module BTS_Tests { import from General_Types all; import from GSM_Types all; import from GSM_RR_Types all; import from Osmocom_Types all; import from GSM_Types all; import from GSM_RR_Types all; import from GSM_SystemInformation all; import from L1CTL_PortType all; import from L1CTL_Types all; import from LAPDm_Types all; import from Osmocom_CTRL_Adapter all; import from Osmocom_CTRL_Functions all; import from RSL_Types all; import from IPA_Types all; import from IPA_Emulation all; import from RSL_Emulation all; import from IPL4asp_Types all; import from TRXC_Types all; import from TRXC_CodecPort all; import from TRXC_CodecPort_CtrlFunct all; import from PCUIF_Types all; import from PCUIF_CodecPort all; import from MobileL3_CommonIE_Types all; import from MobileL3_RRM_Types all; import from MobileL3_Types all; import from L3_Templates all; import from Osmocom_VTY_Functions all; import from TELNETasp_PortType all; /* The tests assume a BTS with the following timeslot configuration: * TS0 : Combined CCCH + SDCCH/4 * TS1 .. TS 4: TCH/F * TS5 : TCH/H * TS6 : SDCCH/8 * TS7 : PDCH */ modulepar { charstring mp_rsl_ip := "127.0.0.2"; integer mp_rsl_port := 3003; integer mp_trx0_arfcn := 871; charstring mp_bb_trxc_ip := "127.0.0.1"; integer mp_bb_trxc_port := 6701; charstring mp_pcu_socket := PCU_SOCK_DEFAULT; integer mp_tolerance_rxqual := 1; integer mp_tolerance_rxlev := 3; charstring mp_ctrl_ip := "127.0.0.1"; integer mp_ctrl_port := 4238; } type record of RslChannelNr ChannelNrs; type component test_CT extends CTRL_Adapter_CT { /* IPA Emulation component underneath RSL */ var IPA_Emulation_CT vc_IPA; /* RSL Emulation component (for ConnHdlr tests) */ var RSL_Emulation_CT vc_RSL; /* Direct RSL_CCHAN_PT */ port RSL_CCHAN_PT RSL_CCHAN; /* L1CTL port (for classic tests) */ port L1CTL_PT L1CTL; /* TRXC port (for classic tests) */ port TRXC_CODEC_PT BB_TRXC; var integer g_bb_trxc_conn_id; port TELNETasp_PT BTSVTY; /* PCU Interface of BTS */ port PCUIF_CODEC_PT PCU; var integer g_pcu_conn_id; /* Last PCU INFO IND we received */ var PCUIF_Message g_pcu_last_info; /* SI configuration */ var SystemInformationConfig si_cfg := { bcch_extended := false, si1_present := false, si2bis_present := false, si2ter_present := false, si2quater_present := false, si7_present := false, si8_present := false, si9_present := false, si13_present := false, si13alt_present := false, si15_present := false, si16_present := false, si17_present := false, si2n_present := false, si21_present := false, si22_present := false }; /* all logical channels available on the BTS */ var ChannelNrs g_AllChannels; } /* an individual call / channel */ type component ConnHdlr extends RSL_DchanHdlr { port L1CTL_PT L1CTL; port TRXC_CODEC_PT BB_TRXC; var integer g_bb_trxc_conn_id; timer g_Tguard; timer g_Tmeas_exp := 2.0; /* >= 103 SACCH multiframe ~ 500ms */ var ConnHdlrPars g_pars; var uint8_t g_next_meas_res_nr := 0; var boolean g_first_meas_res := true; /* PCU Interface of BTS */ port PCUIF_CODEC_PT PCU; } function f_init_rsl(charstring id) runs on test_CT { vc_IPA := IPA_Emulation_CT.create(id & "-RSL-IPA"); vc_RSL := RSL_Emulation_CT.create(id & "-RSL"); map(vc_IPA:IPA_PORT, system:IPA_CODEC_PT); connect(vc_IPA:IPA_RSL_PORT, vc_RSL:IPA_PT); connect(self:RSL_CCHAN, vc_RSL:CCHAN_PT); vc_IPA.start(IPA_Emulation.main_server(mp_rsl_ip, mp_rsl_port)); vc_RSL.start(RSL_Emulation.main(false)); } type record ConnHdlrPars { RslChannelNr chan_nr, RSL_IE_ChannelMode chan_mode, float t_guard, ConnL1Pars l1_pars } template (value) RachControlParameters ts_RachCtrl_default := { max_retrans := RACH_MAX_RETRANS_7, tx_integer := '1001'B, /* 12 slots */ cell_barr_access := false, re_not_allowed := true, acc := '0000010000000000'B }; template (value) CellSelectionParameters ts_CellSelPar_default := { cell_resel_hyst_2dB := 2, ms_txpwr_max_cch := 7, acs := '0'B, neci := true, rxlev_access_min := 0 } template (value) LocationAreaIdentification ts_LAI_default := { mcc_mnc := '262F42'H, lac := 42 } /* Default SYSTEM INFORMATION 3 */ template (value) SystemInformation ts_SI3_default := { header := ts_RrHeader(SYSTEM_INFORMATION_TYPE_3, 18), payload := { si3 := { cell_id := 23, lai := ts_LAI_default, ctrl_chan_desc := { msc_r99 := true, att := true, bs_ag_blks_res := 1, ccch_conf := CCHAN_DESC_1CCCH_COMBINED, si22ind := false, cbq3 := CBQ3_IU_MODE_NOT_SUPPORTED, spare := '00'B, bs_pa_mfrms := 0, /* 2 multiframes */ t3212 := 1 /* 6 minutes */ }, cell_options := { dn_ind := false, pwrc := false, dtx := MS_MAY_USE_UL_DTX, radio_link_tout_div4 := (32/4)-1 }, cell_sel_par := ts_CellSelPar_default, rach_control := ts_RachCtrl_default, rest_octets := '2B2B2B2B'O } } } template (value) SystemInformation ts_SI2_default := { header := ts_RrHeader(SYSTEM_INFORMATION_TYPE_2, 22), payload := { si2 := { bcch_freq_list := '00000000000000000000000000000000'O, ncc_permitted := '11111111'B, rach_control := ts_RachCtrl_default } } } template (value) SystemInformation ts_SI4_default := { header := ts_RrHeader(SYSTEM_INFORMATION_TYPE_4, 12), /* no CBCH / restoct */ payload := { si4 := { lai := ts_LAI_default, cell_sel_par := ts_CellSelPar_default, rach_control := ts_RachCtrl_default, cbch_chan_desc := omit, cbch_mobile_alloc := omit, rest_octets := ''O } } } function f_rsl_bcch_fill_raw(RSL_IE_SysinfoType rsl_si_type, octetstring si_enc) runs on test_CT { log("Setting ", rsl_si_type, ": ", si_enc); RSL_CCHAN.send(ts_RSL_UD(ts_RSL_BCCH_INFO(rsl_si_type, si_enc))); } function f_rsl_bcch_fill(RSL_IE_SysinfoType rsl_si_type, template (value) SystemInformation si_dec) runs on test_CT { var octetstring si_enc := enc_SystemInformation(valueof(si_dec)); log("Setting ", rsl_si_type, ": ", si_dec); f_rsl_bcch_fill_raw(rsl_si_type, si_enc); } private function f_init_vty(charstring id) runs on test_CT { map(self:BTSVTY, system:BTSVTY); f_vty_set_prompts(BTSVTY); f_vty_transceive(BTSVTY, "enable"); } /* PCU socket may at any time receive a new INFO.ind */ private altstep as_pcu_info_ind(PCUIF_CODEC_PT pt, integer pcu_conn_id, out PCUIF_Message pcu_last_info) { var PCUIF_send_data sd; [] pt.receive(t_SD_PCUIF(pcu_conn_id, tr_PCUIF_INFO_IND(0, ?))) -> value sd { pcu_last_info := sd.data; } [] pt.receive(t_SD_PCUIF(pcu_conn_id, tr_PCUIF_INFO_IND(?, ?, ?))) -> value sd { setverdict(fail, "Invalid PCU Version/BTS Number received"); self.stop; } } private function f_init_pcu(PCUIF_CODEC_PT pt, charstring id, out integer pcu_conn_id, out PCUIF_Message pcu_last_info) { timer T := 2.0; var PCUIF_send_data sd; if (mp_pcu_socket == "") { pcu_conn_id := -1; return; } pcu_conn_id := f_pcuif_connect(pt, mp_pcu_socket); T.start; alt { [] as_pcu_info_ind(pt, pcu_conn_id, pcu_last_info); [] T.timeout { setverdict(fail, "Timeout waiting for PCU INFO_IND"); self.stop; } } } /* global init function */ function f_init(charstring id := "BTS-Test") runs on test_CT { g_AllChannels := { /* TS 1..4: TCH/F */ valueof(ts_RslChanNr_Bm(1)), valueof(ts_RslChanNr_Bm(2)), valueof(ts_RslChanNr_Bm(3)), valueof(ts_RslChanNr_Bm(4)), /* TS 5: TCH/H */ valueof(ts_RslChanNr_Lm(5,0)), valueof(ts_RslChanNr_Lm(5,1)), /* TS 0: SDCCH/4 */ valueof(ts_RslChanNr_SDCCH4(0,0)), valueof(ts_RslChanNr_SDCCH4(0,1)), valueof(ts_RslChanNr_SDCCH4(0,2)), valueof(ts_RslChanNr_SDCCH4(0,3)), /* TS 6: SDCCH/8 */ valueof(ts_RslChanNr_SDCCH8(6,0)), valueof(ts_RslChanNr_SDCCH8(6,1)), valueof(ts_RslChanNr_SDCCH8(6,2)), valueof(ts_RslChanNr_SDCCH8(6,3)), valueof(ts_RslChanNr_SDCCH8(6,4)), valueof(ts_RslChanNr_SDCCH8(6,5)), valueof(ts_RslChanNr_SDCCH8(6,6)), valueof(ts_RslChanNr_SDCCH8(6,7)) }; f_init_rsl(id); RSL_CCHAN.receive(ASP_IPA_Event:{up_down := ASP_IPA_EVENT_UP}); f_sleep(0.5); /* workaround for OS#3000 */ f_init_vty(id); f_ipa_ctrl_start(mp_ctrl_ip, mp_ctrl_port); /* Send SI3 to the BTS, it is needed for various computations */ f_rsl_bcch_fill(RSL_SYSTEM_INFO_3, ts_SI3_default); /* SI2 + SI4 are required for SI testing as they are mandatory defaults */ f_rsl_bcch_fill(RSL_SYSTEM_INFO_2, ts_SI2_default); f_rsl_bcch_fill(RSL_SYSTEM_INFO_4, ts_SI4_default); map(self:PCU, system:PCU); f_init_pcu(PCU, id, g_pcu_conn_id, g_pcu_last_info); if (mp_bb_trxc_port != -1) { var TrxcMessage ret; /* start with a default moderate timing offset equalling TA=2 */ f_main_trxc_connect(); ret := f_TRXC_transceive(BB_TRXC, g_bb_trxc_conn_id, valueof(ts_TRXC_FAKE_TIMING(2*256))); } } function f_shutdown() runs on test_CT { /* shut down all "externally interfaced" components first to avoid unclean shutdown */ vc_IPA.stop; vc_RSL.stop; f_ipa_ctrl_stop(); } /* Attach L1CTL to master test_CT (classic tests, non-handler mode) */ function f_init_l1ctl() runs on test_CT { map(self:L1CTL, system:L1CTL); f_connect_reset(L1CTL); } type function void_fn(charstring id) runs on ConnHdlr; /* create a new test component */ function f_start_handler(void_fn fn, ConnHdlrPars pars, boolean pcu_comp := false) runs on test_CT return ConnHdlr { var charstring id := testcasename(); var ConnHdlr vc_conn; vc_conn := ConnHdlr.create(id); /* connect to RSL Emulation main component */ connect(vc_conn:RSL, vc_RSL:CLIENT_PT); connect(vc_conn:RSL_PROC, vc_RSL:RSL_PROC); if (pcu_comp) { /* the ConnHdlr component wants to talk directly to the PCU, so disconnect * it from the test_CT and connect it to the component. This obviously only * works for one component, i.e. no concurrency */ unmap(self:PCU, system:PCU); map(vc_conn:PCU, system:PCU); } vc_conn.start(f_handler_init(fn, id, pars)); return vc_conn; } template ASP_RSL_Unitdata ts_RSL_UD(template RSL_Message rsl, IpaStreamId sid := IPAC_PROTO_RSL_TRX0) := { streamId := sid, rsl := rsl } template ASP_RSL_Unitdata tr_RSL_UD(template RSL_Message rsl, template IpaStreamId sid := IPAC_PROTO_RSL_TRX0) := { streamId := sid, rsl := rsl } private altstep as_Tguard() runs on ConnHdlr { [] g_Tguard.timeout { setverdict(fail, "Tguard timeout"); self.stop; } } private function f_l1_tune(L1CTL_PT L1CTL) { f_L1CTL_FBSB(L1CTL, { false, mp_trx0_arfcn }, CCCH_MODE_COMBINED); } private function f_trxc_connect() runs on ConnHdlr { map(self:BB_TRXC, system:BB_TRXC); var Result res; res := TRXC_CodecPort_CtrlFunct.f_IPL4_connect(BB_TRXC, mp_bb_trxc_ip, mp_bb_trxc_port, "", -1, -1, {udp:={}}, {}); g_bb_trxc_conn_id := res.connId; } private function f_trxc_fake_rssi(uint8_t rssi) runs on ConnHdlr { var TrxcMessage ret; ret := f_TRXC_transceive(BB_TRXC, g_bb_trxc_conn_id, valueof(ts_TRXC_FAKE_RSSI(rssi))); } private function f_trx_fake_toffs256(int16_t toffs256) runs on ConnHdlr { var TrxcMessage ret; ret := f_TRXC_transceive(BB_TRXC, g_bb_trxc_conn_id, valueof(ts_TRXC_FAKE_TIMING(toffs256))); } /* first function started in ConnHdlr component */ private function f_handler_init(void_fn fn, charstring id, ConnHdlrPars pars) runs on ConnHdlr { g_pars := pars; g_chan_nr := pars.chan_nr; map(self:L1CTL, system:L1CTL); f_connect_reset(L1CTL); if (mp_bb_trxc_port != -1) { f_trxc_connect(); } g_Tguard.start(pars.t_guard); activate(as_Tguard()); f_rslem_register(0, pars.chan_nr); /* call the user-supplied test case function */ fn.apply(id); } function f_rsl_transceive_ret(template RSL_Message tx, template RSL_Message exp_rx, charstring id, boolean ignore_other := false) runs on ConnHdlr return RSL_Message { var RSL_Message rx; timer T := 3.0; RSL.send(tx); T.start; alt { [] RSL.receive(exp_rx) -> value rx { T.stop; setverdict(pass); } [] T.timeout { setverdict(fail, "Timeout expecting " & id); self.stop; } [not ignore_other] as_l1_sacch(); [not ignore_other] as_meas_res(); [not ignore_other] as_l1_dcch(); [not ignore_other] RSL.receive { setverdict(fail, "Unexpected RSL message received"); self.stop; } [ignore_other] RSL.receive { repeat; } } return rx; } function f_rsl_transceive(template RSL_Message tx, template RSL_Message exp_rx, charstring id, boolean ignore_other := false) runs on ConnHdlr { var RSL_Message rx := f_rsl_transceive_ret(tx, exp_rx, id, ignore_other); } function f_rsl_chan_act(RSL_IE_ChannelMode mode) runs on ConnHdlr { f_rsl_transceive(ts_RSL_CHAN_ACT(g_chan_nr, mode), tr_RSL_CHAN_ACT_ACK(g_chan_nr), "RSL CHAN ACT"); } function f_rsl_chan_deact() runs on ConnHdlr { f_rsl_transceive(ts_RSL_RF_CHAN_REL(g_chan_nr), tr_RSL_RF_CHAN_REL_ACK(g_chan_nr), "RF CHAN REL", true); } private template ConnHdlrPars t_Pars(template RslChannelNr chan_nr, template RSL_IE_ChannelMode chan_mode, float t_guard := 20.0) := { chan_nr := valueof(chan_nr), chan_mode := valueof(chan_mode), t_guard := t_guard, l1_pars := { dtx_enabled := false, toa256_enabled := false, meas_ul := { full := { rxlev := dbm2rxlev(-53), rxqual := 0 }, sub := { rxlev := dbm2rxlev(-53), rxqual := 0 } }, timing_offset_256syms := 0, bs_power_level := 0, ms_power_level := 0, ms_actual_ta := 0 } } /*********************************************************************** * Channel Activation / Deactivation ***********************************************************************/ /* Stress test: Do 500 channel activations/deactivations in rapid succession */ function f_TC_chan_act_stress(charstring id) runs on ConnHdlr { for (var integer i := 0; i < 500; i := i+1) { f_rsl_chan_act(g_pars.chan_mode); f_rsl_chan_deact(); } setverdict(pass); } testcase TC_chan_act_stress() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(testcasename()); vc_conn := f_start_handler(refers(f_TC_chan_act_stress), pars); vc_conn.done; f_shutdown(); } /* Test if re-activation of an already active channel fails as expected */ function f_TC_chan_act_react(charstring id) runs on ConnHdlr { f_rsl_chan_act(g_pars.chan_mode); /* attempt to activate the same lchan again -> expect reject */ RSL.send(ts_RSL_CHAN_ACT(g_chan_nr, g_pars.chan_mode)); alt { [] RSL.receive(tr_RSL_CHAN_ACT_ACK(g_chan_nr)) { setverdict(fail, "Unexpected CHAN ACT ACK on double activation"); } [] RSL.receive(tr_RSL_CHAN_ACT_NACK(g_chan_nr)) { setverdict(pass); } } f_rsl_chan_deact(); } testcase TC_chan_act_react() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(); vc_conn := f_start_handler(refers(f_TC_chan_act_react), pars); vc_conn.done; f_shutdown(); } /* Attempt to de-activate a channel that's not active */ function f_TC_chan_deact_not_active(charstring id) runs on ConnHdlr { timer T := 3.0; RSL.send(ts_RSL_RF_CHAN_REL(g_chan_nr)); T.start; alt { [] RSL.receive(tr_RSL_RF_CHAN_REL_ACK(g_chan_nr)) { setverdict(pass); } [] T.timeout { setverdict(fail, "Timeout expecting RF_CHAN_REL_ACK"); } } } testcase TC_chan_deact_not_active() runs on test_CT { var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(); var ConnHdlr vc_conn := f_start_handler(refers(f_TC_chan_deact_not_active), pars); vc_conn.done; f_shutdown(); } /* attempt to activate channel with wrong RSL Channel Nr IE; expect NACK */ function f_TC_chan_act_wrong_nr(charstring id) runs on ConnHdlr { RSL.send(ts_RSL_CHAN_ACT(g_chan_nr, g_pars.chan_mode)); alt { [] RSL.receive(tr_RSL_CHAN_ACT_ACK(g_chan_nr)) { setverdict(fail, "Unexpected CHAN ACT ACK"); } [] RSL.receive(tr_RSL_CHAN_ACT_NACK(g_chan_nr)) { setverdict(pass); } } } private type record WrongChanNrCase { RslChannelNr chan_nr, charstring description } private type record of WrongChanNrCase WrongChanNrCases; private template WrongChanNrCase t_WCN(template RslChannelNr chan_nr, charstring desc) := { chan_nr := chan_nr, description := desc } testcase TC_chan_act_wrong_nr() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); var WrongChanNrCases wrong := { valueof(t_WCN(t_RslChanNr_RACH(0), "RACH is not a dedicated channel")), valueof(t_WCN(t_RslChanNr_RACH(1), "RACH doesn't exist on timeslot")), valueof(t_WCN(t_RslChanNr_BCCH(0), "BCCH is not a dedicated channel")), valueof(t_WCN(t_RslChanNr_PCH_AGCH(0), "PCH/AGCH is not a dedicated channel")), valueof(t_WCN(t_RslChanNr_Bm(0), "TS0 cannot be TCH/F")), valueof(t_WCN(t_RslChanNr_Lm(0, 0), "TS0 cannot be TCH/H")), valueof(t_WCN(t_RslChanNr_Lm(0, 1), "TS0 cannot be TCH/H")), valueof(t_WCN(t_RslChanNr_PDCH(0), "TS0 cannot be PDCH")), valueof(t_WCN(t_RslChanNr_SDCCH8(0, 0), "TS0 cannot be SDCCH/8")), valueof(t_WCN(t_RslChanNr_SDCCH8(0, 7), "TS0 cannot be SDCCH/8")), valueof(t_WCN(t_RslChanNr_SDCCH4(7, 0), "TS7 cannot be SDCCH/4")), valueof(t_WCN(t_RslChanNr_SDCCH4(7, 3), "TS7 cannot be SDCCH/4")), valueof(t_WCN(t_RslChanNr_Lm(1, 0), "TS1 cannot be TCH/H")) }; for (var integer i := 0; i < sizeof(wrong); i := i+1) { pars := valueof(t_Pars(wrong[i].chan_nr, ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_chan_act_wrong_nr), pars); vc_conn.done; } f_shutdown(); } /*********************************************************************** * SACCH handling ***********************************************************************/ private function f_exp_sacch(boolean exp) runs on ConnHdlr { timer T_sacch := 3.0; T_sacch.start; alt { [not exp] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_SACCH(0))) { setverdict(fail, "Received SACCH when not expecting it"); } [not exp] T_sacch.timeout { setverdict(pass); } [exp] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_SACCH(0))) { setverdict(pass); } [exp] T_sacch.timeout { setverdict(fail, "Timeout waiting for SACCH on ", g_chan_nr); } [] L1CTL.receive { repeat; } [] RSL.receive { repeat; } } } /* Test if DEACTIVATE SACCH actualy deactivates its transmission (TS 48.058 4.6) */ private function f_TC_deact_sacch(charstring id) runs on ConnHdlr { f_l1_tune(L1CTL); RSL.clear; /* activate the logical channel */ f_est_dchan(); L1CTL.clear; /* check that SACCH actually are received as expected */ f_exp_sacch(true); /* deactivate SACCH on the logical channel */ RSL.send(ts_RSL_DEACT_SACCH(g_chan_nr)); f_sleep(1.0); L1CTL.clear; /* check that no SACCH are received anymore */ f_exp_sacch(false); /* release the channel */ f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_deact_sacch() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); for (var integer i := 0; i < sizeof(g_AllChannels); i := i+1) { //for (var integer i := 0; i < 1; i := i+1) { pars := valueof(t_Pars(g_AllChannels[i], ts_RSL_ChanMode_SIGN)); log(testcasename(), ": Starting for ", g_AllChannels[i]); vc_conn := f_start_handler(refers(f_TC_deact_sacch), pars); vc_conn.done; } /* TODO: do the above in parallel, rather than sequentially? */ f_shutdown(); } /* verify that given SACCH payload is present */ private function f_sacch_present(template octetstring l3_exp) runs on ConnHdlr { var L1ctlDlMessage dl; /* check that the specified SI5 value is actually sent */ timer T_sacch := 3.0; L1CTL.clear; T_sacch.start; alt { [] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_SACCH(0))) -> value dl { var octetstring l3 := substr(dl.payload.data_ind.payload, 4, 19); if (match(l3, l3_exp)) { setverdict(pass); } else { repeat; } } [] L1CTL.receive { repeat; } [] T_sacch.timeout { setverdict(fail, "Timeout waiting for SACCH ", l3_exp); self.stop; } } } /* verify that given SACCH payload is not present */ private function f_sacch_missing(template octetstring l3_exp) runs on ConnHdlr { var L1ctlDlMessage dl; /* check that the specified SI5 value is actually sent */ timer T_sacch := 3.0; L1CTL.clear; T_sacch.start; alt { [] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_SACCH(0))) -> value dl { var octetstring l3 := substr(dl.payload.data_ind.payload, 4, 19); if (match(l3, l3_exp)) { setverdict(fail, "Received unexpected SACCH ", dl); self.stop; } else { repeat; } } [] L1CTL.receive { repeat; } [] T_sacch.timeout { setverdict(pass); } } } /* Test for default SACCH FILL transmitted in DL SACCH (all channel types) */ private function f_TC_sacch_filling(charstring id) runs on ConnHdlr { /* Set a known default SACCH filling for SI5 */ var octetstring si5 := f_rnd_octstring(19); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5, si5)); f_l1_tune(L1CTL); RSL.clear; /* activate the logical channel */ f_est_dchan(); /* check that the specified SI5 value is actually sent */ f_sacch_present(si5); /* release the channel */ RSL.clear; f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_sacch_filling() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); for (var integer i := 0; i < sizeof(g_AllChannels); i := i+1) { pars := valueof(t_Pars(g_AllChannels[i], ts_RSL_ChanMode_SIGN)); log(testcasename(), ": Starting for ", g_AllChannels[i]); vc_conn := f_start_handler(refers(f_TC_sacch_filling), pars); vc_conn.done; } /* TODO: do the above in parallel, rather than sequentially? */ f_shutdown(); } /* Test for lchan-specific SACCH INFO MODIFY (TS 48.058 4.12) */ private function f_TC_sacch_info_mod(charstring id) runs on ConnHdlr { /* Set a known default SACCH filling for SI5 */ var octetstring si5 := f_rnd_octstring(19); var octetstring si5_diff := f_rnd_octstring(19); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5, si5)); f_l1_tune(L1CTL); RSL.clear; log("Activating channel, expecting standard SI5"); /* activate the logical channel */ f_est_dchan(); /* check that the specified SI5 value is actually sent */ f_sacch_present(si5); /* set channel-specific different SI5 */ log("Setting channel specific SACCH INFO, expecting it"); RSL.send(ts_RSL_SACCH_INF_MOD(g_chan_nr, RSL_SYSTEM_INFO_5, si5_diff)) /* check that the specified lchan-specific value is now used */ f_sacch_present(si5_diff); /* deactivate the channel and re-activate it, this should result in default SI5 */ log("De-activating and re-activating channel, expecting standard SI5"); f_rsl_chan_deact(); f_rsl_chan_act(valueof(ts_RSL_ChanMode_SIGN)); /* Verify that the TRX-wide default SACCH filling is present again */ f_sacch_present(si5); /* release the channel */ RSL.clear; f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_sacch_info_mod() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); for (var integer i := 0; i < sizeof(g_AllChannels); i := i+1) { pars := valueof(t_Pars(g_AllChannels[i], ts_RSL_ChanMode_SIGN)); log(testcasename(), ": Starting for ", g_AllChannels[i]); vc_conn := f_start_handler(refers(f_TC_sacch_info_mod), pars); vc_conn.done; } /* TODO: do the above in parallel, rather than sequentially? */ f_shutdown(); } /* Test SACCH scheduling of multiple different SI message types */ private function f_TC_sacch_multi(charstring id) runs on ConnHdlr { var octetstring si5 := f_rnd_octstring(19); var octetstring si5bis := f_rnd_octstring(19); var octetstring si5ter := f_rnd_octstring(19); var octetstring si6 := f_rnd_octstring(19); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5, si5)); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5bis, si5bis)); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5ter, si5ter)); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_6, si6)); f_l1_tune(L1CTL); RSL.clear; /* activate the logical channel */ f_est_dchan(); L1CTL.clear; /* check that SACCH actually are received as expected */ f_sacch_present(si5); f_sacch_present(si5bis); f_sacch_present(si5ter); f_sacch_present(si6); /* release the channel */ f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_sacch_multi() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); for (var integer i := 0; i < sizeof(g_AllChannels); i := i+1) { pars := valueof(t_Pars(g_AllChannels[i], ts_RSL_ChanMode_SIGN)); log(testcasename(), ": Starting for ", g_AllChannels[i]); vc_conn := f_start_handler(refers(f_TC_sacch_multi), pars); vc_conn.done; } /* TODO: do the above in parallel, rather than sequentially? */ f_shutdown(); } /* Test if SACH information is modified as expected */ private function f_TC_sacch_multi_chg(charstring id) runs on ConnHdlr { var octetstring si5 := f_rnd_octstring(19); var octetstring si6 := f_rnd_octstring(19); /* First, configure both SI5 and SI6 to be transmitted */ RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_5, si5)); RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_6, si6)); f_l1_tune(L1CTL); RSL.clear; /* activate the logical channel */ f_est_dchan(); L1CTL.clear; /* check that SACCH actually are received as expected */ f_sacch_present(si5); f_sacch_present(si6); /* disable SI6 */ RSL.send(ts_RSL_SACCH_FILL(RSL_SYSTEM_INFO_6, ''O)); /* check that SI5 is still transmitted */ f_sacch_present(si5); /* check if SI6 is now gone */ f_sacch_missing(si6); /* release the channel */ f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_sacch_multi_chg() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(); for (var integer i := 0; i < sizeof(g_AllChannels); i := i+1) { pars := valueof(t_Pars(g_AllChannels[i], ts_RSL_ChanMode_SIGN)); log(testcasename(), ": Starting for ", g_AllChannels[i]); vc_conn := f_start_handler(refers(f_TC_sacch_multi_chg), pars); vc_conn.done; } /* TODO: do the above in parallel, rather than sequentially? */ f_shutdown(); } /* TODO: Test for SACCH information present in RSL CHAN ACT (overrides FILLING) */ /* TODO: Test for SACCH transmission rules in the context of special CHAN ACT (HO) */ /*********************************************************************** * RACH Handling ***********************************************************************/ /* like L1SAP_IS_PACKET_RACH */ private function ra_is_ps(OCT1 ra) return boolean { if ((ra and4b 'F0'O == '70'O) and (ra and4b '0F'O != '0F'O)) { return true; } return false; } /* generate a random RACH for circuit-switched */ private function f_rnd_ra_cs() return OCT1 { var OCT1 ra; do { ra := f_rnd_octstring(1); } while (ra_is_ps(ra)); return ra; } /* generate a random RACH for packet-switched */ private function f_rnd_ra_ps() return OCT1 { var OCT1 ra; do { ra := f_rnd_octstring(1); } while (not ra_is_ps(ra)); return ra; } /* Send 1000 RACH requests and check their RA+FN on the RSL side */ testcase TC_rach_content() runs on test_CT { f_init(testcasename()); f_init_l1ctl(); f_l1_tune(L1CTL); var GsmFrameNumber fn_last := 0; for (var integer i := 0; i < 1000; i := i+1) { var OCT1 ra := f_rnd_ra_cs(); var GsmFrameNumber fn := f_L1CTL_RACH(L1CTL, oct2int(ra)); if (fn == fn_last) { setverdict(fail, "Two RACH in same FN?!?"); self.stop; } fn_last := fn; timer T := 5.0; T.start; alt { [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_CHAN_RQD(ra, fn, ?))) { T.stop; } [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_CHAN_RQD(?, ?, ?))) { setverdict(fail, "Unexpected CHAN RQD"); self.stop; } [] RSL_CCHAN.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for CHAN RQD"); self.stop; } } } setverdict(pass); f_shutdown(); } /* Send 1000 RACH Requests (flood ~ 89/s) and count if count(Abis) == count(Um) */ testcase TC_rach_count() runs on test_CT { f_init(); f_init_l1ctl(); f_sleep(1.0); f_l1_tune(L1CTL); var GsmFrameNumber fn_last := 0; for (var integer i := 0; i < 1000; i := i+1) { var OCT1 ra := f_rnd_ra_cs(); var GsmFrameNumber fn := f_L1CTL_RACH(L1CTL, oct2int(ra)); if (fn == fn_last) { setverdict(fail, "Two RACH in same FN?!?"); self.stop; } fn_last := fn; } var integer rsl_chrqd := 0; timer T := 3.0; T.start; alt { [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_CHAN_RQD(?,?))) { rsl_chrqd := rsl_chrqd + 1; f_timer_safe_restart(T); repeat; } [] RSL_CCHAN.receive { repeat; } [] T.timeout { } } if (rsl_chrqd == 1000) { setverdict(pass); } else { setverdict(fail, "Received only ", rsl_chrqd, " out of 1000 RACH"); } f_shutdown(); } private function f_main_trxc_connect() runs on test_CT { map(self:BB_TRXC, system:BB_TRXC); var Result res; res := TRXC_CodecPort_CtrlFunct.f_IPL4_connect(BB_TRXC, mp_bb_trxc_ip, mp_bb_trxc_port, "", -1, -1, {udp:={}}, {}); g_bb_trxc_conn_id := res.connId; } private function f_rach_toffs(int16_t toffs256, boolean expect_pass) runs on test_CT { var TrxcMessage ret; /* tell fake_trx to use a given timing offset for all bursts */ ret := f_TRXC_transceive(BB_TRXC, g_bb_trxc_conn_id, valueof(ts_TRXC_FAKE_TIMING(toffs256))); f_sleep(0.5); /* Transmit RACH request + wait for confirmation */ var OCT1 ra := f_rnd_ra_cs(); var GsmFrameNumber fn := f_L1CTL_RACH(L1CTL, oct2int(ra)); /* Check for expected result */ timer T := 1.5; T.start; alt { [expect_pass] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_CHAN_RQD(ra, fn))) { setverdict(pass); } [not expect_pass] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_CHAN_RQD(ra, fn))) { setverdict(fail, "RACH passed but was expected to be dropped: ", toffs256); } [] RSL_CCHAN.receive { repeat; } [not expect_pass] T.timeout { setverdict(pass); } [expect_pass] T.timeout { setverdict(fail, "Timeout waiting for CHAN RQD"); } } } /* Test if dropping of RACH Based on NM_ATT_MAX_TA works */ testcase TC_rach_max_ta() runs on test_CT { f_init(testcasename()); f_init_l1ctl(); f_l1_tune(L1CTL); f_sleep(1.0); /* default max-ta is 63 (full range of GSM timing advance */ /* We allow early arrival up to 2 symbols */ f_rach_toffs(-1*256, true); f_rach_toffs(-2*256, true); f_rach_toffs(-10*256, false); /* 0 / 32 / 63 bits is legal / permitted */ f_rach_toffs(0, true); f_rach_toffs(32*256, true); f_rach_toffs(63*256, true); /* more than 63 bits is not legal / permitted */ f_rach_toffs(64*256, false); f_rach_toffs(127*256, false); f_shutdown(); } /*********************************************************************** * Measurement Processing / Reporting ***********************************************************************/ template LapdmAddressField ts_LapdmAddr(LapdmSapi sapi, boolean c_r) := { spare := '0'B, lpd := 0, sapi := sapi, c_r := c_r, ea := true } template LapdmFrameB ts_LAPDm_B(LapdmSapi sapi, boolean c_r, boolean p, octetstring pl) := { addr := ts_LapdmAddr(sapi, c_r), ctrl := t_LapdmCtrlUI(p), len := 0, /* overwritten */ m := false, el := 1, payload := pl } /* handle incoming downlink SACCH and respond with uplink SACCH (meas res) */ altstep as_l1_sacch() runs on ConnHdlr { var L1ctlDlMessage l1_dl; [] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_SACCH(?))) -> value l1_dl { log("SACCH received: ", l1_dl.payload.data_ind.payload); var GsmRrL3Message meas_rep := valueof(ts_MEAS_REP(true, 23, 23, 0, 0, omit)); var LapdmFrameB lb := valueof(ts_LAPDm_B(0, false, false, enc_GsmRrL3Message(meas_rep))); log("LAPDm: ", lb); var octetstring pl := '0000'O & enc_LapdmFrameB(lb); L1CTL.send(ts_L1CTL_DATA_REQ(g_chan_nr, ts_RslLinkID_SACCH(0), pl)); repeat; } } altstep as_l1_dcch() runs on ConnHdlr { var L1ctlDlMessage l1_dl; [] L1CTL.receive(tr_L1CTL_DATA_IND(g_chan_nr, tr_RslLinkID_DCCH(?))) -> value l1_dl { log("DCCH received: ", l1_dl.payload.data_ind.payload); var octetstring pl := '010301'O; L1CTL.send(ts_L1CTL_DATA_REQ(g_chan_nr, ts_RslLinkID_DCCH(0), pl)); repeat; } } type record MeasElem { uint6_t rxlev, uint3_t rxqual } type record MeasElemFS { MeasElem full, MeasElem sub } type record ConnL1Pars { boolean dtx_enabled, boolean toa256_enabled, MeasElemFS meas_ul, int16_t timing_offset_256syms, uint5_t bs_power_level, uint5_t ms_power_level, uint8_t ms_actual_ta } /* Convert tiing offset from 1/256th symbol to RSL Timing Offset */ private function toffs256s_to_rsl(int16_t toffs256s) return uint8_t { return 63 + (toffs256s/256); } private function f_max(integer a, integer b) return integer { if (a > b) { return a; } else { return b; } } private function f_min(integer a, integer b) return integer { if (a < b) { return a; } else { return b; } } /* compute negative tolerance val-tolerance, ensure >= min */ private function f_tolerance_neg(integer val, integer min, integer tolerance) return integer { val := val - tolerance; return f_max(val, min); } /* compute positive tolerance val+tolerance, ensure <= max */ private function f_tolerance_pos(integer val, integer max, integer tolerance) return integer { val := val + tolerance; return f_min(val, max); } /* return a template of (val-tolerance .. val+tolerance) ensuring it is within (min .. max) */ private function f_tolerance(integer val, integer min, integer max, integer tolerance) return template integer { var template integer ret; ret := (f_tolerance_neg(val, min, tolerance) .. f_tolerance_pos(val, max, tolerance)); return ret; } /* build a template for matching measurement results against */ private function f_build_meas_res_tmpl() runs on ConnHdlr return template RSL_Message { var ConnL1Pars l1p := g_pars.l1_pars; var template RSL_IE_UplinkMeas ul_meas := { len := 3, rfu := '0'B, dtx_d := l1p.dtx_enabled, rxlev_f_u := f_tolerance(l1p.meas_ul.full.rxlev, 0, 63, mp_tolerance_rxlev), reserved1 := '00'B, rxlev_s_u := f_tolerance(l1p.meas_ul.sub.rxlev, 0, 63, mp_tolerance_rxlev), reserved2 := '00'B, rxq_f_u := f_tolerance(l1p.meas_ul.full.rxqual, 0, 7, mp_tolerance_rxqual), rxq_s_u := f_tolerance(l1p.meas_ul.sub.rxqual, 0, 7, mp_tolerance_rxqual), supp_meas_info := omit }; if (l1p.toa256_enabled) { ul_meas.len := 5; ul_meas.supp_meas_info := int2oct(l1p.timing_offset_256syms, 2); } /* HACK HACK HACK FIXME HACK HACK HACK see https://osmocom.org/issues/2988 */ ul_meas.rxlev_f_u := ?; ul_meas.rxlev_s_u := ?; ul_meas.rxq_f_u := ?; ul_meas.rxq_s_u := ?; var template RSL_IE_BS_Power bs_power := { reserved := 0, epc := false, fpc := false, power_level := l1p.bs_power_level }; var template RSL_IE_L1Info l1_info := { ms_power_lvl := l1p.ms_power_level, fpc := false, reserved := 0, actual_ta := l1p.ms_actual_ta }; var uint8_t offs := toffs256s_to_rsl(l1p.timing_offset_256syms); var template uint8_t t_toffs := (offs-1 .. offs+1); /* some tolerance */ return tr_RSL_MEAS_RES_OSMO(g_chan_nr, g_next_meas_res_nr, ul_meas, bs_power, l1_info, ?, t_toffs); } /* verify we regularly receive measurement reports with incrementing numbers */ altstep as_meas_res() runs on ConnHdlr { var RSL_Message rsl; [] RSL.receive(f_build_meas_res_tmpl()) -> value rsl { /* increment counter of next to-be-expected meas rep */ g_next_meas_res_nr := (g_next_meas_res_nr + 1) mod 256; /* Re-start the timer expecting the next MEAS RES */ f_timer_safe_restart(g_Tmeas_exp); repeat; } [] RSL.receive(tr_RSL_MEAS_RES(g_chan_nr, g_next_meas_res_nr)) -> value rsl { /* increment counter of next to-be-expected meas rep */ g_next_meas_res_nr := (g_next_meas_res_nr + 1) mod 256; if (g_first_meas_res) { g_first_meas_res := false; repeat; } else { setverdict(fail, "Received unspecific MEAS RES ", rsl); self.stop; } } [] RSL.receive(tr_RSL_MEAS_RES(?)) -> value rsl { setverdict(fail, "Received unexpected MEAS RES ", rsl); self.stop; } [] g_Tmeas_exp.timeout { setverdict(fail, "Didn't receive expected measurement result") self.stop; } } /* Establish dedicated channel: L1CTL + RSL side */ private function f_est_dchan() runs on ConnHdlr { var GsmFrameNumber fn; var ImmediateAssignment imm_ass; var integer ra := 23; fn := f_L1CTL_RACH(L1CTL, ra); /* This arrives on CCHAN, so we cannot test for receiving CHAN RQDhere */ //RSL.receive(tr_RSL_CHAN_RQD(int2oct(23,1))); /* Activate channel on BTS side */ f_rsl_chan_act(g_pars.chan_mode); /* Send IMM.ASS via CCHAN */ var ChannelDescription ch_desc := { chan_nr := g_pars.chan_nr, tsc := 7, h := false, arfcn := mp_trx0_arfcn, maio_hsn := omit }; var MobileAllocation ma := { len := 0, ma := ''B }; var GsmRrMessage rr_msg := valueof(ts_IMM_ASS(ra, fn, 0, ch_desc, ma)); RSL.send(ts_RSL_IMM_ASSIGN(enc_GsmRrMessage(rr_msg))); /* receive IMM.ASS on MS side */ var ImmediateAssignment ia_um; ia_um := f_L1CTL_WAIT_IMM_ASS(L1CTL, ra, fn); /* enable dedicated mode */ f_L1CTL_DM_EST_REQ_IA(L1CTL, ia_um); g_first_meas_res := true; } /* establish DChan, verify existance + contents of measurement reports */ function f_TC_meas_res_periodic(charstring id) runs on ConnHdlr { f_l1_tune(L1CTL); RSL.clear; if (mp_bb_trxc_port != -1) { g_pars.l1_pars.meas_ul.full.rxlev := dbm2rxlev(-100); f_trxc_fake_rssi(100); g_pars.l1_pars.timing_offset_256syms := 512; /* 2 symbols */ f_trx_fake_toffs256(g_pars.l1_pars.timing_offset_256syms); } else { g_pars.l1_pars.timing_offset_256syms := 0; /* FIXME */ g_pars.l1_pars.meas_ul.full.rxlev := dbm2rxlev(-55); /* FIXME */ } g_pars.l1_pars.meas_ul.sub.rxlev := g_pars.l1_pars.meas_ul.full.rxlev; f_est_dchan(); /* run for a number of seconds, send SACCH + FACCH from MS side and verify * RSL measurement reports on Abis side */ timer T := 8.0; T.start; alt { [] as_l1_sacch(); [] as_meas_res(); [] as_l1_dcch(); [] L1CTL.receive { repeat; } [g_Tmeas_exp.running] T.timeout { /* as_meas_res() would have done setverdict(fail) / self.stop in case * of any earlier errors, so if we reach this timeout, we're good */ setverdict(pass); } [] T.timeout { setverdict(fail, "No MEAS RES received at all"); } } f_rsl_chan_deact(); f_L1CTL_DM_REL_REQ(L1CTL, g_chan_nr); } testcase TC_meas_res_sign_tchf() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); for (var integer tn := 1; tn <= 4; tn := tn+1) { pars := valueof(t_Pars(t_RslChanNr_Bm(tn), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_meas_res_periodic), pars); vc_conn.done; } f_shutdown(); } testcase TC_meas_res_sign_tchh() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); for (var integer ss := 0; ss <= 1; ss := ss+1) { pars := valueof(t_Pars(t_RslChanNr_Lm(5, ss), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_meas_res_periodic), pars); vc_conn.done; } f_shutdown(); } testcase TC_meas_res_sign_sdcch4() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); for (var integer ss := 0; ss <= 3; ss := ss+1) { pars := valueof(t_Pars(t_RslChanNr_SDCCH4(0, ss), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_meas_res_periodic), pars); vc_conn.done; } f_shutdown(); } testcase TC_meas_res_sign_sdcch8() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); for (var integer ss := 0; ss <= 7; ss := ss+1) { pars := valueof(t_Pars(t_RslChanNr_SDCCH8(6, ss), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_meas_res_periodic), pars); vc_conn.done; } f_shutdown(); } testcase TC_meas_res_sign_tchh_toa256() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); f_vty_config(BTSVTY, "bts 0", "supp-meas-info toa256"); for (var integer ss := 0; ss <= 1; ss := ss+1) { pars := valueof(t_Pars(t_RslChanNr_Lm(5, ss), ts_RSL_ChanMode_SIGN)); pars.l1_pars.toa256_enabled := true; vc_conn := f_start_handler(refers(f_TC_meas_res_periodic), pars); vc_conn.done; } f_shutdown(); } /* Test if a channel without valid uplink bursts generates RSL CONN FAIL IND */ private function f_TC_conn_fail_crit(charstring id) runs on ConnHdlr { f_l1_tune(L1CTL); RSL.clear; f_est_dchan(); f_sleep(2.0); L1CTL.send(ts_L1CTL_DM_REL_REQ(g_chan_nr)); timer T := 40.0; T.start; alt { [] RSL.receive(tr_RSL_CONN_FAIL_IND(g_chan_nr, ?)) { setverdict(pass) } [] RSL.receive { repeat }; [] T.timeout { setverdict(fail, "No CONN FAIL IND received"); } } f_rsl_chan_deact(); } testcase TC_conn_fail_crit() runs on test_CT { var ConnHdlr vc_conn; var ConnHdlrPars pars; f_init(testcasename()); pars := valueof(t_Pars(t_RslChanNr_SDCCH8(6, 3), ts_RSL_ChanMode_SIGN)); pars.t_guard := 60.0; vc_conn := f_start_handler(refers(f_TC_conn_fail_crit), pars); vc_conn.done; } /*********************************************************************** * Paging ***********************************************************************/ function tmsi_is_dummy(TMSIP_TMSI_V tmsi) return boolean { if (tmsi == 'FFFFFFFF'O) { return true; } else { return false; } } altstep as_l1_count_paging(inout integer num_paging_rcv_msgs, inout integer num_paging_rcv_ids) runs on test_CT { var L1ctlDlMessage dl; [] L1CTL.receive(tr_L1CTL_DATA_IND(t_RslChanNr_PCH_AGCH(0), ?, c_DummyUI)) { repeat; } [] L1CTL.receive(tr_L1CTL_DATA_IND(t_RslChanNr_PCH_AGCH(0))) -> value dl { var octetstring without_plen := substr(dl.payload.data_ind.payload, 1, lengthof(dl.payload.data_ind.payload)-1); var PDU_ML3_NW_MS rr := dec_PDU_ML3_NW_MS(without_plen); if (match(rr, tr_PAGING_REQ1)) { num_paging_rcv_msgs := num_paging_rcv_msgs + 1; num_paging_rcv_ids := num_paging_rcv_ids + 1; if (isvalue(rr.msgs.rrm.pagingReq_Type1.mobileIdentity2)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } } else if (match(rr, tr_PAGING_REQ2)) { num_paging_rcv_msgs := num_paging_rcv_msgs + 1; if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type2.mobileIdentity1)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type2.mobileIdentity2)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } if (isvalue(rr.msgs.rrm.pagingReq_Type2.mobileIdentity3)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } } else if (match(rr, tr_PAGING_REQ3)) { num_paging_rcv_msgs := num_paging_rcv_msgs + 1; if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type3.mobileIdentity1)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type3.mobileIdentity2)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type3.mobileIdentity3)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } if (not tmsi_is_dummy(rr.msgs.rrm.pagingReq_Type3.mobileIdentity4)) { num_paging_rcv_ids := num_paging_rcv_ids + 1; } } repeat; } } type record PagingTestCfg { boolean combined_ccch, integer bs_ag_blks_res, float load_factor, boolean exp_load_ind, boolean exp_overload, boolean use_tmsi } type record PagingTestState { integer num_paging_sent, integer num_paging_rcv_msgs, integer num_paging_rcv_ids, integer num_overload } /* receive + ignore RSL RF RES IND */ altstep as_rsl_res_ind() runs on test_CT { [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_RF_RES_IND)) { repeat; } } /* Helper function for paging related testing */ private function f_TC_paging(PagingTestCfg cfg) runs on test_CT return PagingTestState { f_init(testcasename()); f_init_l1ctl(); f_l1_tune(L1CTL); var PagingTestState st := { num_paging_sent := 0, num_paging_rcv_msgs := 0, num_paging_rcv_ids := 0, num_overload := 0 }; var float max_pch_blocks_per_sec := f_pch_block_rate_est(cfg.combined_ccch, cfg.bs_ag_blks_res); var float max_pch_imsi_per_sec; if (cfg.use_tmsi) { max_pch_imsi_per_sec := max_pch_blocks_per_sec * 4.0; /* Type 3 */ } else { max_pch_imsi_per_sec := max_pch_blocks_per_sec * 2.0; /* Type 1 */ } var float pch_blocks_per_sec := max_pch_imsi_per_sec * cfg.load_factor; var float interval := 1.0 / pch_blocks_per_sec; log("pch_blocks_per_sec=", pch_blocks_per_sec, " interval=", interval); for (var integer i := 0; i < float2int(20.0/interval); i := i+1) { /* build mobile Identity */ var MobileL3_CommonIE_Types.MobileIdentityLV mi; if (cfg.use_tmsi) { mi := valueof(ts_MI_TMSI_LV(f_rnd_octstring(4))); } else { mi := valueof(ts_MI_IMSI_LV(f_gen_imsi(i))); } var octetstring mi_enc_lv := enc_MobileIdentityLV(mi); var octetstring mi_enc := substr(mi_enc_lv, 1, lengthof(mi_enc_lv)-1); /* Send RSL PAGING COMMAND */ RSL_CCHAN.send(ts_RSL_UD(ts_RSL_PAGING_CMD(mi_enc, i mod 4))); st.num_paging_sent := st.num_paging_sent + 1; /* Wait for interval to next PAGING COMMAND */ timer T_itv := interval; T_itv.start; alt { /* check for presence of CCCH LOAD IND (paging load) */ [cfg.exp_overload] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_PAGING_LOAD_IND(0))) { st.num_overload := st.num_overload + 1; repeat; } [not cfg.exp_overload] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_PAGING_LOAD_IND(0))) { setverdict(fail, "Unexpected PCH Overload"); } [cfg.exp_load_ind] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_PAGING_LOAD_IND)) { log("Rx LOAD_IND"); /* FIXME: analyze/verify interval + contents */ repeat; } /* check if paging requests arrive on Um side */ [] as_l1_count_paging(st.num_paging_rcv_msgs, st.num_paging_rcv_ids); [] L1CTL.receive { repeat; } [] T_itv.timeout { } [] as_rsl_res_ind(); } } /* wait for max 18s for paging queue to drain (size: 200, ~ 13 per s -> 15s) */ timer T_wait := 18.0; T_wait.start; alt { [] as_l1_count_paging(st.num_paging_rcv_msgs, st.num_paging_rcv_ids); [] L1CTL.receive { repeat; } /* 65535 == empty paging queue, we can terminate*/ [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_PAGING_LOAD_IND(65535))) { } [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_PAGING_LOAD_IND)) { repeat; } [] T_wait.timeout { setverdict(fail, "Waiting for empty paging queue"); } [] as_rsl_res_ind(); } f_shutdown(); log("num_paging_sent=", st.num_paging_sent, " rcvd_msgs=", st.num_paging_rcv_msgs, " rcvd_ids=", st.num_paging_rcv_ids); return st; } /* Create ~ 80% paging load (IMSI only) sustained for about 20s, verifying that * - the number of Mobile Identities on Um PCH match the number of pages on RSL * - that CCCH LOAD IND (PCH) are being generated * - that CCCH LOAD IND (PCH) [no load] is received after paging flood is over */ testcase TC_paging_imsi_80percent() runs on test_CT { var PagingTestCfg cfg := { combined_ccch := true, bs_ag_blks_res := 1, load_factor := 0.8, exp_load_ind := true, exp_overload := false, use_tmsi := false }; var PagingTestState st := f_TC_paging(cfg); if (st.num_paging_sent != st.num_paging_rcv_ids) { setverdict(fail, "Expected ", st.num_paging_sent, " pagings but have ", st.num_paging_rcv_ids); } else { setverdict(pass); } } /* Create ~ 80% paging load (TMSI only) sustained for about 20s, verifying that * - the number of Mobile Identities on Um PCH match the number of pages on RSL * - that CCCH LOAD IND (PCH) are being generated * - that CCCH LOAD IND (PCH) [no load] is received after paging flood is over */ testcase TC_paging_tmsi_80percent() runs on test_CT { var PagingTestCfg cfg := { combined_ccch := true, bs_ag_blks_res := 1, load_factor := 0.8, exp_load_ind := true, exp_overload := false, use_tmsi := true }; var PagingTestState st := f_TC_paging(cfg); if (st.num_paging_sent != st.num_paging_rcv_ids) { setverdict(fail, "Expected ", st.num_paging_sent, " pagings but have ", st.num_paging_rcv_ids); } else { setverdict(pass); } } /* Create ~ 200% paging load (IMSI only) sustained for about 20s, verifying that * - the number of Mobile Identities on Um PCH are ~ 82% of the number of pages on RSL * - that CCCH LOAD IND (PCH) are being generated and reach 0 at some point * - that CCCH LOAD IND (PCH) [no load] is received after paging flood is over */ testcase TC_paging_imsi_200percent() runs on test_CT { var PagingTestCfg cfg := { combined_ccch := true, bs_ag_blks_res := 1, load_factor := 2.0, exp_load_ind := true, exp_overload := true, use_tmsi := false }; var PagingTestState st := f_TC_paging(cfg); /* We expect about 80-85% to pass, given that we can fill the paging buffer of 200 * slots and will fully drain that buffer before returning */ var template integer tpl := (st.num_paging_sent*80/100 .. st.num_paging_sent *85/100); if (not match(st.num_paging_rcv_ids, tpl)) { setverdict(fail, "Expected ", tpl, " pagings but have ", st.num_paging_rcv_ids); } else { setverdict(pass); } } /* Create ~ 200% paging load (TMSI only) sustained for about 20s, verifying that * - the number of Mobile Identities on Um PCH are ~ 82% of the number of pages on RSL * - that CCCH LOAD IND (PCH) are being generated and reach 0 at some point * - that CCCH LOAD IND (PCH) [no load] is received after paging flood is over */ testcase TC_paging_tmsi_200percent() runs on test_CT { var PagingTestCfg cfg := { combined_ccch := true, bs_ag_blks_res := 1, load_factor := 2.0, exp_load_ind := true, exp_overload := true, use_tmsi := true }; var PagingTestState st := f_TC_paging(cfg); /* We expect about 70% to pass, given that we can fill the paging buffer of 200 * slots and will fully drain that buffer before returning */ var template integer tpl := (st.num_paging_sent*68/100 .. st.num_paging_sent *72/100); if (not match(st.num_paging_rcv_ids, tpl)) { setverdict(fail, "Expected ", tpl, " pagings but have ", st.num_paging_rcv_ids); } else { setverdict(pass); } } /*********************************************************************** * Immediate Assignment / AGCH ***********************************************************************/ testcase TC_imm_ass() runs on test_CT { f_init(testcasename()); for (var integer i := 0; i < 1000; i := i+1) { var octetstring ia_enc := f_rnd_octstring(8); RSL_CCHAN.send(ts_RSL_UD(ts_RSL_IMM_ASSIGN(ia_enc, 0))); f_sleep(0.02); } /* FIXME: check if imm.ass arrive on Um side */ /* FIXME: check for DELETE INDICATION */ f_sleep(100.0); f_shutdown(); } /*********************************************************************** * BCCH ***********************************************************************/ /* tuple of Frame Number + decoded SI */ type record SystemInformationFn { GsmFrameNumber frame_number, SystemInformation si } /* an arbitrary-length vector of decoded SI + gsmtap header */ type record of SystemInformationFn SystemInformationVector; /* an array of SI-vectors indexed by TC value */ type SystemInformationVector SystemInformationVectorPerTc[8]; /* determine if a given SI vector contains given SI type at least once */ function f_si_vecslot_contains(SystemInformationVector arr, RrMessageType key, boolean bcch_ext := false) return boolean { for (var integer i:= 0; i< sizeof(arr); i := i + 1) { var integer fn_mod51 := arr[i].frame_number mod 51; if (not bcch_ext and fn_mod51 == 2 or bcch_ext and fn_mod51 == 6) { if (arr[i].si.header.message_type == key) { return true; } } } return false; } /* ensure a given TC slot of the SI vector contains given SI type at least once at TC */ function f_ensure_si_vec_contains(SystemInformationVectorPerTc arr, integer tc, RrMessageType key, boolean ext_bcch := false) { if (not f_si_vecslot_contains(arr[tc], key, ext_bcch)) { setverdict(fail, "No ", key, " in TC=", tc, "!"); } } /* check if a given SI vector contains given SI type at least once on any TC */ function f_si_vec_contains(SystemInformationVectorPerTc arr, RrMessageType key) return boolean { for (var integer tc:= 0; tc < sizeof(arr); tc := tc + 1) { if (f_si_vecslot_contains(arr[tc], key) or f_si_vecslot_contains(arr[tc], key, true)) { return true; } } return false; } /* determine if a given SI vector contains given SI type at least N of M times */ function f_si_vecslot_contains_n_of_m(SystemInformationVector arr, RrMessageType key, boolean bcch_ext := false, integer n := 1, integer m := 4) return boolean { var integer count := 0; if (sizeof(arr) < m) { setverdict(fail, "Error: Insufficient SI in array"); self.stop; } for (var integer i:= 0; i < m; i := i + 1) { var integer fn_mod51 := arr[i].frame_number mod 51; if (not bcch_ext and fn_mod51 == 2 or bcch_ext and fn_mod51 == 6) { if (arr[i].si.header.message_type == key) { count := count + 1; } } } if (count >= n) { return true; } else { return false; } } /* ensure a given TC slot of the SI vector contains given SI type at least N out of M times at TC */ function f_ensure_si_vec_contains_n_of_m(SystemInformationVectorPerTc arr, integer tc, RrMessageType key, boolean ext_bcch := false, integer n, integer m) { if (not f_si_vecslot_contains_n_of_m(arr[tc], key, ext_bcch, n, m)) { setverdict(fail, "Not ", n, "/", m, " of ", key, " in TC=", tc, "!"); } } /* determine if a given SI vector contains given SI type at least once */ function f_si_vecslot_contains_only(SystemInformationVector arr, RrMessageType key, boolean bcch_ext := false) return boolean { for (var integer i:= 0; i< sizeof(arr); i := i + 1) { var integer fn_mod51 := arr[i].frame_number mod 51; if (not bcch_ext and fn_mod51 == 2 or bcch_ext and fn_mod51 == 6) { if (arr[i].si.header.message_type != key) { return false; } } } return true; } /* ensure a given TC slot of the SI vector contains only given SI type */ function f_ensure_si_vec_contains_only(SystemInformationVectorPerTc arr, integer tc, RrMessageType key, boolean ext_bcch := false) { if (not f_si_vecslot_contains_only(arr[tc], key, ext_bcch)) { setverdict(fail, "Not all ", key, " in TC=", tc, "!"); } } /* SI configuration of cell, against which we validate actual SI messages */ type set SystemInformationConfig { boolean bcch_extended, boolean si1_present, boolean si2bis_present, boolean si2ter_present, boolean si2quater_present, boolean si7_present, boolean si8_present, boolean si9_present, boolean si13_present, boolean si13alt_present, boolean si15_present, boolean si16_present, boolean si17_present, boolean si2n_present, boolean si21_present, boolean si22_present } /* validate the SI scheduling according to TS 45.002 version 14.1.0 Release 14, Section 6.3.1.3 */ function f_validate_si_scheduling(SystemInformationConfig cfg, SystemInformationVectorPerTc si_per_tc) { var integer i; for (i := 0; i < sizeof(si_per_tc); i := i + 1) { if (sizeof(si_per_tc[i]) == 0) { setverdict(fail, "No SI messages for TC=", i); } } if (cfg.si1_present) { /* ii) System Information Type 1 needs to be sent if frequency hopping is in use or * when the NCH is present in a cell. If the MS finds another message on BCCH Norm * when TC = 0, it can assume that System Information Type 1 is not in use. */ f_ensure_si_vec_contains(si_per_tc, 0, SYSTEM_INFORMATION_TYPE_1); /* make sure *ALL* contain SI1 */ f_ensure_si_vec_contains_only(si_per_tc, 0, SYSTEM_INFORMATION_TYPE_1); } f_ensure_si_vec_contains(si_per_tc, 1, SYSTEM_INFORMATION_TYPE_2); /* iii) A SI 2 message will be sent at least every time TC = 1 */ f_ensure_si_vec_contains(si_per_tc, 2, SYSTEM_INFORMATION_TYPE_3); f_ensure_si_vec_contains(si_per_tc, 6, SYSTEM_INFORMATION_TYPE_3); f_ensure_si_vec_contains(si_per_tc, 3, SYSTEM_INFORMATION_TYPE_4); f_ensure_si_vec_contains(si_per_tc, 7, SYSTEM_INFORMATION_TYPE_4); /* iii) System information type 2 bis or 2 ter messages are sent if needed, as determined by the * system operator. If only one of them is needed, it is sent when TC = 5. If both are * needed, 2bis is sent when TC = 5 and 2ter is sent at least once within any of 4 * consecutive occurrences of TC = 4. */ if (cfg.si2bis_present and not cfg.si2ter_present) { f_ensure_si_vec_contains(si_per_tc, 5, SYSTEM_INFORMATION_TYPE_2bis); } else if (cfg.si2ter_present and not cfg.si2bis_present) { f_ensure_si_vec_contains(si_per_tc, 5, SYSTEM_INFORMATION_TYPE_2ter); } else if (cfg.si2ter_present and cfg.si2bis_present) { f_ensure_si_vec_contains(si_per_tc, 5, SYSTEM_INFORMATION_TYPE_2bis); f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_2ter, false, 1, 4); } if (cfg.si7_present or cfg.si8_present) { /* vi) Use of System Information type 7 and 8 is not always necessary. It is necessary * if System Information type 4 does not contain all information needed for cell * selection and reselection. */ if (not cfg.bcch_extended) { testcase.stop("Error: SI7/SI8 require BCCH Extd."); } if (cfg.si7_present) { f_ensure_si_vec_contains(si_per_tc, 7, SYSTEM_INFORMATION_TYPE_7, true); } if (cfg.si8_present) { f_ensure_si_vec_contains(si_per_tc, 3, SYSTEM_INFORMATION_TYPE_8, true); } } if (cfg.si2quater_present) { /* iii) System information type 2 quater is sent if needed, as determined by the system * operator. If sent on BCCH Norm, it shall be sent when TC = 5 if neither of 2bis * and 2ter are used, otherwise it shall be sent at least once within any of 4 * consecutive occurrences of TC = 4. If sent on BCCH Ext, it is sent at least once * within any of 4 consecutive occurrences of TC = 5. */ if (not (cfg.bcch_extended)) { if (not (cfg.si2bis_present or cfg.si2ter_present)) { f_ensure_si_vec_contains(si_per_tc, 5, SYSTEM_INFORMATION_TYPE_2quater); } else { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_2quater, false, 1, 4); } } else { f_ensure_si_vec_contains_n_of_m(si_per_tc, 5, SYSTEM_INFORMATION_TYPE_2quater, true, 1, 4); } } if (cfg.si9_present) { /* vi) System Information type 9 is sent in those blocks with TC = 4 which are specified * in system information type 3 as defined in 3GPP TS 44.018. */ f_ensure_si_vec_contains(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_9); // FIXME SI3 } if (cfg.si13_present) { /* vii) System Information type 13 is only related to the GPRS service. System Information * Type 13 need only be sent if GPRS support is indicated in one or more of System * Information Type 3 or 4 or 7 or 8 messages. These messages also indicate if the * message is sent on the BCCH Norm or if the message is transmitted on the BCCH Ext. * In the case that the message is sent on the BCCH Norm, it is sent at least once * within any of 4 consecutive occurrences of TC=4. */ if (not cfg.bcch_extended) { log("not-bccch-extended"); f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_13, false, 1, 4); } else { log("bccch-extended"); f_ensure_si_vec_contains(si_per_tc, 0, SYSTEM_INFORMATION_TYPE_13, true); } if (f_si_vec_contains(si_per_tc, SYSTEM_INFORMATION_TYPE_13alt)) { setverdict(fail, "Cannot have SI13alt and SI13"); } } if (cfg.si16_present or cfg.si17_present) { /* viii) System Information type 16 and 17 are only related to the SoLSA service. They * should not be sent in a cell where network sharing is used (see rule xv). */ if (cfg.si22_present) { testcase.stop("Error: Cannot have SI16/SI17 and SI22!"); } if (f_si_vec_contains(si_per_tc, SYSTEM_INFORMATION_TYPE_22)) { setverdict(fail, "Cannot have SI16/SI17 and SI22!"); } if (not cfg.bcch_extended) { testcase.stop("Error: SI16/SI17 requires BCCH Extd!"); } if (cfg.si16_present) { f_ensure_si_vec_contains(si_per_tc, 6, SYSTEM_INFORMATION_TYPE_16, true); } if (cfg.si17_present) { f_ensure_si_vec_contains(si_per_tc, 2, SYSTEM_INFORMATION_TYPE_17, true); } } /* ix) System Information type 18 and 20 are sent in order to transmit non-GSM * broadcast information. The frequency with which they are sent is determined by the * system operator. System Information type 9 identifies the scheduling of System * Information type 18 and 20 messages. */ /* x) System Information Type 19 is sent if COMPACT neighbours exist. If System * Information Type 19 is present, then its scheduling shall be indicated in System * Information Type 9. */ if (cfg.si15_present) { /* xi) System Information Type 15 is broadcast if dynamic ARFCN mapping is used in the * PLMN. If sent on BCCH Norm, it is sent at least once within any of 4 consecutive * occurrences of TC = 4. If sent on BCCH Ext, it is sent at least once within any of * 4 consecutive occurrences of TC = 1. */ if (not cfg.bcch_extended) { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_15, false, 1, 4); } else { f_ensure_si_vec_contains_n_of_m(si_per_tc, 1, SYSTEM_INFORMATION_TYPE_15, true, 1, 4); } } if (cfg.si13alt_present) { /* xii) System Information type 13 alt is only related to the GERAN Iu mode. System * Information Type 13 alt need only be sent if GERAN Iu mode support is indicated in * one or more of System Information Type 3 or 4 or 7 or 8 messages and SI 13 is not * broadcast. These messages also indicate if the message is sent on the BCCH Norm or * if the message is transmitted on the BCCH Ext. In the case that the message is sent * on the BCCH Norm, it is sent at least once within any of 4 consecutive occurrences * of TC = 4. */ if (cfg.si13_present) { testcase.stop("Error: Cannot have SI13alt and SI13"); } if (f_si_vec_contains(si_per_tc, SYSTEM_INFORMATION_TYPE_13)) { setverdict(fail, "Cannot have SI13alt and SI13"); } if (not cfg.bcch_extended) { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_13alt, false, 1, 4); } else { f_ensure_si_vec_contains(si_per_tc, 0, SYSTEM_INFORMATION_TYPE_13alt, true); } } if (cfg.si2n_present) { /* xiii) System Information Type 2n is optionally sent on BCCH Norm or BCCH Ext if needed, * as determined by the system operator. In the case that the message is sent on the * BCCH Norm, it is sent at least once within any of 4 consecutive occurrences of TC = * 4. If the message is sent on BCCH Ext, it is sent at least once within any of 2 * consecutive occurrences of TC = 4. */ if (not cfg.bcch_extended) { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_2n, false, 1, 4); } else { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_2n, true, 2, 4); } } if (cfg.si21_present) { /* xiv) System Information Type 21 is optionally sent on BCCH Norm or BCCH Ext, as * determined by the system operator. If Extended Access Barring is in use in the cell * then this message is sent at least once within any of 4 consecutive occurrences of * TC = 4 regardless if it is sent on BCCH Norm or BCCH Ext. If BCCH Ext is used in a * cell then this message shall only be sent on BCCH Ext. */ if (not cfg.bcch_extended) { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_21, false, 1, 4); } else { f_ensure_si_vec_contains_n_of_m(si_per_tc, 4, SYSTEM_INFORMATION_TYPE_21, true, 1, 4); if (f_si_vecslot_contains(si_per_tc[4], SYSTEM_INFORMATION_TYPE_21)) { setverdict(fail, "Cannot have SI21 on BCCH Norm if BCCH Extd enabled!"); } } } if (cfg.si22_present) { /* xv) System Information Type 22 is sent if network sharing is in use in the cell. It * should not be sent in a cell where SoLSA is used (see rule viii). System * Information Type 22 instances shall be sent on BCCH Ext within any occurrence of TC * =2 and TC=6. */ if (cfg.si16_present or cfg.si17_present) { testcase.stop("Error: Cannot have SI16/SI17 and SI22!"); } if (f_si_vec_contains(si_per_tc, SYSTEM_INFORMATION_TYPE_16) or f_si_vec_contains(si_per_tc, SYSTEM_INFORMATION_TYPE_17)) { setverdict(fail, "Cannot have SI16/SI17 and SI22!"); } if (not cfg.bcch_extended) { testcase.stop("Error: SI22 requires BCCH Extd!"); } else { f_ensure_si_vec_contains_only(si_per_tc, 2, SYSTEM_INFORMATION_TYPE_22, true); f_ensure_si_vec_contains_only(si_per_tc, 6, SYSTEM_INFORMATION_TYPE_22, true); } } } /* sample Systme Information for specified duration via L1CTL */ function f_l1_sample_si(L1CTL_PT pt, float duration := 8.0) return SystemInformationVectorPerTc { timer T := duration; var SystemInformationVectorPerTc si_per_tc; var L1ctlDlMessage l1_dl; /* initialize all per-TC vectors empty */ for (var integer i:= 0; i < sizeof(si_per_tc); i := i+1) { si_per_tc[i] := {}; } /* flush all previous L1 queued msgs */ pt.clear; T.start; alt { [] pt.receive(tr_L1CTL_DATA_IND(t_RslChanNr_BCCH(0), ?)) -> value l1_dl { /* somehow dec_SystemInformation will try to decode even non-RR as SI */ if (not (l1_dl.payload.data_ind.payload[1] == '06'O)) { log("Ignoring non-RR SI ", l1_dl); repeat; } var SystemInformationFn sig := { frame_number := l1_dl.dl_info.frame_nr, si := dec_SystemInformation(l1_dl.payload.data_ind.payload) } var integer tc := f_gsm_compute_tc(sig.frame_number); log("SI received at TC=", tc, ": ", sig.si); /* append to the per-TC bucket */ si_per_tc[tc] := si_per_tc[tc] & { sig }; repeat; } [] pt.receive { repeat; } [] T.timeout { } } for (var integer i:= 0; i < sizeof(si_per_tc); i := i+1) { log(testcasename(), ": TC=", i, " has #of SI=", sizeof(si_per_tc[i])); } log("si_per_tc=", si_per_tc); return si_per_tc; } /* helper function: Set given SI via RSL + validate scheduling. * CALLER MUST MAKE SURE TO CHANGE GLOBAL si_cfg! */ function f_TC_si_sched() runs on test_CT { var SystemInformationVectorPerTc si_per_tc; f_init_l1ctl(); f_l1_tune(L1CTL); /* Sample + Validate Scheduling */ si_per_tc := f_l1_sample_si(L1CTL); f_validate_si_scheduling(si_cfg, si_per_tc); setverdict(pass); } testcase TC_si_sched_default() runs on test_CT { f_init(); /* 2+3+4 are mandatory and set in f_init() */ f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_1() runs on test_CT { f_init(); si_cfg.si1_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_1, '5506198fb38000000000000000000000000000e504002b'O); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_2bis() runs on test_CT { f_init(); si_cfg.si2bis_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2bis, '550602bfe809b3ff00000000000000000000007900002b'O); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_2ter() runs on test_CT { f_init(); si_cfg.si2ter_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2ter, '010603bf66b0aa0a00000002000000000000002b2b2b2b'O); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_2ter_2bis() runs on test_CT { f_init(); si_cfg.si2bis_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2bis, '550602bfe809b3ff00000000000000000000007900002b'O); si_cfg.si2ter_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2ter, '010603bf66b0aa0a00000002000000000000002b2b2b2b'O); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_2quater() runs on test_CT { f_init(); si_cfg.si2quater_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2quater, '050607a8a0364aa698d72ff424feee0506d5e7fff02043'O); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_13() runs on test_CT { f_init(); si_cfg.si13_present := true; //f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_13, fixme); f_TC_si_sched(); f_shutdown(); } testcase TC_si_sched_13_2bis_2ter_2quater() runs on test_CT { f_init(); si_cfg.si2bis_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2bis, '550602bfe809b3ff00000000000000000000007900002b'O); si_cfg.si2ter_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2ter, '010603bf66b0aa0a00000002000000000000002b2b2b2b'O); si_cfg.si2quater_present := true; f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_2quater, '050607a8a0364aa698d72ff424feee0506d5e7fff02043'O); si_cfg.si13_present := true; //f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_13, fixme); f_TC_si_sched(); f_shutdown(); } testcase TC_bcch_info() runs on test_CT { f_init(testcasename()); /* FIXME: enable / disable individual BCCH info */ //ts_RSL_BCCH_INFO(si_type, info); /* expect no ERROR REPORT after either of them * /* negative test: ensure ERROR REPORT on unsupported types */ f_shutdown(); } /*********************************************************************** * Low-Level Protocol Errors / ERROR REPORT ***********************************************************************/ private function f_exp_err_rep(template RSL_Cause cause) runs on test_CT { timer T := 5.0; T.start; alt { [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_ERROR_REPORT(cause))) { setverdict(pass); } [] RSL_CCHAN.receive(tr_RSL_UD(tr_RSL_ERROR_REPORT(?))) { setverdict(fail, "Wrong cause in RSL ERR REP"); } [] RSL_CCHAN.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for RSL ERR REP"); } } } /* Provoke a protocol error (message too short) and match on ERROR REPORT */ testcase TC_rsl_protocol_error() runs on test_CT { f_init(testcasename()); var RSL_Message rsl := valueof(ts_RSL_BCCH_INFO(RSL_SYSTEM_INFO_1, ''O)); rsl.ies := omit; RSL_CCHAN.send(ts_RSL_UD(rsl)); f_exp_err_rep(RSL_ERR_PROTO); } /* Provoke a mandatory IE error and match on ERROR REPORT */ testcase TC_rsl_mand_ie_error() runs on test_CT { f_init(testcasename()); var RSL_Message rsl := valueof(ts_RSL_BCCH_INFO(RSL_SYSTEM_INFO_1, ''O)); rsl.ies := { rsl.ies[0] }; RSL_CCHAN.send(ts_RSL_UD(rsl)); f_exp_err_rep(RSL_ERR_MAND_IE_ERROR); } /* Provoke an IE content error and match on ERROR REPORT */ testcase TC_rsl_ie_content_error() runs on test_CT { f_init(testcasename()); var RSL_Message rsl := valueof(ts_RSL_BCCH_INFO(RSL_SYSTEM_INFO_1, ''O)); rsl.ies[1].body.sysinfo_type := RSL_SYSTEM_INFO_5; RSL_CCHAN.send(ts_RSL_UD(rsl)); f_exp_err_rep(RSL_ERR_IE_CONTENT); } /*********************************************************************** * IPA CRCX/MDCX/DLCS media stream handling ***********************************************************************/ /* Send IPA DLCX to inactive lchan */ function f_TC_ipa_dlcx_not_active(charstring id) runs on ConnHdlr { f_rsl_transceive(ts_RSL_IPA_DLCX(g_chan_nr, 0), tr_RSL_IPA_DLCX_ACK(g_chan_nr, ?, ?), "IPA DLCX ACK"); } testcase TC_ipa_dlcx_not_active() runs on test_CT { var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(testcasename()); var ConnHdlr vc_conn := f_start_handler(refers(f_TC_ipa_dlcx_not_active), pars); vc_conn.done; } /* Send IPA CRCX twice to inactive lchan */ function f_TC_ipa_crcx_twice_not_active(charstring id) runs on ConnHdlr { f_rsl_transceive(ts_RSL_IPA_CRCX(g_chan_nr), tr_RSL_IPA_CRCX_ACK(g_chan_nr, ?, ?, ?), "IPA CRCX ACK"); f_rsl_transceive(ts_RSL_IPA_CRCX(g_chan_nr), tr_RSL_IPA_CRCX_NACK(g_chan_nr, RSL_ERR_RES_UNAVAIL), "IPA CRCX NACK"); } testcase TC_ipa_crcx_twice_not_active() runs on test_CT { var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(testcasename()); var ConnHdlr vc_conn := f_start_handler(refers(f_TC_ipa_crcx_twice_not_active), pars); vc_conn.done; } /* Regular sequence of CRCX/MDCX/DLCX */ function f_TC_ipa_crcx_mdcx_dlcx_not_active(charstring id) runs on ConnHdlr { f_rsl_transceive(ts_RSL_IPA_CRCX(g_chan_nr), tr_RSL_IPA_CRCX_ACK(g_chan_nr, ?, ?, ?), "IPA CRCX ACK"); var uint32_t remote_ip := f_rnd_int(c_UINT32_MAX); var uint16_t remote_port := f_rnd_int(c_UINT16_MAX); var uint7_t rtp_pt2 := f_rnd_int(127); var uint16_t fake_conn_id := 23; /* we're too lazy to read it out from the CRCX ACK above */ f_rsl_transceive(ts_RSL_IPA_MDCX(g_chan_nr, fake_conn_id, remote_ip, remote_port, rtp_pt2), tr_RSL_IPA_MDCX_ACK(g_chan_nr, ?, ?, ?, rtp_pt2), "IPA MDCX ACK"); f_rsl_transceive(ts_RSL_IPA_DLCX(g_chan_nr, fake_conn_id), tr_RSL_IPA_DLCX_ACK(g_chan_nr, ?, ?), "IPA DLCX ACK"); } testcase TC_ipa_crcx_mdcx_dlcx_not_active() runs on test_CT { var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(testcasename()); var ConnHdlr vc_conn := f_start_handler(refers(f_TC_ipa_crcx_mdcx_dlcx_not_active), pars); vc_conn.done; } /* Sequence of CRCX, 2x MDCX, DLCX */ function f_TC_ipa_crcx_mdcx_mdcx_dlcx_not_active(charstring id) runs on ConnHdlr { f_rsl_transceive(ts_RSL_IPA_CRCX(g_chan_nr), tr_RSL_IPA_CRCX_ACK(g_chan_nr, ?, ?, ?), "IPA CRCX ACK"); var uint32_t remote_ip := f_rnd_int(c_UINT32_MAX); var uint16_t remote_port := f_rnd_int(c_UINT16_MAX); var uint7_t rtp_pt2 := f_rnd_int(127); var uint16_t fake_conn_id := 23; /* we're too lazy to read it out from the CRCX ACK above */ f_rsl_transceive(ts_RSL_IPA_MDCX(g_chan_nr, fake_conn_id, remote_ip, remote_port, rtp_pt2), tr_RSL_IPA_MDCX_ACK(g_chan_nr, ?, ?, ?, rtp_pt2), "IPA MDCX ACK"); /* Second MDCX */ remote_ip := f_rnd_int(c_UINT32_MAX); remote_port := f_rnd_int(c_UINT16_MAX); f_rsl_transceive(ts_RSL_IPA_MDCX(g_chan_nr, fake_conn_id, remote_ip, remote_port, rtp_pt2), tr_RSL_IPA_MDCX_ACK(g_chan_nr, ?, ?, ?, rtp_pt2), "IPA MDCX ACK"); f_rsl_transceive(ts_RSL_IPA_DLCX(g_chan_nr, fake_conn_id), tr_RSL_IPA_DLCX_ACK(g_chan_nr, ?, ?), "IPA DLCX ACK"); } testcase TC_ipa_crcx_mdcx_mdcx_dlcx_not_active() runs on test_CT { var ConnHdlrPars pars := valueof(t_Pars(t_RslChanNr_Bm(1), ts_RSL_ChanMode_SIGN)); f_init(testcasename()); var ConnHdlr vc_conn := f_start_handler(refers(f_TC_ipa_crcx_mdcx_mdcx_dlcx_not_active), pars); vc_conn.done; } /* IPA CRCX on SDCCH/4 and SDCCH/8 (doesn't make sense) */ function f_TC_ipa_crcx_sdcch_not_active(charstring id) runs on ConnHdlr { f_rsl_transceive(ts_RSL_IPA_CRCX(g_chan_nr), tr_RSL_IPA_CRCX_NACK(g_chan_nr, ?), "IPA CRCX NACK"); } testcase TC_ipa_crcx_sdcch_not_active() runs on test_CT { var ConnHdlrPars pars; var ConnHdlr vc_conn; f_init(testcasename()); pars := valueof(t_Pars(t_RslChanNr_SDCCH4(0,1), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_ipa_crcx_sdcch_not_active), pars); vc_conn.done; pars := valueof(t_Pars(t_RslChanNr_SDCCH8(6,5), ts_RSL_ChanMode_SIGN)); vc_conn := f_start_handler(refers(f_TC_ipa_crcx_sdcch_not_active), pars); vc_conn.done; } /*********************************************************************** * PCU Socket related tests ***********************************************************************/ private function f_TC_pcu_act_req(uint8_t bts_nr, uint8_t trx_nr, uint8_t ts_nr, boolean exp_success) runs on test_CT { timer T := 3.0; /* we don't expect any RTS.req before PDCH are active */ T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ(bts_nr))) { setverdict(fail, "PCU RTS.req before PDCH active?"); self.stop; } [] PCU.receive { repeat; } [] T.timeout { } } /* Send PDCH activate request for known PDCH timeslot */ PCU.send(t_SD_PCUIF(g_pcu_conn_id, ts_PCUIF_ACT_REQ(bts_nr, trx_nr, ts_nr))); /* we now expect RTS.req for this timeslot (only) */ T.start; alt { [exp_success] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ(bts_nr, trx_nr, ts_nr))) { setverdict(pass); } [not exp_success] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ(bts_nr, trx_nr, ts_nr))) { setverdict(fail, "Unexpected RTS.req for supposedly failing activation"); self.stop; } [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ)) { setverdict(fail, "RTS.req for wrong TRX/TS"); self.stop; } [] PCU.receive { repeat; } [exp_success] T.timeout { setverdict(fail, "Timeout waiting for PCU RTS.req"); } [not exp_success] T.timeout { setverdict(pass); } } } private function f_TC_pcu_deact_req(uint8_t bts_nr, uint8_t trx_nr, uint8_t ts_nr) runs on test_CT { timer T := 3.0; /* Send PDCH activate request for known PDCH timeslot */ PCU.send(t_SD_PCUIF(g_pcu_conn_id, ts_PCUIF_DEACT_REQ(bts_nr, trx_nr, ts_nr))); PCU.clear; /* we now expect no RTS.req for this timeslot */ T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ(bts_nr, trx_nr, ts_nr))) { setverdict(fail, "Received unexpected PCU RTS.req"); self.stop; } [] PCU.receive { repeat; } [] T.timeout { setverdict(pass); } } } /* PDCH activation via PCU socket; check for presence of RTS.req */ testcase TC_pcu_act_req() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); } /* PDCH activation via PCU socket on non-PDCU timeslot */ testcase TC_pcu_act_req_wrong_ts() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 1, false); } /* PDCH activation via PCU socket on wrong BTS */ testcase TC_pcu_act_req_wrong_bts() runs on test_CT { f_init(); f_TC_pcu_act_req(23, 0, 7, false); } /* PDCH activation via PCU socket on wrong TRX */ testcase TC_pcu_act_req_wrong_trx() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 23, 7, false); } /* PDCH deactivation via PCU socket; check for absence of RTS.req */ testcase TC_pcu_deact_req() runs on test_CT { f_init(); /* Activate PDCH */ f_TC_pcu_act_req(0, 0, 7, true); f_sleep(1.0); /* and De-Activate again */ f_TC_pcu_deact_req(0, 0, 7); } /* Attempt to deactivate a PDCH on a non-PDCH timeslot */ testcase TC_pcu_deact_req_wrong_ts() runs on test_CT { f_init(); f_TC_pcu_deact_req(0, 0, 1); } /* Test the PCU->BTS Version and BTS->PCU SI13 handshake */ testcase TC_pcu_ver_si13() runs on test_CT { const octetstring si13 := '00010203040506070909'O; var PCUIF_send_data sd; timer T:= 3.0; f_init(); /* Set SI13 via RSL */ f_rsl_bcch_fill_raw(RSL_SYSTEM_INFO_13, si13); PCU.send(t_SD_PCUIF(g_pcu_conn_id, ts_PCUIF_TXT_IND(0, PCU_VERSION, "BTS_Test v23"))); T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_DATA_IND(0, 0, 0, ?, PCU_IF_SAPI_BCCH))) -> value sd { if (substr(sd.data.u.data_ind.data, 0, lengthof(si13)) == si13) { setverdict(pass); } else { repeat; } } [] PCU.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for SI13"); self.stop; } } } private const octetstring c_PCU_DATA := '000102030405060708090a0b0c0d0e0f10111213141516'O; /* helper function to send a PCU DATA.req */ private function f_pcu_data_req(uint8_t bts_nr, uint8_t trx_nr, uint8_t ts_nr, uint8_t block_nr, uint32_t fn, PCUIF_Sapi sapi, octetstring data) runs on test_CT { PCU.send(t_SD_PCUIF(g_pcu_conn_id, ts_PCUIF_DATA_REQ(bts_nr, trx_nr, ts_nr, block_nr, fn, sapi, data))); } /* helper function to wait for RTS.ind for given SAPI on given BTS/TRX/TS and then send */ private function f_pcu_wait_rts_and_data_req(uint8_t bts_nr, uint8_t trx_nr, uint8_t ts_nr, PCUIF_Sapi sapi, octetstring data) runs on test_CT { var PCUIF_send_data sd; timer T := 3.0; T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RTS_REQ(bts_nr, trx_nr, ts_nr, sapi))) -> value sd { f_pcu_data_req(bts_nr, trx_nr, ts_nr, sd.data.u.rts_req.block_nr, sd.data.u.rts_req.fn, sapi, data); } [] PCU.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for RTS.ind"); } } } /* Send DATA.req on invalid BTS */ testcase TC_pcu_data_req_wrong_bts() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_data_req(23, 0, 7, 0, 0, PCU_IF_SAPI_PDTCH, c_PCU_DATA); /* FIXME: how to check this wasn't actually sent and didn't crash BTS? */ f_sleep(10.0); } /* Send DATA.req on invalid TRX */ testcase TC_pcu_data_req_wrong_trx() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_data_req(0, 100, 7, 0, 0, PCU_IF_SAPI_PDTCH, c_PCU_DATA); /* FIXME: how to check this wasn't actually sent and didn't crash BTS? */ f_sleep(10.0); } /* Send DATA.req on invalid timeslot */ testcase TC_pcu_data_req_wrong_ts() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_data_req(0, 0, 70, 0, 0, PCU_IF_SAPI_PDTCH, c_PCU_DATA); /* FIXME: how to check this wasn't actually sent and didn't crash BTS? */ f_sleep(10.0); } /* Send DATA.req on timeslot that hasn't been activated */ testcase TC_pcu_data_req_ts_inactive() runs on test_CT { f_init(); f_pcu_data_req(0, 0, 7, 0, 0, PCU_IF_SAPI_PDTCH, c_PCU_DATA); /* FIXME: how to check this wasn't actually sent and didn't crash BTS? */ f_sleep(2.0); } testcase TC_pcu_data_req_pdtch() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_wait_rts_and_data_req(0, 0, 7, PCU_IF_SAPI_PDTCH, c_PCU_DATA); /* FIXME: how to check this was actually sent */ f_sleep(2.0); } testcase TC_pcu_data_req_ptcch() runs on test_CT { f_init(); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_wait_rts_and_data_req(0, 0, 7, PCU_IF_SAPI_PTCCH, c_PCU_DATA); /* FIXME: how to check this was actually sent */ f_sleep(2.0); } /* Send AGCH from PCU; check it appears on Um side */ testcase TC_pcu_data_req_agch() runs on test_CT { timer T := 3.0; f_init(); f_init_l1ctl(); f_l1_tune(L1CTL); f_TC_pcu_act_req(0, 0, 7, true); f_pcu_data_req(0, 0, 7, 0, 0, PCU_IF_SAPI_AGCH, c_PCU_DATA); T.start; alt { [] L1CTL.receive(tr_L1CTL_DATA_IND(t_RslChanNr_PCH_AGCH(0), ?, c_PCU_DATA)) { setverdict(pass); } [] L1CTL.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for PCU-originated AGCH block on Um"); } } } /* Send IMM.ASS from PCU for PCH; check it appears on Um side */ testcase TC_pcu_data_req_imm_ass_pch() runs on test_CT { var octetstring imm_ass := f_rnd_octstring(23); f_init(); f_init_l1ctl(); f_l1_tune(L1CTL); /* append 3 last imsi digits so BTS can compute pagng group */ var uint32_t fn := f_PCUIF_tx_imm_ass_pch(PCU, g_pcu_conn_id, imm_ass, '123459987'H); timer T := 0.5; T.start; alt { [] L1CTL.receive(tr_L1CTL_DATA_IND(t_RslChanNr_PCH_AGCH(0), ?, imm_ass)) { /* TODO: verify paging group */ setverdict(pass); } [] L1CTL.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for PCU-originated AGCH block on Um"); } } } /* Send RACH from Um side, expect it to show up on PCU socket */ testcase TC_pcu_rach_content() runs on test_CT { f_init(); f_init_l1ctl(); f_l1_tune(L1CTL); var GsmFrameNumber fn_last := 0; for (var integer i := 0; i < 1000; i := i+1) { var OCT1 ra := f_rnd_ra_ps(); var GsmFrameNumber fn := f_L1CTL_RACH(L1CTL, oct2int(ra)); if (fn == fn_last) { setverdict(fail, "Two RACH in same FN?!?"); self.stop; } fn_last := fn; timer T := 2.0; T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RACH_IND(0, oct2int(ra), 0, ?, fn))) { T.stop; } [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_RACH_IND)) { setverdict(fail, "Unexpected RACH IND"); self.stop; } [] PCU.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for RACH IND"); self.stop; } } } setverdict(pass); } private function f_pad_oct(octetstring str, integer len, OCT1 pad) return octetstring { var integer strlen := lengthof(str); for (var integer i := 0; i < len-strlen; i := i+1) { str := str & pad; } return str; } /* Send PAGING via RSL, expect it to shw up on PCU socket */ testcase TC_pcu_paging_from_rsl() runs on test_CT { f_init(); for (var integer i := 0; i < 100; i := i+1) { var MobileL3_CommonIE_Types.MobileIdentityLV mi; timer T := 3.0; if (i < 50) { mi := valueof(ts_MI_TMSI_LV(f_rnd_octstring(4))); } else { mi := valueof(ts_MI_IMSI_LV(f_gen_imsi(i))); } var octetstring mi_enc_lv := enc_MobileIdentityLV(mi); var octetstring mi_enc := substr(mi_enc_lv, 1, lengthof(mi_enc_lv)-1); var octetstring t_mi_lv := f_pad_oct(mi_enc_lv, 9, '00'O); /* Send RSL PAGING COMMAND */ RSL_CCHAN.send(ts_RSL_UD(ts_RSL_PAGING_CMD(mi_enc, i mod 4))); T.start; alt { [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_PAG_REQ(0, t_mi_lv))) { } [] PCU.receive(t_SD_PCUIF(g_pcu_conn_id, tr_PCUIF_PAG_REQ)) { setverdict(fail, "Unexpected PAGING REQ"); self.stop; } [] PCU.receive { repeat; } [] T.timeout { setverdict(fail, "Timeout waiting for PAGING REQ"); self.stop; } } } setverdict(pass); } /* TODO Areas: * channel activation ** with BS_Power / MS_Power, bypassing power control loop ** on primary vs. secondary TRX ** with encryption from initial activation on ** with timing advance from initial activation on * mode modify ** encryption ** multirate * check DEACTIVATE SACCH * encryption command / intricate logic about tx-only/tx+rx/... ** unsupported algorithm * handover detection * MS Power Control * BS Power Control * Physical Context * SACCH info modify * CCCH Load Indication for PCH and RACH * Delete Indication on AGCH overflow * SMS Broadcast Req / Cmd / CBCH LOad Ind * RF resource ind * error handling * discriminator error ** type error ** sequence error ** IE duplicated? * PCU interface ** TIME_IND from BTS->PCU ** DATA_IND from BTS->PCU ** verification of PCU-originated DATA_REQ arrival on Um/MS side */ control { execute( TC_chan_act_stress() ); execute( TC_chan_act_react() ); execute( TC_chan_deact_not_active() ); execute( TC_chan_act_wrong_nr() ); execute( TC_deact_sacch() ); execute( TC_sacch_filling() ); execute( TC_sacch_info_mod() ); execute( TC_sacch_multi() ); execute( TC_sacch_multi_chg() ); execute( TC_rach_content() ); execute( TC_rach_count() ); execute( TC_rach_max_ta() ); execute( TC_meas_res_sign_tchf() ); execute( TC_meas_res_sign_tchh() ); execute( TC_meas_res_sign_sdcch4() ); execute( TC_meas_res_sign_sdcch8() ); execute( TC_meas_res_sign_tchh_toa256() ); execute( TC_conn_fail_crit() ); execute( TC_paging_imsi_80percent() ); execute( TC_paging_tmsi_80percent() ); execute( TC_paging_imsi_200percent() ); execute( TC_paging_tmsi_200percent() ); execute( TC_rsl_protocol_error() ); execute( TC_rsl_mand_ie_error() ); execute( TC_rsl_ie_content_error() ); execute( TC_si_sched_default() ); execute( TC_si_sched_1() ); execute( TC_si_sched_2bis() ); execute( TC_si_sched_2ter() ); execute( TC_si_sched_2ter_2bis() ); execute( TC_si_sched_2quater() ); execute( TC_si_sched_13() ); execute( TC_si_sched_13_2bis_2ter_2quater() ); execute( TC_ipa_dlcx_not_active() ); execute( TC_ipa_crcx_twice_not_active() ); execute( TC_ipa_crcx_mdcx_dlcx_not_active() ); execute( TC_ipa_crcx_mdcx_mdcx_dlcx_not_active() ); execute( TC_ipa_crcx_sdcch_not_active() ); execute( TC_pcu_act_req() ); execute( TC_pcu_act_req_wrong_ts() ); execute( TC_pcu_act_req_wrong_bts() ); execute( TC_pcu_act_req_wrong_trx() ); execute( TC_pcu_deact_req() ); execute( TC_pcu_deact_req_wrong_ts() ); execute( TC_pcu_ver_si13() ); execute( TC_pcu_data_req_wrong_bts() ); execute( TC_pcu_data_req_wrong_trx() ); execute( TC_pcu_data_req_wrong_ts() ); execute( TC_pcu_data_req_ts_inactive() ); execute( TC_pcu_data_req_pdtch() ); execute( TC_pcu_data_req_ptcch() ); execute( TC_pcu_data_req_agch() ); execute( TC_pcu_data_req_imm_ass_pch() ); execute( TC_pcu_rach_content() ); execute( TC_pcu_paging_from_rsl() ); } }