module PCUIF_Components { /* * Components for (RAW) PCU test cases. * * (C) 2019 Vadim Yanitskiy * * All rights reserved. * * Released under the terms of GNU General Public License, Version 2 or * (at your option) any later version. * * SPDX-License-Identifier: GPL-2.0-or-later */ import from IPL4asp_Types all; import from UD_Types all; import from PCUIF_Types all; import from PCUIF_CodecPort all; /* Component communication diagram: * * +-----+ +----------+ +---------+ * | MTC +---------------+ PCUIF_CT +------+ OsmoPCU | * +--+--+ +----+-----+ +---------+ * | | * | | * | | * | +-----------+ | +---------------+ * +----+ BTS_CT #1 +------+ | ClckGen_CT #1 | * | +-----+-----+ | +-------+-------+ * | | | | * | +---------------------------+ * | | * | +-----------+ | +---------------+ * +----+ BTS_CT #2 +------+ | ClckGen_CT #2 | * | +-----+-----+ | +-------+-------+ * | | | | * | +---------------------------+ * | | * | +-----------+ | +---------------+ * +----+ BTS_CT #N +------+ | ClckGen_CT #N | * +-----+-----+ +-------+-------+ * | | * +---------------------------+ */ /* Events are used by the components to indicate that something * has happened, e.g. we have got a connection from the PCU. */ type enumerated RAW_PCU_EventType { /* Events related to RAW_PCUIF_CT */ PCU_EV_DISCONNECT, /*!< OsmoPCU has disconnected */ PCU_EV_CONNECT, /*!< OsmoPCU is now connected */ /* Events related to RAW_PCU_BTS_CT */ BTS_EV_SI13_NEGO, /*!< SI13 negotiation complete */ /* TDMA clock related events (TDMA frame-number in parameters) */ TDMA_EV_PDTCH_BLOCK_BEG, /*!< 1/4 bursts of a PDTCH block on both Uplink and Downlink */ TDMA_EV_PDTCH_BLOCK_END, /*!< 4/4 bursts of a PDTCH block on both Uplink and Downlink */ TDMA_EV_PTCCH_DL_BLOCK, /*!< 4/4 bursts of a PTCCH block on Downlink */ TDMA_EV_PTCCH_UL_BURST, /*!< One Access Burst on PTCCH/U */ TDMA_EV_PDTCH_BLOCK_SENT /*!< A PDTCH block has been sent to the PCU */ }; /* Union of all possible parameters of the events */ type union RAW_PCU_EventParam { integer tdma_fn }; type record RAW_PCU_Event { RAW_PCU_EventType event, /* TODO: can we use 'anytype' here? */ RAW_PCU_EventParam data optional }; template (value) RAW_PCU_Event ts_RAW_PCU_EV(RAW_PCU_EventType event) := { event := event, data := omit } template RAW_PCU_Event tr_RAW_PCU_EV(template RAW_PCU_EventType event := ?, template RAW_PCU_EventParam data := *) := { event := event, data := data } template (value) RAW_PCU_Event ts_RAW_PCU_CLCK_EV(RAW_PCU_EventType event, integer fn) := { event := event, data := { tdma_fn := fn } } template RAW_PCU_Event tr_RAW_PCU_CLCK_EV := { event := (TDMA_EV_PDTCH_BLOCK_BEG, TDMA_EV_PDTCH_BLOCK_END, TDMA_EV_PTCCH_DL_BLOCK, TDMA_EV_PTCCH_UL_BURST, TDMA_EV_PDTCH_BLOCK_SENT), data := { tdma_fn := ? } } /* Commands are mostly used by the MTC to configure the components * at run-time, e.g. to enable or disable some optional features. */ type enumerated RAW_PCU_CommandType { GENERAL_CMD_SHUTDOWN, /*!< Shut down component and all its child components */ TDMA_CMD_ENABLE_PTCCH_UL_FWD /*!< Enable forwarding of TDMA_EV_PTCCH_UL_BURST to the MTC */ }; type record RAW_PCU_Command { RAW_PCU_CommandType cmd, anytype data optional }; template (value) RAW_PCU_Command ts_RAW_PCU_CMD(RAW_PCU_CommandType cmd) := { cmd := cmd, data := omit } template RAW_PCU_Command tr_RAW_PCU_CMD(template RAW_PCU_CommandType cmd := ?, template anytype data := *) := { cmd := cmd, data := data } /* Generic port for messages and events */ type port RAW_PCU_MSG_PT message { inout RAW_PCU_Command; inout RAW_PCU_Event; inout PCUIF_Message; } with { extension "internal" }; /* TDMA frame clock generator */ type component RAW_PCU_ClckGen_CT { /* One TDMA frame is 4.615 ms long */ timer T_TDMAClock := 4.615 / 1000.0; port RAW_PCU_MSG_PT CLCK; var integer fn := 0; } /* Derive PTCCH/U sub-slot from a given TDMA frame-number */ function f_tdma_ptcch_fn2ss(integer fn) return integer { var integer ss := -1; /* See 3GPP TS 45.002, table 6 */ select (fn mod 416) { case (12) { ss := 0; } case (38) { ss := 1; } case (64) { ss := 2; } case (90) { ss := 3; } case (116) { ss := 4; } case (142) { ss := 5; } case (168) { ss := 6; } case (194) { ss := 7; } case (220) { ss := 8; } case (246) { ss := 9; } case (272) { ss := 10; } case (298) { ss := 11; } case (324) { ss := 12; } case (350) { ss := 13; } case (376) { ss := 14; } case (402) { ss := 15; } } return ss; } function f_ClckGen_CT_handler() runs on RAW_PCU_ClckGen_CT { var integer fn104, fn52, fn13; while (true) { fn104 := fn mod 104; fn52 := fn mod 52; fn13 := fn mod 13; if (fn13 == 0 or fn13 == 4 or fn13 == 8) { /* 1/4 bursts of a PDTCH block on both Uplink and Downlink */ CLCK.send(ts_RAW_PCU_CLCK_EV(TDMA_EV_PDTCH_BLOCK_BEG, fn)); } else if (fn13 == 3 or fn13 == 7 or fn13 == 11) { /* 4/4 bursts of a PDTCH block on both Uplink and Downlink */ CLCK.send(ts_RAW_PCU_CLCK_EV(TDMA_EV_PDTCH_BLOCK_END, fn)); } else if (fn52 == 12 or fn52 == 38) { /* 4/4 bursts of a PTCCH (Timing Advance Control) block on Downlink */ if (fn104 == 90) { CLCK.send(ts_RAW_PCU_CLCK_EV(TDMA_EV_PTCCH_DL_BLOCK, fn)); } /* One Access Burst on PTCCH/U (goes 3 time-slots after PTCCH/D) */ CLCK.send(ts_RAW_PCU_CLCK_EV(TDMA_EV_PTCCH_UL_BURST, fn)); } /* TDMA hyperframe period is (2048 * 51 * 26) frames */ fn := (fn + 1) mod (2048 * 51 * 26); /* (Re)start TDMA clock timer and wait */ T_TDMAClock.start; T_TDMAClock.timeout; } } type record of PCUIF_Message PCUIF_MsgQueue; /* Enqueue a given message to the end of a given queue */ private function f_PCUIF_MsgQueue_enqueue(inout PCUIF_MsgQueue queue, in PCUIF_Message msg) { queue := queue & { msg }; } /* Dequeue the first message of a given queue */ private function f_PCUIF_MsgQueue_dequeue(inout PCUIF_MsgQueue queue, out PCUIF_Message msg) { var integer len := lengthof(queue); if (len == 0) { setverdict(fail, "Failed to dequeue a message: the queue is empty!"); mtc.stop; } /* Store the first message */ msg := queue[0]; /* Remove the first message from queue */ if (len > 1) { queue := substr(queue, 1, len - 1); } else { queue := { }; } } /* Get first message from queue. true if non-empty, false otherwise */ private function f_PCUIF_MsgQueue_first(inout PCUIF_MsgQueue queue, out PCUIF_Message msg) return boolean { if (lengthof(queue) == 0) { return false; } msg := queue[0]; return true; } /* Multiple base stations can be connected to the PCU. This component * represents one BTS with an associated TDMA clock generator. */ type component RAW_PCU_BTS_CT { /* TDMA clock generator */ var RAW_PCU_ClckGen_CT vc_CLCK_GEN; port RAW_PCU_MSG_PT CLCK; /* Queues of PCUIF messages to be sent * TODO: we may have multiple PDCH time-slots */ var PCUIF_MsgQueue pdtch_data_queue := { }; var PCUIF_MsgQueue pdtch_rts_queue := { }; var PCUIF_MsgQueue ptcch_rts_queue := { }; /* Connection towards the PCU interface */ port RAW_PCU_MSG_PT PCUIF; /* Connection towards the test case */ port RAW_PCU_MSG_PT TC; /* Whether to forward PTCCH/U burst events to the TC */ var boolean cfg_ptcch_burst_fwd := false; } /* Queue received messages from Test Case, they will eventually be scheduled and * sent according to their FN. FN value of 0 has the special meaning of "schedule * as soon as possible". */ private altstep as_BTS_CT_MsgQueue(integer bts_nr) runs on RAW_PCU_BTS_CT { var PCUIF_Message pcu_msg; /* Enqueue DATA.ind and RTS.req messages */ [] TC.receive(tr_PCUIF_MSG(PCU_IF_MSG_DATA_IND, bts_nr)) -> value pcu_msg { f_PCUIF_MsgQueue_enqueue(pdtch_data_queue, pcu_msg); repeat; } [] TC.receive(tr_PCUIF_RTS_REQ(bts_nr, sapi := PCU_IF_SAPI_PDTCH)) -> value pcu_msg { f_PCUIF_MsgQueue_enqueue(pdtch_rts_queue, pcu_msg); repeat; } [] TC.receive(tr_PCUIF_RTS_REQ(bts_nr, sapi := PCU_IF_SAPI_PTCCH)) -> value pcu_msg { f_PCUIF_MsgQueue_enqueue(ptcch_rts_queue, pcu_msg); repeat; } /* Forward other messages directly to the PCU */ [] TC.receive(tr_PCUIF_MSG(?, bts_nr)) -> value pcu_msg { PCUIF.send(pcu_msg); repeat; } } /* Handle schedule events and manage actions: Send msgs over PCUIF to PCU, * advertise Test Case about sent messages, etc. */ private altstep as_BTS_CT_TDMASched(integer bts_nr) runs on RAW_PCU_BTS_CT { var PCUIF_Message pcu_msg; var RAW_PCU_Event event; var integer ev_begin_fn; var integer next_fn; [] CLCK.receive(tr_RAW_PCU_EV(TDMA_EV_PDTCH_BLOCK_BEG)) -> value event { /* If the RTS queue for PDTCH is not empty, send a message */ if (lengthof(pdtch_rts_queue) > 0) { f_PCUIF_MsgQueue_dequeue(pdtch_rts_queue, pcu_msg); /* Patch TDMA frame / block number and send */ pcu_msg.u.rts_req.fn := event.data.tdma_fn; pcu_msg.u.rts_req.block_nr := 0; /* FIXME! */ PCUIF.send(pcu_msg); } /* We don't really need to send every frame to OsmoPCU, because * it omits frame numbers not starting at a MAC block. */ PCUIF.send(ts_PCUIF_TIME_IND(bts_nr, event.data.tdma_fn)); repeat; } [lengthof(pdtch_data_queue) > 0] CLCK.receive(tr_RAW_PCU_EV(TDMA_EV_PDTCH_BLOCK_END)) -> value event { /* FN matching the beginning of current block: */ ev_begin_fn := event.data.tdma_fn - 3; /* Check if we reached time to serve the first DATA.ind message in the queue: */ f_PCUIF_MsgQueue_first(pdtch_data_queue, pcu_msg); next_fn := pcu_msg.u.data_ind.fn; if (next_fn != 0 and next_fn != ev_begin_fn) { if (next_fn < ev_begin_fn) { setverdict(fail, "We are late scheduling the block! ", next_fn, " < ", ev_begin_fn); mtc.stop; } repeat; } /* Dequeue a DATA.ind message */ f_PCUIF_MsgQueue_dequeue(pdtch_data_queue, pcu_msg); /* Patch TDMA frame / block number */ pcu_msg.u.data_ind.fn := ev_begin_fn; pcu_msg.u.data_ind.block_nr := 0; /* FIXME! */ PCUIF.send(pcu_msg); /* Send to the PCU and notify the TC */ TC.send(ts_RAW_PCU_CLCK_EV(TDMA_EV_PDTCH_BLOCK_SENT, ev_begin_fn)); repeat; } [lengthof(ptcch_rts_queue) > 0] CLCK.receive(tr_RAW_PCU_EV(TDMA_EV_PTCCH_DL_BLOCK)) -> value event { /* FN matching the beginning of current block (PTCCH is interleaved over 4 non-consecutive bursts): */ ev_begin_fn := event.data.tdma_fn - 78; /* Dequeue an RTS.req message for PTCCH */ f_PCUIF_MsgQueue_dequeue(ptcch_rts_queue, pcu_msg); /* Patch TDMA frame / block number and send */ pcu_msg.u.rts_req.fn := ev_begin_fn; pcu_msg.u.rts_req.block_nr := 0; /* FIXME! */ PCUIF.send(pcu_msg); repeat; } /* Optional forwarding of PTCCH/U burst indications to the test case */ [cfg_ptcch_burst_fwd] CLCK.receive(tr_RAW_PCU_EV(TDMA_EV_PTCCH_UL_BURST)) -> value event { TC.send(event); repeat; } /* Ignore other clock events (and guard against an empty queue) */ [] CLCK.receive(tr_RAW_PCU_CLCK_EV) { repeat; } } function f_BTS_CT_handler(integer bts_nr, PCUIF_info_ind info_ind) runs on RAW_PCU_BTS_CT { var PCUIF_Message pcu_msg; var RAW_PCU_Command cmd; var RAW_PCU_Event event; /* Init TDMA clock generator (so we can stop and start it) */ vc_CLCK_GEN := RAW_PCU_ClckGen_CT.create("ClckGen-" & int2str(bts_nr)) alive; connect(vc_CLCK_GEN:CLCK, self:CLCK); /* Wait until the PCU is connected */ PCUIF.receive(tr_RAW_PCU_EV(PCU_EV_CONNECT)); alt { /* Wait for TXT.ind (PCU_VERSION) and respond with INFO.ind (SI13) */ [] PCUIF.receive(tr_PCUIF_TXT_IND(bts_nr, PCU_VERSION, ?)) -> value pcu_msg { log("Rx TXT.ind from the PCU, version is ", pcu_msg.u.txt_ind.text); /* Send System Information 13 to the PCU */ PCUIF.send(PCUIF_Message:{ msg_type := PCU_IF_MSG_INFO_IND, bts_nr := bts_nr, spare := '0000'O, u := { info_ind := info_ind } }); /* Notify the test case that we're done with SI13 */ TC.send(ts_RAW_PCU_EV(BTS_EV_SI13_NEGO)); /* Start feeding clock to the PCU */ vc_CLCK_GEN.start(f_ClckGen_CT_handler()); repeat; } /* PCU -> TS becomes active */ [] PCUIF.receive(tr_PCUIF_ACT_REQ(bts_nr, ?, ?)) -> value pcu_msg { log("Rx ACT.req from the PCU: TRX" & int2str(pcu_msg.u.act_req.trx_nr) & "/TS" & int2str(pcu_msg.u.act_req.ts_nr)); repeat; } /* PCU -> TS becomes inactive */ [] PCUIF.receive(tr_PCUIF_DEACT_REQ(bts_nr, ?, ?)) -> value pcu_msg { log("Rx DEACT.req from the PCU: TRX" & int2str(pcu_msg.u.act_req.trx_nr) & "/TS" & int2str(pcu_msg.u.act_req.ts_nr)); repeat; } /* PCU -> test case forwarding (filter by the BTS number) */ [] PCUIF.receive(tr_PCUIF_MSG(?, bts_nr)) -> value pcu_msg { TC.send(pcu_msg); repeat; } /* TC -> [Queue] -> PCU forwarding */ [] as_BTS_CT_MsgQueue(bts_nr); /* TDMA scheduler (clock and queue handling) */ [] as_BTS_CT_TDMASched(bts_nr); /* Command handling */ [] TC.receive(tr_RAW_PCU_CMD(GENERAL_CMD_SHUTDOWN)) { log("Shutting down virtual BTS #", bts_nr, "..."); vc_CLCK_GEN.stop; break; } [] TC.receive(tr_RAW_PCU_CMD(TDMA_CMD_ENABLE_PTCCH_UL_FWD)) { log("Enabling forwarding of PTCCH/U TDMA events to the TC"); cfg_ptcch_burst_fwd := true; repeat; } [] TC.receive(tr_RAW_PCU_CMD) -> value cmd { log("Ignore unhandled command: ", cmd); repeat; } /* TODO: handle events (e.g. disconnection) from the PCU interface */ [] PCUIF.receive(tr_RAW_PCU_EV) -> value event { log("Ignore unhandled event: ", event); repeat; } } } /* PCU interface (UNIX domain socket) handler */ type component RAW_PCUIF_CT { var ConnectionId g_pcu_conn_id := -1; var boolean g_pcu_connected := false; port PCUIF_CODEC_PT PCU; /* Connection towards BTS component(s) */ port RAW_PCU_MSG_PT BTS; /* Connection to the MTC (test case) */ port RAW_PCU_MSG_PT MTC; }; /* All received messages and events from OsmoPCU can be additionally sent * directly to the MTC component. Pass direct := true to enable this mode. */ function f_PCUIF_CT_handler(charstring pcu_sock_path, boolean direct := false) runs on RAW_PCUIF_CT { var PCUIF_send_data pcu_sd_msg; var PCUIF_Message pcu_msg; timer T_Conn := 10.0; log("Init PCU interface on '" & pcu_sock_path & "', waiting for connection..."); g_pcu_conn_id := f_pcuif_listen(PCU, pcu_sock_path); /* Wait for connection */ T_Conn.start; alt { [not g_pcu_connected] PCU.receive(UD_connected:?) { log("OsmoPCU is now connected"); /* Duplicate this event to the MTC if requested */ if (direct) { MTC.send(ts_RAW_PCU_EV(PCU_EV_CONNECT)); } BTS.send(ts_RAW_PCU_EV(PCU_EV_CONNECT)); g_pcu_connected := true; setverdict(pass); T_Conn.stop; repeat; } /* PCU -> BTS / MTC message forwarding */ [g_pcu_connected] PCU.receive(PCUIF_send_data:?) -> value pcu_sd_msg { /* Send to the BTSes if at least one is connected */ if (BTS.checkstate("Connected")) { BTS.send(pcu_sd_msg.data); } /* Duplicate this message to the MTC if requested */ if (direct) { MTC.send(pcu_sd_msg.data); } repeat; } /* MTC -> PCU message forwarding */ [g_pcu_connected] MTC.receive(PCUIF_Message:?) -> value pcu_msg { PCU.send(t_SD_PCUIF(g_pcu_conn_id, pcu_msg)); repeat; } /* BTS -> PCU message forwarding */ [g_pcu_connected] BTS.receive(PCUIF_Message:?) -> value pcu_msg { PCU.send(t_SD_PCUIF(g_pcu_conn_id, pcu_msg)); repeat; } [not g_pcu_connected] MTC.receive(PCUIF_Message:?) -> value pcu_msg { log("PCU is not connected, dropping ", pcu_msg); repeat; } [not g_pcu_connected] BTS.receive(PCUIF_Message:?) -> value pcu_msg { log("PCU is not connected, dropping ", pcu_msg); repeat; } /* TODO: handle disconnect and reconnect of the PCU */ [] PCU.receive { log("Unhandled message on PCU interface"); repeat; } [not g_pcu_connected] T_Conn.timeout { setverdict(fail, "Timeout waiting for PCU connection"); mtc.stop; } } } }