/* OpenBSC Abis interface to E1 */ /* (C) 2008-2009 by Harald Welte * * All Rights Reserved * * SPDX-License-Identifier: AGPL-3.0+ * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . * */ #include "internal.h" #include "../config.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define NUM_E1_TS 32 static void *tall_e1inp_ctx; /* list of all E1 drivers */ LLIST_HEAD(e1inp_driver_list); /* list of all E1 lines */ LLIST_HEAD(e1inp_line_list); static void *tall_sigl_ctx; static const struct rate_ctr_desc e1inp_ctr_d[] = { [E1I_CTR_HDLC_ABORT] = { "hdlc:abort", "HDLC abort" }, [E1I_CTR_HDLC_BADFCS] = { "hdlc:bad_fcs", "HLDC Bad FCS" }, [E1I_CTR_HDLC_OVERR] = { "hdlc:overrun", "HDLC Overrun" }, [E1I_CTR_ALARM] = { "alarm", "Alarm" }, [E1I_CTR_REMOVED] = { "removed", "Line removed" }, }; static const struct rate_ctr_group_desc e1inp_ctr_g_d = { .group_name_prefix = "e1inp", .group_description = "E1 Input subsystem", .num_ctr = ARRAY_SIZE(e1inp_ctr_d), .ctr_desc = e1inp_ctr_d, }; /* * pcap writing of the misdn load * pcap format is from http://wiki.wireshark.org/Development/LibpcapFileFormat */ #define DLT_LINUX_LAPD 177 #define PCAP_INPUT 0 #define PCAP_OUTPUT 1 struct pcap_hdr { uint32_t magic_number; uint16_t version_major; uint16_t version_minor; int32_t thiszone; uint32_t sigfigs; uint32_t snaplen; uint32_t network; } __attribute__((packed)); struct pcaprec_hdr { uint32_t ts_sec; uint32_t ts_usec; uint32_t incl_len; uint32_t orig_len; } __attribute__((packed)); struct fake_linux_lapd_header { uint16_t pkttype; uint16_t hatype; uint16_t halen; uint64_t addr; int16_t protocol; } __attribute__((packed)); struct lapd_header { #if OSMO_IS_LITTLE_ENDIAN uint8_t ea1 : 1; uint8_t cr : 1; uint8_t sapi : 6; uint8_t ea2 : 1; uint8_t tei : 7; uint8_t control_foo; /* fake UM's ... */ #elif OSMO_IS_BIG_ENDIAN /* auto-generated from the little endian part above (libosmocore/contrib/struct_endianness.py) */ uint8_t sapi:6, cr:1, ea1:1; uint8_t tei:7, ea2:1; uint8_t control_foo; #endif } __attribute__((packed)); osmo_static_assert(offsetof(struct fake_linux_lapd_header, hatype) == 2, hatype_offset); osmo_static_assert(offsetof(struct fake_linux_lapd_header, halen) == 4, halen_offset); osmo_static_assert(offsetof(struct fake_linux_lapd_header, addr) == 6, addr_offset); osmo_static_assert(offsetof(struct fake_linux_lapd_header, protocol) == 14, proto_offset); osmo_static_assert(sizeof(struct fake_linux_lapd_header) == 16, lapd_header_size); int e1_set_pcap_fd2(struct e1inp_line *line, int fd) { static const struct pcap_hdr header = { .magic_number = 0xa1b2c3d4, .version_major = 2, .version_minor = 4, .thiszone = 0, .sigfigs = 0, .snaplen = 65535, .network = DLT_LINUX_LAPD, }; int i; /* write header */ if (fd >= 0) { int rc = write(fd, &header, sizeof(header)); if (rc < 0) return rc; } /* Set the PCAP file descriptor for all timeslots that have * software LAPD instances, to ensure the osmo_lapd_pcap code is * used to write PCAP files (if requested) */ for (i = 0; i < ARRAY_SIZE(line->ts); i++) { struct e1inp_ts *e1i_ts = &line->ts[i]; if (e1i_ts->lapd) e1i_ts->lapd->pcap_fd = fd; } /* close previous and update */ if (line->pcap_fd >= 0) close(line->pcap_fd); line->pcap_fd = fd; return 0; } static int pcap_fd = -1; int e1_set_pcap_fd(int fd) { const struct pcap_hdr header = { .magic_number = 0xa1b2c3d4, .version_major = 2, .version_minor = 4, .thiszone = 0, .sigfigs = 0, .snaplen = 65535, .network = DLT_LINUX_LAPD, }; struct e1inp_line *line; int i; /* write header */ if (fd >= 0) { int rc = write(fd, &header, sizeof(header)); if (rc < 0) return rc; } /* update fd in all lines in our global list of e1 lines */ llist_for_each_entry(line, &e1inp_line_list, list) { /* Set the PCAP file descriptor for all timeslots that have * software LAPD instances, to ensure the osmo_lapd_pcap code is * used to write PCAP files (if requested) */ for (i = 0; i < ARRAY_SIZE(line->ts); i++) { struct e1inp_ts *e1i_ts = &line->ts[i]; if (e1i_ts->lapd) e1i_ts->lapd->pcap_fd = fd; } } /* close previous and update global */ if (pcap_fd >= 0) close(pcap_fd); pcap_fd = fd; return 0; } /* This currently only works for the D-Channel */ static void write_pcap_packet(int direction, int sapi, int tei, struct msgb *msg, int pcap_fd) { if (pcap_fd < 0) return; time_t cur_time; struct tm *tm; struct fake_linux_lapd_header header = { .pkttype = 4, .hatype = 0, .halen = 0, .addr = direction == PCAP_OUTPUT ? 0x0 : 0x1, .protocol = ntohs(48), }; struct lapd_header lapd_header = { .ea1 = 0, .cr = direction == PCAP_OUTPUT ? 1 : 0, .sapi = sapi & 0x3F, .ea2 = 1, .tei = tei & 0x7F, .control_foo = 0x03 /* UI */, }; struct pcaprec_hdr payload_header = { .ts_sec = 0, .ts_usec = 0, .incl_len = msgb_l2len(msg) + sizeof(struct fake_linux_lapd_header) + sizeof(struct lapd_header), .orig_len = msgb_l2len(msg) + sizeof(struct fake_linux_lapd_header) + sizeof(struct lapd_header), }; cur_time = time(NULL); tm = localtime(&cur_time); payload_header.ts_sec = mktime(tm); write(pcap_fd, &payload_header, sizeof(payload_header)); write(pcap_fd, &header, sizeof(header)); write(pcap_fd, &lapd_header, sizeof(lapd_header)); write(pcap_fd, msg->l2h, msgb_l2len(msg)); } const struct value_string e1inp_sign_type_names[5] = { { E1INP_SIGN_NONE, "None" }, { E1INP_SIGN_OML, "OML" }, { E1INP_SIGN_RSL, "RSL" }, { E1INP_SIGN_OSMO, "OSMO" }, { 0, NULL } }; const char *e1inp_signtype_name(enum e1inp_sign_type tp) { return get_value_string(e1inp_sign_type_names, tp); } const struct value_string e1inp_ts_type_names[] = { { E1INP_TS_TYPE_NONE, "None" }, { E1INP_TS_TYPE_SIGN, "Signalling" }, { E1INP_TS_TYPE_TRAU, "TRAU" }, { E1INP_TS_TYPE_RAW, "RAW" }, { E1INP_TS_TYPE_HDLC, "HDLC" }, { E1INP_TS_TYPE_I460, "I460" }, { 0, NULL } }; const char *e1inp_tstype_name(enum e1inp_ts_type tp) { return get_value_string(e1inp_ts_type_names, tp); } int abis_sendmsg(struct msgb *msg) { struct e1inp_sign_link *sign_link = msg->dst; struct e1inp_driver *e1inp_driver; struct e1inp_ts *e1i_ts; msg->l2h = msg->data; /* don't know how to route this message. */ if (sign_link == NULL) { LOGP(DLINP, LOGL_ERROR, "abis_sendmsg: msg->dst == NULL: %s\n", osmo_hexdump(msg->data, msg->len)); talloc_free(msg); return -EINVAL; } e1i_ts = sign_link->ts; msgb_enqueue(&sign_link->tx_list, msg); if (!osmo_timer_pending(&e1i_ts->sign.tx_timer)) { /* notify the driver we have something to write */ e1inp_driver = sign_link->ts->line->driver; e1inp_driver->want_write(e1i_ts); } /* we only need to write a 'Fake LAPD' packet here, if the * underlying driver hides LAPD from us. If we use the * libosmocore LAPD implementation, it will take care of writing * the _actual_ LAPD packet */ if (!e1i_ts->lapd) { write_pcap_packet(PCAP_OUTPUT, sign_link->sapi, sign_link->tei, msg, e1i_ts->line->pcap_fd); } return 0; } int abis_rsl_sendmsg(struct msgb *msg) { return abis_sendmsg(msg); } int e1inp_ts_send_raw(struct e1inp_ts *ts, struct msgb *msg) { struct e1inp_driver *driver; OSMO_ASSERT(ts->type == E1INP_TS_TYPE_RAW); /* notify the driver we have something to write */ driver = ts->line->driver; driver->want_write(ts); msgb_enqueue(&ts->raw.tx_queue, msg); return 0; } int e1inp_ts_send_hdlc(struct e1inp_ts *ts, struct msgb *msg) { struct e1inp_driver *driver; OSMO_ASSERT(ts->type == E1INP_TS_TYPE_HDLC); /* notify the driver we have something to write */ driver = ts->line->driver; driver->want_write(ts); msgb_enqueue(&ts->hdlc.tx_queue, msg); return 0; } /* Depending on its typ a timeslot may hold resources which must be cleaned up * or reset before the type of the timeslot type may be changed. */ static int cleanup_e1inp_ts(struct e1inp_ts *e1i_ts) { int rc; switch (e1i_ts->type) { case E1INP_TS_TYPE_SIGN: /* The caller is responsible for removing all signalling links * first. */ if (!llist_empty(&e1i_ts->sign.sign_links)) { LOGPITS(e1i_ts, DLMI, LOGL_ERROR, "timeslot still holds active signalling links -- cannot modify timeslot!\n"); return -EINVAL; } return 0; case E1INP_TS_TYPE_TRAU: /* Call the initialization functions once more. This will * deactivate all subchannels so that the related callbacks * are no longer called */ subchan_mux_init(&e1i_ts->trau.mux); subch_demux_init(&e1i_ts->trau.demux); return 0; case E1INP_TS_TYPE_RAW: msgb_queue_free(&e1i_ts->raw.tx_queue); return 0; case E1INP_TS_TYPE_HDLC: msgb_queue_free(&e1i_ts->hdlc.tx_queue); return 0; case E1INP_TS_TYPE_I460: /* The caller is responsible for removing all I.460 subchannels * first. */ rc = osmo_i460_subchan_count(&e1i_ts->i460.i460_ts); if (rc != 0) { LOGPITS(e1i_ts, DLMI, LOGL_ERROR, "timeslot still holds active I.460 subchannels -- cannot modify timeslot!\n"); return -EINVAL; } return 0; case E1INP_TS_TYPE_NONE: return 0; default: LOGPITS(e1i_ts, DLMI, LOGL_ERROR, "unsupported E1 TS type %u\n", e1i_ts->type); return -EINVAL; } return 0; } /* Timeslot */ int e1inp_ts_config_trau(struct e1inp_ts *ts, struct e1inp_line *line, int (*trau_rcv_cb)(struct subch_demux *dmx, int ch, const ubit_t *data, int len, void *_priv)) { if (ts->type == E1INP_TS_TYPE_TRAU && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_TRAU; ts->line = line; subchan_mux_init(&ts->trau.mux); ts->trau.demux.out_cb = trau_rcv_cb; ts->trau.demux.data = ts; subch_demux_init(&ts->trau.demux); return 0; } int e1inp_ts_config_i460(struct e1inp_ts *ts, struct e1inp_line *line) { if (ts->type == E1INP_TS_TYPE_I460 && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_I460; ts->line = line; osmo_i460_ts_init(&ts->i460.i460_ts); return 0; } void e1inp_ts_name(char *out, size_t out_len, const struct e1inp_ts *ts) { if (ts->line->name) snprintf(out, out_len, "%s:%u", ts->line->name, ts->num); else snprintf(out, out_len, "%u:%u", ts->line->num, ts->num); } int e1inp_ts_config_sign(struct e1inp_ts *ts, struct e1inp_line *line) { if (ts->type == E1INP_TS_TYPE_SIGN && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_SIGN; ts->line = line; if (line && line->driver) ts->sign.delay = line->driver->default_delay; else ts->sign.delay = 100000; INIT_LLIST_HEAD(&ts->sign.sign_links); return 0; } int e1inp_ts_config_raw(struct e1inp_ts *ts, struct e1inp_line *line, void (*raw_recv_cb)(struct e1inp_ts *ts, struct msgb *msg)) { if (ts->type == E1INP_TS_TYPE_RAW && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_RAW; ts->line = line; ts->raw.recv_cb = raw_recv_cb; INIT_LLIST_HEAD(&ts->raw.tx_queue); return 0; } int e1inp_ts_config_hdlc(struct e1inp_ts *ts, struct e1inp_line *line, void (*hdlc_recv_cb)(struct e1inp_ts *ts, struct msgb *msg)) { if (ts->type == E1INP_TS_TYPE_HDLC && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_HDLC; ts->line = line; ts->hdlc.recv_cb = hdlc_recv_cb; INIT_LLIST_HEAD(&ts->hdlc.tx_queue); return 0; } int e1inp_ts_config_none(struct e1inp_ts *ts, struct e1inp_line *line) { if (ts->type == E1INP_TS_TYPE_NONE && ts->line && line) return 0; cleanup_e1inp_ts(ts); ts->type = E1INP_TS_TYPE_NONE; ts->line = line; return 0; } int e1inp_ts_set_sa_bits(struct e1inp_line *line, uint8_t sa_bits) { struct e1inp_driver *driver; driver = line->driver; if (!driver->set_sa_bits) return -ENOTSUP; return driver->set_sa_bits(line, sa_bits); } static int e1inp_line_use_cb(struct osmo_use_count_entry *use_count_entry, int32_t old_use_count, const char *file, int file_line) { char buf[512]; struct osmo_use_count *uc = use_count_entry->use_count; struct e1inp_line *line = uc->talloc_object; LOGPSRC(DLINP, LOGL_INFO, file, file_line, "E1L(%u) Line (%p) reference count %s changed %" PRId32 " -> %" PRId32 " [%s]\n", (line)->num, line, use_count_entry->use, old_use_count, use_count_entry->count, osmo_use_count_name_buf(buf, sizeof(buf), uc)); if (!use_count_entry->count) osmo_use_count_free(use_count_entry); if (osmo_use_count_total(uc) > 0) return 0; /* Remove our counter group from libosmocore's global counter * list if we are freeing the last remaining talloc context. * Otherwise we get a use-after-free when libosmocore's timer * ticks again and attempts to update these counters (OS#3011). * * Note that talloc internally counts "secondary" references * _in addition to_ the initial allocation context, so yes, * we must check for *zero* remaining secondary contexts here. */ if (talloc_reference_count(line->rate_ctr) == 0) { rate_ctr_group_free(line->rate_ctr); } else { /* We are not freeing the last talloc context. * Instead of calling talloc_free(), unlink this 'line' pointer * which serves as one of several talloc contexts for the rate * counters and driver private state. */ talloc_unlink(line, line->rate_ctr); if (line->driver_data) talloc_unlink(line, line->driver_data); } llist_del(&line->list); talloc_free(line); return 0; } struct e1inp_line *e1inp_line_find(uint8_t e1_nr) { struct e1inp_line *e1i_line; /* iterate over global list of e1 lines */ llist_for_each_entry(e1i_line, &e1inp_line_list, list) { if (e1i_line->num == e1_nr) return e1i_line; } return NULL; } /*! Create a new e1inp line object. * \param[in] e1_nr The line number of the new line to be created. * \param[in] driver_name String identifying the driver (see e1inp_driver_register() for more info). * \returns pointer to the new object created. * * The allocated object is returned with a count reference with name "ctor", * which must be dropped in order to free the object [e1inp_line_put2(line, "ctor")]. */ struct e1inp_line * e1inp_line_create(uint8_t e1_nr, const char *driver_name) { struct e1inp_driver *driver; struct e1inp_line *line; int i; line = e1inp_line_find(e1_nr); if (line) { LOGPIL(line, DLINP, LOGL_ERROR, "E1 Line %u already exists\n", e1_nr); return NULL; } driver = e1inp_driver_find(driver_name); if (!driver) { LOGP(DLINP, LOGL_ERROR, "No such E1 driver '%s'\n", driver_name); return NULL; } line = talloc_zero(tall_e1inp_ctx, struct e1inp_line); if (!line) return NULL; line->driver = driver; line->num = e1_nr; line->pcap_fd = -1; line->keepalive_idle_timeout = E1INP_USE_DEFAULT; line->keepalive_num_probes = E1INP_USE_DEFAULT; line->keepalive_probe_interval = E1INP_USE_DEFAULT; line->connect_timeout = 0; line->rate_ctr = rate_ctr_group_alloc(line, &e1inp_ctr_g_d, line->num); if (!line->rate_ctr) { LOGPIL(line, DLINP, LOGL_ERROR, "Cannot allocate counter group\n"); talloc_free(line); return NULL; } line->num_ts = NUM_E1_TS; for (i = 0; i < line->num_ts; i++) { line->ts[i].num = i+1; line->ts[i].line = line; } line->use_count.talloc_object = line; line->use_count.use_cb = e1inp_line_use_cb; if (driver->line_create) { if (driver->line_create(line) < 0) { LOGPIL(line, DLINP, LOGL_ERROR, "Cannot initialize line driver\n"); talloc_free(line); return NULL; } } e1inp_line_get2(line, "ctor"); llist_add_tail(&line->list, &e1inp_line_list); return line; } struct e1inp_line * e1inp_line_clone(void *ctx, struct e1inp_line *line, const char *use) { struct e1inp_line *clone; /* clone virtual E1 line for this new OML link. */ clone = talloc_zero(ctx, struct e1inp_line); if (clone == NULL) return NULL; memcpy(clone, line, sizeof(struct e1inp_line)); if (line->name) { clone->name = talloc_strdup(clone, line->name); OSMO_ASSERT(clone->name); } if (line->sock_path) { clone->sock_path = talloc_strdup(clone, line->sock_path); OSMO_ASSERT(clone->sock_path); } /* Update TS to point to the cloned line: */ for (unsigned int i = 0; i < line->num_ts; i++) clone->ts[i].line = clone; /* * Rate counters and driver data are shared between clones. These are pointers * to dynamic memory so we use reference counting to avoid a double-free (see OS#3137). */ OSMO_ASSERT(line->rate_ctr); clone->rate_ctr = talloc_reference(clone, line->rate_ctr); if (line->driver_data) clone->driver_data = talloc_reference(clone, line->driver_data); clone->use_count = (struct osmo_use_count) { .talloc_object = clone, .use_cb = e1inp_line_use_cb, .use_counts = {0}, }; /* initialize list so it can be safely deleted without affecting original line */ INIT_LLIST_HEAD(&clone->list); e1inp_line_get2(clone, use); /* Clone is used internally for bfd */ return clone; } void e1inp_line_get(struct e1inp_line *line) { e1inp_line_get2(line, "unknown"); } void e1inp_line_put(struct e1inp_line *line) { e1inp_line_put2(line, "unknown"); } void e1inp_line_bind_ops(struct e1inp_line *line, const struct e1inp_line_ops *ops) { line->ops = ops; } #if 0 struct e1inp_line *e1inp_line_find_create(uint8_t e1_nr) { struct e1inp_line *line; int i; line = e1inp_line_find(e1_nr); if (line) return line; line = talloc_zero(tall_e1inp_ctx, struct e1inp_line); if (!line) return NULL; line->num = e1_nr; for (i = 0; i < NUM_E1_TS; i++) { line->ts[i].num = i+1; line->ts[i].line = line; } llist_add_tail(&line->list, &e1inp_line_list); return line; } #endif static struct e1inp_ts *e1inp_ts_get(uint8_t e1_nr, uint8_t ts_nr) { struct e1inp_line *e1i_line; e1i_line = e1inp_line_find(e1_nr); if (!e1i_line) return NULL; return &e1i_line->ts[ts_nr-1]; } struct subch_mux *e1inp_get_mux(uint8_t e1_nr, uint8_t ts_nr) { struct e1inp_ts *e1i_ts = e1inp_ts_get(e1_nr, ts_nr); if (!e1i_ts) return NULL; return &e1i_ts->trau.mux; } /* Signalling Link */ struct e1inp_sign_link *e1inp_lookup_sign_link(struct e1inp_ts *e1i, uint8_t tei, uint8_t sapi) { struct e1inp_sign_link *link; llist_for_each_entry(link, &e1i->sign.sign_links, list) { if (link->sapi == sapi && link->tei == tei) return link; } return NULL; } /* create a new signalling link in a E1 timeslot */ struct e1inp_sign_link * e1inp_sign_link_create(struct e1inp_ts *ts, enum e1inp_sign_type type, struct gsm_bts_trx *trx, uint8_t tei, uint8_t sapi) { struct e1inp_sign_link *link; if (ts->type != E1INP_TS_TYPE_SIGN) return NULL; link = talloc_zero(tall_sigl_ctx, struct e1inp_sign_link); if (!link) return NULL; link->ts = ts; link->type = type; INIT_LLIST_HEAD(&link->tx_list); link->trx = trx; link->tei = tei; link->sapi = sapi; e1inp_line_get2(link->ts->line, "e1inp_sign_link"); llist_add_tail(&link->list, &ts->sign.sign_links); return link; } void e1inp_sign_link_destroy(struct e1inp_sign_link *link) { struct msgb *msg; /* Catch upper layers behaving wrongly, calling e1inp_sign_link_destroy() * and then during the driver->close() callback below ending up calling * this function again deeper in the call stack in the same code path. */ if (llist_empty(&link->list)) { LOGP(DLINP, LOGL_ERROR, "Fix your application, " "caught reentrant e1inp_sign_link_destroy(%p)!\n", link); return; } /* Use llist_del_init() to catch double destroy above: */ llist_del_init(&link->list); while (!llist_empty(&link->tx_list)) { msg = msgb_dequeue(&link->tx_list); msgb_free(msg); } if (link->ts->type == E1INP_TS_TYPE_SIGN) osmo_timer_del(&link->ts->sign.tx_timer); if (link->ts->line->driver->close) link->ts->line->driver->close(link); e1inp_line_put2(link->ts->line, "e1inp_sign_link"); talloc_free(link); } /* XXX */ /* the E1 driver tells us he has received something on a TS */ int e1inp_rx_ts(struct e1inp_ts *ts, struct msgb *msg, uint8_t tei, uint8_t sapi) { struct e1inp_sign_link *link; int ret = 0; switch (ts->type) { case E1INP_TS_TYPE_SIGN: /* we only need to write a 'Fake LAPD' packet here, if * the underlying driver hides LAPD from us. If we use * the libosmocore LAPD implementation, it will take * care of writing the _actual_ LAPD packet */ if (!ts->lapd) write_pcap_packet(PCAP_INPUT, sapi, tei, msg, ts->line->pcap_fd); /* consult the list of signalling links */ link = e1inp_lookup_sign_link(ts, tei, sapi); if (!link) { LOGPITS(ts, DLMI, LOGL_ERROR, "didn't find signalling link for " "tei %d, sapi %d\n", tei, sapi); msgb_free(msg); return -EINVAL; } if (!ts->line->ops->sign_link) { LOGPITS(ts, DLINP, LOGL_ERROR, "Fix your application, " "no action set for signalling messages.\n"); msgb_free(msg); return -ENOENT; } msg->dst = link; ts->line->ops->sign_link(msg); break; case E1INP_TS_TYPE_TRAU: ret = subch_demux_in(&ts->trau.demux, msg->l2h, msgb_l2len(msg)); msgb_free(msg); break; case E1INP_TS_TYPE_RAW: ts->raw.recv_cb(ts, msg); break; case E1INP_TS_TYPE_HDLC: ts->hdlc.recv_cb(ts, msg); break; case E1INP_TS_TYPE_I460: osmo_i460_demux_in(&ts->i460.i460_ts, msg->l2h, msgb_l2len(msg)); msgb_free(msg); break; default: ret = -EINVAL; LOGPITS(ts, DLMI, LOGL_ERROR, "unknown TS type %u\n", ts->type); msgb_free(msg); break; } return ret; } /*! \brief Receive some data from the L1/HDLC into LAPD of a timeslot * \param[in] e1i_ts E1 Timeslot data structure * \param[in] msg Message buffer containing full LAPD message * * This is a wrapper around e1inp_rx_ts(), but feeding the incoming * message first into our LAPD code. This allows a driver to read raw * (HDLC decoded) data from the timeslot, instead of a LAPD stack * present in any underlying driver. */ int e1inp_rx_ts_lapd(struct e1inp_ts *e1i_ts, struct msgb *msg) { unsigned int sapi, tei; int ret = 0, error = 0; sapi = msg->data[0] >> 2; if ((msg->data[0] & 0x1)) tei = 0; else tei = msg->data[1] >> 1; LOGPITS(e1i_ts, DLMI, LOGL_DEBUG, "<= len = %d, sapi(%d) tei(%d)\n", msg->len, sapi, tei); ret = lapd_receive(e1i_ts->lapd, msg, &error); if (ret < 0) { switch(error) { case LAPD_ERR_UNKNOWN_TEI: /* We don't know about this TEI, probably the BSC * lost local states (it crashed or it was stopped), * notify the driver to see if it can do anything to * recover the existing signalling links with the BTS. */ e1inp_event(e1i_ts, S_L_INP_TEI_UNKNOWN, tei, sapi); return -EIO; } } return 0; } void e1inp_dlsap_up(struct osmo_dlsap_prim *dp, uint8_t tei, uint8_t sapi, void *rx_cbdata) { struct e1inp_ts *e1i_ts = rx_cbdata; struct msgb *msg = dp->oph.msg; switch (dp->oph.primitive) { case PRIM_DL_EST: LOGPITS(e1i_ts, DLMI, LOGL_DEBUG, "DL_EST: sapi(%d) tei(%d)\n", sapi, tei); e1inp_event(e1i_ts, S_L_INP_TEI_UP, tei, sapi); break; case PRIM_DL_REL: LOGPITS(e1i_ts, DLMI, LOGL_DEBUG, "DL_REL: sapi(%d) tei(%d)\n", sapi, tei); e1inp_event(e1i_ts, S_L_INP_TEI_DN, tei, sapi); break; case PRIM_DL_DATA: case PRIM_DL_UNIT_DATA: if (dp->oph.operation == PRIM_OP_INDICATION) { msg->l2h = msg->l3h; LOGPITS(e1i_ts, DLMI, LOGL_DEBUG, "RX: %s sapi=%d tei=%d\n", osmo_hexdump(msgb_l2(msg), msgb_l2len(msg)), sapi, tei); e1inp_rx_ts(e1i_ts, msg, tei, sapi); return; } break; case PRIM_MDL_ERROR: LOGPITS(e1i_ts, DLMI, LOGL_DEBUG, "MDL_EERROR: cause(%d)\n", dp->u.error_ind.cause); break; default: printf("ERROR: unknown prim\n"); break; } msgb_free(msg); return; } #define TSX_ALLOC_SIZE 4096 /* called by driver if it wants to transmit on a given TS */ struct msgb *e1inp_tx_ts(struct e1inp_ts *e1i_ts, struct e1inp_sign_link **sign_link) { struct e1inp_sign_link *link; struct msgb *msg = NULL; int len; switch (e1i_ts->type) { case E1INP_TS_TYPE_SIGN: /* FIXME: implement this round robin */ llist_for_each_entry(link, &e1i_ts->sign.sign_links, list) { msg = msgb_dequeue(&link->tx_list); if (msg) { if (sign_link) *sign_link = link; break; } } break; case E1INP_TS_TYPE_TRAU: msg = msgb_alloc(TSX_ALLOC_SIZE, "TRAU_TX"); if (!msg) return NULL; len = subchan_mux_out(&e1i_ts->trau.mux, msg->data, 40); if (len != 40) { LOGPITS(e1i_ts, DLMI, LOGL_ERROR, "cannot transmit, failed to mux\n"); msgb_free(msg); return NULL; } msgb_put(msg, 40); break; case E1INP_TS_TYPE_RAW: /* Get msgb from tx_queue */ msg = msgb_dequeue(&e1i_ts->raw.tx_queue); break; case E1INP_TS_TYPE_HDLC: /* Get msgb from tx_queue */ msg = msgb_dequeue(&e1i_ts->hdlc.tx_queue); break; case E1INP_TS_TYPE_I460: msg = msgb_alloc(TSX_ALLOC_SIZE, "I460_TX"); if (!msg) return NULL; len = osmo_i460_mux_out(&e1i_ts->i460.i460_ts, msg->data, 160); msgb_put(msg, len); break; default: LOGPITS(e1i_ts, DLMI, LOGL_ERROR, "unsupported E1 TS type %u\n", e1i_ts->type); return NULL; } return msg; } int e1inp_int_snd_event(struct e1inp_ts *ts, struct e1inp_sign_link *link, int evt) { struct input_signal_data isd; isd.line = ts->line; isd.ts_nr = ts->num; isd.link_type = link->type; isd.trx = link->trx; isd.tei = link->tei; isd.sapi = link->sapi; /* report further upwards */ osmo_signal_dispatch(SS_L_INPUT, evt, &isd); return 0; } /* called by driver in case some kind of link state event */ int e1inp_event(struct e1inp_ts *ts, int evt, uint8_t tei, uint8_t sapi) { struct e1inp_sign_link *link; link = e1inp_lookup_sign_link(ts, tei, sapi); if (!link) return -EINVAL; return e1inp_int_snd_event(ts, link, evt); } /* register a driver with the E1 core */ int e1inp_driver_register(struct e1inp_driver *drv) { llist_add_tail(&drv->list, &e1inp_driver_list); return 0; } struct e1inp_driver *e1inp_driver_find(const char *name) { struct e1inp_driver *drv; llist_for_each_entry(drv, &e1inp_driver_list, list) { if (!strcasecmp(name, drv->name)) return drv; } return NULL; } int e1inp_line_update(struct e1inp_line *line) { struct input_signal_data isd; int i, rc; if (line->driver && line->ops && line->driver->line_update) { rc = line->driver->line_update(line); } else rc = 0; /* Set the PCAP file descriptor for all timeslots that have * software LAPD instances, to ensure the osmo_lapd_pcap code is * used to write PCAP files (if requested) */ for (i = 0; i < ARRAY_SIZE(line->ts); i++) { struct e1inp_ts *e1i_ts = &line->ts[i]; if (e1i_ts->lapd) e1i_ts->lapd->pcap_fd = line->pcap_fd; } /* Send a signal to anyone who is interested in new lines being * configured */ memset(&isd, 0, sizeof(isd)); isd.line = line; osmo_signal_dispatch(SS_L_INPUT, S_L_INP_LINE_INIT, &isd); return rc; } static int e1i_sig_cb(unsigned int subsys, unsigned int signal, void *handler_data, void *signal_data) { struct e1inp_line *line; if (subsys != SS_L_GLOBAL || signal != S_L_GLOBAL_SHUTDOWN) return 0; llist_for_each_entry(line, &e1inp_line_list, list) { if (line->pcap_fd >=0) close(line->pcap_fd); line->pcap_fd = -1; } return 0; } const struct value_string e1inp_signal_names[] = { { S_L_INP_NONE, "NONE" }, { S_L_INP_TEI_UP, "TEI-UP" }, { S_L_INP_TEI_DN, "TEI-DOWN" }, { S_L_INP_TEI_UNKNOWN, "TEI-UNKNOWN" }, { S_L_INP_LINE_INIT, "LINE-INIT" }, { S_L_INP_LINE_ALARM, "LINE-ALARM" }, { S_L_INP_LINE_NOALARM, "LINE-NOALARM" }, { S_L_INP_LINE_LOS, "LINE-LOS" }, { S_L_INP_LINE_NOLOS, "LINE-NOLOS" }, { S_L_INP_LINE_AIS, "LINE-AIS" }, { S_L_INP_LINE_NOAIS, "LINE-NOAIS" }, { S_L_INP_LINE_RAI, "LINE-RAI" }, { S_L_INP_LINE_NORAI, "LINE-NORAI" }, { S_L_INP_LINE_SLIP_RX, "LINE-SLIP-RX" }, { S_L_INP_LINE_SLIP_TX, "LINE-SLIP-TX" }, { S_L_INP_LINE_SA_BITS, "LINE-SA-BITS" }, { S_L_INP_LINE_LOF, "LINE-LOF" }, { S_L_INP_LINE_NOLOF, "LINE-NOLOF" }, { 0, NULL } }; void e1inp_misdn_init(void); void e1inp_dahdi_init(void); void e1inp_e1d_init(void); void e1inp_ipaccess_init(void); void e1inp_rs232_init(void); void e1inp_unixsocket_init(void); void e1inp_init(void) { tall_e1inp_ctx = talloc_named_const(libosmo_abis_ctx, 1, "e1inp"); tall_sigl_ctx = talloc_named_const(tall_e1inp_ctx, 1, "e1inp_sign_link"); osmo_signal_register_handler(SS_L_GLOBAL, e1i_sig_cb, NULL); e1inp_misdn_init(); #ifdef HAVE_DAHDI_USER_H e1inp_dahdi_init(); #endif #ifdef HAVE_E1D e1inp_e1d_init(); #endif e1inp_ipaccess_init(); e1inp_rs232_init(); e1inp_unixsocket_init(); }