/* $Id: capi.c,v 1.9.6.2 2001/09/23 22:24:32 kai Exp $ * * ISDN lowlevel-module for the IBM ISDN-S0 Active 2000. * CAPI encoder/decoder * * Author Fritz Elfert * Copyright by Fritz Elfert * * This software may be used and distributed according to the terms * of the GNU General Public License, incorporated herein by reference. * * Thanks to Friedemann Baitinger and IBM Germany * */ #include "act2000.h" #include "capi.h" static actcapi_msgdsc valid_msg[] = { {{ 0x86, 0x02}, "DATA_B3_IND"}, /* DATA_B3_IND/CONF must be first because of speed!!! */ {{ 0x86, 0x01}, "DATA_B3_CONF"}, {{ 0x02, 0x01}, "CONNECT_CONF"}, {{ 0x02, 0x02}, "CONNECT_IND"}, {{ 0x09, 0x01}, "CONNECT_INFO_CONF"}, {{ 0x03, 0x02}, "CONNECT_ACTIVE_IND"}, {{ 0x04, 0x01}, "DISCONNECT_CONF"}, {{ 0x04, 0x02}, "DISCONNECT_IND"}, {{ 0x05, 0x01}, "LISTEN_CONF"}, {{ 0x06, 0x01}, "GET_PARAMS_CONF"}, {{ 0x07, 0x01}, "INFO_CONF"}, {{ 0x07, 0x02}, "INFO_IND"}, {{ 0x08, 0x01}, "DATA_CONF"}, {{ 0x08, 0x02}, "DATA_IND"}, {{ 0x40, 0x01}, "SELECT_B2_PROTOCOL_CONF"}, {{ 0x80, 0x01}, "SELECT_B3_PROTOCOL_CONF"}, {{ 0x81, 0x01}, "LISTEN_B3_CONF"}, {{ 0x82, 0x01}, "CONNECT_B3_CONF"}, {{ 0x82, 0x02}, "CONNECT_B3_IND"}, {{ 0x83, 0x02}, "CONNECT_B3_ACTIVE_IND"}, {{ 0x84, 0x01}, "DISCONNECT_B3_CONF"}, {{ 0x84, 0x02}, "DISCONNECT_B3_IND"}, {{ 0x85, 0x01}, "GET_B3_PARAMS_CONF"}, {{ 0x01, 0x01}, "RESET_B3_CONF"}, {{ 0x01, 0x02}, "RESET_B3_IND"}, /* {{ 0x87, 0x02, "HANDSET_IND"}, not implemented */ {{ 0xff, 0x01}, "MANUFACTURER_CONF"}, {{ 0xff, 0x02}, "MANUFACTURER_IND"}, #ifdef DEBUG_MSG /* Requests */ {{ 0x01, 0x00}, "RESET_B3_REQ"}, {{ 0x02, 0x00}, "CONNECT_REQ"}, {{ 0x04, 0x00}, "DISCONNECT_REQ"}, {{ 0x05, 0x00}, "LISTEN_REQ"}, {{ 0x06, 0x00}, "GET_PARAMS_REQ"}, {{ 0x07, 0x00}, "INFO_REQ"}, {{ 0x08, 0x00}, "DATA_REQ"}, {{ 0x09, 0x00}, "CONNECT_INFO_REQ"}, {{ 0x40, 0x00}, "SELECT_B2_PROTOCOL_REQ"}, {{ 0x80, 0x00}, "SELECT_B3_PROTOCOL_REQ"}, {{ 0x81, 0x00}, "LISTEN_B3_REQ"}, {{ 0x82, 0x00}, "CONNECT_B3_REQ"}, {{ 0x84, 0x00}, "DISCONNECT_B3_REQ"}, {{ 0x85, 0x00}, "GET_B3_PARAMS_REQ"}, {{ 0x86, 0x00}, "DATA_B3_REQ"}, {{ 0xff, 0x00}, "MANUFACTURER_REQ"}, /* Responses */ {{ 0x01, 0x03}, "RESET_B3_RESP"}, {{ 0x02, 0x03}, "CONNECT_RESP"}, {{ 0x03, 0x03}, "CONNECT_ACTIVE_RESP"}, {{ 0x04, 0x03}, "DISCONNECT_RESP"}, {{ 0x07, 0x03}, "INFO_RESP"}, {{ 0x08, 0x03}, "DATA_RESP"}, {{ 0x82, 0x03}, "CONNECT_B3_RESP"}, {{ 0x83, 0x03}, "CONNECT_B3_ACTIVE_RESP"}, {{ 0x84, 0x03}, "DISCONNECT_B3_RESP"}, {{ 0x86, 0x03}, "DATA_B3_RESP"}, {{ 0xff, 0x03}, "MANUFACTURER_RESP"}, #endif {{ 0x00, 0x00}, NULL}, }; #define num_valid_msg (sizeof(valid_msg)/sizeof(actcapi_msgdsc)) #define num_valid_imsg 27 /* MANUFACTURER_IND */ /* * Check for a valid incoming CAPI message. * Return: * 0 = Invalid message * 1 = Valid message, no B-Channel-data * 2 = Valid message, B-Channel-data */ int actcapi_chkhdr(act2000_card * card, actcapi_msghdr *hdr) { int i; if (hdr->applicationID != 1) return 0; if (hdr->len < 9) return 0; for (i = 0; i < num_valid_imsg; i++) if ((hdr->cmd.cmd == valid_msg[i].cmd.cmd) && (hdr->cmd.subcmd == valid_msg[i].cmd.subcmd)) { return (i?1:2); } return 0; } #define ACTCAPI_MKHDR(l, c, s) { \ skb = alloc_skb(l + 8, GFP_ATOMIC); \ if (skb) { \ m = (actcapi_msg *)skb_put(skb, l + 8); \ m->hdr.len = l + 8; \ m->hdr.applicationID = 1; \ m->hdr.cmd.cmd = c; \ m->hdr.cmd.subcmd = s; \ m->hdr.msgnum = actcapi_nextsmsg(card); \ } else m = NULL;\ } #define ACTCAPI_CHKSKB if (!skb) { \ printk(KERN_WARNING "actcapi: alloc_skb failed\n"); \ return; \ } #define ACTCAPI_QUEUE_TX { \ actcapi_debug_msg(skb, 1); \ skb_queue_tail(&card->sndq, skb); \ act2000_schedule_tx(card); \ } int actcapi_listen_req(act2000_card *card) { __u16 eazmask = 0; int i; actcapi_msg *m; struct sk_buff *skb; for (i = 0; i < ACT2000_BCH; i++) eazmask |= card->bch[i].eazmask; ACTCAPI_MKHDR(9, 0x05, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return -ENOMEM; } m->msg.listen_req.controller = 0; m->msg.listen_req.infomask = 0x3f; /* All information */ m->msg.listen_req.eazmask = eazmask; m->msg.listen_req.simask = (eazmask)?0x86:0; /* All SI's */ ACTCAPI_QUEUE_TX; return 0; } int actcapi_connect_req(act2000_card *card, act2000_chan *chan, char *phone, char eaz, int si1, int si2) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR((11 + strlen(phone)), 0x02, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); chan->fsm_state = ACT2000_STATE_NULL; return -ENOMEM; } m->msg.connect_req.controller = 0; m->msg.connect_req.bchan = 0x83; m->msg.connect_req.infomask = 0x3f; m->msg.connect_req.si1 = si1; m->msg.connect_req.si2 = si2; m->msg.connect_req.eaz = eaz?eaz:'0'; m->msg.connect_req.addr.len = strlen(phone) + 1; m->msg.connect_req.addr.tnp = 0x81; memcpy(m->msg.connect_req.addr.num, phone, strlen(phone)); chan->callref = m->hdr.msgnum; ACTCAPI_QUEUE_TX; return 0; } static void actcapi_connect_b3_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(17, 0x82, 0x00); ACTCAPI_CHKSKB; m->msg.connect_b3_req.plci = chan->plci; memset(&m->msg.connect_b3_req.ncpi, 0, sizeof(m->msg.connect_b3_req.ncpi)); m->msg.connect_b3_req.ncpi.len = 13; m->msg.connect_b3_req.ncpi.modulo = 8; ACTCAPI_QUEUE_TX; } /* * Set net type (1TR6) or (EDSS1) */ int actcapi_manufacturer_req_net(act2000_card *card) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(5, 0xff, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return -ENOMEM; } m->msg.manufacturer_req_net.manuf_msg = 0x11; m->msg.manufacturer_req_net.controller = 1; m->msg.manufacturer_req_net.nettype = (card->ptype == ISDN_PTYPE_EURO)?1:0; ACTCAPI_QUEUE_TX; printk(KERN_INFO "act2000 %s: D-channel protocol now %s\n", card->interface.id, (card->ptype == ISDN_PTYPE_EURO)?"euro":"1tr6"); card->interface.features &= ~(ISDN_FEATURE_P_UNKNOWN | ISDN_FEATURE_P_EURO | ISDN_FEATURE_P_1TR6); card->interface.features |= ((card->ptype == ISDN_PTYPE_EURO)?ISDN_FEATURE_P_EURO:ISDN_FEATURE_P_1TR6); return 0; } /* * Switch V.42 on or off */ #if 0 int actcapi_manufacturer_req_v42(act2000_card *card, ulong arg) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(8, 0xff, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return -ENOMEM; } m->msg.manufacturer_req_v42.manuf_msg = 0x10; m->msg.manufacturer_req_v42.controller = 0; m->msg.manufacturer_req_v42.v42control = (arg?1:0); ACTCAPI_QUEUE_TX; return 0; } #endif /* 0 */ /* * Set error-handler */ int actcapi_manufacturer_req_errh(act2000_card *card) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(4, 0xff, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return -ENOMEM; } m->msg.manufacturer_req_err.manuf_msg = 0x03; m->msg.manufacturer_req_err.controller = 0; ACTCAPI_QUEUE_TX; return 0; } /* * Set MSN-Mapping. */ int actcapi_manufacturer_req_msn(act2000_card *card) { msn_entry *p = card->msn_list; actcapi_msg *m; struct sk_buff *skb; int len; while (p) { int i; len = strlen(p->msn); for (i = 0; i < 2; i++) { ACTCAPI_MKHDR(6 + len, 0xff, 0x00); if (!skb) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return -ENOMEM; } m->msg.manufacturer_req_msn.manuf_msg = 0x13 + i; m->msg.manufacturer_req_msn.controller = 0; m->msg.manufacturer_req_msn.msnmap.eaz = p->eaz; m->msg.manufacturer_req_msn.msnmap.len = len; memcpy(m->msg.manufacturer_req_msn.msnmap.msn, p->msn, len); ACTCAPI_QUEUE_TX; } p = p->next; } return 0; } void actcapi_select_b2_protocol_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(10, 0x40, 0x00); ACTCAPI_CHKSKB; m->msg.select_b2_protocol_req.plci = chan->plci; memset(&m->msg.select_b2_protocol_req.dlpd, 0, sizeof(m->msg.select_b2_protocol_req.dlpd)); m->msg.select_b2_protocol_req.dlpd.len = 6; switch (chan->l2prot) { case ISDN_PROTO_L2_TRANS: m->msg.select_b2_protocol_req.protocol = 0x03; m->msg.select_b2_protocol_req.dlpd.dlen = 4000; break; case ISDN_PROTO_L2_HDLC: m->msg.select_b2_protocol_req.protocol = 0x02; m->msg.select_b2_protocol_req.dlpd.dlen = 4000; break; case ISDN_PROTO_L2_X75I: case ISDN_PROTO_L2_X75UI: case ISDN_PROTO_L2_X75BUI: m->msg.select_b2_protocol_req.protocol = 0x01; m->msg.select_b2_protocol_req.dlpd.dlen = 4000; m->msg.select_b2_protocol_req.dlpd.laa = 3; m->msg.select_b2_protocol_req.dlpd.lab = 1; m->msg.select_b2_protocol_req.dlpd.win = 7; m->msg.select_b2_protocol_req.dlpd.modulo = 8; break; } ACTCAPI_QUEUE_TX; } static void actcapi_select_b3_protocol_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(17, 0x80, 0x00); ACTCAPI_CHKSKB; m->msg.select_b3_protocol_req.plci = chan->plci; memset(&m->msg.select_b3_protocol_req.ncpd, 0, sizeof(m->msg.select_b3_protocol_req.ncpd)); switch (chan->l3prot) { case ISDN_PROTO_L3_TRANS: m->msg.select_b3_protocol_req.protocol = 0x04; m->msg.select_b3_protocol_req.ncpd.len = 13; m->msg.select_b3_protocol_req.ncpd.modulo = 8; break; } ACTCAPI_QUEUE_TX; } static void actcapi_listen_b3_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x81, 0x00); ACTCAPI_CHKSKB; m->msg.listen_b3_req.plci = chan->plci; ACTCAPI_QUEUE_TX; } static void actcapi_disconnect_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(3, 0x04, 0x00); ACTCAPI_CHKSKB; m->msg.disconnect_req.plci = chan->plci; m->msg.disconnect_req.cause = 0; ACTCAPI_QUEUE_TX; } void actcapi_disconnect_b3_req(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(17, 0x84, 0x00); ACTCAPI_CHKSKB; m->msg.disconnect_b3_req.ncci = chan->ncci; memset(&m->msg.disconnect_b3_req.ncpi, 0, sizeof(m->msg.disconnect_b3_req.ncpi)); m->msg.disconnect_b3_req.ncpi.len = 13; m->msg.disconnect_b3_req.ncpi.modulo = 8; chan->fsm_state = ACT2000_STATE_BHWAIT; ACTCAPI_QUEUE_TX; } void actcapi_connect_resp(act2000_card *card, act2000_chan *chan, __u8 cause) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(3, 0x02, 0x03); ACTCAPI_CHKSKB; m->msg.connect_resp.plci = chan->plci; m->msg.connect_resp.rejectcause = cause; if (cause) { chan->fsm_state = ACT2000_STATE_NULL; chan->plci = 0x8000; } else chan->fsm_state = ACT2000_STATE_IWAIT; ACTCAPI_QUEUE_TX; } static void actcapi_connect_active_resp(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x03, 0x03); ACTCAPI_CHKSKB; m->msg.connect_resp.plci = chan->plci; if (chan->fsm_state == ACT2000_STATE_IWAIT) chan->fsm_state = ACT2000_STATE_IBWAIT; ACTCAPI_QUEUE_TX; } static void actcapi_connect_b3_resp(act2000_card *card, act2000_chan *chan, __u8 rejectcause) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR((rejectcause?3:17), 0x82, 0x03); ACTCAPI_CHKSKB; m->msg.connect_b3_resp.ncci = chan->ncci; m->msg.connect_b3_resp.rejectcause = rejectcause; if (!rejectcause) { memset(&m->msg.connect_b3_resp.ncpi, 0, sizeof(m->msg.connect_b3_resp.ncpi)); m->msg.connect_b3_resp.ncpi.len = 13; m->msg.connect_b3_resp.ncpi.modulo = 8; chan->fsm_state = ACT2000_STATE_BWAIT; } ACTCAPI_QUEUE_TX; } static void actcapi_connect_b3_active_resp(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x83, 0x03); ACTCAPI_CHKSKB; m->msg.connect_b3_active_resp.ncci = chan->ncci; chan->fsm_state = ACT2000_STATE_ACTIVE; ACTCAPI_QUEUE_TX; } static void actcapi_info_resp(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x07, 0x03); ACTCAPI_CHKSKB; m->msg.info_resp.plci = chan->plci; ACTCAPI_QUEUE_TX; } static void actcapi_disconnect_b3_resp(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x84, 0x03); ACTCAPI_CHKSKB; m->msg.disconnect_b3_resp.ncci = chan->ncci; chan->ncci = 0x8000; chan->queued = 0; ACTCAPI_QUEUE_TX; } static void actcapi_disconnect_resp(act2000_card *card, act2000_chan *chan) { actcapi_msg *m; struct sk_buff *skb; ACTCAPI_MKHDR(2, 0x04, 0x03); ACTCAPI_CHKSKB; m->msg.disconnect_resp.plci = chan->plci; chan->plci = 0x8000; ACTCAPI_QUEUE_TX; } static int new_plci(act2000_card *card, __u16 plci) { int i; for (i = 0; i < ACT2000_BCH; i++) if (card->bch[i].plci == 0x8000) { card->bch[i].plci = plci; return i; } return -1; } static int find_plci(act2000_card *card, __u16 plci) { int i; for (i = 0; i < ACT2000_BCH; i++) if (card->bch[i].plci == plci) return i; return -1; } static int find_ncci(act2000_card *card, __u16 ncci) { int i; for (i = 0; i < ACT2000_BCH; i++) if (card->bch[i].ncci == ncci) return i; return -1; } static int find_dialing(act2000_card *card, __u16 callref) { int i; for (i = 0; i < ACT2000_BCH; i++) if ((card->bch[i].callref == callref) && (card->bch[i].fsm_state == ACT2000_STATE_OCALL)) return i; return -1; } static int actcapi_data_b3_ind(act2000_card *card, struct sk_buff *skb) { __u16 plci; __u16 ncci; __u16 controller; __u8 blocknr; int chan; actcapi_msg *msg = (actcapi_msg *)skb->data; EVAL_NCCI(msg->msg.data_b3_ind.fakencci, plci, controller, ncci); chan = find_ncci(card, ncci); if (chan < 0) return 0; if (card->bch[chan].fsm_state != ACT2000_STATE_ACTIVE) return 0; if (card->bch[chan].plci != plci) return 0; blocknr = msg->msg.data_b3_ind.blocknr; skb_pull(skb, 19); card->interface.rcvcallb_skb(card->myid, chan, skb); if (!(skb = alloc_skb(11, GFP_ATOMIC))) { printk(KERN_WARNING "actcapi: alloc_skb failed\n"); return 1; } msg = (actcapi_msg *)skb_put(skb, 11); msg->hdr.len = 11; msg->hdr.applicationID = 1; msg->hdr.cmd.cmd = 0x86; msg->hdr.cmd.subcmd = 0x03; msg->hdr.msgnum = actcapi_nextsmsg(card); msg->msg.data_b3_resp.ncci = ncci; msg->msg.data_b3_resp.blocknr = blocknr; ACTCAPI_QUEUE_TX; return 1; } /* * Walk over ackq, unlink DATA_B3_REQ from it, if * ncci and blocknr are matching. * Decrement queued-bytes counter. */ static int handle_ack(act2000_card *card, act2000_chan *chan, __u8 blocknr) { unsigned long flags; struct sk_buff *skb; struct sk_buff *tmp; struct actcapi_msg *m; int ret = 0; spin_lock_irqsave(&card->lock, flags); skb = skb_peek(&card->ackq); spin_unlock_irqrestore(&card->lock, flags); if (!skb) { printk(KERN_WARNING "act2000: handle_ack nothing found!\n"); return 0; } tmp = skb; while (1) { m = (actcapi_msg *)tmp->data; if ((((m->msg.data_b3_req.fakencci >> 8) & 0xff) == chan->ncci) && (m->msg.data_b3_req.blocknr == blocknr)) { /* found corresponding DATA_B3_REQ */ skb_unlink(tmp, &card->ackq); chan->queued -= m->msg.data_b3_req.datalen; if (m->msg.data_b3_req.flags) ret = m->msg.data_b3_req.datalen; dev_kfree_skb(tmp); if (chan->queued < 0) chan->queued = 0; return ret; } spin_lock_irqsave(&card->lock, flags); tmp = skb_peek((struct sk_buff_head *)tmp); spin_unlock_irqrestore(&card->lock, flags); if ((tmp == skb) || (tmp == NULL)) { /* reached end of queue */ printk(KERN_WARNING "act2000: handle_ack nothing found!\n"); return 0; } } } void actcapi_dispatch(struct work_struct *work) { struct act2000_card *card = container_of(work, struct act2000_card, rcv_tq); struct sk_buff *skb; actcapi_msg *msg; __u16 ccmd; int chan; int len; act2000_chan *ctmp; isdn_ctrl cmd; char tmp[170]; while ((skb = skb_dequeue(&card->rcvq))) { actcapi_debug_msg(skb, 0); msg = (actcapi_msg *)skb->data; ccmd = ((msg->hdr.cmd.cmd << 8) | msg->hdr.cmd.subcmd); switch (ccmd) { case 0x8602: /* DATA_B3_IND */ if (actcapi_data_b3_ind(card, skb)) return; break; case 0x8601: /* DATA_B3_CONF */ chan = find_ncci(card, msg->msg.data_b3_conf.ncci); if ((chan >= 0) && (card->bch[chan].fsm_state == ACT2000_STATE_ACTIVE)) { if (msg->msg.data_b3_conf.info != 0) printk(KERN_WARNING "act2000: DATA_B3_CONF: %04x\n", msg->msg.data_b3_conf.info); len = handle_ack(card, &card->bch[chan], msg->msg.data_b3_conf.blocknr); if (len) { cmd.driver = card->myid; cmd.command = ISDN_STAT_BSENT; cmd.arg = chan; cmd.parm.length = len; card->interface.statcallb(&cmd); } } break; case 0x0201: /* CONNECT_CONF */ chan = find_dialing(card, msg->hdr.msgnum); if (chan >= 0) { if (msg->msg.connect_conf.info) { card->bch[chan].fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } else { card->bch[chan].fsm_state = ACT2000_STATE_OWAIT; card->bch[chan].plci = msg->msg.connect_conf.plci; } } break; case 0x0202: /* CONNECT_IND */ chan = new_plci(card, msg->msg.connect_ind.plci); if (chan < 0) { ctmp = (act2000_chan *)tmp; ctmp->plci = msg->msg.connect_ind.plci; actcapi_connect_resp(card, ctmp, 0x11); /* All Card-Cannels busy */ } else { card->bch[chan].fsm_state = ACT2000_STATE_ICALL; cmd.driver = card->myid; cmd.command = ISDN_STAT_ICALL; cmd.arg = chan; cmd.parm.setup.si1 = msg->msg.connect_ind.si1; cmd.parm.setup.si2 = msg->msg.connect_ind.si2; if (card->ptype == ISDN_PTYPE_EURO) strcpy(cmd.parm.setup.eazmsn, act2000_find_eaz(card, msg->msg.connect_ind.eaz)); else { cmd.parm.setup.eazmsn[0] = msg->msg.connect_ind.eaz; cmd.parm.setup.eazmsn[1] = 0; } memset(cmd.parm.setup.phone, 0, sizeof(cmd.parm.setup.phone)); memcpy(cmd.parm.setup.phone, msg->msg.connect_ind.addr.num, msg->msg.connect_ind.addr.len - 1); cmd.parm.setup.plan = msg->msg.connect_ind.addr.tnp; cmd.parm.setup.screen = 0; if (card->interface.statcallb(&cmd) == 2) actcapi_connect_resp(card, &card->bch[chan], 0x15); /* Reject Call */ } break; case 0x0302: /* CONNECT_ACTIVE_IND */ chan = find_plci(card, msg->msg.connect_active_ind.plci); if (chan >= 0) switch (card->bch[chan].fsm_state) { case ACT2000_STATE_IWAIT: actcapi_connect_active_resp(card, &card->bch[chan]); break; case ACT2000_STATE_OWAIT: actcapi_connect_active_resp(card, &card->bch[chan]); actcapi_select_b2_protocol_req(card, &card->bch[chan]); break; } break; case 0x8202: /* CONNECT_B3_IND */ chan = find_plci(card, msg->msg.connect_b3_ind.plci); if ((chan >= 0) && (card->bch[chan].fsm_state == ACT2000_STATE_IBWAIT)) { card->bch[chan].ncci = msg->msg.connect_b3_ind.ncci; actcapi_connect_b3_resp(card, &card->bch[chan], 0); } else { ctmp = (act2000_chan *)tmp; ctmp->ncci = msg->msg.connect_b3_ind.ncci; actcapi_connect_b3_resp(card, ctmp, 0x11); /* All Card-Cannels busy */ } break; case 0x8302: /* CONNECT_B3_ACTIVE_IND */ chan = find_ncci(card, msg->msg.connect_b3_active_ind.ncci); if ((chan >= 0) && (card->bch[chan].fsm_state == ACT2000_STATE_BWAIT)) { actcapi_connect_b3_active_resp(card, &card->bch[chan]); cmd.driver = card->myid; cmd.command = ISDN_STAT_BCONN; cmd.arg = chan; card->interface.statcallb(&cmd); } break; case 0x8402: /* DISCONNECT_B3_IND */ chan = find_ncci(card, msg->msg.disconnect_b3_ind.ncci); if (chan >= 0) { ctmp = &card->bch[chan]; actcapi_disconnect_b3_resp(card, ctmp); switch (ctmp->fsm_state) { case ACT2000_STATE_ACTIVE: ctmp->fsm_state = ACT2000_STATE_DHWAIT2; cmd.driver = card->myid; cmd.command = ISDN_STAT_BHUP; cmd.arg = chan; card->interface.statcallb(&cmd); break; case ACT2000_STATE_BHWAIT2: actcapi_disconnect_req(card, ctmp); ctmp->fsm_state = ACT2000_STATE_DHWAIT; cmd.driver = card->myid; cmd.command = ISDN_STAT_BHUP; cmd.arg = chan; card->interface.statcallb(&cmd); break; } } break; case 0x0402: /* DISCONNECT_IND */ chan = find_plci(card, msg->msg.disconnect_ind.plci); if (chan >= 0) { ctmp = &card->bch[chan]; actcapi_disconnect_resp(card, ctmp); ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } else { ctmp = (act2000_chan *)tmp; ctmp->plci = msg->msg.disconnect_ind.plci; actcapi_disconnect_resp(card, ctmp); } break; case 0x4001: /* SELECT_B2_PROTOCOL_CONF */ chan = find_plci(card, msg->msg.select_b2_protocol_conf.plci); if (chan >= 0) switch (card->bch[chan].fsm_state) { case ACT2000_STATE_ICALL: case ACT2000_STATE_OWAIT: ctmp = &card->bch[chan]; if (msg->msg.select_b2_protocol_conf.info == 0) actcapi_select_b3_protocol_req(card, ctmp); else { ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } break; } break; case 0x8001: /* SELECT_B3_PROTOCOL_CONF */ chan = find_plci(card, msg->msg.select_b3_protocol_conf.plci); if (chan >= 0) switch (card->bch[chan].fsm_state) { case ACT2000_STATE_ICALL: case ACT2000_STATE_OWAIT: ctmp = &card->bch[chan]; if (msg->msg.select_b3_protocol_conf.info == 0) actcapi_listen_b3_req(card, ctmp); else { ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } } break; case 0x8101: /* LISTEN_B3_CONF */ chan = find_plci(card, msg->msg.listen_b3_conf.plci); if (chan >= 0) switch (card->bch[chan].fsm_state) { case ACT2000_STATE_ICALL: ctmp = &card->bch[chan]; if (msg->msg.listen_b3_conf.info == 0) actcapi_connect_resp(card, ctmp, 0); else { ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } break; case ACT2000_STATE_OWAIT: ctmp = &card->bch[chan]; if (msg->msg.listen_b3_conf.info == 0) { actcapi_connect_b3_req(card, ctmp); ctmp->fsm_state = ACT2000_STATE_OBWAIT; cmd.driver = card->myid; cmd.command = ISDN_STAT_DCONN; cmd.arg = chan; card->interface.statcallb(&cmd); } else { ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } break; } break; case 0x8201: /* CONNECT_B3_CONF */ chan = find_plci(card, msg->msg.connect_b3_conf.plci); if ((chan >= 0) && (card->bch[chan].fsm_state == ACT2000_STATE_OBWAIT)) { ctmp = &card->bch[chan]; if (msg->msg.connect_b3_conf.info) { ctmp->fsm_state = ACT2000_STATE_NULL; cmd.driver = card->myid; cmd.command = ISDN_STAT_DHUP; cmd.arg = chan; card->interface.statcallb(&cmd); } else { ctmp->ncci = msg->msg.connect_b3_conf.ncci; ctmp->fsm_state = ACT2000_STATE_BWAIT; } } break; case 0x8401: /* DISCONNECT_B3_CONF */ chan = find_ncci(card, msg->msg.disconnect_b3_conf.ncci); if ((chan >= 0) && (card->bch[chan].fsm_state == ACT2000_STATE_BHWAIT)) card->bch[chan].fsm_state = ACT2000_STATE_BHWAIT2; break; case 0x0702: /* INFO_IND */ chan = find_plci(card, msg->msg.info_ind.plci); if (chan >= 0) /* TODO: Eval Charging info / cause */ actcapi_info_resp(card, &card->bch[chan]); break; case 0x0401: /* LISTEN_CONF */ case 0x0501: /* LISTEN_CONF */ case 0xff01: /* MANUFACTURER_CONF */ break; case 0xff02: /* MANUFACTURER_IND */ if (msg->msg.manuf_msg == 3) { memset(tmp, 0, sizeof(tmp)); strncpy(tmp, &msg->msg.manufacturer_ind_err.errstring, msg->hdr.len - 16); if (msg->msg.manufacturer_ind_err.errcode) printk(KERN_WARNING "act2000: %s\n", tmp); else { printk(KERN_DEBUG "act2000: %s\n", tmp); if ((!strncmp(tmp, "INFO: Trace buffer con", 22)) || (!strncmp(tmp, "INFO: Compile Date/Tim", 22))) { card->flags |= ACT2000_FLAGS_RUNNING; cmd.command = ISDN_STAT_RUN; cmd.driver = card->myid; cmd.arg = 0; actcapi_manufacturer_req_net(card); actcapi_manufacturer_req_msn(card); actcapi_listen_req(card); card->interface.statcallb(&cmd); } } } break; default: printk(KERN_WARNING "act2000: UNHANDLED Message %04x\n", ccmd); break; } dev_kfree_skb(skb); } } #ifdef DEBUG_MSG static void actcapi_debug_caddr(actcapi_addr *addr) { char tmp[30]; printk(KERN_DEBUG " Alen = %d\n", addr->len); if (addr->len > 0) printk(KERN_DEBUG " Atnp = 0x%02x\n", addr->tnp); if (addr->len > 1) { memset(tmp, 0, 30); memcpy(tmp, addr->num, addr->len - 1); printk(KERN_DEBUG " Anum = '%s'\n", tmp); } } static void actcapi_debug_ncpi(actcapi_ncpi *ncpi) { printk(KERN_DEBUG " ncpi.len = %d\n", ncpi->len); if (ncpi->len >= 2) printk(KERN_DEBUG " ncpi.lic = 0x%04x\n", ncpi->lic); if (ncpi->len >= 4) printk(KERN_DEBUG " ncpi.hic = 0x%04x\n", ncpi->hic); if (ncpi->len >= 6) printk(KERN_DEBUG " ncpi.ltc = 0x%04x\n", ncpi->ltc); if (ncpi->len >= 8) printk(KERN_DEBUG " ncpi.htc = 0x%04x\n", ncpi->htc); if (ncpi->len >= 10) printk(KERN_DEBUG " ncpi.loc = 0x%04x\n", ncpi->loc); if (ncpi->len >= 12) printk(KERN_DEBUG " ncpi.hoc = 0x%04x\n", ncpi->hoc); if (ncpi->len >= 13) printk(KERN_DEBUG " ncpi.mod = %d\n", ncpi->modulo); } static void actcapi_debug_dlpd(actcapi_dlpd *dlpd) { printk(KERN_DEBUG " dlpd.len = %d\n", dlpd->len); if (dlpd->len >= 2) printk(KERN_DEBUG " dlpd.dlen = 0x%04x\n", dlpd->dlen); if (dlpd->len >= 3) printk(KERN_DEBUG " dlpd.laa = 0x%02x\n", dlpd->laa); if (dlpd->len >= 4) printk(KERN_DEBUG " dlpd.lab = 0x%02x\n", dlpd->lab); if (dlpd->len >= 5) printk(KERN_DEBUG " dlpd.modulo = %d\n", dlpd->modulo); if (dlpd->len >= 6) printk(KERN_DEBUG " dlpd.win = %d\n", dlpd->win); } #ifdef DEBUG_DUMP_SKB static void dump_skb(struct sk_buff *skb) { char tmp[80]; char *p = skb->data; char *t = tmp; int i; for (i = 0; i < skb->len; i++) { t += sprintf(t, "%02x ", *p++ & 0xff); if ((i & 0x0f) == 8) { printk(KERN_DEBUG "dump: %s\n", tmp); t = tmp; } } if (i & 0x07) printk(KERN_DEBUG "dump: %s\n", tmp); } #endif void actcapi_debug_msg(struct sk_buff *skb, int direction) { actcapi_msg *msg = (actcapi_msg *)skb->data; char *descr; int i; char tmp[170]; #ifndef DEBUG_DATA_MSG if (msg->hdr.cmd.cmd == 0x86) return; #endif descr = "INVALID"; #ifdef DEBUG_DUMP_SKB dump_skb(skb); #endif for (i = 0; i < num_valid_msg; i++) if ((msg->hdr.cmd.cmd == valid_msg[i].cmd.cmd) && (msg->hdr.cmd.subcmd == valid_msg[i].cmd.subcmd)) { descr = valid_msg[i].description; break; } printk(KERN_DEBUG "%s %s msg\n", direction?"Outgoing":"Incoming", descr); printk(KERN_DEBUG " ApplID = %d\n", msg->hdr.applicationID); printk(KERN_DEBUG " Len = %d\n", msg->hdr.len); printk(KERN_DEBUG " MsgNum = 0x%04x\n", msg->hdr.msgnum); printk(KERN_DEBUG " Cmd = 0x%02x\n", msg->hdr.cmd.cmd); printk(KERN_DEBUG " SubCmd = 0x%02x\n", msg->hdr.cmd.subcmd); switch (i) { case 0: /* DATA B3 IND */ printk(KERN_DEBUG " BLOCK = 0x%02x\n", msg->msg.data_b3_ind.blocknr); break; case 2: /* CONNECT CONF */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_conf.plci); printk(KERN_DEBUG " Info = 0x%04x\n", msg->msg.connect_conf.info); break; case 3: /* CONNECT IND */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_ind.plci); printk(KERN_DEBUG " Contr = %d\n", msg->msg.connect_ind.controller); printk(KERN_DEBUG " SI1 = %d\n", msg->msg.connect_ind.si1); printk(KERN_DEBUG " SI2 = %d\n", msg->msg.connect_ind.si2); printk(KERN_DEBUG " EAZ = '%c'\n", msg->msg.connect_ind.eaz); actcapi_debug_caddr(&msg->msg.connect_ind.addr); break; case 5: /* CONNECT ACTIVE IND */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_active_ind.plci); actcapi_debug_caddr(&msg->msg.connect_active_ind.addr); break; case 8: /* LISTEN CONF */ printk(KERN_DEBUG " Contr = %d\n", msg->msg.listen_conf.controller); printk(KERN_DEBUG " Info = 0x%04x\n", msg->msg.listen_conf.info); break; case 11: /* INFO IND */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.info_ind.plci); printk(KERN_DEBUG " Imsk = 0x%04x\n", msg->msg.info_ind.nr.mask); if (msg->hdr.len > 12) { int l = msg->hdr.len - 12; int j; char *p = tmp; for (j = 0; j < l ; j++) p += sprintf(p, "%02x ", msg->msg.info_ind.el.display[j]); printk(KERN_DEBUG " D = '%s'\n", tmp); } break; case 14: /* SELECT B2 PROTOCOL CONF */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.select_b2_protocol_conf.plci); printk(KERN_DEBUG " Info = 0x%04x\n", msg->msg.select_b2_protocol_conf.info); break; case 15: /* SELECT B3 PROTOCOL CONF */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.select_b3_protocol_conf.plci); printk(KERN_DEBUG " Info = 0x%04x\n", msg->msg.select_b3_protocol_conf.info); break; case 16: /* LISTEN B3 CONF */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.listen_b3_conf.plci); printk(KERN_DEBUG " Info = 0x%04x\n", msg->msg.listen_b3_conf.info); break; case 18: /* CONNECT B3 IND */ printk(KERN_DEBUG " NCCI = 0x%04x\n", msg->msg.connect_b3_ind.ncci); printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_b3_ind.plci); actcapi_debug_ncpi(&msg->msg.connect_b3_ind.ncpi); break; case 19: /* CONNECT B3 ACTIVE IND */ printk(KERN_DEBUG " NCCI = 0x%04x\n", msg->msg.connect_b3_active_ind.ncci); actcapi_debug_ncpi(&msg->msg.connect_b3_active_ind.ncpi); break; case 26: /* MANUFACTURER IND */ printk(KERN_DEBUG " Mmsg = 0x%02x\n", msg->msg.manufacturer_ind_err.manuf_msg); switch (msg->msg.manufacturer_ind_err.manuf_msg) { case 3: printk(KERN_DEBUG " Contr = %d\n", msg->msg.manufacturer_ind_err.controller); printk(KERN_DEBUG " Code = 0x%08x\n", msg->msg.manufacturer_ind_err.errcode); memset(tmp, 0, sizeof(tmp)); strncpy(tmp, &msg->msg.manufacturer_ind_err.errstring, msg->hdr.len - 16); printk(KERN_DEBUG " Emsg = '%s'\n", tmp); break; } break; case 30: /* LISTEN REQ */ printk(KERN_DEBUG " Imsk = 0x%08x\n", msg->msg.listen_req.infomask); printk(KERN_DEBUG " Emsk = 0x%04x\n", msg->msg.listen_req.eazmask); printk(KERN_DEBUG " Smsk = 0x%04x\n", msg->msg.listen_req.simask); break; case 35: /* SELECT_B2_PROTOCOL_REQ */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.select_b2_protocol_req.plci); printk(KERN_DEBUG " prot = 0x%02x\n", msg->msg.select_b2_protocol_req.protocol); if (msg->hdr.len >= 11) printk(KERN_DEBUG "No dlpd\n"); else actcapi_debug_dlpd(&msg->msg.select_b2_protocol_req.dlpd); break; case 44: /* CONNECT RESP */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_resp.plci); printk(KERN_DEBUG " CAUSE = 0x%02x\n", msg->msg.connect_resp.rejectcause); break; case 45: /* CONNECT ACTIVE RESP */ printk(KERN_DEBUG " PLCI = 0x%04x\n", msg->msg.connect_active_resp.plci); break; } } #endif