/* $OpenBSD: if_umb.c,v 1.35 2020/07/10 13:26:41 patrick Exp $ */ /* * Copyright (c) 2016 genua mbH * All rights reserved. * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* * Mobile Broadband Interface Model specification: * http://www.usb.org/developers/docs/devclass_docs/MBIM10Errata1_073013.zip * Compliance testing guide * http://www.usb.org/developers/docs/devclass_docs/MBIM-Compliance-1.0.pdf */ #include "bpfilter.h" #include #include #include #include #include #if NBPFILTER > 0 #include #endif #include #include #include #include #include #include #include #ifdef INET6 #include #include #include #include #include #endif #include #include #include #include #include #include #include #include #include #ifdef UMB_DEBUG #define DPRINTF(x...) \ do { if (umb_debug) log(LOG_DEBUG, x); } while (0) #define DPRINTFN(n, x...) \ do { if (umb_debug >= (n)) log(LOG_DEBUG, x); } while (0) #define DDUMPN(n, b, l) \ do { \ if (umb_debug >= (n)) \ umb_dump((b), (l)); \ } while (0) int umb_debug = 0; char *umb_uuid2str(uint8_t [MBIM_UUID_LEN]); void umb_dump(void *, int); #else #define DPRINTF(x...) do { } while (0) #define DPRINTFN(n, x...) do { } while (0) #define DDUMPN(n, b, l) do { } while (0) #endif #define DEVNAM(sc) (((struct umb_softc *)(sc))->sc_dev.dv_xname) /* * State change timeout */ #define UMB_STATE_CHANGE_TIMEOUT 30 /* * State change flags */ #define UMB_NS_DONT_DROP 0x0001 /* do not drop below current state */ #define UMB_NS_DONT_RAISE 0x0002 /* do not raise below current state */ /* * Diagnostic macros */ const struct umb_valdescr umb_regstates[] = MBIM_REGSTATE_DESCRIPTIONS; const struct umb_valdescr umb_dataclasses[] = MBIM_DATACLASS_DESCRIPTIONS; const struct umb_valdescr umb_simstate[] = MBIM_SIMSTATE_DESCRIPTIONS; const struct umb_valdescr umb_messages[] = MBIM_MESSAGES_DESCRIPTIONS; const struct umb_valdescr umb_status[] = MBIM_STATUS_DESCRIPTIONS; const struct umb_valdescr umb_cids[] = MBIM_CID_DESCRIPTIONS; const struct umb_valdescr umb_pktstate[] = MBIM_PKTSRV_STATE_DESCRIPTIONS; const struct umb_valdescr umb_actstate[] = MBIM_ACTIVATION_STATE_DESCRIPTIONS; const struct umb_valdescr umb_error[] = MBIM_ERROR_DESCRIPTIONS; const struct umb_valdescr umb_pintype[] = MBIM_PINTYPE_DESCRIPTIONS; const struct umb_valdescr umb_istate[] = UMB_INTERNAL_STATE_DESCRIPTIONS; #define umb_regstate(c) umb_val2descr(umb_regstates, (c)) #define umb_dataclass(c) umb_val2descr(umb_dataclasses, (c)) #define umb_simstate(s) umb_val2descr(umb_simstate, (s)) #define umb_request2str(m) umb_val2descr(umb_messages, (m)) #define umb_status2str(s) umb_val2descr(umb_status, (s)) #define umb_cid2str(c) umb_val2descr(umb_cids, (c)) #define umb_packet_state(s) umb_val2descr(umb_pktstate, (s)) #define umb_activation(s) umb_val2descr(umb_actstate, (s)) #define umb_error2str(e) umb_val2descr(umb_error, (e)) #define umb_pin_type(t) umb_val2descr(umb_pintype, (t)) #define umb_istate(s) umb_val2descr(umb_istate, (s)) int umb_match(struct device *, void *, void *); void umb_attach(struct device *, struct device *, void *); int umb_detach(struct device *, int); void umb_ncm_setup(struct umb_softc *); int umb_alloc_xfers(struct umb_softc *); void umb_free_xfers(struct umb_softc *); int umb_alloc_bulkpipes(struct umb_softc *); void umb_close_bulkpipes(struct umb_softc *); int umb_ioctl(struct ifnet *, u_long, caddr_t); int umb_output(struct ifnet *, struct mbuf *, struct sockaddr *, struct rtentry *); int umb_input(struct ifnet *, struct mbuf *, void *); void umb_start(struct ifnet *); void umb_rtrequest(struct ifnet *, int, struct rtentry *); void umb_watchdog(struct ifnet *); void umb_statechg_timeout(void *); void umb_newstate(struct umb_softc *, enum umb_state, int); void umb_state_task(void *); void umb_up(struct umb_softc *); void umb_down(struct umb_softc *, int); void umb_get_response_task(void *); void umb_decode_response(struct umb_softc *, void *, int); void umb_handle_indicate_status_msg(struct umb_softc *, void *, int); void umb_handle_opendone_msg(struct umb_softc *, void *, int); void umb_handle_closedone_msg(struct umb_softc *, void *, int); int umb_decode_register_state(struct umb_softc *, void *, int); int umb_decode_devices_caps(struct umb_softc *, void *, int); int umb_decode_subscriber_status(struct umb_softc *, void *, int); int umb_decode_radio_state(struct umb_softc *, void *, int); int umb_decode_pin(struct umb_softc *, void *, int); int umb_decode_packet_service(struct umb_softc *, void *, int); int umb_decode_signal_state(struct umb_softc *, void *, int); int umb_decode_connect_info(struct umb_softc *, void *, int); void umb_clear_addr(struct umb_softc *); int umb_add_inet_config(struct umb_softc *, struct in_addr, u_int, struct in_addr); int umb_add_inet6_config(struct umb_softc *, struct in6_addr *, u_int, struct in6_addr *); void umb_send_inet_proposal(struct umb_softc *, int); int umb_decode_ip_configuration(struct umb_softc *, void *, int); void umb_rx(struct umb_softc *); void umb_rxeof(struct usbd_xfer *, void *, usbd_status); int umb_encap(struct umb_softc *); void umb_txeof(struct usbd_xfer *, void *, usbd_status); void umb_decap(struct umb_softc *, struct usbd_xfer *); usbd_status umb_send_encap_command(struct umb_softc *, void *, int); int umb_get_encap_response(struct umb_softc *, void *, int *); void umb_ctrl_msg(struct umb_softc *, uint32_t, void *, int); void umb_open(struct umb_softc *); void umb_close(struct umb_softc *); int umb_setpin(struct umb_softc *, int, int, void *, int, void *, int); void umb_setdataclass(struct umb_softc *); void umb_radio(struct umb_softc *, int); void umb_allocate_cid(struct umb_softc *); void umb_send_fcc_auth(struct umb_softc *); void umb_packet_service(struct umb_softc *, int); void umb_connect(struct umb_softc *); void umb_disconnect(struct umb_softc *); void umb_send_connect(struct umb_softc *, int); void umb_qry_ipconfig(struct umb_softc *); void umb_cmd(struct umb_softc *, int, int, void *, int); void umb_cmd1(struct umb_softc *, int, int, void *, int, uint8_t *); void umb_command_done(struct umb_softc *, void *, int); void umb_decode_cid(struct umb_softc *, uint32_t, void *, int); void umb_decode_qmi(struct umb_softc *, uint8_t *, int); void umb_intr(struct usbd_xfer *, void *, usbd_status); int umb_xfer_tout = USBD_DEFAULT_TIMEOUT; uint8_t umb_uuid_basic_connect[] = MBIM_UUID_BASIC_CONNECT; uint8_t umb_uuid_context_internet[] = MBIM_UUID_CONTEXT_INTERNET; uint8_t umb_uuid_qmi_mbim[] = MBIM_UUID_QMI_MBIM; uint32_t umb_session_id = 0; struct cfdriver umb_cd = { NULL, "umb", DV_DULL }; const struct cfattach umb_ca = { sizeof (struct umb_softc), umb_match, umb_attach, umb_detach, NULL, }; int umb_delay = 4000; /* * These devices require an "FCC Authentication" command. */ const struct usb_devno umb_fccauth_devs[] = { { USB_VENDOR_SIERRA, USB_PRODUCT_SIERRA_EM7455 }, }; uint8_t umb_qmi_alloc_cid[] = { 0x01, 0x0f, 0x00, /* len */ 0x00, /* QMUX flags */ 0x00, /* service "ctl" */ 0x00, /* CID */ 0x00, /* QMI flags */ 0x01, /* transaction */ 0x22, 0x00, /* msg "Allocate CID" */ 0x04, 0x00, /* TLV len */ 0x01, 0x01, 0x00, 0x02 /* TLV */ }; uint8_t umb_qmi_fcc_auth[] = { 0x01, 0x0c, 0x00, /* len */ 0x00, /* QMUX flags */ 0x02, /* service "dms" */ #define UMB_QMI_CID_OFFS 5 0x00, /* CID (filled in later) */ 0x00, /* QMI flags */ 0x01, 0x00, /* transaction */ 0x5f, 0x55, /* msg "Send FCC Authentication" */ 0x00, 0x00 /* TLV len */ }; int umb_match(struct device *parent, void *match, void *aux) { struct usb_attach_arg *uaa = aux; usb_interface_descriptor_t *id; if (!uaa->iface) return UMATCH_NONE; if ((id = usbd_get_interface_descriptor(uaa->iface)) == NULL) return UMATCH_NONE; /* * If this function implements NCM, check if alternate setting * 1 implements MBIM. */ if (id->bInterfaceClass == UICLASS_CDC && id->bInterfaceSubClass == UISUBCLASS_NETWORK_CONTROL_MODEL) id = usbd_find_idesc(uaa->device->cdesc, uaa->iface->index, 1); if (id == NULL) return UMATCH_NONE; if (id->bInterfaceClass == UICLASS_CDC && id->bInterfaceSubClass == UISUBCLASS_MOBILE_BROADBAND_INTERFACE_MODEL && id->bInterfaceProtocol == 0) return UMATCH_IFACECLASS_IFACESUBCLASS_IFACEPROTO; return UMATCH_NONE; } void umb_attach(struct device *parent, struct device *self, void *aux) { struct umb_softc *sc = (struct umb_softc *)self; struct usb_attach_arg *uaa = aux; usbd_status status; struct usbd_desc_iter iter; const usb_descriptor_t *desc; int v; struct usb_cdc_union_descriptor *ud; struct mbim_descriptor *md; int i; int ctrl_ep; usb_interface_descriptor_t *id; usb_config_descriptor_t *cd; usb_endpoint_descriptor_t *ed; usb_interface_assoc_descriptor_t *ad; int current_ifaceno = -1; int data_ifaceno = -1; int altnum; int s; struct ifnet *ifp; sc->sc_udev = uaa->device; sc->sc_ctrl_ifaceno = uaa->ifaceno; ml_init(&sc->sc_tx_ml); /* * Some MBIM hardware does not provide the mandatory CDC Union * Descriptor, so we also look at matching Interface * Association Descriptors to find out the MBIM Data Interface * number. */ sc->sc_ver_maj = sc->sc_ver_min = -1; sc->sc_maxpktlen = MBIM_MAXSEGSZ_MINVAL; usbd_desc_iter_init(sc->sc_udev, &iter); while ((desc = usbd_desc_iter_next(&iter))) { if (desc->bDescriptorType == UDESC_IFACE_ASSOC) { ad = (usb_interface_assoc_descriptor_t *)desc; if (ad->bFirstInterface == uaa->ifaceno && ad->bInterfaceCount > 1) data_ifaceno = uaa->ifaceno + 1; continue; } if (desc->bDescriptorType == UDESC_INTERFACE) { id = (usb_interface_descriptor_t *)desc; current_ifaceno = id->bInterfaceNumber; continue; } if (current_ifaceno != uaa->ifaceno) continue; if (desc->bDescriptorType != UDESC_CS_INTERFACE) continue; switch (desc->bDescriptorSubtype) { case UDESCSUB_CDC_UNION: ud = (struct usb_cdc_union_descriptor *)desc; data_ifaceno = ud->bSlaveInterface[0]; break; case UDESCSUB_MBIM: md = (struct mbim_descriptor *)desc; v = UGETW(md->bcdMBIMVersion); sc->sc_ver_maj = MBIM_VER_MAJOR(v); sc->sc_ver_min = MBIM_VER_MINOR(v); sc->sc_ctrl_len = UGETW(md->wMaxControlMessage); /* Never trust a USB device! Could try to exploit us */ if (sc->sc_ctrl_len < MBIM_CTRLMSG_MINLEN || sc->sc_ctrl_len > MBIM_CTRLMSG_MAXLEN) { DPRINTF("%s: control message len %d out of " "bounds [%d .. %d]\n", DEVNAM(sc), sc->sc_ctrl_len, MBIM_CTRLMSG_MINLEN, MBIM_CTRLMSG_MAXLEN); /* cont. anyway */ } sc->sc_maxpktlen = UGETW(md->wMaxSegmentSize); DPRINTFN(2, "%s: ctrl_len=%d, maxpktlen=%d, cap=0x%x\n", DEVNAM(sc), sc->sc_ctrl_len, sc->sc_maxpktlen, md->bmNetworkCapabilities); break; default: break; } } if (sc->sc_ver_maj < 0) { printf("%s: missing MBIM descriptor\n", DEVNAM(sc)); goto fail; } if (usb_lookup(umb_fccauth_devs, uaa->vendor, uaa->product)) { sc->sc_flags |= UMBFLG_FCC_AUTH_REQUIRED; sc->sc_cid = -1; } for (i = 0; i < uaa->nifaces; i++) { if (usbd_iface_claimed(sc->sc_udev, i)) continue; id = usbd_get_interface_descriptor(uaa->ifaces[i]); if (id != NULL && id->bInterfaceNumber == data_ifaceno) { sc->sc_data_iface = uaa->ifaces[i]; usbd_claim_iface(sc->sc_udev, i); } } if (sc->sc_data_iface == NULL) { printf("%s: no data interface found\n", DEVNAM(sc)); goto fail; } /* * If this is a combined NCM/MBIM function, switch to * alternate setting one to enable MBIM. */ id = usbd_get_interface_descriptor(uaa->iface); if (id->bInterfaceClass == UICLASS_CDC && id->bInterfaceSubClass == UISUBCLASS_NETWORK_CONTROL_MODEL) usbd_set_interface(uaa->iface, 1); id = usbd_get_interface_descriptor(uaa->iface); ctrl_ep = -1; for (i = 0; i < id->bNumEndpoints && ctrl_ep == -1; i++) { ed = usbd_interface2endpoint_descriptor(uaa->iface, i); if (ed == NULL) break; if (UE_GET_XFERTYPE(ed->bmAttributes) == UE_INTERRUPT && UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) ctrl_ep = ed->bEndpointAddress; } if (ctrl_ep == -1) { printf("%s: missing interrupt endpoint\n", DEVNAM(sc)); goto fail; } /* * For the MBIM Data Interface, select the appropriate * alternate setting by looking for a matching descriptor that * has two endpoints. */ cd = usbd_get_config_descriptor(sc->sc_udev); altnum = usbd_get_no_alts(cd, data_ifaceno); for (i = 0; i < altnum; i++) { id = usbd_find_idesc(cd, sc->sc_data_iface->index, i); if (id == NULL) continue; if (id->bInterfaceClass == UICLASS_CDC_DATA && id->bInterfaceSubClass == UISUBCLASS_DATA && id->bInterfaceProtocol == UIPROTO_DATA_MBIM && id->bNumEndpoints == 2) break; } if (i == altnum || id == NULL) { printf("%s: missing alt setting for interface #%d\n", DEVNAM(sc), data_ifaceno); goto fail; } status = usbd_set_interface(sc->sc_data_iface, i); if (status) { printf("%s: select alt setting %d for interface #%d " "failed: %s\n", DEVNAM(sc), i, data_ifaceno, usbd_errstr(status)); goto fail; } id = usbd_get_interface_descriptor(sc->sc_data_iface); sc->sc_rx_ep = sc->sc_tx_ep = -1; for (i = 0; i < id->bNumEndpoints; i++) { if ((ed = usbd_interface2endpoint_descriptor(sc->sc_data_iface, i)) == NULL) break; if (UE_GET_XFERTYPE(ed->bmAttributes) == UE_BULK && UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_IN) sc->sc_rx_ep = ed->bEndpointAddress; else if (UE_GET_XFERTYPE(ed->bmAttributes) == UE_BULK && UE_GET_DIR(ed->bEndpointAddress) == UE_DIR_OUT) sc->sc_tx_ep = ed->bEndpointAddress; } if (sc->sc_rx_ep == -1 || sc->sc_tx_ep == -1) { printf("%s: missing bulk endpoints\n", DEVNAM(sc)); goto fail; } DPRINTFN(2, "%s: ctrl-ifno#%d: ep-ctrl=%d, data-ifno#%d: ep-rx=%d, " "ep-tx=%d\n", DEVNAM(sc), sc->sc_ctrl_ifaceno, UE_GET_ADDR(ctrl_ep), data_ifaceno, UE_GET_ADDR(sc->sc_rx_ep), UE_GET_ADDR(sc->sc_tx_ep)); usb_init_task(&sc->sc_umb_task, umb_state_task, sc, USB_TASK_TYPE_GENERIC); usb_init_task(&sc->sc_get_response_task, umb_get_response_task, sc, USB_TASK_TYPE_GENERIC); timeout_set(&sc->sc_statechg_timer, umb_statechg_timeout, sc); if (usbd_open_pipe_intr(uaa->iface, ctrl_ep, USBD_SHORT_XFER_OK, &sc->sc_ctrl_pipe, sc, &sc->sc_intr_msg, sizeof (sc->sc_intr_msg), umb_intr, USBD_DEFAULT_INTERVAL)) { printf("%s: failed to open control pipe\n", DEVNAM(sc)); goto fail; } sc->sc_resp_buf = malloc(sc->sc_ctrl_len, M_USBDEV, M_NOWAIT); if (sc->sc_resp_buf == NULL) { printf("%s: allocation of resp buffer failed\n", DEVNAM(sc)); goto fail; } sc->sc_ctrl_msg = malloc(sc->sc_ctrl_len, M_USBDEV, M_NOWAIT); if (sc->sc_ctrl_msg == NULL) { printf("%s: allocation of ctrl msg buffer failed\n", DEVNAM(sc)); goto fail; } sc->sc_info.regstate = MBIM_REGSTATE_UNKNOWN; sc->sc_info.pin_attempts_left = UMB_VALUE_UNKNOWN; sc->sc_info.rssi = UMB_VALUE_UNKNOWN; sc->sc_info.ber = UMB_VALUE_UNKNOWN; umb_ncm_setup(sc); DPRINTFN(2, "%s: rx/tx size %d/%d\n", DEVNAM(sc), sc->sc_rx_bufsz, sc->sc_tx_bufsz); s = splnet(); ifp = GET_IFP(sc); ifp->if_flags = IFF_SIMPLEX | IFF_MULTICAST | IFF_POINTOPOINT; ifp->if_ioctl = umb_ioctl; ifp->if_start = umb_start; ifp->if_rtrequest = umb_rtrequest; ifp->if_watchdog = umb_watchdog; strlcpy(ifp->if_xname, DEVNAM(sc), IFNAMSIZ); ifp->if_link_state = LINK_STATE_DOWN; ifp->if_type = IFT_MBIM; ifp->if_priority = IF_WWAN_DEFAULT_PRIORITY; ifp->if_addrlen = 0; ifp->if_hdrlen = sizeof (struct ncm_header16) + sizeof (struct ncm_pointer16); ifp->if_mtu = 1500; /* use a common default */ ifp->if_hardmtu = sc->sc_maxpktlen; ifp->if_output = umb_output; if_attach(ifp); if_ih_insert(ifp, umb_input, NULL); if_alloc_sadl(ifp); ifp->if_softc = sc; #if NBPFILTER > 0 bpfattach(&ifp->if_bpf, ifp, DLT_LOOP, sizeof(uint32_t)); #endif /* * Open the device now so that we are able to query device information. * XXX maybe close when done? */ umb_open(sc); splx(s); DPRINTF("%s: vers %d.%d\n", DEVNAM(sc), sc->sc_ver_maj, sc->sc_ver_min); return; fail: usbd_deactivate(sc->sc_udev); return; } int umb_detach(struct device *self, int flags) { struct umb_softc *sc = (struct umb_softc *)self; struct ifnet *ifp = GET_IFP(sc); int s; s = splnet(); if (ifp->if_flags & IFF_RUNNING) umb_down(sc, 1); umb_close(sc); usb_rem_wait_task(sc->sc_udev, &sc->sc_get_response_task); if (timeout_initialized(&sc->sc_statechg_timer)) timeout_del(&sc->sc_statechg_timer); sc->sc_nresp = 0; usb_rem_wait_task(sc->sc_udev, &sc->sc_umb_task); if (sc->sc_ctrl_pipe) { usbd_close_pipe(sc->sc_ctrl_pipe); sc->sc_ctrl_pipe = NULL; } if (sc->sc_ctrl_msg) { free(sc->sc_ctrl_msg, M_USBDEV, sc->sc_ctrl_len); sc->sc_ctrl_msg = NULL; } if (sc->sc_resp_buf) { free(sc->sc_resp_buf, M_USBDEV, sc->sc_ctrl_len); sc->sc_resp_buf = NULL; } if (ifp->if_softc != NULL) { if_ih_remove(ifp, umb_input, NULL); if_detach(ifp); } splx(s); return 0; } void umb_ncm_setup(struct umb_softc *sc) { usb_device_request_t req; struct ncm_ntb_parameters np; /* Query NTB tranfers sizes */ req.bmRequestType = UT_READ_CLASS_INTERFACE; req.bRequest = NCM_GET_NTB_PARAMETERS; USETW(req.wValue, 0); USETW(req.wIndex, sc->sc_ctrl_ifaceno); USETW(req.wLength, sizeof (np)); if (usbd_do_request(sc->sc_udev, &req, &np) == USBD_NORMAL_COMPLETION && UGETW(np.wLength) == sizeof (np)) { sc->sc_rx_bufsz = UGETDW(np.dwNtbInMaxSize); sc->sc_tx_bufsz = UGETDW(np.dwNtbOutMaxSize); sc->sc_maxdgram = UGETW(np.wNtbOutMaxDatagrams); sc->sc_align = UGETW(np.wNdpOutAlignment); sc->sc_ndp_div = UGETW(np.wNdpOutDivisor); sc->sc_ndp_remainder = UGETW(np.wNdpOutPayloadRemainder); /* Validate values */ if (!powerof2(sc->sc_align) || sc->sc_align == 0 || sc->sc_align >= sc->sc_tx_bufsz) sc->sc_align = sizeof (uint32_t); if (!powerof2(sc->sc_ndp_div) || sc->sc_ndp_div == 0 || sc->sc_ndp_div >= sc->sc_tx_bufsz) sc->sc_ndp_div = sizeof (uint32_t); if (sc->sc_ndp_remainder >= sc->sc_ndp_div) sc->sc_ndp_remainder = 0; } else { sc->sc_rx_bufsz = sc->sc_tx_bufsz = 8 * 1024; sc->sc_maxdgram = 0; sc->sc_align = sc->sc_ndp_div = sizeof (uint32_t); sc->sc_ndp_remainder = 0; } } int umb_alloc_xfers(struct umb_softc *sc) { if (!sc->sc_rx_xfer) { if ((sc->sc_rx_xfer = usbd_alloc_xfer(sc->sc_udev)) != NULL) sc->sc_rx_buf = usbd_alloc_buffer(sc->sc_rx_xfer, sc->sc_rx_bufsz); } if (!sc->sc_tx_xfer) { if ((sc->sc_tx_xfer = usbd_alloc_xfer(sc->sc_udev)) != NULL) sc->sc_tx_buf = usbd_alloc_buffer(sc->sc_tx_xfer, sc->sc_tx_bufsz); } return (sc->sc_rx_buf && sc->sc_tx_buf) ? 1 : 0; } void umb_free_xfers(struct umb_softc *sc) { if (sc->sc_rx_xfer) { /* implicit usbd_free_buffer() */ usbd_free_xfer(sc->sc_rx_xfer); sc->sc_rx_xfer = NULL; sc->sc_rx_buf = NULL; } if (sc->sc_tx_xfer) { usbd_free_xfer(sc->sc_tx_xfer); sc->sc_tx_xfer = NULL; sc->sc_tx_buf = NULL; } ml_purge(&sc->sc_tx_ml); } int umb_alloc_bulkpipes(struct umb_softc *sc) { struct ifnet *ifp = GET_IFP(sc); if (!(ifp->if_flags & IFF_RUNNING)) { if (usbd_open_pipe(sc->sc_data_iface, sc->sc_rx_ep, USBD_EXCLUSIVE_USE, &sc->sc_rx_pipe)) return 0; if (usbd_open_pipe(sc->sc_data_iface, sc->sc_tx_ep, USBD_EXCLUSIVE_USE, &sc->sc_tx_pipe)) return 0; ifp->if_flags |= IFF_RUNNING; ifq_clr_oactive(&ifp->if_snd); umb_rx(sc); } return 1; } void umb_close_bulkpipes(struct umb_softc *sc) { struct ifnet *ifp = GET_IFP(sc); ifp->if_flags &= ~IFF_RUNNING; ifq_clr_oactive(&ifp->if_snd); ifp->if_timer = 0; if (sc->sc_rx_pipe) { usbd_close_pipe(sc->sc_rx_pipe); sc->sc_rx_pipe = NULL; } if (sc->sc_tx_pipe) { usbd_close_pipe(sc->sc_tx_pipe); sc->sc_tx_pipe = NULL; } } int umb_ioctl(struct ifnet *ifp, u_long cmd, caddr_t data) { struct proc *p = curproc; struct umb_softc *sc = ifp->if_softc; struct ifreq *ifr = (struct ifreq *)data; int s, error = 0; struct umb_parameter mp; if (usbd_is_dying(sc->sc_udev)) return ENXIO; s = splnet(); switch (cmd) { case SIOCSIFFLAGS: usb_add_task(sc->sc_udev, &sc->sc_umb_task); break; case SIOCGUMBINFO: error = copyout(&sc->sc_info, ifr->ifr_data, sizeof (sc->sc_info)); break; case SIOCSUMBPARAM: if ((error = suser(p)) != 0) break; if ((error = copyin(ifr->ifr_data, &mp, sizeof (mp))) != 0) break; if ((error = umb_setpin(sc, mp.op, mp.is_puk, mp.pin, mp.pinlen, mp.newpin, mp.newpinlen)) != 0) break; if (mp.apnlen < 0 || mp.apnlen > sizeof (sc->sc_info.apn)) { error = EINVAL; break; } sc->sc_roaming = mp.roaming ? 1 : 0; memset(sc->sc_info.apn, 0, sizeof (sc->sc_info.apn)); memcpy(sc->sc_info.apn, mp.apn, mp.apnlen); sc->sc_info.apnlen = mp.apnlen; sc->sc_info.preferredclasses = mp.preferredclasses; umb_setdataclass(sc); break; case SIOCGUMBPARAM: memset(&mp, 0, sizeof (mp)); memcpy(mp.apn, sc->sc_info.apn, sc->sc_info.apnlen); mp.apnlen = sc->sc_info.apnlen; mp.roaming = sc->sc_roaming; mp.preferredclasses = sc->sc_info.preferredclasses; error = copyout(&mp, ifr->ifr_data, sizeof (mp)); break; case SIOCSIFMTU: /* Does this include the NCM headers and tail? */ if (ifr->ifr_mtu > ifp->if_hardmtu) { error = EINVAL; break; } ifp->if_mtu = ifr->ifr_mtu; break; case SIOCSIFADDR: case SIOCAIFADDR: case SIOCSIFDSTADDR: case SIOCADDMULTI: case SIOCDELMULTI: break; default: error = ENOTTY; break; } splx(s); return error; } int umb_output(struct ifnet *ifp, struct mbuf *m, struct sockaddr *dst, struct rtentry *rtp) { if ((ifp->if_flags & (IFF_UP|IFF_RUNNING)) != (IFF_UP|IFF_RUNNING)) { m_freem(m); return ENETDOWN; } m->m_pkthdr.ph_family = dst->sa_family; return if_enqueue(ifp, m); } int umb_input(struct ifnet *ifp, struct mbuf *m, void *cookie) { uint32_t af; if ((ifp->if_flags & IFF_UP) == 0) { m_freem(m); return 1; } if (m->m_pkthdr.len < sizeof (struct ip) + sizeof(af)) { ifp->if_ierrors++; DPRINTFN(4, "%s: dropping short packet (len %d)\n", __func__, m->m_pkthdr.len); m_freem(m); return 1; } m->m_pkthdr.ph_rtableid = ifp->if_rdomain; /* pop of DLT_LOOP header, no longer needed */ af = *mtod(m, uint32_t *); m_adj(m, sizeof (af)); af = ntohl(af); ifp->if_ibytes += m->m_pkthdr.len; switch (af) { case AF_INET: ipv4_input(ifp, m); return 1; #ifdef INET6 case AF_INET6: ipv6_input(ifp, m); return 1; #endif /* INET6 */ default: ifp->if_ierrors++; DPRINTFN(4, "%s: dropping packet with bad IP version (af %d)\n", __func__, af); m_freem(m); return 1; } return 1; } static inline int umb_align(size_t bufsz, int offs, int alignment, int remainder) { size_t m = alignment - 1; int align; align = (((size_t)offs + m) & ~m) - alignment + remainder; if (align < offs) align += alignment; if (align > bufsz) align = bufsz; return align - offs; } static inline int umb_padding(void *buf, size_t bufsz, int offs, int alignment, int remainder) { int nb; nb = umb_align(bufsz, offs, alignment, remainder); if (nb > 0) memset(buf + offs, 0, nb); return nb; } void umb_start(struct ifnet *ifp) { struct umb_softc *sc = ifp->if_softc; struct mbuf *m = NULL; int ndgram = 0; int offs, plen, len, mlen; int maxalign; if (usbd_is_dying(sc->sc_udev) || !(ifp->if_flags & IFF_RUNNING) || ifq_is_oactive(&ifp->if_snd)) return; KASSERT(ml_empty(&sc->sc_tx_ml)); offs = sizeof (struct ncm_header16); offs += umb_align(sc->sc_tx_bufsz, offs, sc->sc_align, 0); /* * Note that 'struct ncm_pointer16' already includes space for the * terminating zero pointer. */ offs += sizeof (struct ncm_pointer16); plen = sizeof (struct ncm_pointer16_dgram); maxalign = (sc->sc_ndp_div - 1) + sc->sc_ndp_remainder; len = 0; while (1) { m = ifq_deq_begin(&ifp->if_snd); if (m == NULL) break; /* * Check if mbuf plus required NCM pointer still fits into * xfer buffers. Assume maximal padding. */ plen += sizeof (struct ncm_pointer16_dgram); mlen = maxalign + m->m_pkthdr.len; if ((sc->sc_maxdgram != 0 && ndgram >= sc->sc_maxdgram) || (offs + plen + len + mlen > sc->sc_tx_bufsz)) { ifq_deq_rollback(&ifp->if_snd, m); break; } ifq_deq_commit(&ifp->if_snd, m); ndgram++; len += mlen; ml_enqueue(&sc->sc_tx_ml, m); #if NBPFILTER > 0 if (ifp->if_bpf) bpf_mtap_af(ifp->if_bpf, m->m_pkthdr.ph_family, m, BPF_DIRECTION_OUT); #endif } if (ml_empty(&sc->sc_tx_ml)) return; if (umb_encap(sc)) { ifq_set_oactive(&ifp->if_snd); ifp->if_timer = (2 * umb_xfer_tout) / 1000; } } void umb_rtrequest(struct ifnet *ifp, int req, struct rtentry *rt) { struct umb_softc *sc = ifp->if_softc; if (req == RTM_PROPOSAL) { umb_send_inet_proposal(sc, AF_INET); #ifdef INET6 umb_send_inet_proposal(sc, AF_INET6); #endif return; } p2p_rtrequest(ifp, req, rt); } void umb_watchdog(struct ifnet *ifp) { struct umb_softc *sc = ifp->if_softc; if (usbd_is_dying(sc->sc_udev)) return; ifp->if_oerrors++; printf("%s: watchdog timeout\n", DEVNAM(sc)); usbd_abort_pipe(sc->sc_tx_pipe); return; } void umb_statechg_timeout(void *arg) { struct umb_softc *sc = arg; struct ifnet *ifp = GET_IFP(sc); if (sc->sc_info.regstate != MBIM_REGSTATE_ROAMING || sc->sc_roaming) if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: state change timeout\n", DEVNAM(sc)); usb_add_task(sc->sc_udev, &sc->sc_umb_task); } void umb_newstate(struct umb_softc *sc, enum umb_state newstate, int flags) { struct ifnet *ifp = GET_IFP(sc); if (newstate == sc->sc_state) return; if (((flags & UMB_NS_DONT_DROP) && newstate < sc->sc_state) || ((flags & UMB_NS_DONT_RAISE) && newstate > sc->sc_state)) return; if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: state going %s from '%s' to '%s'\n", DEVNAM(sc), newstate > sc->sc_state ? "up" : "down", umb_istate(sc->sc_state), umb_istate(newstate)); sc->sc_state = newstate; usb_add_task(sc->sc_udev, &sc->sc_umb_task); } void umb_state_task(void *arg) { struct umb_softc *sc = arg; struct ifnet *ifp = GET_IFP(sc); int s; int state; if (sc->sc_info.regstate == MBIM_REGSTATE_ROAMING && !sc->sc_roaming) { /* * Query the registration state until we're with the home * network again. */ umb_cmd(sc, MBIM_CID_REGISTER_STATE, MBIM_CMDOP_QRY, NULL, 0); return; } s = splnet(); if (ifp->if_flags & IFF_UP) umb_up(sc); else umb_down(sc, 0); state = sc->sc_state == UMB_S_UP ? LINK_STATE_UP : LINK_STATE_DOWN; if (ifp->if_link_state != state) { if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: link state changed from %s to %s\n", DEVNAM(sc), LINK_STATE_IS_UP(ifp->if_link_state) ? "up" : "down", LINK_STATE_IS_UP(state) ? "up" : "down"); ifp->if_link_state = state; if_link_state_change(ifp); } splx(s); } void umb_up(struct umb_softc *sc) { splassert(IPL_NET); switch (sc->sc_state) { case UMB_S_DOWN: DPRINTF("%s: init: opening ...\n", DEVNAM(sc)); umb_open(sc); break; case UMB_S_OPEN: if (sc->sc_flags & UMBFLG_FCC_AUTH_REQUIRED) { if (sc->sc_cid == -1) { DPRINTF("%s: init: allocating CID ...\n", DEVNAM(sc)); umb_allocate_cid(sc); break; } else umb_newstate(sc, UMB_S_CID, UMB_NS_DONT_DROP); } else { DPRINTF("%s: init: turning radio on ...\n", DEVNAM(sc)); umb_radio(sc, 1); break; } /*FALLTHROUGH*/ case UMB_S_CID: DPRINTF("%s: init: sending FCC auth ...\n", DEVNAM(sc)); umb_send_fcc_auth(sc); break; case UMB_S_RADIO: DPRINTF("%s: init: checking SIM state ...\n", DEVNAM(sc)); umb_cmd(sc, MBIM_CID_SUBSCRIBER_READY_STATUS, MBIM_CMDOP_QRY, NULL, 0); break; case UMB_S_SIMREADY: DPRINTF("%s: init: attaching ...\n", DEVNAM(sc)); umb_packet_service(sc, 1); break; case UMB_S_ATTACHED: sc->sc_tx_seq = 0; if (!umb_alloc_xfers(sc)) { umb_free_xfers(sc); printf("%s: allocation of xfers failed\n", DEVNAM(sc)); break; } DPRINTF("%s: init: connecting ...\n", DEVNAM(sc)); umb_connect(sc); break; case UMB_S_CONNECTED: DPRINTF("%s: init: getting IP config ...\n", DEVNAM(sc)); umb_qry_ipconfig(sc); break; case UMB_S_UP: DPRINTF("%s: init: reached state UP\n", DEVNAM(sc)); if (!umb_alloc_bulkpipes(sc)) { printf("%s: opening bulk pipes failed\n", DEVNAM(sc)); umb_down(sc, 1); } break; } if (sc->sc_state < UMB_S_UP) timeout_add_sec(&sc->sc_statechg_timer, UMB_STATE_CHANGE_TIMEOUT); else timeout_del(&sc->sc_statechg_timer); return; } void umb_down(struct umb_softc *sc, int force) { splassert(IPL_NET); umb_close_bulkpipes(sc); if (sc->sc_state < UMB_S_CONNECTED) umb_free_xfers(sc); switch (sc->sc_state) { case UMB_S_UP: umb_clear_addr(sc); /*FALLTHROUGH*/ case UMB_S_CONNECTED: DPRINTF("%s: stop: disconnecting ...\n", DEVNAM(sc)); umb_disconnect(sc); if (!force) break; /*FALLTHROUGH*/ case UMB_S_ATTACHED: DPRINTF("%s: stop: detaching ...\n", DEVNAM(sc)); umb_packet_service(sc, 0); if (!force) break; /*FALLTHROUGH*/ case UMB_S_SIMREADY: case UMB_S_RADIO: DPRINTF("%s: stop: turning radio off ...\n", DEVNAM(sc)); umb_radio(sc, 0); if (!force) break; /*FALLTHROUGH*/ case UMB_S_CID: case UMB_S_OPEN: case UMB_S_DOWN: /* Do not close the device */ DPRINTF("%s: stop: reached state DOWN\n", DEVNAM(sc)); break; } if (force) sc->sc_state = UMB_S_OPEN; if (sc->sc_state > UMB_S_OPEN) timeout_add_sec(&sc->sc_statechg_timer, UMB_STATE_CHANGE_TIMEOUT); else timeout_del(&sc->sc_statechg_timer); } void umb_get_response_task(void *arg) { struct umb_softc *sc = arg; int len; int s; /* * Function is required to send on RESPONSE_AVAILABLE notification for * each encapsulated response that is to be processed by the host. * But of course, we can receive multiple notifications before the * response task is run. */ s = splusb(); while (sc->sc_nresp > 0) { --sc->sc_nresp; len = sc->sc_ctrl_len; if (umb_get_encap_response(sc, sc->sc_resp_buf, &len)) umb_decode_response(sc, sc->sc_resp_buf, len); } splx(s); } void umb_decode_response(struct umb_softc *sc, void *response, int len) { struct mbim_msghdr *hdr = response; struct mbim_fragmented_msg_hdr *fraghdr; uint32_t type; uint32_t tid; DPRINTFN(3, "%s: got response: len %d\n", DEVNAM(sc), len); DDUMPN(4, response, len); if (len < sizeof (*hdr) || letoh32(hdr->len) != len) { /* * We should probably cancel a transaction, but since the * message is too short, we cannot decode the transaction * id (tid) and hence don't know, whom to cancel. Must wait * for the timeout. */ DPRINTF("%s: received short response (len %d)\n", DEVNAM(sc), len); return; } /* * XXX FIXME: if message is fragmented, store it until last frag * is received and then re-assemble all fragments. */ type = letoh32(hdr->type); tid = letoh32(hdr->tid); switch (type) { case MBIM_INDICATE_STATUS_MSG: case MBIM_COMMAND_DONE: fraghdr = response; if (letoh32(fraghdr->frag.nfrag) != 1) { DPRINTF("%s: discarding fragmented messages\n", DEVNAM(sc)); return; } break; default: break; } DPRINTF("%s: <- rcv %s (tid %u)\n", DEVNAM(sc), umb_request2str(type), tid); switch (type) { case MBIM_FUNCTION_ERROR_MSG: case MBIM_HOST_ERROR_MSG: { struct mbim_f2h_hosterr *e; int err; if (len >= sizeof (*e)) { e = response; err = letoh32(e->err); DPRINTF("%s: %s message, error %s (tid %u)\n", DEVNAM(sc), umb_request2str(type), umb_error2str(err), tid); if (err == MBIM_ERROR_NOT_OPENED) umb_newstate(sc, UMB_S_DOWN, 0); } break; } case MBIM_INDICATE_STATUS_MSG: umb_handle_indicate_status_msg(sc, response, len); break; case MBIM_OPEN_DONE: umb_handle_opendone_msg(sc, response, len); break; case MBIM_CLOSE_DONE: umb_handle_closedone_msg(sc, response, len); break; case MBIM_COMMAND_DONE: umb_command_done(sc, response, len); break; default: DPRINTF("%s: discard message %s\n", DEVNAM(sc), umb_request2str(type)); break; } } void umb_handle_indicate_status_msg(struct umb_softc *sc, void *data, int len) { struct mbim_f2h_indicate_status *m = data; uint32_t infolen; uint32_t cid; if (len < sizeof (*m)) { DPRINTF("%s: discard short %s message\n", DEVNAM(sc), umb_request2str(letoh32(m->hdr.type))); return; } if (memcmp(m->devid, umb_uuid_basic_connect, sizeof (m->devid))) { DPRINTF("%s: discard %s message for other UUID '%s'\n", DEVNAM(sc), umb_request2str(letoh32(m->hdr.type)), umb_uuid2str(m->devid)); return; } infolen = letoh32(m->infolen); if (len < sizeof (*m) + infolen) { DPRINTF("%s: discard truncated %s message (want %d, got %d)\n", DEVNAM(sc), umb_request2str(letoh32(m->hdr.type)), (int)sizeof (*m) + infolen, len); return; } cid = letoh32(m->cid); DPRINTF("%s: indicate %s status\n", DEVNAM(sc), umb_cid2str(cid)); umb_decode_cid(sc, cid, m->info, infolen); } void umb_handle_opendone_msg(struct umb_softc *sc, void *data, int len) { struct mbim_f2h_openclosedone *resp = data; struct ifnet *ifp = GET_IFP(sc); uint32_t status; status = letoh32(resp->status); if (status == MBIM_STATUS_SUCCESS) { if (sc->sc_maxsessions == 0) { umb_cmd(sc, MBIM_CID_DEVICE_CAPS, MBIM_CMDOP_QRY, NULL, 0); umb_cmd(sc, MBIM_CID_PIN, MBIM_CMDOP_QRY, NULL, 0); umb_cmd(sc, MBIM_CID_REGISTER_STATE, MBIM_CMDOP_QRY, NULL, 0); } umb_newstate(sc, UMB_S_OPEN, UMB_NS_DONT_DROP); } else if (ifp->if_flags & IFF_DEBUG) log(LOG_ERR, "%s: open error: %s\n", DEVNAM(sc), umb_status2str(status)); return; } void umb_handle_closedone_msg(struct umb_softc *sc, void *data, int len) { struct mbim_f2h_openclosedone *resp = data; uint32_t status; status = letoh32(resp->status); if (status == MBIM_STATUS_SUCCESS) umb_newstate(sc, UMB_S_DOWN, 0); else DPRINTF("%s: close error: %s\n", DEVNAM(sc), umb_status2str(status)); return; } static inline void umb_getinfobuf(void *in, int inlen, uint32_t offs, uint32_t sz, void *out, size_t outlen) { offs = letoh32(offs); sz = letoh32(sz); if (inlen >= offs + sz) { memset(out, 0, outlen); memcpy(out, in + offs, MIN(sz, outlen)); } } static inline int umb_addstr(void *buf, size_t bufsz, int *offs, void *str, int slen, uint32_t *offsmember, uint32_t *sizemember) { if (*offs + slen > bufsz) return 0; *sizemember = htole32((uint32_t)slen); if (slen && str) { *offsmember = htole32((uint32_t)*offs); memcpy(buf + *offs, str, slen); *offs += slen; *offs += umb_padding(buf, bufsz, *offs, sizeof (uint32_t), 0); } else *offsmember = htole32(0); return 1; } int umb_decode_register_state(struct umb_softc *sc, void *data, int len) { struct mbim_cid_registration_state_info *rs = data; struct ifnet *ifp = GET_IFP(sc); if (len < sizeof (*rs)) return 0; sc->sc_info.nwerror = letoh32(rs->nwerror); sc->sc_info.regstate = letoh32(rs->regstate); sc->sc_info.regmode = letoh32(rs->regmode); sc->sc_info.cellclass = letoh32(rs->curcellclass); /* XXX should we remember the provider_id? */ umb_getinfobuf(data, len, rs->provname_offs, rs->provname_size, sc->sc_info.provider, sizeof (sc->sc_info.provider)); umb_getinfobuf(data, len, rs->roamingtxt_offs, rs->roamingtxt_size, sc->sc_info.roamingtxt, sizeof (sc->sc_info.roamingtxt)); DPRINTFN(2, "%s: %s, availclass 0x%x, class 0x%x, regmode %d\n", DEVNAM(sc), umb_regstate(sc->sc_info.regstate), letoh32(rs->availclasses), sc->sc_info.cellclass, sc->sc_info.regmode); if (sc->sc_info.regstate == MBIM_REGSTATE_ROAMING && !sc->sc_roaming && sc->sc_info.activation == MBIM_ACTIVATION_STATE_ACTIVATED) { if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: disconnecting from roaming network\n", DEVNAM(sc)); umb_disconnect(sc); } return 1; } int umb_decode_devices_caps(struct umb_softc *sc, void *data, int len) { struct mbim_cid_device_caps *dc = data; if (len < sizeof (*dc)) return 0; sc->sc_maxsessions = letoh32(dc->max_sessions); sc->sc_info.supportedclasses = letoh32(dc->dataclass); umb_getinfobuf(data, len, dc->devid_offs, dc->devid_size, sc->sc_info.devid, sizeof (sc->sc_info.devid)); umb_getinfobuf(data, len, dc->fwinfo_offs, dc->fwinfo_size, sc->sc_info.fwinfo, sizeof (sc->sc_info.fwinfo)); umb_getinfobuf(data, len, dc->hwinfo_offs, dc->hwinfo_size, sc->sc_info.hwinfo, sizeof (sc->sc_info.hwinfo)); DPRINTFN(2, "%s: max sessions %d, supported classes 0x%x\n", DEVNAM(sc), sc->sc_maxsessions, sc->sc_info.supportedclasses); return 1; } int umb_decode_subscriber_status(struct umb_softc *sc, void *data, int len) { struct mbim_cid_subscriber_ready_info *si = data; struct ifnet *ifp = GET_IFP(sc); int npn; if (len < sizeof (*si)) return 0; sc->sc_info.sim_state = letoh32(si->ready); umb_getinfobuf(data, len, si->sid_offs, si->sid_size, sc->sc_info.sid, sizeof (sc->sc_info.sid)); umb_getinfobuf(data, len, si->icc_offs, si->icc_size, sc->sc_info.iccid, sizeof (sc->sc_info.iccid)); npn = letoh32(si->no_pn); if (npn > 0) umb_getinfobuf(data, len, si->pn[0].offs, si->pn[0].size, sc->sc_info.pn, sizeof (sc->sc_info.pn)); else memset(sc->sc_info.pn, 0, sizeof (sc->sc_info.pn)); if (sc->sc_info.sim_state == MBIM_SIMSTATE_LOCKED) sc->sc_info.pin_state = UMB_PUK_REQUIRED; if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: SIM %s\n", DEVNAM(sc), umb_simstate(sc->sc_info.sim_state)); if (sc->sc_info.sim_state == MBIM_SIMSTATE_INITIALIZED) umb_newstate(sc, UMB_S_SIMREADY, UMB_NS_DONT_DROP); return 1; } int umb_decode_radio_state(struct umb_softc *sc, void *data, int len) { struct mbim_cid_radio_state_info *rs = data; struct ifnet *ifp = GET_IFP(sc); if (len < sizeof (*rs)) return 0; sc->sc_info.hw_radio_on = (letoh32(rs->hw_state) == MBIM_RADIO_STATE_ON) ? 1 : 0; sc->sc_info.sw_radio_on = (letoh32(rs->sw_state) == MBIM_RADIO_STATE_ON) ? 1 : 0; if (!sc->sc_info.hw_radio_on) { printf("%s: radio is disabled by hardware switch\n", DEVNAM(sc)); /* * XXX do we need a time to poll the state of the rfkill switch * or will the device send an unsolicited notification * in case the state changes? */ umb_newstate(sc, UMB_S_OPEN, 0); } else if (!sc->sc_info.sw_radio_on) { if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: radio is off\n", DEVNAM(sc)); umb_newstate(sc, UMB_S_OPEN, 0); } else umb_newstate(sc, UMB_S_RADIO, UMB_NS_DONT_DROP); return 1; } int umb_decode_pin(struct umb_softc *sc, void *data, int len) { struct mbim_cid_pin_info *pi = data; struct ifnet *ifp = GET_IFP(sc); uint32_t attempts_left; if (len < sizeof (*pi)) return 0; attempts_left = letoh32(pi->remaining_attempts); if (attempts_left != 0xffffffff) sc->sc_info.pin_attempts_left = attempts_left; switch (letoh32(pi->state)) { case MBIM_PIN_STATE_UNLOCKED: sc->sc_info.pin_state = UMB_PIN_UNLOCKED; break; case MBIM_PIN_STATE_LOCKED: switch (letoh32(pi->type)) { case MBIM_PIN_TYPE_PIN1: sc->sc_info.pin_state = UMB_PIN_REQUIRED; break; case MBIM_PIN_TYPE_PUK1: sc->sc_info.pin_state = UMB_PUK_REQUIRED; break; case MBIM_PIN_TYPE_PIN2: case MBIM_PIN_TYPE_PUK2: /* Assume that PIN1 was accepted */ sc->sc_info.pin_state = UMB_PIN_UNLOCKED; break; } break; } if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: %s state %s (%d attempts left)\n", DEVNAM(sc), umb_pin_type(letoh32(pi->type)), (letoh32(pi->state) == MBIM_PIN_STATE_UNLOCKED) ? "unlocked" : "locked", letoh32(pi->remaining_attempts)); /* * In case the PIN was set after IFF_UP, retrigger the state machine */ usb_add_task(sc->sc_udev, &sc->sc_umb_task); return 1; } int umb_decode_packet_service(struct umb_softc *sc, void *data, int len) { struct mbim_cid_packet_service_info *psi = data; int state, highestclass; uint64_t up_speed, down_speed; struct ifnet *ifp = GET_IFP(sc); if (len < sizeof (*psi)) return 0; sc->sc_info.nwerror = letoh32(psi->nwerror); state = letoh32(psi->state); highestclass = letoh32(psi->highest_dataclass); up_speed = letoh64(psi->uplink_speed); down_speed = letoh64(psi->downlink_speed); if (sc->sc_info.packetstate != state || sc->sc_info.uplink_speed != up_speed || sc->sc_info.downlink_speed != down_speed) { if (ifp->if_flags & IFF_DEBUG) { log(LOG_INFO, "%s: packet service ", DEVNAM(sc)); if (sc->sc_info.packetstate != state) addlog("changed from %s to ", umb_packet_state(sc->sc_info.packetstate)); addlog("%s, class %s, speed: %llu up / %llu down\n", umb_packet_state(state), umb_dataclass(highestclass), up_speed, down_speed); } } sc->sc_info.packetstate = state; sc->sc_info.highestclass = highestclass; sc->sc_info.uplink_speed = up_speed; sc->sc_info.downlink_speed = down_speed; if (sc->sc_info.regmode == MBIM_REGMODE_AUTOMATIC) { /* * For devices using automatic registration mode, just proceed, * once registration has completed. */ if (ifp->if_flags & IFF_UP) { switch (sc->sc_info.regstate) { case MBIM_REGSTATE_HOME: case MBIM_REGSTATE_ROAMING: case MBIM_REGSTATE_PARTNER: umb_newstate(sc, UMB_S_ATTACHED, UMB_NS_DONT_DROP); break; default: break; } } else umb_newstate(sc, UMB_S_SIMREADY, UMB_NS_DONT_RAISE); } else switch (sc->sc_info.packetstate) { case MBIM_PKTSERVICE_STATE_ATTACHED: umb_newstate(sc, UMB_S_ATTACHED, UMB_NS_DONT_DROP); break; case MBIM_PKTSERVICE_STATE_DETACHED: umb_newstate(sc, UMB_S_SIMREADY, UMB_NS_DONT_RAISE); break; } return 1; } int umb_decode_signal_state(struct umb_softc *sc, void *data, int len) { struct mbim_cid_signal_state *ss = data; struct ifnet *ifp = GET_IFP(sc); int rssi; if (len < sizeof (*ss)) return 0; if (letoh32(ss->rssi) == 99) rssi = UMB_VALUE_UNKNOWN; else { rssi = -113 + 2 * letoh32(ss->rssi); if ((ifp->if_flags & IFF_DEBUG) && sc->sc_info.rssi != rssi && sc->sc_state >= UMB_S_CONNECTED) log(LOG_INFO, "%s: rssi %d dBm\n", DEVNAM(sc), rssi); } sc->sc_info.rssi = rssi; sc->sc_info.ber = letoh32(ss->err_rate); if (sc->sc_info.ber == -99) sc->sc_info.ber = UMB_VALUE_UNKNOWN; return 1; } int umb_decode_connect_info(struct umb_softc *sc, void *data, int len) { struct mbim_cid_connect_info *ci = data; struct ifnet *ifp = GET_IFP(sc); int act; if (len < sizeof (*ci)) return 0; if (letoh32(ci->sessionid) != umb_session_id) { DPRINTF("%s: discard connection info for session %u\n", DEVNAM(sc), letoh32(ci->sessionid)); return 1; } if (memcmp(ci->context, umb_uuid_context_internet, sizeof (ci->context))) { DPRINTF("%s: discard connection info for other context\n", DEVNAM(sc)); return 1; } act = letoh32(ci->activation); if (sc->sc_info.activation != act) { if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: connection %s\n", DEVNAM(sc), umb_activation(act)); sc->sc_info.activation = act; sc->sc_info.nwerror = letoh32(ci->nwerror); if (sc->sc_info.activation == MBIM_ACTIVATION_STATE_ACTIVATED) umb_newstate(sc, UMB_S_CONNECTED, UMB_NS_DONT_DROP); else if (sc->sc_info.activation == MBIM_ACTIVATION_STATE_DEACTIVATED) umb_newstate(sc, UMB_S_ATTACHED, 0); /* else: other states are purely transitional */ } return 1; } void umb_clear_addr(struct umb_softc *sc) { struct ifnet *ifp = GET_IFP(sc); memset(sc->sc_info.ipv4dns, 0, sizeof (sc->sc_info.ipv4dns)); memset(sc->sc_info.ipv6dns, 0, sizeof (sc->sc_info.ipv6dns)); umb_send_inet_proposal(sc, AF_INET); #ifdef INET6 umb_send_inet_proposal(sc, AF_INET6); #endif NET_LOCK(); in_ifdetach(ifp); #ifdef INET6 in6_ifdetach(ifp); #endif NET_UNLOCK(); } int umb_add_inet_config(struct umb_softc *sc, struct in_addr ip, u_int prefixlen, struct in_addr gw) { struct ifnet *ifp = GET_IFP(sc); struct in_aliasreq ifra; struct sockaddr_in *sin, default_sin; struct rt_addrinfo info; struct rtentry *rt; int rv; memset(&ifra, 0, sizeof (ifra)); sin = &ifra.ifra_addr; sin->sin_family = AF_INET; sin->sin_len = sizeof (*sin); sin->sin_addr = ip; sin = &ifra.ifra_dstaddr; sin->sin_family = AF_INET; sin->sin_len = sizeof (*sin); sin->sin_addr = gw; sin = &ifra.ifra_mask; sin->sin_family = AF_INET; sin->sin_len = sizeof (*sin); in_len2mask(&sin->sin_addr, prefixlen); rv = in_ioctl(SIOCAIFADDR, (caddr_t)&ifra, ifp, 1); if (rv != 0) { printf("%s: unable to set IPv4 address, error %d\n", DEVNAM(ifp->if_softc), rv); return rv; } memset(&default_sin, 0, sizeof(default_sin)); default_sin.sin_family = AF_INET; default_sin.sin_len = sizeof (default_sin); memset(&info, 0, sizeof(info)); info.rti_flags = RTF_GATEWAY /* maybe | RTF_STATIC */; info.rti_ifa = ifa_ifwithaddr(sintosa(&ifra.ifra_addr), ifp->if_rdomain); info.rti_info[RTAX_DST] = sintosa(&default_sin); info.rti_info[RTAX_NETMASK] = sintosa(&default_sin); info.rti_info[RTAX_GATEWAY] = sintosa(&ifra.ifra_dstaddr); NET_LOCK(); rv = rtrequest(RTM_ADD, &info, 0, &rt, ifp->if_rdomain); NET_UNLOCK(); if (rv) { printf("%s: unable to set IPv4 default route, " "error %d\n", DEVNAM(ifp->if_softc), rv); rtm_miss(RTM_MISS, &info, 0, RTP_NONE, 0, rv, ifp->if_rdomain); } else { /* Inform listeners of the new route */ rtm_send(rt, RTM_ADD, rv, ifp->if_rdomain); rtfree(rt); } if (ifp->if_flags & IFF_DEBUG) { char str[3][INET_ADDRSTRLEN]; log(LOG_INFO, "%s: IPv4 addr %s, mask %s, gateway %s\n", DEVNAM(ifp->if_softc), sockaddr_ntop(sintosa(&ifra.ifra_addr), str[0], sizeof(str[0])), sockaddr_ntop(sintosa(&ifra.ifra_mask), str[1], sizeof(str[1])), sockaddr_ntop(sintosa(&ifra.ifra_dstaddr), str[2], sizeof(str[2]))); } return 0; } #ifdef INET6 int umb_add_inet6_config(struct umb_softc *sc, struct in6_addr *ip, u_int prefixlen, struct in6_addr *gw) { struct ifnet *ifp = GET_IFP(sc); struct in6_aliasreq ifra; struct sockaddr_in6 *sin6, default_sin6; struct rt_addrinfo info; struct rtentry *rt; int rv; memset(&ifra, 0, sizeof (ifra)); sin6 = &ifra.ifra_addr; sin6->sin6_family = AF_INET6; sin6->sin6_len = sizeof (*sin6); memcpy(&sin6->sin6_addr, ip, sizeof (sin6->sin6_addr)); sin6 = &ifra.ifra_dstaddr; sin6->sin6_family = AF_INET6; sin6->sin6_len = sizeof (*sin6); memcpy(&sin6->sin6_addr, gw, sizeof (sin6->sin6_addr)); /* XXX: in6_update_ifa() accepts only 128 bits for P2P interfaces. */ prefixlen = 128; sin6 = &ifra.ifra_prefixmask; sin6->sin6_family = AF_INET6; sin6->sin6_len = sizeof (*sin6); in6_prefixlen2mask(&sin6->sin6_addr, prefixlen); ifra.ifra_lifetime.ia6t_vltime = ND6_INFINITE_LIFETIME; ifra.ifra_lifetime.ia6t_pltime = ND6_INFINITE_LIFETIME; rv = in6_ioctl(SIOCAIFADDR_IN6, (caddr_t)&ifra, ifp, 1); if (rv != 0) { printf("%s: unable to set IPv6 address, error %d\n", DEVNAM(ifp->if_softc), rv); return rv; } memset(&default_sin6, 0, sizeof(default_sin6)); default_sin6.sin6_family = AF_INET6; default_sin6.sin6_len = sizeof (default_sin6); memset(&info, 0, sizeof(info)); info.rti_flags = RTF_GATEWAY /* maybe | RTF_STATIC */; info.rti_ifa = ifa_ifwithaddr(sin6tosa(&ifra.ifra_addr), ifp->if_rdomain); info.rti_info[RTAX_DST] = sin6tosa(&default_sin6); info.rti_info[RTAX_NETMASK] = sin6tosa(&default_sin6); info.rti_info[RTAX_GATEWAY] = sin6tosa(&ifra.ifra_dstaddr); NET_LOCK(); rv = rtrequest(RTM_ADD, &info, 0, &rt, ifp->if_rdomain); NET_UNLOCK(); if (rv) { printf("%s: unable to set IPv6 default route, " "error %d\n", DEVNAM(ifp->if_softc), rv); rtm_miss(RTM_MISS, &info, 0, RTP_NONE, 0, rv, ifp->if_rdomain); } else { /* Inform listeners of the new route */ rtm_send(rt, RTM_ADD, rv, ifp->if_rdomain); rtfree(rt); } if (ifp->if_flags & IFF_DEBUG) { char str[3][INET6_ADDRSTRLEN]; log(LOG_INFO, "%s: IPv6 addr %s, mask %s, gateway %s\n", DEVNAM(ifp->if_softc), sockaddr_ntop(sin6tosa(&ifra.ifra_addr), str[0], sizeof(str[0])), sockaddr_ntop(sin6tosa(&ifra.ifra_prefixmask), str[1], sizeof(str[1])), sockaddr_ntop(sin6tosa(&ifra.ifra_dstaddr), str[2], sizeof(str[2]))); } return 0; } #endif void umb_send_inet_proposal(struct umb_softc *sc, int af) { struct ifnet *ifp = GET_IFP(sc); struct sockaddr_rtdns rtdns; struct rt_addrinfo info; int i, flag = 0; size_t sz = 0; memset(&rtdns, 0, sizeof(rtdns)); memset(&info, 0, sizeof(info)); for (i = 0; i < UMB_MAX_DNSSRV; i++) { if (af == AF_INET) { sz = sizeof (sc->sc_info.ipv4dns[i]); if (sc->sc_info.ipv4dns[i].s_addr == INADDR_ANY) break; memcpy(rtdns.sr_dns + i * sz, &sc->sc_info.ipv4dns[i], sz); flag = RTF_UP; #ifdef INET6 } else if (af == AF_INET6) { sz = sizeof (sc->sc_info.ipv6dns[i]); if (IN6_ARE_ADDR_EQUAL(&sc->sc_info.ipv6dns[i], &in6addr_any)) break; memcpy(rtdns.sr_dns + i * sz, &sc->sc_info.ipv6dns[i], sz); flag = RTF_UP; #endif } } rtdns.sr_family = af; rtdns.sr_len = 2 + i * sz; info.rti_info[RTAX_DNS] = srtdnstosa(&rtdns); rtm_proposal(ifp, &info, flag, RTP_PROPOSAL_UMB); } int umb_decode_ip_configuration(struct umb_softc *sc, void *data, int len) { struct mbim_cid_ip_configuration_info *ic = data; struct ifnet *ifp = GET_IFP(sc); int s; uint32_t avail_v4; uint32_t val; int n, i; int off; struct mbim_cid_ipv4_element ipv4elem; struct in_addr addr, gw; int state = -1; int rv; int hasmtu = 0; #ifdef INET6 uint32_t avail_v6; struct mbim_cid_ipv6_element ipv6elem; struct in6_addr addr6, gw6; #endif if (len < sizeof (*ic)) return 0; if (letoh32(ic->sessionid) != umb_session_id) { DPRINTF("%s: ignore IP configration for session id %d\n", DEVNAM(sc), letoh32(ic->sessionid)); return 0; } s = splnet(); memset(sc->sc_info.ipv4dns, 0, sizeof (sc->sc_info.ipv4dns)); memset(sc->sc_info.ipv6dns, 0, sizeof (sc->sc_info.ipv6dns)); /* * IPv4 configuation */ avail_v4 = letoh32(ic->ipv4_available); if ((avail_v4 & (MBIM_IPCONF_HAS_ADDRINFO | MBIM_IPCONF_HAS_GWINFO)) == (MBIM_IPCONF_HAS_ADDRINFO | MBIM_IPCONF_HAS_GWINFO)) { n = letoh32(ic->ipv4_naddr); off = letoh32(ic->ipv4_addroffs); if (n == 0 || off + sizeof (ipv4elem) > len) goto tryv6; if (n != 1 && ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: more than one IPv4 addr: %d\n", DEVNAM(ifp->if_softc), n); /* Only pick the first one */ memcpy(&ipv4elem, data + off, sizeof (ipv4elem)); ipv4elem.prefixlen = letoh32(ipv4elem.prefixlen); addr.s_addr = ipv4elem.addr; off = letoh32(ic->ipv4_gwoffs); if (off + sizeof (gw) > len) goto done; memcpy(&gw, data + off, sizeof(gw)); rv = umb_add_inet_config(sc, addr, ipv4elem.prefixlen, gw); if (rv == 0) state = UMB_S_UP; } memset(sc->sc_info.ipv4dns, 0, sizeof (sc->sc_info.ipv4dns)); if (avail_v4 & MBIM_IPCONF_HAS_DNSINFO) { n = letoh32(ic->ipv4_ndnssrv); off = letoh32(ic->ipv4_dnssrvoffs); i = 0; while (n-- > 0) { if (off + sizeof (addr) > len) break; memcpy(&addr, data + off, sizeof(addr)); if (i < UMB_MAX_DNSSRV) sc->sc_info.ipv4dns[i++] = addr; off += sizeof(addr); if (ifp->if_flags & IFF_DEBUG) { char str[INET_ADDRSTRLEN]; log(LOG_INFO, "%s: IPv4 nameserver %s\n", DEVNAM(ifp->if_softc), inet_ntop(AF_INET, &addr, str, sizeof(str))); } } umb_send_inet_proposal(sc, AF_INET); } if ((avail_v4 & MBIM_IPCONF_HAS_MTUINFO)) { val = letoh32(ic->ipv4_mtu); if (ifp->if_hardmtu != val && val <= sc->sc_maxpktlen) { hasmtu = 1; ifp->if_hardmtu = val; if (ifp->if_mtu > val) ifp->if_mtu = val; } } tryv6:; #ifdef INET6 /* * IPv6 configuation */ avail_v6 = letoh32(ic->ipv6_available); if (avail_v6 == 0) { if (ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: ISP or WWAN module offers no IPv6 " "support\n", DEVNAM(ifp->if_softc)); goto done; } if ((avail_v6 & (MBIM_IPCONF_HAS_ADDRINFO | MBIM_IPCONF_HAS_GWINFO)) == (MBIM_IPCONF_HAS_ADDRINFO | MBIM_IPCONF_HAS_GWINFO)) { n = letoh32(ic->ipv6_naddr); off = letoh32(ic->ipv6_addroffs); if (n == 0 || off + sizeof (ipv6elem) > len) goto done; if (n != 1 && ifp->if_flags & IFF_DEBUG) log(LOG_INFO, "%s: more than one IPv6 addr: %d\n", DEVNAM(ifp->if_softc), n); /* Only pick the first one */ memcpy(&ipv6elem, data + off, sizeof (ipv6elem)); memcpy(&addr6, ipv6elem.addr, sizeof (addr6)); off = letoh32(ic->ipv6_gwoffs); if (off + sizeof (gw6) > len) goto done; memcpy(&gw6, data + off, sizeof (gw6)); rv = umb_add_inet6_config(sc, &addr6, ipv6elem.prefixlen, &gw6); if (rv == 0) state = UMB_S_UP; } if (avail_v6 & MBIM_IPCONF_HAS_DNSINFO) { n = letoh32(ic->ipv6_ndnssrv); off = letoh32(ic->ipv6_dnssrvoffs); i = 0; while (n-- > 0) { if (off + sizeof (addr6) > len) break; memcpy(&addr6, data + off, sizeof(addr6)); if (i < UMB_MAX_DNSSRV) sc->sc_info.ipv6dns[i++] = addr6; off += sizeof(addr6); if (ifp->if_flags & IFF_DEBUG) { char str[INET6_ADDRSTRLEN]; log(LOG_INFO, "%s: IPv6 nameserver %s\n", DEVNAM(ifp->if_softc), inet_ntop(AF_INET6, &addr6, str, sizeof(str))); } } umb_send_inet_proposal(sc, AF_INET6); } if ((avail_v6 & MBIM_IPCONF_HAS_MTUINFO)) { val = letoh32(ic->ipv6_mtu); if (ifp->if_hardmtu != val && val <= sc->sc_maxpktlen) { hasmtu = 1; ifp->if_hardmtu = val; if (ifp->if_mtu > val) ifp->if_mtu = val; } } #endif done: if (hasmtu && (ifp->if_flags & IFF_DEBUG)) log(LOG_INFO, "%s: MTU %d\n", DEVNAM(sc), ifp->if_hardmtu); if (state != -1) umb_newstate(sc, state, 0); splx(s); return 1; } void umb_rx(struct umb_softc *sc) { usbd_setup_xfer(sc->sc_rx_xfer, sc->sc_rx_pipe, sc, sc->sc_rx_buf, sc->sc_rx_bufsz, USBD_SHORT_XFER_OK | USBD_NO_COPY, USBD_NO_TIMEOUT, umb_rxeof); usbd_transfer(sc->sc_rx_xfer); } void umb_rxeof(struct usbd_xfer *xfer, void *priv, usbd_status status) { struct umb_softc *sc = priv; struct ifnet *ifp = GET_IFP(sc); if (usbd_is_dying(sc->sc_udev) || !(ifp->if_flags & IFF_RUNNING)) return; if (status != USBD_NORMAL_COMPLETION) { if (status == USBD_NOT_STARTED || status == USBD_CANCELLED) return; DPRINTF("%s: rx error: %s\n", DEVNAM(sc), usbd_errstr(status)); if (status == USBD_STALLED) usbd_clear_endpoint_stall_async(sc->sc_rx_pipe); if (++sc->sc_rx_nerr > 100) { log(LOG_ERR, "%s: too many rx errors, disabling\n", DEVNAM(sc)); usbd_deactivate(sc->sc_udev); } } else { sc->sc_rx_nerr = 0; umb_decap(sc, xfer); } umb_rx(sc); return; } int umb_encap(struct umb_softc *sc) { struct ncm_header16 *hdr; struct ncm_pointer16 *ptr; struct ncm_pointer16_dgram *dgram; int offs, poffs; struct mbuf_list tmpml = MBUF_LIST_INITIALIZER(); struct mbuf *m; usbd_status err; /* All size constraints have been validated by the caller! */ hdr = sc->sc_tx_buf; USETDW(hdr->dwSignature, NCM_HDR16_SIG); USETW(hdr->wHeaderLength, sizeof (*hdr)); USETW(hdr->wBlockLength, 0); USETW(hdr->wSequence, sc->sc_tx_seq); sc->sc_tx_seq++; offs = sizeof (*hdr); offs += umb_padding(sc->sc_tx_buf, sc->sc_tx_bufsz, offs, sc->sc_align, 0); USETW(hdr->wNdpIndex, offs); poffs = offs; ptr = (struct ncm_pointer16 *)(sc->sc_tx_buf + offs); USETDW(ptr->dwSignature, MBIM_NCM_NTH16_SIG(umb_session_id)); USETW(ptr->wNextNdpIndex, 0); dgram = &ptr->dgram[0]; offs = (caddr_t)dgram - (caddr_t)sc->sc_tx_buf; /* Leave space for dgram pointers */ while ((m = ml_dequeue(&sc->sc_tx_ml)) != NULL) { offs += sizeof (*dgram); ml_enqueue(&tmpml, m); } offs += sizeof (*dgram); /* one more to terminate pointer list */ USETW(ptr->wLength, offs - poffs); /* Encap mbufs */ while ((m = ml_dequeue(&tmpml)) != NULL) { offs += umb_padding(sc->sc_tx_buf, sc->sc_tx_bufsz, offs, sc->sc_ndp_div, sc->sc_ndp_remainder); USETW(dgram->wDatagramIndex, offs); USETW(dgram->wDatagramLen, m->m_pkthdr.len); dgram++; m_copydata(m, 0, m->m_pkthdr.len, sc->sc_tx_buf + offs); offs += m->m_pkthdr.len; ml_enqueue(&sc->sc_tx_ml, m); } /* Terminating pointer */ USETW(dgram->wDatagramIndex, 0); USETW(dgram->wDatagramLen, 0); USETW(hdr->wBlockLength, offs); DPRINTFN(3, "%s: encap %d bytes\n", DEVNAM(sc), offs); DDUMPN(5, sc->sc_tx_buf, offs); KASSERT(offs <= sc->sc_tx_bufsz); usbd_setup_xfer(sc->sc_tx_xfer, sc->sc_tx_pipe, sc, sc->sc_tx_buf, offs, USBD_FORCE_SHORT_XFER | USBD_NO_COPY, umb_xfer_tout, umb_txeof); err = usbd_transfer(sc->sc_tx_xfer); if (err != USBD_IN_PROGRESS) { DPRINTF("%s: start tx error: %s\n", DEVNAM(sc), usbd_errstr(err)); ml_purge(&sc->sc_tx_ml); return 0; } return 1; } void umb_txeof(struct usbd_xfer *xfer, void *priv, usbd_status status) { struct umb_softc *sc = priv; struct ifnet *ifp = GET_IFP(sc); int s; s = splnet(); ml_purge(&sc->sc_tx_ml); ifq_clr_oactive(&ifp->if_snd); ifp->if_timer = 0; if (status != USBD_NORMAL_COMPLETION) { if (status != USBD_NOT_STARTED && status != USBD_CANCELLED) { ifp->if_oerrors++; DPRINTF("%s: tx error: %s\n", DEVNAM(sc), usbd_errstr(status)); if (status == USBD_STALLED) usbd_clear_endpoint_stall_async(sc->sc_tx_pipe); } } if (ifq_empty(&ifp->if_snd) == 0) umb_start(ifp); splx(s); } void umb_decap(struct umb_softc *sc, struct usbd_xfer *xfer) { struct ifnet *ifp = GET_IFP(sc); int s; void *buf; uint32_t len, af = 0; char *dp; struct ncm_header16 *hdr16; struct ncm_header32 *hdr32; struct ncm_pointer16 *ptr16; struct ncm_pointer16_dgram *dgram16; struct ncm_pointer32_dgram *dgram32; uint32_t hsig, psig; int hlen, blen; int ptrlen, ptroff, dgentryoff; uint32_t doff, dlen; struct mbuf_list ml = MBUF_LIST_INITIALIZER(); struct mbuf *m; usbd_get_xfer_status(xfer, NULL, &buf, &len, NULL); DPRINTFN(4, "%s: recv %d bytes\n", DEVNAM(sc), len); DDUMPN(5, buf, len); s = splnet(); if (len < sizeof (*hdr16)) goto toosmall; hdr16 = (struct ncm_header16 *)buf; hsig = UGETDW(hdr16->dwSignature); hlen = UGETW(hdr16->wHeaderLength); if (len < hlen) goto toosmall; switch (hsig) { case NCM_HDR16_SIG: blen = UGETW(hdr16->wBlockLength); ptroff = UGETW(hdr16->wNdpIndex); if (hlen != sizeof (*hdr16)) { DPRINTF("%s: bad header len %d for NTH16 (exp %zu)\n", DEVNAM(sc), hlen, sizeof (*hdr16)); goto fail; } break; case NCM_HDR32_SIG: hdr32 = (struct ncm_header32 *)hdr16; blen = UGETDW(hdr32->dwBlockLength); ptroff = UGETDW(hdr32->dwNdpIndex); if (hlen != sizeof (*hdr32)) { DPRINTF("%s: bad header len %d for NTH32 (exp %zu)\n", DEVNAM(sc), hlen, sizeof (*hdr32)); goto fail; } break; default: DPRINTF("%s: unsupported NCM header signature (0x%08x)\n", DEVNAM(sc), hsig); goto fail; } if (blen != 0 && len < blen) { DPRINTF("%s: bad NTB len (%d) for %d bytes of data\n", DEVNAM(sc), blen, len); goto fail; } ptr16 = (struct ncm_pointer16 *)(buf + ptroff); psig = UGETDW(ptr16->dwSignature); ptrlen = UGETW(ptr16->wLength); if (len < ptrlen + ptroff) goto toosmall; if (!MBIM_NCM_NTH16_ISISG(psig) && !MBIM_NCM_NTH32_ISISG(psig)) { DPRINTF("%s: unsupported NCM pointer signature (0x%08x)\n", DEVNAM(sc), psig); goto fail; } switch (hsig) { case NCM_HDR16_SIG: dgentryoff = offsetof(struct ncm_pointer16, dgram); break; case NCM_HDR32_SIG: dgentryoff = offsetof(struct ncm_pointer32, dgram); break; default: goto fail; } while (dgentryoff < ptrlen) { switch (hsig) { case NCM_HDR16_SIG: if (ptroff + dgentryoff < sizeof (*dgram16)) goto done; dgram16 = (struct ncm_pointer16_dgram *) (buf + ptroff + dgentryoff); dgentryoff += sizeof (*dgram16); dlen = UGETW(dgram16->wDatagramLen); doff = UGETW(dgram16->wDatagramIndex); break; case NCM_HDR32_SIG: if (ptroff + dgentryoff < sizeof (*dgram32)) goto done; dgram32 = (struct ncm_pointer32_dgram *) (buf + ptroff + dgentryoff); dgentryoff += sizeof (*dgram32); dlen = UGETDW(dgram32->dwDatagramLen); doff = UGETDW(dgram32->dwDatagramIndex); break; default: ifp->if_ierrors++; goto done; } /* Terminating zero entry */ if (dlen == 0 || doff == 0) break; if (len < dlen + doff) { /* Skip giant datagram but continue processing */ DPRINTF("%s: datagram too large (%d @ off %d)\n", DEVNAM(sc), dlen, doff); continue; } dp = buf + doff; DPRINTFN(3, "%s: decap %d bytes\n", DEVNAM(sc), dlen); m = m_devget(dp, dlen, sizeof(uint32_t)); if (m == NULL) { ifp->if_iqdrops++; continue; } m = m_prepend(m, sizeof(uint32_t), M_DONTWAIT); if (m == NULL) { ifp->if_iqdrops++; continue; } switch (*dp & 0xf0) { case 4 << 4: af = htonl(AF_INET); break; case 6 << 4: af = htonl(AF_INET6); break; } *mtod(m, uint32_t *) = af; ml_enqueue(&ml, m); } done: if_input(ifp, &ml); splx(s); return; toosmall: DPRINTF("%s: packet too small (%d)\n", DEVNAM(sc), len); fail: ifp->if_ierrors++; splx(s); } usbd_status umb_send_encap_command(struct umb_softc *sc, void *data, int len) { struct usbd_xfer *xfer; usb_device_request_t req; char *buf; if (len > sc->sc_ctrl_len) return USBD_INVAL; if ((xfer = usbd_alloc_xfer(sc->sc_udev)) == NULL) return USBD_NOMEM; if ((buf = usbd_alloc_buffer(xfer, len)) == NULL) { usbd_free_xfer(xfer); return USBD_NOMEM; } memcpy(buf, data, len); /* XXX FIXME: if (total len > sc->sc_ctrl_len) => must fragment */ req.bmRequestType = UT_WRITE_CLASS_INTERFACE; req.bRequest = UCDC_SEND_ENCAPSULATED_COMMAND; USETW(req.wValue, 0); USETW(req.wIndex, sc->sc_ctrl_ifaceno); USETW(req.wLength, len); DELAY(umb_delay); return usbd_request_async(xfer, &req, NULL, NULL); } int umb_get_encap_response(struct umb_softc *sc, void *buf, int *len) { usb_device_request_t req; usbd_status err; req.bmRequestType = UT_READ_CLASS_INTERFACE; req.bRequest = UCDC_GET_ENCAPSULATED_RESPONSE; USETW(req.wValue, 0); USETW(req.wIndex, sc->sc_ctrl_ifaceno); USETW(req.wLength, *len); /* XXX FIXME: re-assemble fragments */ DELAY(umb_delay); err = usbd_do_request_flags(sc->sc_udev, &req, buf, USBD_SHORT_XFER_OK, len, umb_xfer_tout); if (err == USBD_NORMAL_COMPLETION) return 1; DPRINTF("%s: ctrl recv: %s\n", DEVNAM(sc), usbd_errstr(err)); return 0; } void umb_ctrl_msg(struct umb_softc *sc, uint32_t req, void *data, int len) { struct ifnet *ifp = GET_IFP(sc); uint32_t tid; struct mbim_msghdr *hdr = data; usbd_status err; int s; assertwaitok(); if (usbd_is_dying(sc->sc_udev)) return; if (len < sizeof (*hdr)) return; tid = ++sc->sc_tid; hdr->type = htole32(req); hdr->len = htole32(len); hdr->tid = htole32(tid); #ifdef UMB_DEBUG if (umb_debug) { const char *op, *str; if (req == MBIM_COMMAND_MSG) { struct mbim_h2f_cmd *c = data; if (letoh32(c->op) == MBIM_CMDOP_SET) op = "set"; else op = "qry"; str = umb_cid2str(letoh32(c->cid)); } else { op = "snd"; str = umb_request2str(req); } DPRINTF("%s: -> %s %s (tid %u)\n", DEVNAM(sc), op, str, tid); } #endif s = splusb(); err = umb_send_encap_command(sc, data, len); splx(s); if (err != USBD_NORMAL_COMPLETION) { if (ifp->if_flags & IFF_DEBUG) log(LOG_ERR, "%s: send %s msg (tid %u) failed: %s\n", DEVNAM(sc), umb_request2str(req), tid, usbd_errstr(err)); /* will affect other transactions, too */ usbd_abort_pipe(sc->sc_udev->default_pipe); } else { DPRINTFN(2, "%s: sent %s (tid %u)\n", DEVNAM(sc), umb_request2str(req), tid); DDUMPN(3, data, len); } return; } void umb_open(struct umb_softc *sc) { struct mbim_h2f_openmsg msg; memset(&msg, 0, sizeof (msg)); msg.maxlen = htole32(sc->sc_ctrl_len); umb_ctrl_msg(sc, MBIM_OPEN_MSG, &msg, sizeof (msg)); return; } void umb_close(struct umb_softc *sc) { struct mbim_h2f_closemsg msg; memset(&msg, 0, sizeof (msg)); umb_ctrl_msg(sc, MBIM_CLOSE_MSG, &msg, sizeof (msg)); } int umb_setpin(struct umb_softc *sc, int op, int is_puk, void *pin, int pinlen, void *newpin, int newpinlen) { struct mbim_cid_pin cp; int off; if (pinlen == 0) return 0; if (pinlen < 0 || pinlen > MBIM_PIN_MAXLEN || newpinlen < 0 || newpinlen > MBIM_PIN_MAXLEN || op < 0 || op > MBIM_PIN_OP_CHANGE || (is_puk && op != MBIM_PIN_OP_ENTER)) return EINVAL; memset(&cp, 0, sizeof (cp)); cp.type = htole32(is_puk ? MBIM_PIN_TYPE_PUK1 : MBIM_PIN_TYPE_PIN1); off = offsetof(struct mbim_cid_pin, data); if (!umb_addstr(&cp, sizeof (cp), &off, pin, pinlen, &cp.pin_offs, &cp.pin_size)) return EINVAL; cp.op = htole32(op); if (newpinlen) { if (!umb_addstr(&cp, sizeof (cp), &off, newpin, newpinlen, &cp.newpin_offs, &cp.newpin_size)) return EINVAL; } else { if ((op == MBIM_PIN_OP_CHANGE) || is_puk) return EINVAL; if (!umb_addstr(&cp, sizeof (cp), &off, NULL, 0, &cp.newpin_offs, &cp.newpin_size)) return EINVAL; } umb_cmd(sc, MBIM_CID_PIN, MBIM_CMDOP_SET, &cp, off); return 0; } void umb_setdataclass(struct umb_softc *sc) { struct mbim_cid_registration_state rs; uint32_t classes; if (sc->sc_info.supportedclasses == MBIM_DATACLASS_NONE) return; memset(&rs, 0, sizeof (rs)); rs.regaction = htole32(MBIM_REGACTION_AUTOMATIC); classes = sc->sc_info.supportedclasses; if (sc->sc_info.preferredclasses != MBIM_DATACLASS_NONE) classes &= sc->sc_info.preferredclasses; rs.data_class = htole32(classes); umb_cmd(sc, MBIM_CID_REGISTER_STATE, MBIM_CMDOP_SET, &rs, sizeof (rs)); } void umb_radio(struct umb_softc *sc, int on) { struct mbim_cid_radio_state s; DPRINTF("%s: set radio %s\n", DEVNAM(sc), on ? "on" : "off"); memset(&s, 0, sizeof (s)); s.state = htole32(on ? MBIM_RADIO_STATE_ON : MBIM_RADIO_STATE_OFF); umb_cmd(sc, MBIM_CID_RADIO_STATE, MBIM_CMDOP_SET, &s, sizeof (s)); } void umb_allocate_cid(struct umb_softc *sc) { umb_cmd1(sc, MBIM_CID_DEVICE_CAPS, MBIM_CMDOP_SET, umb_qmi_alloc_cid, sizeof (umb_qmi_alloc_cid), umb_uuid_qmi_mbim); } void umb_send_fcc_auth(struct umb_softc *sc) { uint8_t fccauth[sizeof (umb_qmi_fcc_auth)]; if (sc->sc_cid == -1) { DPRINTF("%s: missing CID, cannot send FCC auth\n", DEVNAM(sc)); umb_allocate_cid(sc); return; } memcpy(fccauth, umb_qmi_fcc_auth, sizeof (fccauth)); fccauth[UMB_QMI_CID_OFFS] = sc->sc_cid; umb_cmd1(sc, MBIM_CID_DEVICE_CAPS, MBIM_CMDOP_SET, fccauth, sizeof (fccauth), umb_uuid_qmi_mbim); } void umb_packet_service(struct umb_softc *sc, int attach) { struct mbim_cid_packet_service s; DPRINTF("%s: %s packet service\n", DEVNAM(sc), attach ? "attach" : "detach"); memset(&s, 0, sizeof (s)); s.action = htole32(attach ? MBIM_PKTSERVICE_ACTION_ATTACH : MBIM_PKTSERVICE_ACTION_DETACH); umb_cmd(sc, MBIM_CID_PACKET_SERVICE, MBIM_CMDOP_SET, &s, sizeof (s)); } void umb_connect(struct umb_softc *sc) { struct ifnet *ifp = GET_IFP(sc); if (sc->sc_info.regstate == MBIM_REGSTATE_ROAMING && !sc->sc_roaming) { log(LOG_INFO, "%s: connection disabled in roaming network\n", DEVNAM(sc)); return; } if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: connecting ...\n", DEVNAM(sc)); umb_send_connect(sc, MBIM_CONNECT_ACTIVATE); } void umb_disconnect(struct umb_softc *sc) { struct ifnet *ifp = GET_IFP(sc); if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: disconnecting ...\n", DEVNAM(sc)); umb_send_connect(sc, MBIM_CONNECT_DEACTIVATE); } void umb_send_connect(struct umb_softc *sc, int command) { struct mbim_cid_connect *c; int off; /* Too large or the stack */ c = malloc(sizeof (*c), M_USBDEV, M_WAIT|M_ZERO); c->sessionid = htole32(umb_session_id); c->command = htole32(command); off = offsetof(struct mbim_cid_connect, data); if (!umb_addstr(c, sizeof (*c), &off, sc->sc_info.apn, sc->sc_info.apnlen, &c->access_offs, &c->access_size)) goto done; /* XXX FIXME: support user name and passphrase */ c->user_offs = htole32(0); c->user_size = htole32(0); c->passwd_offs = htole32(0); c->passwd_size = htole32(0); c->authprot = htole32(MBIM_AUTHPROT_NONE); c->compression = htole32(MBIM_COMPRESSION_NONE); c->iptype = htole32(MBIM_CONTEXT_IPTYPE_IPV4); #ifdef INET6 /* XXX FIXME: support IPv6-only mode, too */ if ((sc->sc_flags & UMBFLG_NO_INET6) == 0 && in6ifa_ifpforlinklocal(GET_IFP(sc), 0) != NULL) c->iptype = htole32(MBIM_CONTEXT_IPTYPE_IPV4V6); #endif memcpy(c->context, umb_uuid_context_internet, sizeof (c->context)); umb_cmd(sc, MBIM_CID_CONNECT, MBIM_CMDOP_SET, c, off); done: free(c, M_USBDEV, sizeof (*c)); return; } void umb_qry_ipconfig(struct umb_softc *sc) { struct mbim_cid_ip_configuration_info ipc; memset(&ipc, 0, sizeof (ipc)); ipc.sessionid = htole32(umb_session_id); umb_cmd(sc, MBIM_CID_IP_CONFIGURATION, MBIM_CMDOP_QRY, &ipc, sizeof (ipc)); } void umb_cmd(struct umb_softc *sc, int cid, int op, void *data, int len) { umb_cmd1(sc, cid, op, data, len, umb_uuid_basic_connect); } void umb_cmd1(struct umb_softc *sc, int cid, int op, void *data, int len, uint8_t *uuid) { struct mbim_h2f_cmd *cmd; int totlen; /* XXX FIXME support sending fragments */ if (sizeof (*cmd) + len > sc->sc_ctrl_len) { DPRINTF("%s: set %s msg too long: cannot send\n", DEVNAM(sc), umb_cid2str(cid)); return; } cmd = sc->sc_ctrl_msg; memset(cmd, 0, sizeof (*cmd)); cmd->frag.nfrag = htole32(1); memcpy(cmd->devid, uuid, sizeof (cmd->devid)); cmd->cid = htole32(cid); cmd->op = htole32(op); cmd->infolen = htole32(len); totlen = sizeof (*cmd); if (len > 0) { memcpy(cmd + 1, data, len); totlen += len; } umb_ctrl_msg(sc, MBIM_COMMAND_MSG, cmd, totlen); } void umb_command_done(struct umb_softc *sc, void *data, int len) { struct mbim_f2h_cmddone *cmd = data; struct ifnet *ifp = GET_IFP(sc); uint32_t status; uint32_t cid; uint32_t infolen; int qmimsg = 0; if (len < sizeof (*cmd)) { DPRINTF("%s: discard short %s message\n", DEVNAM(sc), umb_request2str(letoh32(cmd->hdr.type))); return; } cid = letoh32(cmd->cid); if (memcmp(cmd->devid, umb_uuid_basic_connect, sizeof (cmd->devid))) { if (memcmp(cmd->devid, umb_uuid_qmi_mbim, sizeof (cmd->devid))) { DPRINTF("%s: discard %s message for other UUID '%s'\n", DEVNAM(sc), umb_request2str(letoh32(cmd->hdr.type)), umb_uuid2str(cmd->devid)); return; } else qmimsg = 1; } status = letoh32(cmd->status); switch (status) { case MBIM_STATUS_SUCCESS: break; #ifdef INET6 case MBIM_STATUS_NO_DEVICE_SUPPORT: if ((cid == MBIM_CID_CONNECT) && (sc->sc_flags & UMBFLG_NO_INET6) == 0) { sc->sc_flags |= UMBFLG_NO_INET6; if (ifp->if_flags & IFF_DEBUG) log(LOG_ERR, "%s: device does not support IPv6\n", DEVNAM(sc)); } /* Re-trigger the connect, this time IPv4 only */ usb_add_task(sc->sc_udev, &sc->sc_umb_task); return; #endif case MBIM_STATUS_NOT_INITIALIZED: if (ifp->if_flags & IFF_DEBUG) log(LOG_ERR, "%s: SIM not initialized (PIN missing)\n", DEVNAM(sc)); return; case MBIM_STATUS_PIN_REQUIRED: sc->sc_info.pin_state = UMB_PIN_REQUIRED; /*FALLTHROUGH*/ default: if (ifp->if_flags & IFF_DEBUG) log(LOG_ERR, "%s: set/qry %s failed: %s\n", DEVNAM(sc), umb_cid2str(cid), umb_status2str(status)); return; } infolen = letoh32(cmd->infolen); if (len < sizeof (*cmd) + infolen) { DPRINTF("%s: discard truncated %s message (want %d, got %d)\n", DEVNAM(sc), umb_cid2str(cid), (int)sizeof (*cmd) + infolen, len); return; } if (qmimsg) { if (sc->sc_flags & UMBFLG_FCC_AUTH_REQUIRED) umb_decode_qmi(sc, cmd->info, infolen); } else { DPRINTFN(2, "%s: set/qry %s done\n", DEVNAM(sc), umb_cid2str(cid)); umb_decode_cid(sc, cid, cmd->info, infolen); } } void umb_decode_cid(struct umb_softc *sc, uint32_t cid, void *data, int len) { int ok = 1; switch (cid) { case MBIM_CID_DEVICE_CAPS: ok = umb_decode_devices_caps(sc, data, len); break; case MBIM_CID_SUBSCRIBER_READY_STATUS: ok = umb_decode_subscriber_status(sc, data, len); break; case MBIM_CID_RADIO_STATE: ok = umb_decode_radio_state(sc, data, len); break; case MBIM_CID_PIN: ok = umb_decode_pin(sc, data, len); break; case MBIM_CID_REGISTER_STATE: ok = umb_decode_register_state(sc, data, len); break; case MBIM_CID_PACKET_SERVICE: ok = umb_decode_packet_service(sc, data, len); break; case MBIM_CID_SIGNAL_STATE: ok = umb_decode_signal_state(sc, data, len); break; case MBIM_CID_CONNECT: ok = umb_decode_connect_info(sc, data, len); break; case MBIM_CID_IP_CONFIGURATION: ok = umb_decode_ip_configuration(sc, data, len); break; default: /* * Note: the above list is incomplete and only contains * mandatory CIDs from the BASIC_CONNECT set. * So alternate values are not unusual. */ DPRINTFN(4, "%s: ignore %s\n", DEVNAM(sc), umb_cid2str(cid)); break; } if (!ok) DPRINTF("%s: discard %s with bad info length %d\n", DEVNAM(sc), umb_cid2str(cid), len); return; } void umb_decode_qmi(struct umb_softc *sc, uint8_t *data, int len) { uint8_t srv; uint16_t msg, tlvlen; uint32_t val; #define UMB_QMI_QMUXLEN 6 if (len < UMB_QMI_QMUXLEN) goto tooshort; srv = data[4]; data += UMB_QMI_QMUXLEN; len -= UMB_QMI_QMUXLEN; #define UMB_GET16(p) ((uint16_t)*p | (uint16_t)*(p + 1) << 8) #define UMB_GET32(p) ((uint32_t)*p | (uint32_t)*(p + 1) << 8 | \ (uint32_t)*(p + 2) << 16 |(uint32_t)*(p + 3) << 24) switch (srv) { case 0: /* ctl */ #define UMB_QMI_CTLLEN 6 if (len < UMB_QMI_CTLLEN) goto tooshort; msg = UMB_GET16(&data[2]); tlvlen = UMB_GET16(&data[4]); data += UMB_QMI_CTLLEN; len -= UMB_QMI_CTLLEN; break; case 2: /* dms */ #define UMB_QMI_DMSLEN 7 if (len < UMB_QMI_DMSLEN) goto tooshort; msg = UMB_GET16(&data[3]); tlvlen = UMB_GET16(&data[5]); data += UMB_QMI_DMSLEN; len -= UMB_QMI_DMSLEN; break; default: DPRINTF("%s: discard QMI message for unknown service type %d\n", DEVNAM(sc), srv); return; } if (len < tlvlen) goto tooshort; #define UMB_QMI_TLVLEN 3 while (len > 0) { if (len < UMB_QMI_TLVLEN) goto tooshort; tlvlen = UMB_GET16(&data[1]); if (len < UMB_QMI_TLVLEN + tlvlen) goto tooshort; switch (data[0]) { case 1: /* allocation info */ if (msg == 0x0022) { /* Allocate CID */ if (tlvlen != 2 || data[3] != 2) /* dms */ break; sc->sc_cid = data[4]; DPRINTF("%s: QMI CID %d allocated\n", DEVNAM(sc), sc->sc_cid); umb_newstate(sc, UMB_S_CID, UMB_NS_DONT_DROP); } break; case 2: /* response */ if (tlvlen != sizeof (val)) break; val = UMB_GET32(&data[3]); switch (msg) { case 0x0022: /* Allocate CID */ if (val != 0) { log(LOG_ERR, "%s: allocation of QMI CID" " failed, error 0x%x\n", DEVNAM(sc), val); /* XXX how to proceed? */ return; } break; case 0x555f: /* Send FCC Authentication */ if (val == 0) DPRINTF("%s: send FCC " "Authentication succeeded\n", DEVNAM(sc)); else if (val == 0x001a0001) DPRINTF("%s: FCC Authentication " "not required\n", DEVNAM(sc)); else log(LOG_INFO, "%s: send FCC " "Authentication failed, " "error 0x%x\n", DEVNAM(sc), val); /* FCC Auth is needed only once after power-on*/ sc->sc_flags &= ~UMBFLG_FCC_AUTH_REQUIRED; /* Try to proceed anyway */ DPRINTF("%s: init: turning radio on ...\n", DEVNAM(sc)); umb_radio(sc, 1); break; default: break; } break; default: break; } data += UMB_QMI_TLVLEN + tlvlen; len -= UMB_QMI_TLVLEN + tlvlen; } return; tooshort: DPRINTF("%s: discard short QMI message\n", DEVNAM(sc)); return; } void umb_intr(struct usbd_xfer *xfer, void *priv, usbd_status status) { struct umb_softc *sc = priv; struct ifnet *ifp = GET_IFP(sc); int total_len; if (status != USBD_NORMAL_COMPLETION) { DPRINTF("%s: notification error: %s\n", DEVNAM(sc), usbd_errstr(status)); if (status == USBD_STALLED) usbd_clear_endpoint_stall_async(sc->sc_ctrl_pipe); return; } usbd_get_xfer_status(xfer, NULL, NULL, &total_len, NULL); if (total_len < UCDC_NOTIFICATION_LENGTH) { DPRINTF("%s: short notification (%d<%d)\n", DEVNAM(sc), total_len, UCDC_NOTIFICATION_LENGTH); return; } if (sc->sc_intr_msg.bmRequestType != UCDC_NOTIFICATION) { DPRINTF("%s: unexpected notification (type=0x%02x)\n", DEVNAM(sc), sc->sc_intr_msg.bmRequestType); return; } switch (sc->sc_intr_msg.bNotification) { case UCDC_N_NETWORK_CONNECTION: if (ifp->if_flags & IFF_DEBUG) log(LOG_DEBUG, "%s: network %sconnected\n", DEVNAM(sc), UGETW(sc->sc_intr_msg.wValue) ? "" : "dis"); break; case UCDC_N_RESPONSE_AVAILABLE: DPRINTFN(2, "%s: umb_intr: response available\n", DEVNAM(sc)); ++sc->sc_nresp; usb_add_task(sc->sc_udev, &sc->sc_get_response_task); break; case UCDC_N_CONNECTION_SPEED_CHANGE: DPRINTFN(2, "%s: umb_intr: connection speed changed\n", DEVNAM(sc)); break; default: DPRINTF("%s: unexpected notifiation (0x%02x)\n", DEVNAM(sc), sc->sc_intr_msg.bNotification); break; } } /* * Diagnostic routines */ #ifdef UMB_DEBUG char * umb_uuid2str(uint8_t uuid[MBIM_UUID_LEN]) { static char uuidstr[2 * MBIM_UUID_LEN + 5]; #define UUID_BFMT "%02X" #define UUID_SEP "-" snprintf(uuidstr, sizeof (uuidstr), UUID_BFMT UUID_BFMT UUID_BFMT UUID_BFMT UUID_SEP UUID_BFMT UUID_BFMT UUID_SEP UUID_BFMT UUID_BFMT UUID_SEP UUID_BFMT UUID_BFMT UUID_SEP UUID_BFMT UUID_BFMT UUID_BFMT UUID_BFMT UUID_BFMT UUID_BFMT, uuid[0], uuid[1], uuid[2], uuid[3], uuid[4], uuid[5], uuid[6], uuid[7], uuid[8], uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14], uuid[15]); return uuidstr; } void umb_dump(void *buf, int len) { int i = 0; uint8_t *c = buf; if (len == 0) return; while (i < len) { if ((i % 16) == 0) { if (i > 0) addlog("\n"); log(LOG_DEBUG, "%4d: ", i); } addlog(" %02x", *c); c++; i++; } addlog("\n"); } #endif /* UMB_DEBUG */