/* packet-ulp.c * Routines for OMA UserPlane Location Protocol packet dissection * Copyright 2006, Anders Broman * * Wireshark - Network traffic analyzer * By Gerald Combs * Copyright 1998 Gerald Combs * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * * ref OMA-TS-ULP-V2_0_2-20140708-A * http://www.openmobilealliance.org */ #include "config.h" #include "math.h" #include #include #include #include "packet-per.h" #include "packet-tcp.h" #include "packet-gsm_map.h" #include "packet-e164.h" #include "packet-e212.h" #define PNAME "OMA UserPlane Location Protocol" #define PSNAME "ULP" #define PFNAME "ulp" void proto_register_ulp(void); static dissector_handle_t rrlp_handle; static dissector_handle_t lpp_handle; /* IANA Registered Ports * oma-ulp 7275/tcp OMA UserPlane Location * oma-ulp 7275/udp OMA UserPlane Location */ static guint gbl_ulp_tcp_port = 7275; static guint gbl_ulp_udp_port = 7275; /* Initialize the protocol and registered fields */ static int proto_ulp = -1; #define ULP_HEADER_SIZE 2 static gboolean ulp_desegment = TRUE; #include "packet-ulp-hf.c" static int hf_ulp_mobile_directory_number = -1; static int hf_ulp_ganssTimeModels_bit0 = -1; static int hf_ulp_ganssTimeModels_bit1 = -1; static int hf_ulp_ganssTimeModels_bit2 = -1; static int hf_ulp_ganssTimeModels_bit3 = -1; static int hf_ulp_ganssTimeModels_bit4 = -1; static int hf_ulp_ganssTimeModels_spare = -1; /* Initialize the subtree pointers */ static gint ett_ulp = -1; static gint ett_ulp_setid = -1; static gint ett_ulp_thirdPartyId = -1; static gint ett_ulp_ganssTimeModels = -1; #include "packet-ulp-ett.c" static const value_string ulp_ganss_id_vals[] = { { 0, "Galileo"}, { 1, "SBAS"}, { 2, "Modernized GPS"}, { 3, "QZSS"}, { 4, "GLONASS"}, { 5, "BDS"}, { 0, NULL}, }; static const value_string ulp_ganss_sbas_id_vals[] = { { 0, "WAAS"}, { 1, "EGNOS"}, { 2, "MSAS"}, { 3, "GAGAN"}, { 0, NULL}, }; static void ulp_ganssDataBitInterval_fmt(gchar *s, guint32 v) { if (v == 15) { g_snprintf(s, ITEM_LABEL_LENGTH, "Time interval is not specified (15)"); } else { double interval = (0.1*pow(2, (double)v)); g_snprintf(s, ITEM_LABEL_LENGTH, "%g s (%u)", interval, v); } } static void ulp_ExtendedEphemeris_validity_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%u h (%u)", 4*v, v); } static void ulp_PositionEstimate_latitude_fmt(gchar *s, guint32 v) { double latitude = ((double)v*90)/pow(2,23); g_snprintf(s, ITEM_LABEL_LENGTH, "%g degrees (%u)", latitude, v); } static void ulp_PositionEstimate_longitude_fmt(gchar *s, guint32 v) { double longitude = ((double)(gint32)v*360)/pow(2,24); g_snprintf(s, ITEM_LABEL_LENGTH, "%g degrees (%u)", longitude, v); } static void ulp_NMRelement_rxLev_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "RxLev < -110 dBm (0)"); } else if (v == 63) { g_snprintf(s, ITEM_LABEL_LENGTH, "RxLev >= -48 dBm (63)"); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm <= RxLev < %d dBm (%u)", -111+v, -110+v, v); } } static void ulp_UTRA_CarrierRSSI_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSSI < -100 dBm (0)"); } else if (v == 76) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSSI >= -25 dBm (76)"); } else if (v > 76) { g_snprintf(s, ITEM_LABEL_LENGTH, "Spare (%u)", v); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm <= RSSI < %d dBm (%u)", -101+v, -100+v, v); } } static void ulp_PrimaryCCPCH_RSCP_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSCP < -115 dBm (0)"); } else if (v == 91) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSCP >= -25 dBm (91)"); } else if (v > 91) { g_snprintf(s, ITEM_LABEL_LENGTH, "Spare (%u)", v); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm <= RSCP < %d dBm (%u)", -116+v, -115+v, v); } } static void ulp_CPICH_Ec_N0_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "CPICH Ec/N0 < -24 dB (0)"); } else if (v == 49) { g_snprintf(s, ITEM_LABEL_LENGTH, "CPICH Ec/N0 >= 0 dB (49)"); } else if (v > 49) { g_snprintf(s, ITEM_LABEL_LENGTH, "Spare (%u)", v); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%.1f dB <= CPICH Ec/N0 < %.1f dB (%u)", -24.5+((float)v/2), -24+((float)v/2), v); } } static void ulp_CPICH_RSCP_fmt(gchar *s, guint32 v) { if (v == 123) { g_snprintf(s, ITEM_LABEL_LENGTH, "CPICH RSCP < -120 dBm (123)"); } else if (v > 123) { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm <= CPICH RSCP < %d dBm (%u)", -244+v, -243+v, v); } else if (v == 91) { g_snprintf(s, ITEM_LABEL_LENGTH, "CPICH RSCP >= -25 dBm (91)"); } else if (v < 91) { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm < CPICH RSCP <= %d dBm (%u)", -116+v, -115+v, v); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "Spare (%u)", v); } } static void ulp_QoP_horacc_fmt(gchar *s, guint32 v) { double uncertainty = 10*(pow(1.1, (double)v)-1); if (uncertainty < 1000) { g_snprintf(s, ITEM_LABEL_LENGTH, "%f m (%u)", uncertainty, v); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%f km (%u)", uncertainty/1000, v); } } static void ulp_QoP_veracc_fmt(gchar *s, guint32 v) { double uncertainty = 45*(pow(1.025, (double)v)-1); g_snprintf(s, ITEM_LABEL_LENGTH, "%f m (%u)", uncertainty, v); } static void ulp_QoP_delay_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%g s (%u)", pow(2, (double)v), v); } static const true_false_string ulp_vertical_dir_val = { "Downward", "Upward" }; static void ulp_RelativeTime_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%.2f s (%u)", 0.01*v, v); } static void ulp_RSRP_Range_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSRP < -140 dBm (0)"); } else if (v == 97) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSRP >= -44 dBm (97)"); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%d dBm <= RSRP < %d dBm (%u)", -141+v, -140+v, v); } } static void ulp_RSRQ_Range_fmt(gchar *s, guint32 v) { if (v == 0) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSRQ < -19.5dB (0)"); } else if (v == 64) { g_snprintf(s, ITEM_LABEL_LENGTH, "RSRQ >= -3 dB (34)"); } else { g_snprintf(s, ITEM_LABEL_LENGTH, "%.1f dB <= RSRQ < %.1f dB (%u)", -20+((float)v/2), -19.5+((float)v/2), v); } } static void ulp_SignalDelta_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%s dB (%u)", v ? "0.5" : "0", v); } static void ulp_locationAccuracy_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%.1f m (%u)", 0.1*v, v); } static void ulp_WimaxRTD_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%.2f us (%u)", 0.01*v, v); } static void ulp_WimaxNMR_rssi_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%.2f dBm (%u)", -103.75+(0.25*v), v); } static void ulp_UTRAN_gpsReferenceTimeUncertainty_fmt(gchar *s, guint32 v) { double uncertainty = 0.0022*(pow(1.18, (double)v)-1); g_snprintf(s, ITEM_LABEL_LENGTH, "%f us (%u)", uncertainty, v); } static const value_string ulp_ganss_time_id_vals[] = { { 0, "Galileo"}, { 1, "QZSS"}, { 2, "GLONASS"}, { 3, "BDS"}, { 0, NULL}, }; static void ulp_utran_GANSSTimingOfCell_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%.2f us (%u)", 0.25*v, v); } static void ulp_Coordinate_latitude_fmt(gchar *s, guint32 v) { g_snprintf(s, ITEM_LABEL_LENGTH, "%f degrees (%u)", ((float)v/8388607.0)*90, v); } static void ulp_Coordinate_longitude_fmt(gchar *s, guint32 v) { gint32 longitude = (gint32) v; g_snprintf(s, ITEM_LABEL_LENGTH, "%f degrees (%d)", ((float)longitude/8388608.0)*180, longitude); } /* Include constants */ #include "packet-ulp-val.h" typedef struct { guint8 notif_enc_type; guint8 ganss_req_gen_data_ganss_id; } ulp_private_data_t; static ulp_private_data_t* ulp_get_private_data(asn1_ctx_t *actx) { if (actx->private_data == NULL) { actx->private_data = wmem_new0(wmem_packet_scope(), ulp_private_data_t); } return (ulp_private_data_t*)actx->private_data; } #include "packet-ulp-fn.c" static guint get_ulp_pdu_len(packet_info *pinfo _U_, tvbuff_t *tvb, int offset, void *data _U_) { /* PDU length = Message length */ return tvb_get_ntohs(tvb,offset); } static int dissect_ulp_tcp(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree, void* data) { tcp_dissect_pdus(tvb, pinfo, tree, ulp_desegment, ULP_HEADER_SIZE, get_ulp_pdu_len, dissect_ULP_PDU_PDU, data); return tvb_captured_length(tvb); } void proto_reg_handoff_ulp(void); /*--- proto_register_ulp -------------------------------------------*/ void proto_register_ulp(void) { /* List of fields */ static hf_register_info hf[] = { #include "packet-ulp-hfarr.c" { &hf_ulp_mobile_directory_number, { "Mobile Directory Number", "ulp.mobile_directory_number", FT_STRING, BASE_NONE, NULL, 0, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_bit0, { "GPS", "ulp.ganssTimeModels.gps", FT_BOOLEAN, 16, TFS(&tfs_yes_no), 0x8000, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_bit1, { "Galileo", "ulp.ganssTimeModels.galileo", FT_BOOLEAN, 16, TFS(&tfs_yes_no), 0x4000, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_bit2, { "QZSS", "ulp.ganssTimeModels.qzss", FT_BOOLEAN, 16, TFS(&tfs_yes_no), 0x2000, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_bit3, { "GLONASS", "ulp.ganssTimeModels.glonass", FT_BOOLEAN, 16, TFS(&tfs_yes_no), 0x1000, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_bit4, { "BDS", "ulp.ganssTimeModels.bds", FT_BOOLEAN, 16, TFS(&tfs_yes_no), 0x0800, NULL, HFILL }}, { &hf_ulp_ganssTimeModels_spare, { "Spare", "ulp.ganssTimeModels.spare", FT_UINT16, BASE_HEX, NULL, 0x07ff, NULL, HFILL }}, }; /* List of subtrees */ static gint *ett[] = { &ett_ulp, &ett_ulp_setid, &ett_ulp_thirdPartyId, &ett_ulp_ganssTimeModels, #include "packet-ulp-ettarr.c" }; module_t *ulp_module; /* Register protocol */ proto_ulp = proto_register_protocol(PNAME, PSNAME, PFNAME); register_dissector("ulp", dissect_ulp_tcp, proto_ulp); /* Register fields and subtrees */ proto_register_field_array(proto_ulp, hf, array_length(hf)); proto_register_subtree_array(ett, array_length(ett)); ulp_module = prefs_register_protocol(proto_ulp,proto_reg_handoff_ulp); prefs_register_bool_preference(ulp_module, "desegment_ulp_messages", "Reassemble ULP messages spanning multiple TCP segments", "Whether the ULP dissector should reassemble messages spanning multiple TCP segments." " To use this option, you must also enable \"Allow subdissectors to reassemble TCP streams\" in the TCP protocol settings.", &ulp_desegment); /* Register a configuration option for port */ prefs_register_uint_preference(ulp_module, "tcp.port", "ULP TCP Port", "Set the TCP port for ULP messages (IANA registered port is 7275)", 10, &gbl_ulp_tcp_port); prefs_register_uint_preference(ulp_module, "udp.port", "ULP UDP Port", "Set the UDP port for ULP messages (IANA registered port is 7275)", 10, &gbl_ulp_udp_port); } /*--- proto_reg_handoff_ulp ---------------------------------------*/ void proto_reg_handoff_ulp(void) { static gboolean initialized = FALSE; static dissector_handle_t ulp_tcp_handle, ulp_udp_handle; static guint local_ulp_tcp_port, local_ulp_udp_port; if (!initialized) { ulp_tcp_handle = find_dissector("ulp"); dissector_add_string("media_type","application/oma-supl-ulp", ulp_tcp_handle); dissector_add_string("media_type","application/vnd.omaloc-supl-init", ulp_tcp_handle); ulp_udp_handle = create_dissector_handle(dissect_ULP_PDU_PDU, proto_ulp); rrlp_handle = find_dissector("rrlp"); lpp_handle = find_dissector("lpp"); initialized = TRUE; } else { dissector_delete_uint("tcp.port", local_ulp_tcp_port, ulp_tcp_handle); dissector_delete_uint("udp.port", local_ulp_udp_port, ulp_udp_handle); } local_ulp_tcp_port = gbl_ulp_tcp_port; dissector_add_uint("tcp.port", gbl_ulp_tcp_port, ulp_tcp_handle); local_ulp_udp_port = gbl_ulp_udp_port; dissector_add_uint("udp.port", gbl_ulp_udp_port, ulp_udp_handle); }