/* $OpenBSD: hci_link.c,v 1.3 2007/06/06 18:32:55 uwe Exp $ */ /* $NetBSD: hci_link.c,v 1.11 2007/04/21 06:15:23 plunky Exp $ */ /*- * Copyright (c) 2005 Iain Hibbert. * Copyright (c) 2006 Itronix Inc. * 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. * 3. The name of Itronix Inc. may not be used to endorse * or promote products derived from this software without specific * prior written permission. * * THIS SOFTWARE IS PROVIDED BY ITRONIX INC. ``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 ITRONIX INC. 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. */ #include #include #include #include #include #include #include #include #include #include #include #include /******************************************************************************* * * HCI ACL Connections */ /* * Automatically expire unused ACL connections after this number of * seconds (if zero, do not expire unused connections) [sysctl] */ int hci_acl_expiry = 10; /* seconds */ /* * hci_acl_open(unit, bdaddr) * * open ACL connection to remote bdaddr. Only one ACL connection is permitted * between any two Bluetooth devices, so we look for an existing one before * trying to start a new one. */ struct hci_link * hci_acl_open(struct hci_unit *unit, bdaddr_t *bdaddr) { struct hci_link *link; struct hci_memo *memo; hci_create_con_cp cp; int err; KASSERT(unit != NULL); KASSERT(bdaddr != NULL); link = hci_link_lookup_bdaddr(unit, bdaddr, HCI_LINK_ACL); if (link == NULL) { link = hci_link_alloc(unit); if (link == NULL) return NULL; link->hl_type = HCI_LINK_ACL; bdaddr_copy(&link->hl_bdaddr, bdaddr); } switch(link->hl_state) { case HCI_LINK_CLOSED: /* * open connection to remote device */ memset(&cp, 0, sizeof(cp)); bdaddr_copy(&cp.bdaddr, bdaddr); cp.pkt_type = htole16(unit->hci_packet_type); memo = hci_memo_find(unit, bdaddr); if (memo != NULL) { cp.page_scan_rep_mode = memo->response.page_scan_rep_mode; cp.page_scan_mode = memo->response.page_scan_mode; cp.clock_offset = htole16(memo->response.clock_offset); } if (unit->hci_link_policy & HCI_LINK_POLICY_ENABLE_ROLE_SWITCH) cp.accept_role_switch = 1; err = hci_send_cmd(unit, HCI_CMD_CREATE_CON, &cp, sizeof(cp)); if (err) { hci_link_free(link, err); return NULL; } link->hl_state = HCI_LINK_WAIT_CONNECT; break; case HCI_LINK_WAIT_CONNECT: case HCI_LINK_WAIT_AUTH: case HCI_LINK_WAIT_ENCRYPT: case HCI_LINK_WAIT_SECURE: /* * somebody else already trying to connect, we just * sit on the bench with them.. */ break; case HCI_LINK_OPEN: /* * If already open, halt any expiry timeouts. We dont need * to care about already invoking timeouts since refcnt >0 * will keep the link alive. */ timeout_del(&link->hl_expire); break; default: UNKNOWN(link->hl_state); return NULL; } /* open */ link->hl_refcnt++; return link; } /* * Close ACL connection. When there are no more references to this link, * we can either close it down or schedule a delayed closedown. */ void hci_acl_close(struct hci_link *link, int err) { KASSERT(link != NULL); if (--link->hl_refcnt == 0) { if (link->hl_state == HCI_LINK_CLOSED) hci_link_free(link, err); else if (hci_acl_expiry > 0) timeout_add(&link->hl_expire, hci_acl_expiry * hz); } } /* * Incoming ACL connection. * * For now, we accept all connections but it would be better to check * the L2CAP listen list and only accept when there is a listener * available. * * There should not be a link to the same bdaddr already, we check * anyway though its left unhandled for now. */ struct hci_link * hci_acl_newconn(struct hci_unit *unit, bdaddr_t *bdaddr) { struct hci_link *link; link = hci_link_lookup_bdaddr(unit, bdaddr, HCI_LINK_ACL); if (link != NULL) return NULL; link = hci_link_alloc(unit); if (link != NULL) { link->hl_state = HCI_LINK_WAIT_CONNECT; link->hl_type = HCI_LINK_ACL; bdaddr_copy(&link->hl_bdaddr, bdaddr); if (hci_acl_expiry > 0) timeout_add(&link->hl_expire, hci_acl_expiry * hz); } return link; } void hci_acl_timeout(void *arg) { struct hci_link *link = arg; hci_discon_cp cp; int s, err; s = splsoftnet(); if (link->hl_refcnt > 0) goto out; DPRINTF("link #%d expired\n", link->hl_handle); switch (link->hl_state) { case HCI_LINK_CLOSED: case HCI_LINK_WAIT_CONNECT: hci_link_free(link, ECONNRESET); break; case HCI_LINK_WAIT_AUTH: case HCI_LINK_WAIT_ENCRYPT: case HCI_LINK_WAIT_SECURE: case HCI_LINK_OPEN: cp.con_handle = htole16(link->hl_handle); cp.reason = 0x13; /* "Remote User Terminated Connection" */ err = hci_send_cmd(link->hl_unit, HCI_CMD_DISCONNECT, &cp, sizeof(cp)); if (err) { DPRINTF("error %d sending HCI_CMD_DISCONNECT\n", err); } break; default: UNKNOWN(link->hl_state); break; } out: splx(s); } /* * Initiate any Link Mode change requests. */ int hci_acl_setmode(struct hci_link *link) { int err; KASSERT(link != NULL); KASSERT(link->hl_unit != NULL); if (link->hl_state != HCI_LINK_OPEN) return EINPROGRESS; if ((link->hl_flags & HCI_LINK_AUTH_REQ) && !(link->hl_flags & HCI_LINK_AUTH)) { hci_auth_req_cp cp; DPRINTF("requesting auth for handle #%d\n", link->hl_handle); link->hl_state = HCI_LINK_WAIT_AUTH; cp.con_handle = htole16(link->hl_handle); err = hci_send_cmd(link->hl_unit, HCI_CMD_AUTH_REQ, &cp, sizeof(cp)); return (err == 0 ? EINPROGRESS : err); } if ((link->hl_flags & HCI_LINK_ENCRYPT_REQ) && !(link->hl_flags & HCI_LINK_ENCRYPT)) { hci_set_con_encryption_cp cp; /* XXX we should check features for encryption capability */ DPRINTF("requesting encryption for handle #%d\n", link->hl_handle); link->hl_state = HCI_LINK_WAIT_ENCRYPT; cp.con_handle = htole16(link->hl_handle); cp.encryption_enable = 0x01; err = hci_send_cmd(link->hl_unit, HCI_CMD_SET_CON_ENCRYPTION, &cp, sizeof(cp)); return (err == 0 ? EINPROGRESS : err); } if ((link->hl_flags & HCI_LINK_SECURE_REQ)) { hci_change_con_link_key_cp cp; /* always change link key for SECURE requests */ link->hl_flags &= ~HCI_LINK_SECURE; DPRINTF("changing link key for handle #%d\n", link->hl_handle); link->hl_state = HCI_LINK_WAIT_SECURE; cp.con_handle = htole16(link->hl_handle); err = hci_send_cmd(link->hl_unit, HCI_CMD_CHANGE_CON_LINK_KEY, &cp, sizeof(cp)); return (err == 0 ? EINPROGRESS : err); } return 0; } /* * Link Mode changed. * * This is called from event handlers when the mode change * is complete. We notify upstream and restart the link. */ void hci_acl_linkmode(struct hci_link *link) { struct l2cap_channel *chan, *next; int err, mode = 0; DPRINTF("handle #%d, auth %s, encrypt %s, secure %s\n", link->hl_handle, (link->hl_flags & HCI_LINK_AUTH ? "on" : "off"), (link->hl_flags & HCI_LINK_ENCRYPT ? "on" : "off"), (link->hl_flags & HCI_LINK_SECURE ? "on" : "off")); if (link->hl_flags & HCI_LINK_AUTH) mode |= L2CAP_LM_AUTH; if (link->hl_flags & HCI_LINK_ENCRYPT) mode |= L2CAP_LM_ENCRYPT; if (link->hl_flags & HCI_LINK_SECURE) mode |= L2CAP_LM_SECURE; /* * The link state will only be OPEN here if the mode change * was successful. So, we can proceed with L2CAP connections, * or notify already establshed channels, to allow any that * are dissatisfied to disconnect before we restart. */ next = LIST_FIRST(&l2cap_active_list); while ((chan = next) != NULL) { next = LIST_NEXT(chan, lc_ncid); if (chan->lc_link != link) continue; switch(chan->lc_state) { case L2CAP_WAIT_SEND_CONNECT_REQ: /* we are connecting */ if ((mode & chan->lc_mode) != chan->lc_mode) { l2cap_close(chan, ECONNABORTED); break; } chan->lc_state = L2CAP_WAIT_RECV_CONNECT_RSP; err = l2cap_send_connect_req(chan); if (err) { l2cap_close(chan, err); break; } break; case L2CAP_WAIT_SEND_CONNECT_RSP: /* they are connecting */ if ((mode & chan->lc_mode) != chan->lc_mode) { l2cap_send_connect_rsp(link, chan->lc_ident, 0, chan->lc_rcid, L2CAP_SECURITY_BLOCK); l2cap_close(chan, ECONNABORTED); break; } l2cap_send_connect_rsp(link, chan->lc_ident, chan->lc_lcid, chan->lc_rcid, L2CAP_SUCCESS); chan->lc_state = L2CAP_WAIT_CONFIG; chan->lc_flags |= (L2CAP_WAIT_CONFIG_RSP | L2CAP_WAIT_CONFIG_REQ); err = l2cap_send_config_req(chan); if (err) { l2cap_close(chan, err); break; } break; case L2CAP_WAIT_RECV_CONNECT_RSP: case L2CAP_WAIT_CONFIG: case L2CAP_OPEN: /* already established */ (*chan->lc_proto->linkmode)(chan->lc_upper, mode); break; default: break; } } link->hl_state = HCI_LINK_OPEN; hci_acl_start(link); } /* * Receive ACL Data * * we accumulate packet fragments on the hci_link structure * until a full L2CAP frame is ready, then send it on. */ void hci_acl_recv(struct mbuf *m, struct hci_unit *unit) { struct hci_link *link; hci_acldata_hdr_t hdr; uint16_t handle, want; int pb, got; KASSERT(m != NULL); KASSERT(unit != NULL); KASSERT(m->m_pkthdr.len >= sizeof(hdr)); m_copydata(m, 0, sizeof(hdr), (caddr_t)&hdr); m_adj(m, sizeof(hdr)); #ifdef DIAGNOSTIC if (hdr.type != HCI_ACL_DATA_PKT) { printf("%s: bad ACL packet type\n", unit->hci_devname); goto bad; } if (m->m_pkthdr.len != letoh16(hdr.length)) { printf("%s: bad ACL packet length (%d != %d)\n", unit->hci_devname, m->m_pkthdr.len, letoh16(hdr.length)); goto bad; } #endif hdr.length = letoh16(hdr.length); hdr.con_handle = letoh16(hdr.con_handle); handle = HCI_CON_HANDLE(hdr.con_handle); pb = HCI_PB_FLAG(hdr.con_handle); link = hci_link_lookup_handle(unit, handle); if (link == NULL) { hci_discon_cp cp; DPRINTF("%s: dumping packet for unknown handle #%d\n", unit->hci_devname, handle); /* * There is no way to find out what this connection handle is * for, just get rid of it. This may happen, if a USB dongle * is plugged into a self powered hub and does not reset when * the system is shut down. */ cp.con_handle = htole16(handle); cp.reason = 0x13; /* "Remote User Terminated Connection" */ hci_send_cmd(unit, HCI_CMD_DISCONNECT, &cp, sizeof(cp)); goto bad; } switch (pb) { case HCI_PACKET_START: if (link->hl_rxp != NULL) printf("%s: dropped incomplete ACL packet\n", unit->hci_devname); if (m->m_pkthdr.len < sizeof(l2cap_hdr_t)) { printf("%s: short ACL packet\n", unit->hci_devname); goto bad; } link->hl_rxp = m; got = m->m_pkthdr.len; break; case HCI_PACKET_FRAGMENT: if (link->hl_rxp == NULL) { printf("%s: unexpected packet fragment\n", unit->hci_devname); goto bad; } got = m->m_pkthdr.len + link->hl_rxp->m_pkthdr.len; m_cat(link->hl_rxp, m); m = link->hl_rxp; m->m_pkthdr.len = got; break; default: printf("%s: unknown packet type\n", unit->hci_devname); goto bad; } m_copydata(m, 0, sizeof(want), (caddr_t)&want); want = letoh16(want) + sizeof(l2cap_hdr_t) - got; if (want > 0) return; link->hl_rxp = NULL; if (want == 0) { l2cap_recv_frame(m, link); return; } bad: m_freem(m); } /* * Send ACL data on link * * We must fragment packets into chunks of less than unit->hci_max_acl_size and * prepend a relevant ACL header to each fragment. We keep a PDU structure * attached to the link, so that completed fragments can be marked off and * more data requested from above once the PDU is sent. */ int hci_acl_send(struct mbuf *m, struct hci_link *link, struct l2cap_channel *chan) { struct l2cap_pdu *pdu; struct mbuf *n = NULL; int plen, mlen, num = 0; KASSERT(link != NULL); KASSERT(m != NULL); KASSERT(m->m_flags & M_PKTHDR); KASSERT(m->m_pkthdr.len > 0); if (link->hl_state == HCI_LINK_CLOSED) { m_freem(m); return ENETDOWN; } pdu = pool_get(&l2cap_pdu_pool, PR_NOWAIT); if (pdu == NULL) goto nomem; bzero(pdu, sizeof *pdu); pdu->lp_chan = chan; pdu->lp_pending = 0; plen = m->m_pkthdr.len; mlen = link->hl_unit->hci_max_acl_size; DPRINTFN(5, "%s: handle #%d, plen = %d, max = %d\n", link->hl_unit->hci_devname, link->hl_handle, plen, mlen); while (plen > 0) { if (plen > mlen) { n = m_split(m, mlen, M_DONTWAIT); if (n == NULL) goto nomem; } else { mlen = plen; } if (num++ == 0) m->m_flags |= M_PROTO1; /* tag first fragment */ DPRINTFN(10, "chunk of %d (plen = %d) bytes\n", mlen, plen); IF_ENQUEUE(&pdu->lp_data, m); m = n; plen -= mlen; } TAILQ_INSERT_TAIL(&link->hl_txq, pdu, lp_next); link->hl_txqlen += num; hci_acl_start(link); return 0; nomem: if (m) m_freem(m); if (pdu) { IF_PURGE(&pdu->lp_data); pool_put(&l2cap_pdu_pool, pdu); } return ENOMEM; } /* * Start sending ACL data on link. * * This is called when the queue may need restarting: as new data * is queued, after link mode changes have completed, or when device * buffers have cleared. * * We may use all the available packet slots. The reason that we add * the ACL encapsulation here rather than in hci_acl_send() is that L2CAP * signal packets may be queued before the handle is given to us.. */ void hci_acl_start(struct hci_link *link) { struct hci_unit *unit; hci_acldata_hdr_t *hdr; struct l2cap_pdu *pdu; struct mbuf *m; uint16_t handle; KASSERT(link != NULL); unit = link->hl_unit; KASSERT(unit != NULL); /* this is mainly to block ourselves (below) */ if (link->hl_state != HCI_LINK_OPEN) return; if (link->hl_txqlen == 0 || unit->hci_num_acl_pkts == 0) return; /* find first PDU with data to send */ pdu = TAILQ_FIRST(&link->hl_txq); for (;;) { if (pdu == NULL) return; if (!IF_IS_EMPTY(&pdu->lp_data)) break; pdu = TAILQ_NEXT(pdu, lp_next); } while (unit->hci_num_acl_pkts > 0) { IF_DEQUEUE(&pdu->lp_data, m); KASSERT(m != NULL); if (m->m_flags & M_PROTO1) handle = HCI_MK_CON_HANDLE(link->hl_handle, HCI_PACKET_START, 0); else handle = HCI_MK_CON_HANDLE(link->hl_handle, HCI_PACKET_FRAGMENT, 0); M_PREPEND(m, sizeof(*hdr), M_DONTWAIT); if (m == NULL) break; hdr = mtod(m, hci_acldata_hdr_t *); hdr->type = HCI_ACL_DATA_PKT; hdr->con_handle = htole16(handle); hdr->length = htole16(m->m_pkthdr.len - sizeof(*hdr)); link->hl_txqlen--; pdu->lp_pending++; hci_output_acl(unit, m); if (IF_IS_EMPTY(&pdu->lp_data)) { if (pdu->lp_chan) { /* * This should enable streaming of PDUs - when * we have placed all the fragments on the acl * output queue, we trigger the L2CAP layer to * send us down one more. Use a false state so * we dont run into ourselves coming back from * the future.. */ link->hl_state = HCI_LINK_BLOCK; l2cap_start(pdu->lp_chan); link->hl_state = HCI_LINK_OPEN; } pdu = TAILQ_NEXT(pdu, lp_next); if (pdu == NULL) break; } } /* * We had our turn now, move to the back of the queue to let * other links have a go at the output buffers.. */ if (TAILQ_NEXT(link, hl_next)) { TAILQ_REMOVE(&unit->hci_links, link, hl_next); TAILQ_INSERT_TAIL(&unit->hci_links, link, hl_next); } } /* * Confirm ACL packets cleared from Controller buffers. We scan our PDU * list to clear pending fragments and signal upstream for more data * when a PDU is complete. */ void hci_acl_complete(struct hci_link *link, int num) { struct l2cap_pdu *pdu; struct l2cap_channel *chan; DPRINTFN(5, "handle #%d (%d)\n", link->hl_handle, num); while (num > 0) { pdu = TAILQ_FIRST(&link->hl_txq); if (pdu == NULL) { printf("%s: %d packets completed on handle #%x " "but none pending!\n", link->hl_unit->hci_devname, num, link->hl_handle); return; } if (num >= pdu->lp_pending) { num -= pdu->lp_pending; pdu->lp_pending = 0; if (IF_IS_EMPTY(&pdu->lp_data)) { TAILQ_REMOVE(&link->hl_txq, pdu, lp_next); chan = pdu->lp_chan; if (chan != NULL) { chan->lc_pending--; (*chan->lc_proto->complete) (chan->lc_upper, 1); if (chan->lc_pending == 0) l2cap_start(chan); } pool_put(&l2cap_pdu_pool, pdu); } } else { pdu->lp_pending -= num; num = 0; } } } /******************************************************************************* * * HCI SCO Connections */ /* * Incoming SCO Connection. We check the list for anybody willing * to take it. */ struct hci_link * hci_sco_newconn(struct hci_unit *unit, bdaddr_t *bdaddr) { struct sockaddr_bt laddr, raddr; struct sco_pcb *pcb, *new; struct hci_link *sco, *acl; memset(&laddr, 0, sizeof(laddr)); laddr.bt_len = sizeof(laddr); laddr.bt_family = AF_BLUETOOTH; bdaddr_copy(&laddr.bt_bdaddr, &unit->hci_bdaddr); memset(&raddr, 0, sizeof(raddr)); raddr.bt_len = sizeof(raddr); raddr.bt_family = AF_BLUETOOTH; bdaddr_copy(&raddr.bt_bdaddr, bdaddr); /* * There should already be an ACL link up and running before * the controller sends us SCO connection requests, but you * never know.. */ acl = hci_link_lookup_bdaddr(unit, bdaddr, HCI_LINK_ACL); if (acl == NULL || acl->hl_state != HCI_LINK_OPEN) return NULL; LIST_FOREACH(pcb, &sco_pcb, sp_next) { if ((pcb->sp_flags & SP_LISTENING) == 0) continue; new = (*pcb->sp_proto->newconn)(pcb->sp_upper, &laddr, &raddr); if (new == NULL) continue; /* * Ok, got new pcb so we can start a new link and fill * in all the details. */ bdaddr_copy(&new->sp_laddr, &unit->hci_bdaddr); bdaddr_copy(&new->sp_raddr, bdaddr); sco = hci_link_alloc(unit); if (sco == NULL) { sco_detach(&new); return NULL; } sco->hl_type = HCI_LINK_SCO; bdaddr_copy(&sco->hl_bdaddr, bdaddr); sco->hl_link = hci_acl_open(unit, bdaddr); KASSERT(sco->hl_link == acl); sco->hl_sco = new; new->sp_link = sco; new->sp_mtu = unit->hci_max_sco_size; return sco; } return NULL; } /* * receive SCO packet, we only need to strip the header and send * it to the right handler */ void hci_sco_recv(struct mbuf *m, struct hci_unit *unit) { struct hci_link *link; hci_scodata_hdr_t hdr; uint16_t handle; KASSERT(m != NULL); KASSERT(unit != NULL); KASSERT(m->m_pkthdr.len >= sizeof(hdr)); m_copydata(m, 0, sizeof(hdr), (caddr_t)&hdr); m_adj(m, sizeof(hdr)); #ifdef DIAGNOSTIC if (hdr.type != HCI_SCO_DATA_PKT) { printf("%s: bad SCO packet type\n", unit->hci_devname); goto bad; } if (m->m_pkthdr.len != hdr.length) { printf("%s: bad SCO packet length (%d != %d)\n", unit->hci_devname, m->m_pkthdr.len, hdr.length); goto bad; } #endif hdr.con_handle = letoh16(hdr.con_handle); handle = HCI_CON_HANDLE(hdr.con_handle); link = hci_link_lookup_handle(unit, handle); if (link == NULL || link->hl_type == HCI_LINK_ACL) { DPRINTF("%s: dumping packet for unknown handle #%d\n", unit->hci_devname, handle); goto bad; } (*link->hl_sco->sp_proto->input)(link->hl_sco->sp_upper, m); return; bad: m_freem(m); } void hci_sco_start(struct hci_link *link) { } /* * SCO packets have completed at the controller, so we can * signal up to free the buffer space. */ void hci_sco_complete(struct hci_link *link, int num) { DPRINTFN(5, "handle #%d (num=%d)\n", link->hl_handle, num); link->hl_sco->sp_pending--; (*link->hl_sco->sp_proto->complete)(link->hl_sco->sp_upper, num); } /******************************************************************************* * * Generic HCI Connection alloc/free/lookup etc */ struct hci_link * hci_link_alloc(struct hci_unit *unit) { struct hci_link *link; KASSERT(unit != NULL); link = malloc(sizeof *link, M_BLUETOOTH, M_NOWAIT); if (link == NULL) return NULL; bzero(link, sizeof *link); link->hl_unit = unit; link->hl_state = HCI_LINK_CLOSED; /* init ACL portion */ timeout_set(&link->hl_expire, hci_acl_timeout, link); TAILQ_INIT(&link->hl_txq); /* outgoing packets */ TAILQ_INIT(&link->hl_reqs); /* request queue */ link->hl_mtu = L2CAP_MTU_DEFAULT; /* L2CAP signal mtu */ link->hl_flush = L2CAP_FLUSH_TIMO_DEFAULT; /* flush timeout */ /* attach to unit */ TAILQ_INSERT_HEAD(&unit->hci_links, link, hl_next); return link; } void hci_link_free(struct hci_link *link, int err) { struct l2cap_req *req; struct l2cap_pdu *pdu; struct l2cap_channel *chan, *next; KASSERT(link != NULL); DPRINTF("#%d, type = %d, state = %d, refcnt = %d\n", link->hl_handle, link->hl_type, link->hl_state, link->hl_refcnt); /* ACL reference count */ if (link->hl_refcnt > 0) { next = LIST_FIRST(&l2cap_active_list); while ((chan = next) != NULL) { next = LIST_NEXT(chan, lc_ncid); if (chan->lc_link == link) l2cap_close(chan, err); } } KASSERT(link->hl_refcnt == 0); /* ACL L2CAP requests.. */ while ((req = TAILQ_FIRST(&link->hl_reqs)) != NULL) l2cap_request_free(req); KASSERT(TAILQ_EMPTY(&link->hl_reqs)); /* ACL outgoing data queue */ while ((pdu = TAILQ_FIRST(&link->hl_txq)) != NULL) { TAILQ_REMOVE(&link->hl_txq, pdu, lp_next); IF_PURGE(&pdu->lp_data); if (pdu->lp_pending) link->hl_unit->hci_num_acl_pkts += pdu->lp_pending; pool_put(&l2cap_pdu_pool, pdu); } KASSERT(TAILQ_EMPTY(&link->hl_txq)); /* ACL incoming data packet */ if (link->hl_rxp != NULL) { m_freem(link->hl_rxp); link->hl_rxp = NULL; } /* SCO master ACL link */ if (link->hl_link != NULL) { hci_acl_close(link->hl_link, err); link->hl_link = NULL; } /* SCO pcb */ if (link->hl_sco != NULL) { struct sco_pcb *pcb; pcb = link->hl_sco; pcb->sp_link = NULL; link->hl_sco = NULL; (*pcb->sp_proto->disconnected)(pcb->sp_upper, err); } /* flush any SCO data */ IF_PURGE(&link->hl_data); /* * Halt the timeout - if its already running we cannot free the * link structure but the timeout function will call us back in * any case. */ link->hl_state = HCI_LINK_CLOSED; timeout_del(&link->hl_expire); if (timeout_triggered(&link->hl_expire)) return; TAILQ_REMOVE(&link->hl_unit->hci_links, link, hl_next); free(link, M_BLUETOOTH); } /* * Lookup HCI link by address and type. Note that for SCO links there may * be more than one link per address, so we only return links with no * handle (ie new links) */ struct hci_link * hci_link_lookup_bdaddr(struct hci_unit *unit, bdaddr_t *bdaddr, uint16_t type) { struct hci_link *link; KASSERT(unit != NULL); KASSERT(bdaddr != NULL); TAILQ_FOREACH(link, &unit->hci_links, hl_next) { if (link->hl_type != type) continue; if (type == HCI_LINK_SCO && link->hl_handle != 0) continue; if (bdaddr_same(&link->hl_bdaddr, bdaddr)) break; } return link; } struct hci_link * hci_link_lookup_handle(struct hci_unit *unit, uint16_t handle) { struct hci_link *link; KASSERT(unit != NULL); TAILQ_FOREACH(link, &unit->hci_links, hl_next) { if (handle == link->hl_handle) break; } return link; }