket_rfcomm_fcs2 */ /* FCS on 3 bytes */ static u_int8_t ng_btsocket_rfcomm_fcs3(u_int8_t *data) { return (0xff - ng_btsocket_rfcomm_crc(data, 3)); } /* ng_btsocket_rfcomm_fcs3 */ /* * Check FCS * * From Bluetooth spec * * "... In 07.10, the frame check sequence (FCS) is calculated on different * sets of fields for different frame types. These are the fields that the * FCS are calculated on: * * For SABM, DISC, UA, DM frames: on Address, Control and length field. * For UIH frames: on Address and Control field. * * (This is stated here for clarification, and to set the standard for RFCOMM; * the fields included in FCS calculation have actually changed in version * 7.0.0 of TS 07.10, but RFCOMM will not change the FCS calculation scheme * from the one above.) ..." */ static int ng_btsocket_rfcomm_check_fcs(u_int8_t *data, int type, u_int8_t fcs) { if (type != RFCOMM_FRAME_UIH) return (ng_btsocket_rfcomm_fcs3(data) != fcs); return (ng_btsocket_rfcomm_fcs2(data) != fcs); } /* ng_btsocket_rfcomm_check_fcs */ /***************************************************************************** ***************************************************************************** ** Socket interface ***************************************************************************** *****************************************************************************/ /* * Initialize everything */ void ng_btsocket_rfcomm_init(void) { ng_btsocket_rfcomm_debug_level = NG_BTSOCKET_WARN_LEVEL; ng_btsocket_rfcomm_timo = 60; /* RFCOMM task */ TASK_INIT(&ng_btsocket_rfcomm_task, 0, ng_btsocket_rfcomm_sessions_task, NULL); /* RFCOMM sessions list */ LIST_INIT(&ng_btsocket_rfcomm_sessions); mtx_init(&ng_btsocket_rfcomm_sessions_mtx, "btsocks_rfcomm_sessions_mtx", NULL, MTX_DEF); /* RFCOMM sockets list */ LIST_INIT(&ng_btsocket_rfcomm_sockets); mtx_init(&ng_btsocket_rfcomm_sockets_mtx, "btsocks_rfcomm_sockets_mtx", NULL, MTX_DEF); } /* ng_btsocket_rfcomm_init */ /* * Abort connection on socket */ int ng_btsocket_rfcomm_abort(struct socket *so) { so->so_error = ECONNABORTED; return (ng_btsocket_rfcomm_detach(so)); } /* ng_btsocket_rfcomm_abort */ /* * Accept connection on socket. Nothing to do here, socket must be connected * and ready, so just return peer address and be done with it. */ int ng_btsocket_rfcomm_accept(struct socket *so, struct sockaddr **nam) { return (ng_btsocket_rfcomm_peeraddr(so, nam)); } /* ng_btsocket_rfcomm_accept */ /* * Create and attach new socket */ int ng_btsocket_rfcomm_attach(struct socket *so, int proto, struct thread *td) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); int error; /* Check socket and protocol */ if (so->so_type != SOCK_STREAM) return (ESOCKTNOSUPPORT); #if 0 /* XXX sonewconn() calls "pru_attach" with proto == 0 */ if (proto != 0) if (proto != BLUETOOTH_PROTO_RFCOMM) return (EPROTONOSUPPORT); #endif /* XXX */ if (pcb != NULL) return (EISCONN); /* Reserve send and receive space if it is not reserved yet */ if ((so->so_snd.sb_hiwat == 0) || (so->so_rcv.sb_hiwat == 0)) { error = soreserve(so, NG_BTSOCKET_RFCOMM_SENDSPACE, NG_BTSOCKET_RFCOMM_RECVSPACE); if (error != 0) return (error); } /* Allocate the PCB */ MALLOC(pcb, ng_btsocket_rfcomm_pcb_p, sizeof(*pcb), M_NETGRAPH_BTSOCKET_RFCOMM, M_NOWAIT | M_ZERO); if (pcb == NULL) return (ENOMEM); /* Link the PCB and the socket */ so->so_pcb = (caddr_t) pcb; pcb->so = so; /* Initialize PCB */ pcb->state = NG_BTSOCKET_RFCOMM_DLC_CLOSED; pcb->flags = NG_BTSOCKET_RFCOMM_DLC_CFC; pcb->lmodem = pcb->rmodem = (RFCOMM_MODEM_RTC | RFCOMM_MODEM_RTR | RFCOMM_MODEM_DV); pcb->mtu = RFCOMM_DEFAULT_MTU; pcb->tx_cred = 0; pcb->rx_cred = RFCOMM_DEFAULT_CREDITS; mtx_init(&pcb->pcb_mtx, "btsocks_rfcomm_pcb_mtx", NULL, MTX_DEF); callout_handle_init(&pcb->timo); /* Add the PCB to the list */ mtx_lock(&ng_btsocket_rfcomm_sockets_mtx); LIST_INSERT_HEAD(&ng_btsocket_rfcomm_sockets, pcb, next); mtx_unlock(&ng_btsocket_rfcomm_sockets_mtx); return (0); } /* ng_btsocket_rfcomm_attach */ /* * Bind socket */ int ng_btsocket_rfcomm_bind(struct socket *so, struct sockaddr *nam, struct thread *td) { ng_btsocket_rfcomm_pcb_t *pcb = so2rfcomm_pcb(so); struct sockaddr_rfcomm *sa = (struct sockaddr_rfcomm *) nam; if (pcb == NULL) return (EINVAL); /* Verify address */ if (sa == NULL) return (EINVAL); if (sa->rfcomm_family != AF_BLUETOOTH) return (EAFNOSUPPORT); if (sa->rfcomm_len != sizeof(*sa)) return (EINVAL); if (sa->rfcomm_channel > 30) return (EINVAL); if (sa->rfcomm_channel != 0 && ng_btsocket_rfcomm_pcb_by_channel(&sa->rfcomm_bdaddr, sa->rfcomm_channel) != NULL) return (EADDRINUSE); bcopy(&sa->rfcomm_bdaddr, &pcb->src, sizeof(pcb->src)); pcb->channel = sa->rfcomm_channel; return (0); } /* ng_btsocket_rfcomm_bind */ /* * Connect socket */ int ng_btsocket_rfcomm_connect(struct socket *so, struct sockaddr *nam, struct thread *td) { ng_btsocket_rfcomm_pcb_t *pcb = so2rfcomm_pcb(so); struct sockaddr_rfcomm *sa = (struct sockaddr_rfcomm *) nam; ng_btsocket_rfcomm_session_t *s = NULL; struct socket *l2so = NULL; int dlci, error = 0; if (pcb == NULL) return (EINVAL); /* Verify address */ if (sa == NULL) return (EINVAL); if (sa->rfcomm_family != AF_BLUETOOTH) return (EAFNOSUPPORT); if (sa->rfcomm_len != sizeof(*sa)) return (EINVAL); if (sa->rfcomm_channel > 30) return (EINVAL); if (sa->rfcomm_channel == 0 || bcmp(&sa->rfcomm_bdaddr, NG_HCI_BDADDR_ANY, sizeof(bdaddr_t)) == 0) return (EDESTADDRREQ); /* * XXX FIXME - This is FUBAR. socreate() will call soalloc(1), i.e. * soalloc() is allowed to sleep in MALLOC. This creates "could sleep" * WITNESS warnings. To work around this problem we will create L2CAP * socket first and then check if we actually need it. Note that we * will not check for errors in socreate() because if we failed to * create L2CAP socket at this point we still might have already open * session. */ error = socreate(PF_BLUETOOTH, &l2so, SOCK_SEQPACKET, BLUETOOTH_PROTO_L2CAP, td->td_ucred, td); /* * Look for session between "pcb->src" and "sa->rfcomm_bdaddr" (dst) */ mtx_lock(&ng_btsocket_rfcomm_sessions_mtx); s = ng_btsocket_rfcomm_session_by_addr(&pcb->src, &sa->rfcomm_bdaddr); if (s == NULL) { /* * We need to create new RFCOMM session. Check if we have L2CAP * socket. If l2so == NULL then error has the error code from * socreate() */ if (l2so == NULL) { mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); return (error); } error = ng_btsocket_rfcomm_session_create(&s, l2so, &pcb->src, &sa->rfcomm_bdaddr, td); if (error != 0) { mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); soclose(l2so); return (error); } } else if (l2so != NULL) soclose(l2so); /* we don't need new L2CAP socket */ /* * Check if we already have the same DLCI the the same session */ mtx_lock(&s->session_mtx); mtx_lock(&pcb->pcb_mtx); dlci = RFCOMM_MKDLCI(!INITIATOR(s), sa->rfcomm_channel); if (ng_btsocket_rfcomm_pcb_by_dlci(s, dlci) != NULL) { mtx_unlock(&pcb->pcb_mtx); mtx_unlock(&s->session_mtx); mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); return (EBUSY); } /* * Check session state and if its not acceptable then refuse connection */ switch (s->state) { case NG_BTSOCKET_RFCOMM_SESSION_CONNECTING: case NG_BTSOCKET_RFCOMM_SESSION_CONNECTED: case NG_BTSOCKET_RFCOMM_SESSION_OPEN: /* * Update destination address and channel and attach * DLC to the session */ bcopy(&sa->rfcomm_bdaddr, &pcb->dst, sizeof(pcb->dst)); pcb->channel = sa->rfcomm_channel; pcb->dlci = dlci; LIST_INSERT_HEAD(&s->dlcs, pcb, session_next); pcb->session = s; ng_btsocket_rfcomm_timeout(pcb); soisconnecting(pcb->so); if (s->state == NG_BTSOCKET_RFCOMM_SESSION_OPEN) { pcb->mtu = s->mtu; bcopy(&so2l2cap_pcb(s->l2so)->src, &pcb->src, sizeof(pcb->src)); pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONFIGURING; error = ng_btsocket_rfcomm_send_pn(pcb); if (error == 0) error = ng_btsocket_rfcomm_task_wakeup(); } else pcb->state = NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT; break; default: error = ECONNRESET; break; } mtx_unlock(&pcb->pcb_mtx); mtx_unlock(&s->session_mtx); mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); return (error); } /* ng_btsocket_rfcomm_connect */ /* * Process ioctl's calls on socket. * XXX FIXME this should provide interface to the RFCOMM multiplexor channel */ int ng_btsocket_rfcomm_control(struct socket *so, u_long cmd, caddr_t data, struct ifnet *ifp, struct thread *td) { return (EINVAL); } /* ng_btsocket_rfcomm_control */ /* * Process getsockopt/setsockopt system calls */ int ng_btsocket_rfcomm_ctloutput(struct socket *so, struct sockopt *sopt) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); struct ng_btsocket_rfcomm_fc_info fcinfo; int error = 0; if (pcb == NULL) return (EINVAL); if (sopt->sopt_level != SOL_RFCOMM) return (0); mtx_lock(&pcb->pcb_mtx); switch (sopt->sopt_dir) { case SOPT_GET: switch (sopt->sopt_name) { case SO_RFCOMM_MTU: error = sooptcopyout(sopt, &pcb->mtu, sizeof(pcb->mtu)); break; case SO_RFCOMM_FC_INFO: fcinfo.lmodem = pcb->lmodem; fcinfo.rmodem = pcb->rmodem; fcinfo.tx_cred = pcb->tx_cred; fcinfo.rx_cred = pcb->rx_cred; fcinfo.cfc = (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC)? 1 : 0; fcinfo.reserved = 0; error = sooptcopyout(sopt, &fcinfo, sizeof(fcinfo)); break; default: error = ENOPROTOOPT; break; } break; case SOPT_SET: switch (sopt->sopt_name) { default: error = ENOPROTOOPT; break; } break; default: error = EINVAL; break; } mtx_unlock(&pcb->pcb_mtx); return (error); } /* ng_btsocket_rfcomm_ctloutput */ /* * Detach and destroy socket */ int ng_btsocket_rfcomm_detach(struct socket *so) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); if (pcb == NULL) return (EINVAL); mtx_lock(&pcb->pcb_mtx); switch (pcb->state) { case NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT: case NG_BTSOCKET_RFCOMM_DLC_CONFIGURING: case NG_BTSOCKET_RFCOMM_DLC_CONNECTING: case NG_BTSOCKET_RFCOMM_DLC_CONNECTED: /* XXX What to do with pending request? */ if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO) ng_btsocket_rfcomm_untimeout(pcb); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT) pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_DETACHED; else pcb->state = NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING; ng_btsocket_rfcomm_task_wakeup(); break; case NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING: ng_btsocket_rfcomm_task_wakeup(); break; } while (pcb->state != NG_BTSOCKET_RFCOMM_DLC_CLOSED) msleep(&pcb->state, &pcb->pcb_mtx, PZERO, "rf_det", 0); if (pcb->session != NULL) panic("%s: pcb->session != NULL\n", __func__); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO) panic("%s: timeout on closed DLC, flags=%#x\n", __func__, pcb->flags); mtx_lock(&ng_btsocket_rfcomm_sockets_mtx); LIST_REMOVE(pcb, next); mtx_unlock(&ng_btsocket_rfcomm_sockets_mtx); mtx_unlock(&pcb->pcb_mtx); mtx_destroy(&pcb->pcb_mtx); bzero(pcb, sizeof(*pcb)); FREE(pcb, M_NETGRAPH_BTSOCKET_RFCOMM); soisdisconnected(so); ACCEPT_LOCK(); SOCK_LOCK(so); so->so_pcb = NULL; sotryfree(so); return (0); } /* ng_btsocket_rfcomm_detach */ /* * Disconnect socket */ int ng_btsocket_rfcomm_disconnect(struct socket *so) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); if (pcb == NULL) return (EINVAL); mtx_lock(&pcb->pcb_mtx); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING) { mtx_unlock(&pcb->pcb_mtx); return (EINPROGRESS); } /* XXX What to do with pending request? */ if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO) ng_btsocket_rfcomm_untimeout(pcb); switch (pcb->state) { case NG_BTSOCKET_RFCOMM_DLC_CONFIGURING: /* XXX can we get here? */ case NG_BTSOCKET_RFCOMM_DLC_CONNECTING: /* XXX can we get here? */ case NG_BTSOCKET_RFCOMM_DLC_CONNECTED: /* * Just change DLC state and enqueue RFCOMM task. It will * queue and send DISC on the DLC. */ pcb->state = NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING; soisdisconnecting(so); ng_btsocket_rfcomm_task_wakeup(); break; /* * case NG_BTSOCKET_RFCOMM_DLC_CLOSED: * case NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT: * case NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING: */ default: panic("%s: Invalid DLC state=%d, flags=%#x\n", __func__, pcb->state, pcb->flags); break; } mtx_unlock(&pcb->pcb_mtx); return (0); } /* ng_btsocket_rfcomm_disconnect */ /* * Listen on socket. First call to listen() will create listening RFCOMM session */ int ng_btsocket_rfcomm_listen(struct socket *so, struct thread *td) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); ng_btsocket_rfcomm_session_p s = NULL; struct socket *l2so = NULL; int error; if (pcb == NULL) return (EINVAL); if (pcb->channel < 1 || pcb->channel > 30) return (EDESTADDRREQ); /* * XXX FIXME - This is FUBAR. socreate() will call soalloc(1), i.e. * soalloc() is allowed to sleep in MALLOC. This creates "could sleep" * WITNESS warnings. To work around this problem we will create L2CAP * socket first and then check if we actually need it. Note that we * will not check for errors in socreate() because if we failed to * create L2CAP socket at this point we still might have already open * session. */ error = socreate(PF_BLUETOOTH, &l2so, SOCK_SEQPACKET, BLUETOOTH_PROTO_L2CAP, td->td_ucred, td); /* * Look for the session in LISTENING state. There can only be one. */ mtx_lock(&ng_btsocket_rfcomm_sessions_mtx); LIST_FOREACH(s, &ng_btsocket_rfcomm_sessions, next) if (s->state == NG_BTSOCKET_RFCOMM_SESSION_LISTENING) break; if (s == NULL) { /* * We need to create default RFCOMM session. Check if we have * L2CAP socket. If l2so == NULL then error has the error code * from socreate() */ if (l2so == NULL) { mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); return (error); } /* * Create default listen RFCOMM session. The default RFCOMM * session will listen on ANY address. * * XXX FIXME Note that currently there is no way to adjust MTU * for the default session. */ error = ng_btsocket_rfcomm_session_create(&s, l2so, NG_HCI_BDADDR_ANY, NULL, td); if (error != 0) { mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); soclose(l2so); return (error); } } else if (l2so != NULL) soclose(l2so); /* we don't need new L2CAP socket */ mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); return (0); } /* ng_btsocket_listen */ /* * Get peer address */ int ng_btsocket_rfcomm_peeraddr(struct socket *so, struct sockaddr **nam) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); struct sockaddr_rfcomm sa; if (pcb == NULL) return (EINVAL); bcopy(&pcb->dst, &sa.rfcomm_bdaddr, sizeof(sa.rfcomm_bdaddr)); sa.rfcomm_channel = pcb->channel; sa.rfcomm_len = sizeof(sa); sa.rfcomm_family = AF_BLUETOOTH; *nam = sodupsockaddr((struct sockaddr *) &sa, M_NOWAIT); return ((*nam == NULL)? ENOMEM : 0); } /* ng_btsocket_rfcomm_peeraddr */ /* * Send data to socket */ int ng_btsocket_rfcomm_send(struct socket *so, int flags, struct mbuf *m, struct sockaddr *nam, struct mbuf *control, struct thread *td) { ng_btsocket_rfcomm_pcb_t *pcb = so2rfcomm_pcb(so); int error = 0; /* Check socket and input */ if (pcb == NULL || m == NULL || control != NULL) { error = EINVAL; goto drop; } mtx_lock(&pcb->pcb_mtx); /* Make sure DLC is connected */ if (pcb->state != NG_BTSOCKET_RFCOMM_DLC_CONNECTED) { mtx_unlock(&pcb->pcb_mtx); error = ENOTCONN; goto drop; } /* Put the packet on the socket's send queue and wakeup RFCOMM task */ sbappend(&pcb->so->so_snd, m); m = NULL; if (!(pcb->flags & NG_BTSOCKET_RFCOMM_DLC_SENDING)) { pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_SENDING; error = ng_btsocket_rfcomm_task_wakeup(); } mtx_unlock(&pcb->pcb_mtx); drop: NG_FREE_M(m); /* checks for != NULL */ NG_FREE_M(control); return (error); } /* ng_btsocket_rfcomm_send */ /* * Get socket address */ int ng_btsocket_rfcomm_sockaddr(struct socket *so, struct sockaddr **nam) { ng_btsocket_rfcomm_pcb_p pcb = so2rfcomm_pcb(so); struct sockaddr_rfcomm sa; if (pcb == NULL) return (EINVAL); bcopy(&pcb->src, &sa.rfcomm_bdaddr, sizeof(sa.rfcomm_bdaddr)); sa.rfcomm_channel = pcb->channel; sa.rfcomm_len = sizeof(sa); sa.rfcomm_family = AF_BLUETOOTH; *nam = sodupsockaddr((struct sockaddr *) &sa, M_NOWAIT); return ((*nam == NULL)? ENOMEM : 0); } /* ng_btsocket_rfcomm_sockaddr */ /* * Upcall function for L2CAP sockets. Enqueue RFCOMM task. */ static void ng_btsocket_rfcomm_upcall(struct socket *so, void *arg, int waitflag) { int error; if (so == NULL) panic("%s: so == NULL\n", __func__); if ((error = ng_btsocket_rfcomm_task_wakeup()) != 0) NG_BTSOCKET_RFCOMM_ALERT( "%s: Could not enqueue RFCOMM task, error=%d\n", __func__, error); } /* ng_btsocket_rfcomm_upcall */ /* * RFCOMM task. Will handle all RFCOMM sessions in one pass. * XXX FIXME does not scale very well */ static void ng_btsocket_rfcomm_sessions_task(void *ctx, int pending) { ng_btsocket_rfcomm_session_p s = NULL, s_next = NULL; mtx_lock(&ng_btsocket_rfcomm_sessions_mtx); for (s = LIST_FIRST(&ng_btsocket_rfcomm_sessions); s != NULL; ) { mtx_lock(&s->session_mtx); s_next = LIST_NEXT(s, next); ng_btsocket_rfcomm_session_task(s); if (s->state == NG_BTSOCKET_RFCOMM_SESSION_CLOSED) { /* Unlink and clean the session */ LIST_REMOVE(s, next); NG_BT_MBUFQ_DRAIN(&s->outq); if (!LIST_EMPTY(&s->dlcs)) panic("%s: DLC list is not empty\n", __func__); /* Close L2CAP socket */ s->l2so->so_upcallarg = NULL; s->l2so->so_upcall = NULL; SOCKBUF_LOCK(&s->l2so->so_rcv); s->l2so->so_rcv.sb_flags &= ~SB_UPCALL; SOCKBUF_UNLOCK(&s->l2so->so_rcv); SOCKBUF_LOCK(&s->l2so->so_snd); s->l2so->so_snd.sb_flags &= ~SB_UPCALL; SOCKBUF_UNLOCK(&s->l2so->so_snd); soclose(s->l2so); mtx_unlock(&s->session_mtx); mtx_destroy(&s->session_mtx); bzero(s, sizeof(*s)); FREE(s, M_NETGRAPH_BTSOCKET_RFCOMM); } else mtx_unlock(&s->session_mtx); s = s_next; } mtx_unlock(&ng_btsocket_rfcomm_sessions_mtx); } /* ng_btsocket_rfcomm_sessions_task */ /* * Process RFCOMM session. Will handle all RFCOMM sockets in one pass. */ static void ng_btsocket_rfcomm_session_task(ng_btsocket_rfcomm_session_p s) { mtx_assert(&s->session_mtx, MA_OWNED); if (s->l2so->so_rcv.sb_state & SBS_CANTRCVMORE) { NG_BTSOCKET_RFCOMM_INFO( "%s: L2CAP connection has been terminated, so=%p, so_state=%#x, so_count=%d, " \ "state=%d, flags=%#x\n", __func__, s->l2so, s->l2so->so_state, s->l2so->so_count, s->state, s->flags); s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } /* Now process upcall */ switch (s->state) { /* Try to accept new L2CAP connection(s) */ case NG_BTSOCKET_RFCOMM_SESSION_LISTENING: while (ng_btsocket_rfcomm_session_accept(s) == 0) ; break; /* Process the results of the L2CAP connect */ case NG_BTSOCKET_RFCOMM_SESSION_CONNECTING: ng_btsocket_rfcomm_session_process_pcb(s); if (ng_btsocket_rfcomm_session_connect(s) != 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } break; /* Try to receive/send more data */ case NG_BTSOCKET_RFCOMM_SESSION_CONNECTED: case NG_BTSOCKET_RFCOMM_SESSION_OPEN: case NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING: ng_btsocket_rfcomm_session_process_pcb(s); if (ng_btsocket_rfcomm_session_receive(s) != 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } else if (ng_btsocket_rfcomm_session_send(s) != 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } break; case NG_BTSOCKET_RFCOMM_SESSION_CLOSED: break; default: panic("%s: Invalid session state=%d, flags=%#x\n", __func__, s->state, s->flags); break; } } /* ng_btsocket_rfcomm_session_task */ /* * Process RFCOMM connection indicator. Caller must hold s->session_mtx */ static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_connect_ind(ng_btsocket_rfcomm_session_p s, int channel) { ng_btsocket_rfcomm_pcb_p pcb = NULL, pcb1 = NULL; ng_btsocket_l2cap_pcb_p l2pcb = NULL; struct socket *so1 = NULL; mtx_assert(&s->session_mtx, MA_OWNED); /* * Try to find RFCOMM socket that listens on given source address * and channel. This will return the best possible match. */ l2pcb = so2l2cap_pcb(s->l2so); pcb = ng_btsocket_rfcomm_pcb_listener(&l2pcb->src, channel); if (pcb == NULL) return (NULL); /* * Check the pending connections queue and if we have space then * create new socket and set proper source and destination address, * and channel. */ mtx_lock(&pcb->pcb_mtx); if (pcb->so->so_qlen <= pcb->so->so_qlimit) so1 = sonewconn(pcb->so, 0); mtx_unlock(&pcb->pcb_mtx); if (so1 == NULL) return (NULL); /* * If we got here than we have created new socket. So complete the * connection. Set source and destination address from the session. */ pcb1 = so2rfcomm_pcb(so1); if (pcb1 == NULL) panic("%s: pcb1 == NULL\n", __func__); mtx_lock(&pcb1->pcb_mtx); bcopy(&l2pcb->src, &pcb1->src, sizeof(pcb1->src)); bcopy(&l2pcb->dst, &pcb1->dst, sizeof(pcb1->dst)); pcb1->channel = channel; /* Link new DLC to the session. We already hold s->session_mtx */ LIST_INSERT_HEAD(&s->dlcs, pcb1, session_next); pcb1->session = s; mtx_unlock(&pcb1->pcb_mtx); return (pcb1); } /* ng_btsocket_rfcomm_connect_ind */ /* * Process RFCOMM connect confirmation. Caller must hold s->session_mtx. */ static void ng_btsocket_rfcomm_connect_cfm(ng_btsocket_rfcomm_session_p s) { ng_btsocket_rfcomm_pcb_p pcb = NULL, pcb_next = NULL; struct socket *so = NULL; int error; mtx_assert(&s->session_mtx, MA_OWNED); /* * Wake up all waiting sockets and send PN request for each of them. * Note that timeout already been set in ng_btsocket_rfcomm_connect() * * Note: cannot use LIST_FOREACH because ng_btsocket_rfcomm_pcb_kill * will unlink DLC from the session */ for (pcb = LIST_FIRST(&s->dlcs); pcb != NULL; ) { mtx_lock(&pcb->pcb_mtx); pcb_next = LIST_NEXT(pcb, session_next); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT) { pcb->mtu = s->mtu; bcopy(&so2l2cap_pcb(s->l2so)->src, &pcb->src, sizeof(pcb->src)); error = ng_btsocket_rfcomm_send_pn(pcb); if (error == 0) pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONFIGURING; else if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; else so = NULL; } mtx_unlock(&pcb->pcb_mtx); pcb = pcb_next; if (so != NULL) ng_btsocket_rfcomm_detach(so); } } /* ng_btsocket_rfcomm_connect_cfm */ /***************************************************************************** ***************************************************************************** ** RFCOMM sessions ***************************************************************************** *****************************************************************************/ /* * Create new RFCOMM session. That function WILL NOT take ownership over l2so. * Caller MUST free l2so if function failed. */ static int ng_btsocket_rfcomm_session_create(ng_btsocket_rfcomm_session_p *sp, struct socket *l2so, bdaddr_p src, bdaddr_p dst, struct thread *td) { ng_btsocket_rfcomm_session_p s = NULL; struct sockaddr_l2cap l2sa; struct sockopt l2sopt; int mtu, error; mtx_assert(&ng_btsocket_rfcomm_sessions_mtx, MA_OWNED); /* Allocate the RFCOMM session */ MALLOC(s, ng_btsocket_rfcomm_session_p, sizeof(*s), M_NETGRAPH_BTSOCKET_RFCOMM, M_NOWAIT | M_ZERO); if (s == NULL) return (ENOMEM); /* Set defaults */ s->mtu = RFCOMM_DEFAULT_MTU; s->flags = 0; s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; NG_BT_MBUFQ_INIT(&s->outq, ifqmaxlen); /* * XXX Mark session mutex as DUPOK to prevent "duplicated lock of * the same type" message. When accepting new L2CAP connection * ng_btsocket_rfcomm_session_accept() holds both session mutexes * for "old" (accepting) session and "new" (created) session. */ mtx_init(&s->session_mtx, "btsocks_rfcomm_session_mtx", NULL, MTX_DEF|MTX_DUPOK); LIST_INIT(&s->dlcs); /* Prepare L2CAP socket */ l2so->so_upcallarg = NULL; l2so->so_upcall = ng_btsocket_rfcomm_upcall; SOCKBUF_LOCK(&l2so->so_rcv); l2so->so_rcv.sb_flags |= SB_UPCALL; SOCKBUF_UNLOCK(&l2so->so_rcv); SOCKBUF_LOCK(&l2so->so_snd); l2so->so_snd.sb_flags |= SB_UPCALL; SOCKBUF_UNLOCK(&l2so->so_snd); l2so->so_state |= SS_NBIO; s->l2so = l2so; mtx_lock(&s->session_mtx); /* * "src" == NULL and "dst" == NULL means just create session. * caller must do the rest */ if (src == NULL && dst == NULL) goto done; /* * Set incoming MTU on L2CAP socket. It is RFCOMM session default MTU * plus 5 bytes: RFCOMM frame header, one extra byte for length and one * extra byte for credits. */ mtu = s->mtu + sizeof(struct rfcomm_frame_hdr) + 1 + 1; l2sopt.sopt_dir = SOPT_SET; l2sopt.sopt_level = SOL_L2CAP; l2sopt.sopt_name = SO_L2CAP_IMTU; l2sopt.sopt_val = (void *) &mtu; l2sopt.sopt_valsize = sizeof(mtu); l2sopt.sopt_td = NULL; error = sosetopt(s->l2so, &l2sopt); if (error != 0) goto bad; /* Bind socket to "src" address */ l2sa.l2cap_len = sizeof(l2sa); l2sa.l2cap_family = AF_BLUETOOTH; l2sa.l2cap_psm = (dst == NULL)? htole16(NG_L2CAP_PSM_RFCOMM) : 0; bcopy(src, &l2sa.l2cap_bdaddr, sizeof(l2sa.l2cap_bdaddr)); error = sobind(s->l2so, (struct sockaddr *) &l2sa, td); if (error != 0) goto bad; /* If "dst" is not NULL then initiate connect(), otherwise listen() */ if (dst == NULL) { s->flags = 0; s->state = NG_BTSOCKET_RFCOMM_SESSION_LISTENING; error = solisten(s->l2so, 10, td); if (error != 0) goto bad; } else { s->flags = NG_BTSOCKET_RFCOMM_SESSION_INITIATOR; s->state = NG_BTSOCKET_RFCOMM_SESSION_CONNECTING; l2sa.l2cap_len = sizeof(l2sa); l2sa.l2cap_family = AF_BLUETOOTH; l2sa.l2cap_psm = htole16(NG_L2CAP_PSM_RFCOMM); bcopy(dst, &l2sa.l2cap_bdaddr, sizeof(l2sa.l2cap_bdaddr)); error = soconnect(s->l2so, (struct sockaddr *) &l2sa, td); if (error != 0) goto bad; } done: LIST_INSERT_HEAD(&ng_btsocket_rfcomm_sessions, s, next); *sp = s; mtx_unlock(&s->session_mtx); return (0); bad: mtx_unlock(&s->session_mtx); /* Return L2CAP socket back to its original state */ l2so->so_upcallarg = NULL; l2so->so_upcall = NULL; SOCKBUF_LOCK(&l2so->so_rcv); l2so->so_rcv.sb_flags &= ~SB_UPCALL; SOCKBUF_UNLOCK(&l2so->so_rcv); SOCKBUF_LOCK(&l2so->so_snd); l2so->so_snd.sb_flags &= ~SB_UPCALL; SOCKBUF_UNLOCK(&l2so->so_snd); l2so->so_state &= ~SS_NBIO; mtx_destroy(&s->session_mtx); bzero(s, sizeof(*s)); FREE(s, M_NETGRAPH_BTSOCKET_RFCOMM); return (error); } /* ng_btsocket_rfcomm_session_create */ /* * Process accept() on RFCOMM session * XXX FIXME locking for "l2so"? */ static int ng_btsocket_rfcomm_session_accept(ng_btsocket_rfcomm_session_p s0) { struct socket *l2so = NULL; struct sockaddr_l2cap *l2sa = NULL; ng_btsocket_l2cap_pcb_t *l2pcb = NULL; ng_btsocket_rfcomm_session_p s = NULL; int error = 0; mtx_assert(&ng_btsocket_rfcomm_sessions_mtx, MA_OWNED); mtx_assert(&s0->session_mtx, MA_OWNED); /* Check if there is a complete L2CAP connection in the queue */ if ((error = s0->l2so->so_error) != 0) { NG_BTSOCKET_RFCOMM_ERR( "%s: Could not accept connection on L2CAP socket, error=%d\n", __func__, error); s0->l2so->so_error = 0; return (error); } ACCEPT_LOCK(); if (TAILQ_EMPTY(&s0->l2so->so_comp)) { ACCEPT_UNLOCK(); if (s0->l2so->so_rcv.sb_state & SBS_CANTRCVMORE) return (ECONNABORTED); return (EWOULDBLOCK); } /* Accept incoming L2CAP connection */ l2so = TAILQ_FIRST(&s0->l2so->so_comp); if (l2so == NULL) panic("%s: l2so == NULL\n", __func__); TAILQ_REMOVE(&s0->l2so->so_comp, l2so, so_list); s0->l2so->so_qlen --; l2so->so_qstate &= ~SQ_COMP; l2so->so_head = NULL; SOCK_LOCK(l2so); soref(l2so); l2so->so_state |= SS_NBIO; SOCK_UNLOCK(l2so); ACCEPT_UNLOCK(); error = soaccept(l2so, (struct sockaddr **) &l2sa); if (error != 0) { NG_BTSOCKET_RFCOMM_ERR( "%s: soaccept() on L2CAP socket failed, error=%d\n", __func__, error); soclose(l2so); return (error); } /* * Check if there is already active RFCOMM session between two devices. * If so then close L2CAP connection. We only support one RFCOMM session * between each pair of devices. Note that here we assume session in any * state. The session even could be in the middle of disconnecting. */ l2pcb = so2l2cap_pcb(l2so); s = ng_btsocket_rfcomm_session_by_addr(&l2pcb->src, &l2pcb->dst); if (s == NULL) { /* Create a new RFCOMM session */ error = ng_btsocket_rfcomm_session_create(&s, l2so, NULL, NULL, curthread /* XXX */); if (error == 0) { mtx_lock(&s->session_mtx); s->flags = 0; s->state = NG_BTSOCKET_RFCOMM_SESSION_CONNECTED; /* * Adjust MTU on incomming connection. Reserve 5 bytes: * RFCOMM frame header, one extra byte for length and * one extra byte for credits. */ s->mtu = min(l2pcb->imtu, l2pcb->omtu) - sizeof(struct rfcomm_frame_hdr) - 1 - 1; mtx_unlock(&s->session_mtx); } else { NG_BTSOCKET_RFCOMM_ALERT( "%s: Failed to create new RFCOMM session, error=%d\n", __func__, error); soclose(l2so); } } else { NG_BTSOCKET_RFCOMM_WARN( "%s: Rejecting duplicating RFCOMM session between src=%x:%x:%x:%x:%x:%x and " \ "dst=%x:%x:%x:%x:%x:%x, state=%d, flags=%#x\n", __func__, l2pcb->src.b[5], l2pcb->src.b[4], l2pcb->src.b[3], l2pcb->src.b[2], l2pcb->src.b[1], l2pcb->src.b[0], l2pcb->dst.b[5], l2pcb->dst.b[4], l2pcb->dst.b[3], l2pcb->dst.b[2], l2pcb->dst.b[1], l2pcb->dst.b[0], s->state, s->flags); error = EBUSY; soclose(l2so); } return (error); } /* ng_btsocket_rfcomm_session_accept */ /* * Process connect() on RFCOMM session * XXX FIXME locking for "l2so"? */ static int ng_btsocket_rfcomm_session_connect(ng_btsocket_rfcomm_session_p s) { ng_btsocket_l2cap_pcb_p l2pcb = so2l2cap_pcb(s->l2so); int error; mtx_assert(&s->session_mtx, MA_OWNED); /* First check if connection has failed */ if ((error = s->l2so->so_error) != 0) { s->l2so->so_error = 0; NG_BTSOCKET_RFCOMM_ERR( "%s: Could not connect RFCOMM session, error=%d, state=%d, flags=%#x\n", __func__, error, s->state, s->flags); return (error); } /* Is connection still in progress? */ if (s->l2so->so_state & SS_ISCONNECTING) return (0); /* * If we got here then we are connected. Send SABM on DLCI 0 to * open multiplexor channel. */ if (error == 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_CONNECTED; /* * Adjust MTU on outgoing connection. Reserve 5 bytes: RFCOMM * frame header, one extra byte for length and one extra byte * for credits. */ s->mtu = min(l2pcb->imtu, l2pcb->omtu) - sizeof(struct rfcomm_frame_hdr) - 1 - 1; error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_SABM,0); if (error == 0) error = ng_btsocket_rfcomm_task_wakeup(); } return (error); }/* ng_btsocket_rfcomm_session_connect */ /* * Receive data on RFCOMM session * XXX FIXME locking for "l2so"? */ static int ng_btsocket_rfcomm_session_receive(ng_btsocket_rfcomm_session_p s) { struct mbuf *m = NULL; struct uio uio; int more, flags, error; mtx_assert(&s->session_mtx, MA_OWNED); /* Can we read from the L2CAP socket? */ if (!soreadable(s->l2so)) return (0); /* First check for error on L2CAP socket */ if ((error = s->l2so->so_error) != 0) { s->l2so->so_error = 0; NG_BTSOCKET_RFCOMM_ERR( "%s: Could not receive data from L2CAP socket, error=%d, state=%d, flags=%#x\n", __func__, error, s->state, s->flags); return (error); } /* * Read all packets from the L2CAP socket. * XXX FIXME/VERIFY is that correct? For now use m->m_nextpkt as * indication that there is more packets on the socket's buffer. * Also what should we use in uio.uio_resid? * May be s->mtu + sizeof(struct rfcomm_frame_hdr) + 1 + 1? */ for (more = 1; more; ) { /* Try to get next packet from socket */ bzero(&uio, sizeof(uio)); /* uio.uio_td = NULL; */ uio.uio_resid = 1000000000; flags = MSG_DONTWAIT; m = NULL; error = (*s->l2so->so_proto->pr_usrreqs->pru_soreceive)(s->l2so, NULL, &uio, &m, (struct mbuf **) NULL, &flags); if (error != 0) { if (error == EWOULDBLOCK) return (0); /* XXX can happen? */ NG_BTSOCKET_RFCOMM_ERR( "%s: Could not receive data from L2CAP socket, error=%d\n", __func__, error); return (error); } more = (m->m_nextpkt != NULL); m->m_nextpkt = NULL; ng_btsocket_rfcomm_receive_frame(s, m); } return (0); } /* ng_btsocket_rfcomm_session_receive */ /* * Send data on RFCOMM session * XXX FIXME locking for "l2so"? */ static int ng_btsocket_rfcomm_session_send(ng_btsocket_rfcomm_session_p s) { struct mbuf *m = NULL; int error; mtx_assert(&s->session_mtx, MA_OWNED); /* Send as much as we can from the session queue */ while (sowriteable(s->l2so)) { /* Check if socket still OK */ if ((error = s->l2so->so_error) != 0) { s->l2so->so_error = 0; NG_BTSOCKET_RFCOMM_ERR( "%s: Detected error=%d on L2CAP socket, state=%d, flags=%#x\n", __func__, error, s->state, s->flags); return (error); } NG_BT_MBUFQ_DEQUEUE(&s->outq, m); if (m == NULL) return (0); /* we are done */ /* Call send function on the L2CAP socket */ error = (*s->l2so->so_proto->pr_usrreqs->pru_sosend) (s->l2so, NULL, NULL, m, NULL, 0, curthread /* XXX */); if (error != 0) { NG_BTSOCKET_RFCOMM_ERR( "%s: Could not send data to L2CAP socket, error=%d\n", __func__, error); return (error); } } return (0); } /* ng_btsocket_rfcomm_session_send */ /* * Close and disconnect all DLCs for the given session. Caller must hold * s->sesson_mtx. Will wakeup session. */ static void ng_btsocket_rfcomm_session_clean(ng_btsocket_rfcomm_session_p s) { ng_btsocket_rfcomm_pcb_p pcb = NULL, pcb_next = NULL; struct socket *so = NULL; int error; mtx_assert(&s->session_mtx, MA_OWNED); /* * Note: cannot use LIST_FOREACH because ng_btsocket_rfcomm_pcb_kill * will unlink DLC from the session */ for (pcb = LIST_FIRST(&s->dlcs); pcb != NULL; ) { mtx_lock(&pcb->pcb_mtx); pcb_next = LIST_NEXT(pcb, session_next); NG_BTSOCKET_RFCOMM_INFO( "%s: Disconnecting dlci=%d, state=%d, flags=%#x\n", __func__, pcb->dlci, pcb->state, pcb->flags); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_CONNECTED) error = ECONNRESET; else error = ECONNREFUSED; if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; else so = NULL; mtx_unlock(&pcb->pcb_mtx); pcb = pcb_next; if (so != NULL) ng_btsocket_rfcomm_detach(so); } } /* ng_btsocket_rfcomm_session_clean */ /* * Process all DLCs on the session. Caller MUST hold s->session_mtx. */ static void ng_btsocket_rfcomm_session_process_pcb(ng_btsocket_rfcomm_session_p s) { ng_btsocket_rfcomm_pcb_p pcb = NULL, pcb_next = NULL; struct socket *so = NULL; int error; mtx_assert(&s->session_mtx, MA_OWNED); /* * Note: cannot use LIST_FOREACH because ng_btsocket_rfcomm_pcb_kill * will unlink DLC from the session */ for (pcb = LIST_FIRST(&s->dlcs); pcb != NULL; ) { so = NULL; mtx_lock(&pcb->pcb_mtx); pcb_next = LIST_NEXT(pcb, session_next); switch (pcb->state) { /* * If DLC in W4_CONNECT state then we should check for both * timeout and detach. */ case NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT: if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_DETACHED) { if (ng_btsocket_rfcomm_pcb_kill(pcb, 0)) so = pcb->so; } else if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT) if (ng_btsocket_rfcomm_pcb_kill(pcb, ETIMEDOUT)) so = pcb->so; break; /* * If DLC in CONFIGURING or CONNECTING state then we only * should check for timeout. If detach() was called then * DLC will be moved into DISCONNECTING state. */ case NG_BTSOCKET_RFCOMM_DLC_CONFIGURING: case NG_BTSOCKET_RFCOMM_DLC_CONNECTING: if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT) if (ng_btsocket_rfcomm_pcb_kill(pcb, ETIMEDOUT)) so = pcb->so; break; /* * If DLC in CONNECTED state then we need to send data (if any) * from the socket's send queue. Note that we will send data * from either all sockets or none. This may overload session's * outgoing queue (but we do not check for that). * * XXX FIXME need scheduler for RFCOMM sockets */ case NG_BTSOCKET_RFCOMM_DLC_CONNECTED: error = ng_btsocket_rfcomm_pcb_send(pcb, ALOT); if (error != 0) if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; break; /* * If DLC in DISCONNECTING state then we must send DISC frame. * Note that if DLC has timeout set then we do not need to * resend DISC frame. * * XXX FIXME need to drain all data from the socket's queue * if LINGER option was set */ case NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING: if (!(pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO)) { error = ng_btsocket_rfcomm_send_command( pcb->session, RFCOMM_FRAME_DISC, pcb->dlci); if (error == 0) ng_btsocket_rfcomm_timeout(pcb); else if (ng_btsocket_rfcomm_pcb_kill(pcb,error)) so = pcb->so; } else if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT) if (ng_btsocket_rfcomm_pcb_kill(pcb, ETIMEDOUT)) so = pcb->so; break; /* case NG_BTSOCKET_RFCOMM_DLC_CLOSED: */ default: panic("%s: Invalid DLC state=%d, flags=%#x\n", __func__, pcb->state, pcb->flags); break; } mtx_unlock(&pcb->pcb_mtx); pcb = pcb_next; if (so != NULL) ng_btsocket_rfcomm_detach(so); } } /* ng_btsocket_rfcomm_session_process_pcb */ /* * Find RFCOMM session between "src" and "dst". * Caller MUST hold ng_btsocket_rfcomm_sessions_mtx. */ static ng_btsocket_rfcomm_session_p ng_btsocket_rfcomm_session_by_addr(bdaddr_p src, bdaddr_p dst) { ng_btsocket_rfcomm_session_p s = NULL; ng_btsocket_l2cap_pcb_p l2pcb = NULL; int any_src; mtx_assert(&ng_btsocket_rfcomm_sessions_mtx, MA_OWNED); any_src = (bcmp(src, NG_HCI_BDADDR_ANY, sizeof(*src)) == 0); LIST_FOREACH(s, &ng_btsocket_rfcomm_sessions, next) { l2pcb = so2l2cap_pcb(s->l2so); if ((any_src || bcmp(&l2pcb->src, src, sizeof(*src)) == 0) && bcmp(&l2pcb->dst, dst, sizeof(*dst)) == 0) break; } return (s); } /* ng_btsocket_rfcomm_session_by_addr */ /***************************************************************************** ***************************************************************************** ** RFCOMM ***************************************************************************** *****************************************************************************/ /* * Process incoming RFCOMM frame. Caller must hold s->session_mtx. * XXX FIXME check frame length */ static int ng_btsocket_rfcomm_receive_frame(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_frame_hdr *hdr = NULL; struct mbuf *m = NULL; u_int16_t length; u_int8_t dlci, type; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); /* Pullup as much as we can into first mbuf (for direct access) */ length = min(m0->m_pkthdr.len, MHLEN); if (m0->m_len < length) { if ((m0 = m_pullup(m0, length)) == NULL) { NG_BTSOCKET_RFCOMM_ALERT( "%s: m_pullup(%d) failed\n", __func__, length); return (ENOBUFS); } } hdr = mtod(m0, struct rfcomm_frame_hdr *); dlci = RFCOMM_DLCI(hdr->address); type = RFCOMM_TYPE(hdr->control); /* Test EA bit in length. If not set then we have 2 bytes of length */ if (!RFCOMM_EA(hdr->length)) { bcopy(&hdr->length, &length, sizeof(length)); length = le16toh(length); m_adj(m0, sizeof(*hdr) + 1); } else { length = hdr->length >> 1; m_adj(m0, sizeof(*hdr)); } NG_BTSOCKET_RFCOMM_INFO( "%s: Got frame type=%#x, dlci=%d, length=%d, cr=%d, pf=%d, len=%d\n", __func__, type, dlci, length, RFCOMM_CR(hdr->address), RFCOMM_PF(hdr->control), m0->m_pkthdr.len); /* * Get FCS (the last byte in the frame) * XXX this will not work if mbuf chain ends with empty mbuf. * XXX let's hope it never happens :) */ for (m = m0; m->m_next != NULL; m = m->m_next) ; if (m->m_len <= 0) panic("%s: Empty mbuf at the end of the chain, len=%d\n", __func__, m->m_len); /* * Check FCS. We only need to calculate FCS on first 2 or 3 bytes * and already m_pullup'ed mbuf chain, so it should be safe. */ if (ng_btsocket_rfcomm_check_fcs((u_int8_t *) hdr, type, m->m_data[m->m_len - 1])) { NG_BTSOCKET_RFCOMM_ERR( "%s: Invalid RFCOMM packet. Bad checksum\n", __func__); NG_FREE_M(m0); return (EINVAL); } m_adj(m0, -1); /* Trim FCS byte */ /* * Process RFCOMM frame. * * From TS 07.10 spec * * "... In the case where a SABM or DISC command with the P bit set * to 0 is received then the received frame shall be discarded..." * * "... If a unsolicited DM response is received then the frame shall * be processed irrespective of the P/F setting... " * * "... The station may transmit response frames with the F bit set * to 0 at any opportunity on an asynchronous basis. However, in the * case where a UA response is received with the F bit set to 0 then * the received frame shall be discarded..." * * From Bluetooth spec * * "... When credit based flow control is being used, the meaning of * the P/F bit in the control field of the RFCOMM header is redefined * for UIH frames..." */ switch (type) { case RFCOMM_FRAME_SABM: if (RFCOMM_PF(hdr->control)) error = ng_btsocket_rfcomm_receive_sabm(s, dlci); break; case RFCOMM_FRAME_DISC: if (RFCOMM_PF(hdr->control)) error = ng_btsocket_rfcomm_receive_disc(s, dlci); break; case RFCOMM_FRAME_UA: if (RFCOMM_PF(hdr->control)) error = ng_btsocket_rfcomm_receive_ua(s, dlci); break; case RFCOMM_FRAME_DM: error = ng_btsocket_rfcomm_receive_dm(s, dlci); break; case RFCOMM_FRAME_UIH: if (dlci == 0) error = ng_btsocket_rfcomm_receive_mcc(s, m0); else error = ng_btsocket_rfcomm_receive_uih(s, dlci, RFCOMM_PF(hdr->control), m0); return (error); /* NOT REACHED */ default: NG_BTSOCKET_RFCOMM_ERR( "%s: Invalid RFCOMM packet. Unknown type=%#x\n", __func__, type); error = EINVAL; break; } NG_FREE_M(m0); return (error); } /* ng_btsocket_rfcomm_receive_frame */ /* * Process RFCOMM SABM frame */ static int ng_btsocket_rfcomm_receive_sabm(ng_btsocket_rfcomm_session_p s, int dlci) { ng_btsocket_rfcomm_pcb_p pcb = NULL; struct socket *so = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got SABM, session state=%d, flags=%#x, mtu=%d, dlci=%d\n", __func__, s->state, s->flags, s->mtu, dlci); /* DLCI == 0 means open multiplexor channel */ if (dlci == 0) { switch (s->state) { case NG_BTSOCKET_RFCOMM_SESSION_CONNECTED: case NG_BTSOCKET_RFCOMM_SESSION_OPEN: error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_UA, dlci); if (error == 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_OPEN; ng_btsocket_rfcomm_connect_cfm(s); } else { s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } break; default: NG_BTSOCKET_RFCOMM_WARN( "%s: Got SABM for session in invalid state state=%d, flags=%#x\n", __func__, s->state, s->flags); error = EINVAL; break; } return (error); } /* Make sure multiplexor channel is open */ if (s->state != NG_BTSOCKET_RFCOMM_SESSION_OPEN) { NG_BTSOCKET_RFCOMM_ERR( "%s: Got SABM for dlci=%d with mulitplexor channel closed, state=%d, " \ "flags=%#x\n", __func__, dlci, s->state, s->flags); return (EINVAL); } /* * Check if we have this DLCI. This might happen when remote * peer uses PN command before actual open (SABM) happens. */ pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, dlci); if (pcb != NULL) { mtx_lock(&pcb->pcb_mtx); if (pcb->state != NG_BTSOCKET_RFCOMM_DLC_CONNECTING) { NG_BTSOCKET_RFCOMM_ERR( "%s: Got SABM for dlci=%d in invalid state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); mtx_unlock(&pcb->pcb_mtx); return (ENOENT); } ng_btsocket_rfcomm_untimeout(pcb); error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_UA,dlci); if (error == 0) error = ng_btsocket_rfcomm_send_msc(pcb); if (error == 0) { pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONNECTED; soisconnected(pcb->so); } else if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); return (error); } /* * We do not have requested DLCI, so it must be an incoming connection * with default parameters. Try to accept it. */ pcb = ng_btsocket_rfcomm_connect_ind(s, RFCOMM_SRVCHANNEL(dlci)); if (pcb != NULL) { mtx_lock(&pcb->pcb_mtx); pcb->dlci = dlci; error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_UA,dlci); if (error == 0) error = ng_btsocket_rfcomm_send_msc(pcb); if (error == 0) { pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONNECTED; soisconnected(pcb->so); } else if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); } else /* Nobody is listen()ing on the requested DLCI */ error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_DM,dlci); return (error); } /* ng_btsocket_rfcomm_receive_sabm */ /* * Process RFCOMM DISC frame */ static int ng_btsocket_rfcomm_receive_disc(ng_btsocket_rfcomm_session_p s, int dlci) { ng_btsocket_rfcomm_pcb_p pcb = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got DISC, session state=%d, flags=%#x, mtu=%d, dlci=%d\n", __func__, s->state, s->flags, s->mtu, dlci); /* DLCI == 0 means close multiplexor channel */ if (dlci == 0) { /* XXX FIXME assume that remote side will close the socket */ error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_UA, 0); if (error == 0) { if (s->state == NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING) s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; /* XXX */ else s->state = NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING; } else s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; /* XXX */ ng_btsocket_rfcomm_session_clean(s); } else { pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, dlci); if (pcb != NULL) { struct socket *so = NULL; int err; mtx_lock(&pcb->pcb_mtx); NG_BTSOCKET_RFCOMM_INFO( "%s: Got DISC for dlci=%d, state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_UA, dlci); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_CONNECTED) err = 0; else err = ECONNREFUSED; if (ng_btsocket_rfcomm_pcb_kill(pcb, err)) so = pcb->so; mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); } else { NG_BTSOCKET_RFCOMM_WARN( "%s: Got DISC for non-existing dlci=%d\n", __func__, dlci); error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_DM, dlci); } } return (error); } /* ng_btsocket_rfcomm_receive_disc */ /* * Process RFCOMM UA frame */ static int ng_btsocket_rfcomm_receive_ua(ng_btsocket_rfcomm_session_p s, int dlci) { ng_btsocket_rfcomm_pcb_p pcb = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got UA, session state=%d, flags=%#x, mtu=%d, dlci=%d\n", __func__, s->state, s->flags, s->mtu, dlci); /* dlci == 0 means multiplexor channel */ if (dlci == 0) { switch (s->state) { case NG_BTSOCKET_RFCOMM_SESSION_CONNECTED: s->state = NG_BTSOCKET_RFCOMM_SESSION_OPEN; ng_btsocket_rfcomm_connect_cfm(s); break; case NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING: s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); break; default: NG_BTSOCKET_RFCOMM_WARN( "%s: Got UA for session in invalid state=%d(%d), flags=%#x, mtu=%d\n", __func__, s->state, INITIATOR(s), s->flags, s->mtu); error = ENOENT; break; } return (error); } /* Check if we have this DLCI */ pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, dlci); if (pcb != NULL) { struct socket *so = NULL; mtx_lock(&pcb->pcb_mtx); NG_BTSOCKET_RFCOMM_INFO( "%s: Got UA for dlci=%d, state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); switch (pcb->state) { case NG_BTSOCKET_RFCOMM_DLC_CONNECTING: ng_btsocket_rfcomm_untimeout(pcb); error = ng_btsocket_rfcomm_send_msc(pcb); if (error == 0) { pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONNECTED; soisconnected(pcb->so); } break; case NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING: if (ng_btsocket_rfcomm_pcb_kill(pcb, 0)) so = pcb->so; break; default: NG_BTSOCKET_RFCOMM_WARN( "%s: Got UA for dlci=%d in invalid state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); error = ENOENT; break; } mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); } else { NG_BTSOCKET_RFCOMM_WARN( "%s: Got UA for non-existing dlci=%d\n", __func__, dlci); error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_DM,dlci); } return (error); } /* ng_btsocket_rfcomm_receive_ua */ /* * Process RFCOMM DM frame */ static int ng_btsocket_rfcomm_receive_dm(ng_btsocket_rfcomm_session_p s, int dlci) { ng_btsocket_rfcomm_pcb_p pcb = NULL; int error; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got DM, session state=%d, flags=%#x, mtu=%d, dlci=%d\n", __func__, s->state, s->flags, s->mtu, dlci); /* DLCI == 0 means multiplexor channel */ if (dlci == 0) { /* Disconnect all dlc's on the session */ s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; ng_btsocket_rfcomm_session_clean(s); } else { pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, dlci); if (pcb != NULL) { struct socket *so = NULL; mtx_lock(&pcb->pcb_mtx); NG_BTSOCKET_RFCOMM_INFO( "%s: Got DM for dlci=%d, state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_CONNECTED) error = ECONNRESET; else error = ECONNREFUSED; if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); } else NG_BTSOCKET_RFCOMM_WARN( "%s: Got DM for non-existing dlci=%d\n", __func__, dlci); } return (0); } /* ng_btsocket_rfcomm_receive_dm */ /* * Process RFCOMM UIH frame (data) */ static int ng_btsocket_rfcomm_receive_uih(ng_btsocket_rfcomm_session_p s, int dlci, int pf, struct mbuf *m0) { ng_btsocket_rfcomm_pcb_p pcb = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got UIH, session state=%d, flags=%#x, mtu=%d, dlci=%d, pf=%d, len=%d\n", __func__, s->state, s->flags, s->mtu, dlci, pf, m0->m_pkthdr.len); /* XXX should we do it here? Check for session flow control */ if (s->flags & NG_BTSOCKET_RFCOMM_SESSION_LFC) { NG_BTSOCKET_RFCOMM_WARN( "%s: Got UIH with session flow control asserted, state=%d, flags=%#x\n", __func__, s->state, s->flags); goto drop; } /* Check if we have this dlci */ pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, dlci); if (pcb == NULL) { NG_BTSOCKET_RFCOMM_WARN( "%s: Got UIH for non-existing dlci=%d\n", __func__, dlci); error = ng_btsocket_rfcomm_send_command(s,RFCOMM_FRAME_DM,dlci); goto drop; } mtx_lock(&pcb->pcb_mtx); /* Check dlci state */ if (pcb->state != NG_BTSOCKET_RFCOMM_DLC_CONNECTED) { NG_BTSOCKET_RFCOMM_WARN( "%s: Got UIH for dlci=%d in invalid state=%d, flags=%#x\n", __func__, dlci, pcb->state, pcb->flags); error = EINVAL; goto drop1; } /* Check dlci flow control */ if (((pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) && pcb->rx_cred <= 0) || (pcb->lmodem & RFCOMM_MODEM_FC)) { NG_BTSOCKET_RFCOMM_ERR( "%s: Got UIH for dlci=%d with asserted flow control, state=%d, " \ "flags=%#x, rx_cred=%d, lmodem=%#x\n", __func__, dlci, pcb->state, pcb->flags, pcb->rx_cred, pcb->lmodem); goto drop1; } /* Did we get any credits? */ if ((pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) && pf) { NG_BTSOCKET_RFCOMM_INFO( "%s: Got %d more credits for dlci=%d, state=%d, flags=%#x, " \ "rx_cred=%d, tx_cred=%d\n", __func__, *mtod(m0, u_int8_t *), dlci, pcb->state, pcb->flags, pcb->rx_cred, pcb->tx_cred); pcb->tx_cred += *mtod(m0, u_int8_t *); m_adj(m0, 1); /* Send more from the DLC. XXX check for errors? */ ng_btsocket_rfcomm_pcb_send(pcb, ALOT); } /* OK the of the rest of the mbuf is the data */ if (m0->m_pkthdr.len > 0) { /* If we are using credit flow control decrease rx_cred here */ if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) { /* Give remote peer more credits (if needed) */ if (-- pcb->rx_cred <= RFCOMM_MAX_CREDITS / 2) ng_btsocket_rfcomm_send_credits(pcb); else NG_BTSOCKET_RFCOMM_INFO( "%s: Remote side still has credits, dlci=%d, state=%d, flags=%#x, " \ "rx_cred=%d, tx_cred=%d\n", __func__, dlci, pcb->state, pcb->flags, pcb->rx_cred, pcb->tx_cred); } /* Check packet against mtu on dlci */ if (m0->m_pkthdr.len > pcb->mtu) { NG_BTSOCKET_RFCOMM_ERR( "%s: Got oversized UIH for dlci=%d, state=%d, flags=%#x, mtu=%d, len=%d\n", __func__, dlci, pcb->state, pcb->flags, pcb->mtu, m0->m_pkthdr.len); error = EMSGSIZE; } else if (m0->m_pkthdr.len > sbspace(&pcb->so->so_rcv)) { /* * This is really bad. Receive queue on socket does * not have enough space for the packet. We do not * have any other choice but drop the packet. */ NG_BTSOCKET_RFCOMM_ERR( "%s: Not enough space in socket receive queue. Dropping UIH for dlci=%d, " \ "state=%d, flags=%#x, len=%d, space=%ld\n", __func__, dlci, pcb->state, pcb->flags, m0->m_pkthdr.len, sbspace(&pcb->so->so_rcv)); error = ENOBUFS; } else { /* Append packet to the socket receive queue */ sbappend(&pcb->so->so_rcv, m0); m0 = NULL; sorwakeup(pcb->so); } } drop1: mtx_unlock(&pcb->pcb_mtx); drop: NG_FREE_M(m0); /* checks for != NULL */ return (error); } /* ng_btsocket_rfcomm_receive_uih */ /* * Process RFCOMM MCC command (Multiplexor) * * From TS 07.10 spec * * "5.4.3.1 Information Data * * ...The frames (UIH) sent by the initiating station have the C/R bit set * to 1 and those sent by the responding station have the C/R bit set to 0..." * * "5.4.6.2 Operating procedures * * Messages always exist in pairs; a command message and a corresponding * response message. If the C/R bit is set to 1 the message is a command, * if it is set to 0 the message is a response... * * ... * * NOTE: Notice that when UIH frames are used to convey information on DLCI 0 * there are at least two different fields that contain a C/R bit, and the * bits are set of different form. The C/R bit in the Type field shall be set * as it is stated above, while the C/R bit in the Address field (see subclause * 5.2.1.2) shall be set as it is described in subclause 5.4.3.1." */ static int ng_btsocket_rfcomm_receive_mcc(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = NULL; u_int8_t cr, type, length; mtx_assert(&s->session_mtx, MA_OWNED); /* * We can access data directly in the first mbuf, because we have * m_pullup()'ed mbuf chain in ng_btsocket_rfcomm_receive_frame(). * All MCC commands should fit into single mbuf (except probably TEST). */ hdr = mtod(m0, struct rfcomm_mcc_hdr *); cr = RFCOMM_CR(hdr->type); type = RFCOMM_MCC_TYPE(hdr->type); length = RFCOMM_MCC_LENGTH(hdr->length); /* Check MCC frame length */ if (sizeof(*hdr) + length != m0->m_pkthdr.len) { NG_BTSOCKET_RFCOMM_ERR( "%s: Invalid MCC frame length=%d, len=%d\n", __func__, length, m0->m_pkthdr.len); NG_FREE_M(m0); return (EMSGSIZE); } switch (type) { case RFCOMM_MCC_TEST: return (ng_btsocket_rfcomm_receive_test(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_FCON: case RFCOMM_MCC_FCOFF: return (ng_btsocket_rfcomm_receive_fc(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_MSC: return (ng_btsocket_rfcomm_receive_msc(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_RPN: return (ng_btsocket_rfcomm_receive_rpn(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_RLS: return (ng_btsocket_rfcomm_receive_rls(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_PN: return (ng_btsocket_rfcomm_receive_pn(s, m0)); /* NOT REACHED */ case RFCOMM_MCC_NSC: NG_BTSOCKET_RFCOMM_ERR( "%s: Got MCC NSC, type=%#x, cr=%d, length=%d, session state=%d, flags=%#x, " \ "mtu=%d, len=%d\n", __func__, RFCOMM_MCC_TYPE(*((u_int8_t *)(hdr + 1))), cr, length, s->state, s->flags, s->mtu, m0->m_pkthdr.len); NG_FREE_M(m0); break; default: NG_BTSOCKET_RFCOMM_ERR( "%s: Got unknown MCC, type=%#x, cr=%d, length=%d, session state=%d, " \ "flags=%#x, mtu=%d, len=%d\n", __func__, type, cr, length, s->state, s->flags, s->mtu, m0->m_pkthdr.len); /* Reuse mbuf to send NSC */ hdr = mtod(m0, struct rfcomm_mcc_hdr *); m0->m_pkthdr.len = m0->m_len = sizeof(*hdr); /* Create MCC NSC header */ hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_NSC); hdr->length = RFCOMM_MKLEN8(1); /* Put back MCC command type we did not like */ m0->m_data[m0->m_len] = RFCOMM_MKMCC_TYPE(cr, type); m0->m_pkthdr.len ++; m0->m_len ++; /* Send UIH frame */ return (ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0)); /* NOT REACHED */ } return (0); } /* ng_btsocket_rfcomm_receive_mcc */ /* * Receive RFCOMM TEST MCC command */ static int ng_btsocket_rfcomm_receive_test(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr *); int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC TEST, cr=%d, length=%d, session state=%d, flags=%#x, mtu=%d, " \ "len=%d\n", __func__, RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (RFCOMM_CR(hdr->type)) { hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_TEST); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); } else NG_FREE_M(m0); /* XXX ignore response */ return (error); } /* ng_btsocket_rfcomm_receive_test */ /* * Receive RFCOMM FCON/FCOFF MCC command */ static int ng_btsocket_rfcomm_receive_fc(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr *); u_int8_t type = RFCOMM_MCC_TYPE(hdr->type); int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); /* * Turn ON/OFF aggregate flow on the entire session. When remote peer * asserted flow control no transmission shall occur except on dlci 0 * (control channel). */ NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC FC%s, cr=%d, length=%d, session state=%d, flags=%#x, mtu=%d, " \ "len=%d\n", __func__, (type == RFCOMM_MCC_FCON)? "ON" : "OFF", RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (RFCOMM_CR(hdr->type)) { if (type == RFCOMM_MCC_FCON) s->flags &= ~NG_BTSOCKET_RFCOMM_SESSION_RFC; else s->flags |= NG_BTSOCKET_RFCOMM_SESSION_RFC; hdr->type = RFCOMM_MKMCC_TYPE(0, type); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); } else NG_FREE_M(m0); /* XXX ignore response */ return (error); } /* ng_btsocket_rfcomm_receive_fc */ /* * Receive RFCOMM MSC MCC command */ static int ng_btsocket_rfcomm_receive_msc(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr*); struct rfcomm_mcc_msc *msc = (struct rfcomm_mcc_msc *)(hdr+1); ng_btsocket_rfcomm_pcb_t *pcb = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC MSC, dlci=%d, cr=%d, length=%d, session state=%d, flags=%#x, " \ "mtu=%d, len=%d\n", __func__, RFCOMM_DLCI(msc->address), RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (RFCOMM_CR(hdr->type)) { pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, RFCOMM_DLCI(msc->address)); if (pcb == NULL) { NG_BTSOCKET_RFCOMM_WARN( "%s: Got MSC command for non-existing dlci=%d\n", __func__, RFCOMM_DLCI(msc->address)); NG_FREE_M(m0); return (ENOENT); } mtx_lock(&pcb->pcb_mtx); if (pcb->state != NG_BTSOCKET_RFCOMM_DLC_CONNECTING && pcb->state != NG_BTSOCKET_RFCOMM_DLC_CONNECTED) { NG_BTSOCKET_RFCOMM_WARN( "%s: Got MSC on dlci=%d in invalid state=%d\n", __func__, RFCOMM_DLCI(msc->address), pcb->state); mtx_unlock(&pcb->pcb_mtx); NG_FREE_M(m0); return (EINVAL); } pcb->rmodem = msc->modem; /* Update remote port signals */ hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_MSC); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); #if 0 /* YYY */ /* Send more data from DLC. XXX check for errors? */ if (!(pcb->rmodem & RFCOMM_MODEM_FC) && !(pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC)) ng_btsocket_rfcomm_pcb_send(pcb, ALOT); #endif /* YYY */ mtx_unlock(&pcb->pcb_mtx); } else NG_FREE_M(m0); /* XXX ignore response */ return (error); } /* ng_btsocket_rfcomm_receive_msc */ /* * Receive RFCOMM RPN MCC command * XXX FIXME do we need htole16/le16toh for RPN param_mask? */ static int ng_btsocket_rfcomm_receive_rpn(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr *); struct rfcomm_mcc_rpn *rpn = (struct rfcomm_mcc_rpn *)(hdr + 1); int error = 0; u_int16_t param_mask; u_int8_t bit_rate, data_bits, stop_bits, parity, flow_control, xon_char, xoff_char; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC RPN, dlci=%d, cr=%d, length=%d, session state=%d, flags=%#x, " \ "mtu=%d, len=%d\n", __func__, RFCOMM_DLCI(rpn->dlci), RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (RFCOMM_CR(hdr->type)) { param_mask = RFCOMM_RPN_PM_ALL; if (RFCOMM_MCC_LENGTH(hdr->length) == 1) { /* Request - return default setting */ bit_rate = RFCOMM_RPN_BR_115200; data_bits = RFCOMM_RPN_DATA_8; stop_bits = RFCOMM_RPN_STOP_1; parity = RFCOMM_RPN_PARITY_NONE; flow_control = RFCOMM_RPN_FLOW_NONE; xon_char = RFCOMM_RPN_XON_CHAR; xoff_char = RFCOMM_RPN_XOFF_CHAR; } else { /* * Ignore/accept bit_rate, 8 bits, 1 stop bit, no * parity, no flow control lines, default XON/XOFF * chars. */ bit_rate = rpn->bit_rate; rpn->param_mask = le16toh(rpn->param_mask); /* XXX */ data_bits = RFCOMM_RPN_DATA_BITS(rpn->line_settings); if (rpn->param_mask & RFCOMM_RPN_PM_DATA && data_bits != RFCOMM_RPN_DATA_8) { data_bits = RFCOMM_RPN_DATA_8; param_mask ^= RFCOMM_RPN_PM_DATA; } stop_bits = RFCOMM_RPN_STOP_BITS(rpn->line_settings); if (rpn->param_mask & RFCOMM_RPN_PM_STOP && stop_bits != RFCOMM_RPN_STOP_1) { stop_bits = RFCOMM_RPN_STOP_1; param_mask ^= RFCOMM_RPN_PM_STOP; } parity = RFCOMM_RPN_PARITY(rpn->line_settings); if (rpn->param_mask & RFCOMM_RPN_PM_PARITY && parity != RFCOMM_RPN_PARITY_NONE) { parity = RFCOMM_RPN_PARITY_NONE; param_mask ^= RFCOMM_RPN_PM_PARITY; } flow_control = rpn->flow_control; if (rpn->param_mask & RFCOMM_RPN_PM_FLOW && flow_control != RFCOMM_RPN_FLOW_NONE) { flow_control = RFCOMM_RPN_FLOW_NONE; param_mask ^= RFCOMM_RPN_PM_FLOW; } xon_char = rpn->xon_char; if (rpn->param_mask & RFCOMM_RPN_PM_XON && xon_char != RFCOMM_RPN_XON_CHAR) { xon_char = RFCOMM_RPN_XON_CHAR; param_mask ^= RFCOMM_RPN_PM_XON; } xoff_char = rpn->xoff_char; if (rpn->param_mask & RFCOMM_RPN_PM_XOFF && xoff_char != RFCOMM_RPN_XOFF_CHAR) { xoff_char = RFCOMM_RPN_XOFF_CHAR; param_mask ^= RFCOMM_RPN_PM_XOFF; } } rpn->bit_rate = bit_rate; rpn->line_settings = RFCOMM_MKRPN_LINE_SETTINGS(data_bits, stop_bits, parity); rpn->flow_control = flow_control; rpn->xon_char = xon_char; rpn->xoff_char = xoff_char; rpn->param_mask = htole16(param_mask); /* XXX */ m0->m_pkthdr.len = m0->m_len = sizeof(*hdr) + sizeof(*rpn); hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_RPN); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); } else NG_FREE_M(m0); /* XXX ignore response */ return (error); } /* ng_btsocket_rfcomm_receive_rpn */ /* * Receive RFCOMM RLS MCC command */ static int ng_btsocket_rfcomm_receive_rls(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr *); struct rfcomm_mcc_rls *rls = (struct rfcomm_mcc_rls *)(hdr + 1); int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); /* * XXX FIXME Do we have to do anything else here? Remote peer tries to * tell us something about DLCI. Just report what we have received and * return back received values as required by TS 07.10 spec. */ NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC RLS, dlci=%d, status=%#x, cr=%d, length=%d, session state=%d, " \ "flags=%#x, mtu=%d, len=%d\n", __func__, RFCOMM_DLCI(rls->address), rls->status, RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (RFCOMM_CR(hdr->type)) { if (rls->status & 0x1) NG_BTSOCKET_RFCOMM_ERR( "%s: Got RLS dlci=%d, error=%#x\n", __func__, RFCOMM_DLCI(rls->address), rls->status >> 1); hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_RLS); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); } else NG_FREE_M(m0); /* XXX ignore responses */ return (error); } /* ng_btsocket_rfcomm_receive_rls */ /* * Receive RFCOMM PN MCC command */ static int ng_btsocket_rfcomm_receive_pn(ng_btsocket_rfcomm_session_p s, struct mbuf *m0) { struct rfcomm_mcc_hdr *hdr = mtod(m0, struct rfcomm_mcc_hdr*); struct rfcomm_mcc_pn *pn = (struct rfcomm_mcc_pn *)(hdr+1); ng_btsocket_rfcomm_pcb_t *pcb = NULL; int error = 0; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Got MCC PN, dlci=%d, cr=%d, length=%d, flow_control=%#x, priority=%d, " \ "ack_timer=%d, mtu=%d, max_retrans=%d, credits=%d, session state=%d, " \ "flags=%#x, session mtu=%d, len=%d\n", __func__, pn->dlci, RFCOMM_CR(hdr->type), RFCOMM_MCC_LENGTH(hdr->length), pn->flow_control, pn->priority, pn->ack_timer, le16toh(pn->mtu), pn->max_retrans, pn->credits, s->state, s->flags, s->mtu, m0->m_pkthdr.len); if (pn->dlci == 0) { NG_BTSOCKET_RFCOMM_ERR("%s: Zero dlci in MCC PN\n", __func__); NG_FREE_M(m0); return (EINVAL); } /* Check if we have this dlci */ pcb = ng_btsocket_rfcomm_pcb_by_dlci(s, pn->dlci); if (pcb != NULL) { mtx_lock(&pcb->pcb_mtx); if (RFCOMM_CR(hdr->type)) { /* PN Request */ ng_btsocket_rfcomm_set_pn(pcb, 1, pn->flow_control, pn->credits, pn->mtu); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) { pn->flow_control = 0xe0; pn->credits = RFCOMM_DEFAULT_CREDITS; } else { pn->flow_control = 0; pn->credits = 0; } hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_PN); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); } else { /* PN Response - proceed with SABM. Timeout still set */ if (pcb->state == NG_BTSOCKET_RFCOMM_DLC_CONFIGURING) { ng_btsocket_rfcomm_set_pn(pcb, 0, pn->flow_control, pn->credits, pn->mtu); pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONNECTING; error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_SABM, pn->dlci); } else NG_BTSOCKET_RFCOMM_WARN( "%s: Got PN response for dlci=%d in invalid state=%d\n", __func__, pn->dlci, pcb->state); NG_FREE_M(m0); } mtx_unlock(&pcb->pcb_mtx); } else if (RFCOMM_CR(hdr->type)) { /* PN request to non-existing dlci - incomming connection */ pcb = ng_btsocket_rfcomm_connect_ind(s, RFCOMM_SRVCHANNEL(pn->dlci)); if (pcb != NULL) { struct socket *so = NULL; mtx_lock(&pcb->pcb_mtx); pcb->dlci = pn->dlci; ng_btsocket_rfcomm_set_pn(pcb, 1, pn->flow_control, pn->credits, pn->mtu); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) { pn->flow_control = 0xe0; pn->credits = RFCOMM_DEFAULT_CREDITS; } else { pn->flow_control = 0; pn->credits = 0; } hdr->type = RFCOMM_MKMCC_TYPE(0, RFCOMM_MCC_PN); error = ng_btsocket_rfcomm_send_uih(s, RFCOMM_MKADDRESS(INITIATOR(s), 0), 0, 0, m0); if (error == 0) { ng_btsocket_rfcomm_timeout(pcb); pcb->state = NG_BTSOCKET_RFCOMM_DLC_CONNECTING; soisconnecting(pcb->so); } else if (ng_btsocket_rfcomm_pcb_kill(pcb, error)) so = pcb->so; mtx_unlock(&pcb->pcb_mtx); if (so != NULL) ng_btsocket_rfcomm_detach(so); } else { /* Nobody is listen()ing on this channel */ error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_DM, pn->dlci); NG_FREE_M(m0); } } else NG_FREE_M(m0); /* XXX ignore response to non-existing dlci */ return (error); } /* ng_btsocket_rfcomm_receive_pn */ /* * Set PN parameters for dlci. Caller must hold pcb->pcb_mtx. * * From Bluetooth spec. * * "... The CL1 - CL4 field is completely redefined. (In TS07.10 this defines * the convergence layer to use, which is not applicable to RFCOMM. In RFCOMM, * in Bluetooth versions up to 1.0B, this field was forced to 0). * * In the PN request sent prior to a DLC establishment, this field must contain * the value 15 (0xF), indicating support of credit based flow control in the * sender. See Table 5.3 below. If the PN response contains any other value * than 14 (0xE) in this field, it is inferred that the peer RFCOMM entity is * not supporting the credit based flow control feature. (This is only possible * if the peer RFCOMM implementation is only conforming to Bluetooth version * 1.0B.) If a PN request is sent on an already open DLC, then this field must * contain the value zero; it is not possible to set initial credits more * than once per DLC activation. A responding implementation must set this * field in the PN response to 14 (0xE), if (and only if) the value in the PN * request was 15..." */ static void ng_btsocket_rfcomm_set_pn(ng_btsocket_rfcomm_pcb_p pcb, u_int8_t cr, u_int8_t flow_control, u_int8_t credits, u_int16_t mtu) { mtx_assert(&pcb->pcb_mtx, MA_OWNED); pcb->mtu = le16toh(mtu); if (cr) { if (flow_control == 0xf0) { pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_CFC; pcb->tx_cred = credits; } else { pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_CFC; pcb->tx_cred = 0; } } else { if (flow_control == 0xe0) { pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_CFC; pcb->tx_cred = credits; } else { pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_CFC; pcb->tx_cred = 0; } } NG_BTSOCKET_RFCOMM_INFO( "%s: cr=%d, dlci=%d, state=%d, flags=%#x, mtu=%d, rx_cred=%d, tx_cred=%d\n", __func__, cr, pcb->dlci, pcb->state, pcb->flags, pcb->mtu, pcb->rx_cred, pcb->tx_cred); } /* ng_btsocket_rfcomm_set_pn */ /* * Send RFCOMM SABM/DISC/UA/DM frames. Caller must hold s->session_mtx */ static int ng_btsocket_rfcomm_send_command(ng_btsocket_rfcomm_session_p s, u_int8_t type, u_int8_t dlci) { struct rfcomm_cmd_hdr *hdr = NULL; struct mbuf *m = NULL; int cr; mtx_assert(&s->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Sending command type %#x, session state=%d, flags=%#x, mtu=%d, dlci=%d\n", __func__, type, s->state, s->flags, s->mtu, dlci); switch (type) { case RFCOMM_FRAME_SABM: case RFCOMM_FRAME_DISC: cr = INITIATOR(s); break; case RFCOMM_FRAME_UA: case RFCOMM_FRAME_DM: cr = !INITIATOR(s); break; default: panic("%s: Invalid frame type=%#x\n", __func__, type); return (EINVAL); /* NOT REACHED */ } MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) return (ENOBUFS); m->m_pkthdr.len = m->m_len = sizeof(*hdr); hdr = mtod(m, struct rfcomm_cmd_hdr *); hdr->address = RFCOMM_MKADDRESS(cr, dlci); hdr->control = RFCOMM_MKCONTROL(type, 1); hdr->length = RFCOMM_MKLEN8(0); hdr->fcs = ng_btsocket_rfcomm_fcs3((u_int8_t *) hdr); NG_BT_MBUFQ_ENQUEUE(&s->outq, m); return (0); } /* ng_btsocket_rfcomm_send_command */ /* * Send RFCOMM UIH frame. Caller must hold s->session_mtx */ static int ng_btsocket_rfcomm_send_uih(ng_btsocket_rfcomm_session_p s, u_int8_t address, u_int8_t pf, u_int8_t credits, struct mbuf *data) { struct rfcomm_frame_hdr *hdr = NULL; struct mbuf *m = NULL, *mcrc = NULL; u_int16_t length; mtx_assert(&s->session_mtx, MA_OWNED); MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) { NG_FREE_M(data); return (ENOBUFS); } m->m_pkthdr.len = m->m_len = sizeof(*hdr); MGET(mcrc, M_DONTWAIT, MT_DATA); if (mcrc == NULL) { NG_FREE_M(data); return (ENOBUFS); } mcrc->m_len = 1; /* Fill UIH frame header */ hdr = mtod(m, struct rfcomm_frame_hdr *); hdr->address = address; hdr->control = RFCOMM_MKCONTROL(RFCOMM_FRAME_UIH, pf); /* Calculate FCS */ mcrc->m_data[0] = ng_btsocket_rfcomm_fcs2((u_int8_t *) hdr); /* Put length back */ length = (data != NULL)? data->m_pkthdr.len : 0; if (length > 127) { u_int16_t l = htole16(RFCOMM_MKLEN16(length)); bcopy(&l, &hdr->length, sizeof(l)); m->m_pkthdr.len ++; m->m_len ++; } else hdr->length = RFCOMM_MKLEN8(length); if (pf) { m->m_data[m->m_len] = credits; m->m_pkthdr.len ++; m->m_len ++; } /* Add payload */ if (data != NULL) { m_cat(m, data); m->m_pkthdr.len += length; } /* Put FCS back */ m_cat(m, mcrc); m->m_pkthdr.len ++; NG_BTSOCKET_RFCOMM_INFO( "%s: Sending UIH state=%d, flags=%#x, address=%d, length=%d, pf=%d, " \ "credits=%d, len=%d\n", __func__, s->state, s->flags, address, length, pf, credits, m->m_pkthdr.len); NG_BT_MBUFQ_ENQUEUE(&s->outq, m); return (0); } /* ng_btsocket_rfcomm_send_uih */ /* * Send MSC request. Caller must hold pcb->pcb_mtx and pcb->session->session_mtx */ static int ng_btsocket_rfcomm_send_msc(ng_btsocket_rfcomm_pcb_p pcb) { struct mbuf *m = NULL; struct rfcomm_mcc_hdr *hdr = NULL; struct rfcomm_mcc_msc *msc = NULL; mtx_assert(&pcb->session->session_mtx, MA_OWNED); mtx_assert(&pcb->pcb_mtx, MA_OWNED); MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) return (ENOBUFS); m->m_pkthdr.len = m->m_len = sizeof(*hdr) + sizeof(*msc); hdr = mtod(m, struct rfcomm_mcc_hdr *); msc = (struct rfcomm_mcc_msc *)(hdr + 1); hdr->type = RFCOMM_MKMCC_TYPE(1, RFCOMM_MCC_MSC); hdr->length = RFCOMM_MKLEN8(sizeof(*msc)); msc->address = RFCOMM_MKADDRESS(1, pcb->dlci); msc->modem = pcb->lmodem; NG_BTSOCKET_RFCOMM_INFO( "%s: Sending MSC dlci=%d, state=%d, flags=%#x, address=%d, modem=%#x\n", __func__, pcb->dlci, pcb->state, pcb->flags, msc->address, msc->modem); return (ng_btsocket_rfcomm_send_uih(pcb->session, RFCOMM_MKADDRESS(INITIATOR(pcb->session), 0), 0, 0, m)); } /* ng_btsocket_rfcomm_send_msc */ /* * Send PN request. Caller must hold pcb->pcb_mtx and pcb->session->session_mtx */ static int ng_btsocket_rfcomm_send_pn(ng_btsocket_rfcomm_pcb_p pcb) { struct mbuf *m = NULL; struct rfcomm_mcc_hdr *hdr = NULL; struct rfcomm_mcc_pn *pn = NULL; mtx_assert(&pcb->session->session_mtx, MA_OWNED); mtx_assert(&pcb->pcb_mtx, MA_OWNED); MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) return (ENOBUFS); m->m_pkthdr.len = m->m_len = sizeof(*hdr) + sizeof(*pn); hdr = mtod(m, struct rfcomm_mcc_hdr *); pn = (struct rfcomm_mcc_pn *)(hdr + 1); hdr->type = RFCOMM_MKMCC_TYPE(1, RFCOMM_MCC_PN); hdr->length = RFCOMM_MKLEN8(sizeof(*pn)); pn->dlci = pcb->dlci; /* * Set default DLCI priority as described in GSM 07.10 * (ETSI TS 101 369) clause 5.6 page 42 */ pn->priority = (pcb->dlci < 56)? (((pcb->dlci >> 3) << 3) + 7) : 61; pn->ack_timer = 0; pn->mtu = htole16(pcb->mtu); pn->max_retrans = 0; if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) { pn->flow_control = 0xf0; pn->credits = pcb->rx_cred; } else { pn->flow_control = 0; pn->credits = 0; } NG_BTSOCKET_RFCOMM_INFO( "%s: Sending PN dlci=%d, state=%d, flags=%#x, mtu=%d, flow_control=%#x, " \ "credits=%d\n", __func__, pcb->dlci, pcb->state, pcb->flags, pcb->mtu, pn->flow_control, pn->credits); return (ng_btsocket_rfcomm_send_uih(pcb->session, RFCOMM_MKADDRESS(INITIATOR(pcb->session), 0), 0, 0, m)); } /* ng_btsocket_rfcomm_send_pn */ /* * Calculate and send credits based on available space in receive buffer */ static int ng_btsocket_rfcomm_send_credits(ng_btsocket_rfcomm_pcb_p pcb) { int error = 0; u_int8_t credits; mtx_assert(&pcb->pcb_mtx, MA_OWNED); mtx_assert(&pcb->session->session_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Sending more credits, dlci=%d, state=%d, flags=%#x, mtu=%d, " \ "space=%ld, tx_cred=%d, rx_cred=%d\n", __func__, pcb->dlci, pcb->state, pcb->flags, pcb->mtu, sbspace(&pcb->so->so_rcv), pcb->tx_cred, pcb->rx_cred); credits = sbspace(&pcb->so->so_rcv) / pcb->mtu; if (credits > 0) { if (pcb->rx_cred + credits > RFCOMM_MAX_CREDITS) credits = RFCOMM_MAX_CREDITS - pcb->rx_cred; error = ng_btsocket_rfcomm_send_uih( pcb->session, RFCOMM_MKADDRESS(INITIATOR(pcb->session), pcb->dlci), 1, credits, NULL); if (error == 0) { pcb->rx_cred += credits; NG_BTSOCKET_RFCOMM_INFO( "%s: Gave remote side %d more credits, dlci=%d, state=%d, flags=%#x, " \ "rx_cred=%d, tx_cred=%d\n", __func__, credits, pcb->dlci, pcb->state, pcb->flags, pcb->rx_cred, pcb->tx_cred); } else NG_BTSOCKET_RFCOMM_ERR( "%s: Could not send credits, error=%d, dlci=%d, state=%d, flags=%#x, " \ "mtu=%d, space=%ld, tx_cred=%d, rx_cred=%d\n", __func__, error, pcb->dlci, pcb->state, pcb->flags, pcb->mtu, sbspace(&pcb->so->so_rcv), pcb->tx_cred, pcb->rx_cred); } return (error); } /* ng_btsocket_rfcomm_send_credits */ /***************************************************************************** ***************************************************************************** ** RFCOMM DLCs ***************************************************************************** *****************************************************************************/ /* * Send data from socket send buffer * Caller must hold pcb->pcb_mtx and pcb->session->session_mtx */ static int ng_btsocket_rfcomm_pcb_send(ng_btsocket_rfcomm_pcb_p pcb, int limit) { struct mbuf *m = NULL; int sent, length, error; mtx_assert(&pcb->session->session_mtx, MA_OWNED); mtx_assert(&pcb->pcb_mtx, MA_OWNED); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) limit = min(limit, pcb->tx_cred); else if (!(pcb->rmodem & RFCOMM_MODEM_FC)) limit = min(limit, RFCOMM_MAX_CREDITS); /* XXX ??? */ else limit = 0; if (limit == 0) { NG_BTSOCKET_RFCOMM_INFO( "%s: Could not send - remote flow control asserted, dlci=%d, flags=%#x, " \ "rmodem=%#x, tx_cred=%d\n", __func__, pcb->dlci, pcb->flags, pcb->rmodem, pcb->tx_cred); return (0); } for (error = 0, sent = 0; sent < limit; sent ++) { length = min(pcb->mtu, pcb->so->so_snd.sb_cc); if (length == 0) break; /* Get the chunk from the socket's send buffer */ m = ng_btsocket_rfcomm_prepare_packet(&pcb->so->so_snd, length); if (m == NULL) { error = ENOBUFS; break; } sbdrop(&pcb->so->so_snd, length); error = ng_btsocket_rfcomm_send_uih(pcb->session, RFCOMM_MKADDRESS(INITIATOR(pcb->session), pcb->dlci), 0, 0, m); if (error != 0) break; } if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_CFC) pcb->tx_cred -= sent; if (error == 0 && sent > 0) { pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_SENDING; sowwakeup(pcb->so); } return (error); } /* ng_btsocket_rfcomm_pcb_send */ /* * Unlink and disconnect DLC. If ng_btsocket_rfcomm_pcb_kill() returns * non zero value than socket has no reference and has to be detached. * Caller must hold pcb->pcb_mtx and pcb->session->session_mtx */ static int ng_btsocket_rfcomm_pcb_kill(ng_btsocket_rfcomm_pcb_p pcb, int error) { ng_btsocket_rfcomm_session_p s = pcb->session; mtx_assert(&pcb->session->session_mtx, MA_OWNED); mtx_assert(&pcb->pcb_mtx, MA_OWNED); NG_BTSOCKET_RFCOMM_INFO( "%s: Killing DLC, so=%p, dlci=%d, state=%d, flags=%#x, error=%d\n", __func__, pcb->so, pcb->dlci, pcb->state, pcb->flags, error); if (pcb->session == NULL) panic("%s: DLC without session, pcb=%p, state=%d, flags=%#x\n", __func__, pcb, pcb->state, pcb->flags); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO) ng_btsocket_rfcomm_untimeout(pcb); /* Detach DLC from the session. Does not matter which state DLC in */ LIST_REMOVE(pcb, session_next); pcb->session = NULL; /* Change DLC state and wakeup all sleepers */ pcb->state = NG_BTSOCKET_RFCOMM_DLC_CLOSED; pcb->so->so_error = error; soisdisconnected(pcb->so); wakeup(&pcb->state); /* Check if we have any DLCs left on the session */ if (LIST_EMPTY(&s->dlcs) && INITIATOR(s)) { NG_BTSOCKET_RFCOMM_INFO( "%s: Disconnecting session, state=%d, flags=%#x, mtu=%d\n", __func__, s->state, s->flags, s->mtu); switch (s->state) { case NG_BTSOCKET_RFCOMM_SESSION_CLOSED: case NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING: /* * Do not have to do anything here. We can get here * when L2CAP connection was terminated or we have * received DISC on multiplexor channel */ break; case NG_BTSOCKET_RFCOMM_SESSION_OPEN: /* Send DISC on multiplexor channel */ error = ng_btsocket_rfcomm_send_command(s, RFCOMM_FRAME_DISC, 0); if (error == 0) { s->state = NG_BTSOCKET_RFCOMM_SESSION_DISCONNECTING; break; } /* FALL THROUGH */ case NG_BTSOCKET_RFCOMM_SESSION_CONNECTING: case NG_BTSOCKET_RFCOMM_SESSION_CONNECTED: s->state = NG_BTSOCKET_RFCOMM_SESSION_CLOSED; break; /* case NG_BTSOCKET_RFCOMM_SESSION_LISTENING: */ default: panic("%s: Invalid session state=%d, flags=%#x\n", __func__, s->state, s->flags); break; } ng_btsocket_rfcomm_task_wakeup(); } return (pcb->so->so_state & SS_NOFDREF); } /* ng_btsocket_rfcomm_pcb_kill */ /* * Look for RFCOMM socket with given channel and source address */ static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_by_channel(bdaddr_p src, int channel) { ng_btsocket_rfcomm_pcb_p pcb = NULL; mtx_lock(&ng_btsocket_rfcomm_sockets_mtx); LIST_FOREACH(pcb, &ng_btsocket_rfcomm_sockets, next) if (pcb->channel == channel && bcmp(&pcb->src, src, sizeof(*src)) == 0) break; mtx_unlock(&ng_btsocket_rfcomm_sockets_mtx); return (pcb); } /* ng_btsocket_rfcomm_pcb_by_channel */ /* * Look for given dlci for given RFCOMM session. Caller must hold s->session_mtx */ static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_by_dlci(ng_btsocket_rfcomm_session_p s, int dlci) { ng_btsocket_rfcomm_pcb_p pcb = NULL; mtx_assert(&s->session_mtx, MA_OWNED); LIST_FOREACH(pcb, &s->dlcs, session_next) if (pcb->dlci == dlci) break; return (pcb); } /* ng_btsocket_rfcomm_pcb_by_dlci */ /* * Look for socket that listens on given src address and given channel */ static ng_btsocket_rfcomm_pcb_p ng_btsocket_rfcomm_pcb_listener(bdaddr_p src, int channel) { ng_btsocket_rfcomm_pcb_p pcb = NULL, pcb1 = NULL; mtx_lock(&ng_btsocket_rfcomm_sockets_mtx); LIST_FOREACH(pcb, &ng_btsocket_rfcomm_sockets, next) { if (pcb->channel != channel || !(pcb->so->so_options & SO_ACCEPTCONN)) continue; if (bcmp(&pcb->src, src, sizeof(*src)) == 0) break; if (bcmp(&pcb->src, NG_HCI_BDADDR_ANY, sizeof(bdaddr_t)) == 0) pcb1 = pcb; } mtx_unlock(&ng_btsocket_rfcomm_sockets_mtx); return ((pcb != NULL)? pcb : pcb1); } /* ng_btsocket_rfcomm_pcb_listener */ /***************************************************************************** ***************************************************************************** ** Misc. functions ***************************************************************************** *****************************************************************************/ /* * Set timeout. Caller MUST hold pcb_mtx */ static void ng_btsocket_rfcomm_timeout(ng_btsocket_rfcomm_pcb_p pcb) { mtx_assert(&pcb->pcb_mtx, MA_OWNED); if (!(pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO)) { pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_TIMO; pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT; pcb->timo = timeout(ng_btsocket_rfcomm_process_timeout, pcb, ng_btsocket_rfcomm_timo * hz); } else panic("%s: Duplicated socket timeout?!\n", __func__); } /* ng_btsocket_rfcomm_timeout */ /* * Unset pcb timeout. Caller MUST hold pcb_mtx */ static void ng_btsocket_rfcomm_untimeout(ng_btsocket_rfcomm_pcb_p pcb) { mtx_assert(&pcb->pcb_mtx, MA_OWNED); if (pcb->flags & NG_BTSOCKET_RFCOMM_DLC_TIMO) { untimeout(ng_btsocket_rfcomm_process_timeout, pcb, pcb->timo); pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_TIMO; pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT; } else panic("%s: No socket timeout?!\n", __func__); } /* ng_btsocket_rfcomm_timeout */ /* * Process pcb timeout */ static void ng_btsocket_rfcomm_process_timeout(void *xpcb) { ng_btsocket_rfcomm_pcb_p pcb = (ng_btsocket_rfcomm_pcb_p) xpcb; mtx_lock(&pcb->pcb_mtx); NG_BTSOCKET_RFCOMM_INFO( "%s: Timeout, so=%p, dlci=%d, state=%d, flags=%#x\n", __func__, pcb->so, pcb->dlci, pcb->state, pcb->flags); pcb->flags &= ~NG_BTSOCKET_RFCOMM_DLC_TIMO; pcb->flags |= NG_BTSOCKET_RFCOMM_DLC_TIMEDOUT; switch (pcb->state) { case NG_BTSOCKET_RFCOMM_DLC_CONFIGURING: case NG_BTSOCKET_RFCOMM_DLC_CONNECTING: pcb->state = NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING; break; case NG_BTSOCKET_RFCOMM_DLC_W4_CONNECT: case NG_BTSOCKET_RFCOMM_DLC_DISCONNECTING: break; default: panic( "%s: DLC timeout in invalid state, dlci=%d, state=%d, flags=%#x\n", __func__, pcb->dlci, pcb->state, pcb->flags); break; } ng_btsocket_rfcomm_task_wakeup(); mtx_unlock(&pcb->pcb_mtx); } /* ng_btsocket_rfcomm_process_timeout */ /* * Get up to length bytes from the socket buffer */ static struct mbuf * ng_btsocket_rfcomm_prepare_packet(struct sockbuf *sb, int length) { struct mbuf *top = NULL, *m = NULL, *n = NULL, *nextpkt = NULL; int mlen, noff, len; MGETHDR(top, M_DONTWAIT, MT_DATA); if (top == NULL) return (NULL); top->m_pkthdr.len = length; top->m_len = 0; mlen = MHLEN; m = top; n = sb->sb_mb; nextpkt = n->m_nextpkt; noff = 0; while (length > 0 && n != NULL) { len = min(mlen - m->m_len, n->m_len - noff); if (len > length) len = length; bcopy(mtod(n, caddr_t)+noff, mtod(m, caddr_t)+m->m_len, len); m->m_len += len; noff += len; length -= len; if (length > 0 && m->m_len == mlen) { MGET(m->m_next, M_DONTWAIT, MT_DATA); if (m->m_next == NULL) { NG_FREE_M(top); return (NULL); } m = m->m_next; m->m_len = 0; mlen = MLEN; } if (noff == n->m_len) { noff = 0; n = n->m_next; if (n == NULL) n = nextpkt; nextpkt = (n != NULL)? n->m_nextpkt : NULL; } } if (length < 0) panic("%s: length=%d\n", __func__, length); if (length > 0 && n == NULL) panic("%s: bogus length=%d, n=%p\n", __func__, length, n); return (top); } /* ng_btsocket_rfcomm_prepare_packet */