/* ** Copyright 2017, The Android Open Source Project ** ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** ** http://www.apache.org/licenses/LICENSE-2.0 ** ** Unless required by applicable law or agreed to in writing, software ** distributed under the License ioogle/s distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. */ #include "guest/hals/ril/cuttlefish_ril.h" #include #include #include #include #include #include #include #include #include #include "common/libs/device_config/device_config.h" #include "common/libs/net/netlink_client.h" #include "common/libs/net/network_interface.h" #include "common/libs/net/network_interface_manager.h" #define CUTTLEFISH_RIL_VERSION_STRING "Android Cuttlefish RIL 1.4" /* Modem Technology bits */ #define MDM_GSM 0x01 #define MDM_WCDMA 0x02 #define MDM_CDMA 0x04 #define MDM_EVDO 0x08 #define MDM_LTE 0x10 typedef enum { SIM_ABSENT = 0, SIM_NOT_READY = 1, SIM_READY = 2, // SIM_READY means the radio state is RADIO_STATE_SIM_READY SIM_PIN = 3, SIM_PUK = 4, SIM_NETWORK_PERSONALIZATION = 5, RUIM_ABSENT = 6, RUIM_NOT_READY = 7, RUIM_READY = 8, RUIM_PIN = 9, RUIM_PUK = 10, RUIM_NETWORK_PERSONALIZATION = 11 } SIM_Status; static std::unique_ptr global_ril_config = nullptr; static const struct RIL_Env* gce_ril_env; static const struct timeval TIMEVAL_SIMPOLL = {3, 0}; static time_t gce_ril_start_time; static void pollSIMState(void* param); RIL_RadioState gRadioPowerState = RADIO_STATE_OFF; RIL_RadioAccessFamily default_access = RAF_LTE; struct DataCall { enum AllowedAuthenticationType { kNone = 0, kPap = 1, kChap = 2, kBoth = 3 }; enum ConnectionType { kConnTypeIPv4, kConnTypeIPv6, kConnTypeIPv4v6, kConnTypePPP }; enum LinkState { kLinkStateInactive = 0, kLinkStateDown = 1, kLinkStateUp = 2, }; RIL_RadioTechnology technology_; RIL_DataProfile profile_; std::string access_point_; std::string username_; std::string password_; AllowedAuthenticationType auth_type_; ConnectionType connection_type_; LinkState link_state_; RIL_DataCallFailCause fail_cause_; std::string other_properties_; }; static std::string gSimPIN = "0000"; static const std::string gSimPUK = "11223344"; static int gSimPINAttempts = 0; static const int gSimPINAttemptsMax = 3; static SIM_Status gSimStatus = SIM_NOT_READY; static bool areUiccApplicationsEnabled = true; // SetUpNetworkInterface configures IP and Broadcast addresses on a RIL // controlled network interface. // This call returns true, if operation was successful. bool SetUpNetworkInterface(const char* ipaddr, int prefixlen, const char* bcaddr) { auto factory = cuttlefish::NetlinkClientFactory::Default(); std::unique_ptr nl(factory->New(NETLINK_ROUTE)); std::unique_ptr nm( cuttlefish::NetworkInterfaceManager::New(factory)); std::unique_ptr ni(nm->Open("rmnet0", "eth1")); if (ni) { ni->SetName("rmnet0"); ni->SetAddress(ipaddr); ni->SetBroadcastAddress(bcaddr); ni->SetPrefixLength(prefixlen); ni->SetOperational(true); bool res = nm->ApplyChanges(*ni); if (!res) ALOGE("Could not configure rmnet0"); return res; } return false; } // TearDownNetworkInterface disables network interface. // This call returns true, if operation was successful. bool TearDownNetworkInterface() { auto nm(cuttlefish::NetworkInterfaceManager::New(nullptr)); auto ni(nm->Open("rmnet0", "eth1")); if (ni) { ni->SetOperational(false); bool res = nm->ApplyChanges(*ni); if (!res) ALOGE("Could not disable rmnet0"); return res; } return false; } static int gNextDataCallId = 8; static std::map gDataCalls; static bool gRilConnected = false; static int request_or_send_data_calllist(RIL_Token* t) { RIL_Data_Call_Response_v11* responses = new RIL_Data_Call_Response_v11[gDataCalls.size()]; int index = 0; ALOGV("Query data call list: %zu data calls tracked.", gDataCalls.size()); for (std::map::iterator iter = gDataCalls.begin(); iter != gDataCalls.end(); ++iter, ++index) { responses[index].status = iter->second.fail_cause_; responses[index].suggestedRetryTime = -1; responses[index].cid = iter->first; responses[index].active = iter->second.link_state_; switch (iter->second.connection_type_) { case DataCall::kConnTypeIPv4: responses[index].type = (char*)"IP"; break; case DataCall::kConnTypeIPv6: responses[index].type = (char*)"IPV6"; break; case DataCall::kConnTypeIPv4v6: responses[index].type = (char*)"IPV4V6"; break; case DataCall::kConnTypePPP: responses[index].type = (char*)"PPP"; break; default: responses[index].type = (char*)"IP"; break; } responses[index].ifname = (char*)"rmnet0"; responses[index].addresses = const_cast(global_ril_config->ril_address_and_prefix()); responses[index].dnses = const_cast(global_ril_config->ril_dns()); responses[index].gateways = const_cast(global_ril_config->ril_gateway()); responses[index].pcscf = (char*)""; responses[index].mtu = 1440; } bool new_conn_state = (gDataCalls.size() > 0); if (gRilConnected != new_conn_state) { time_t curr_time; time(&curr_time); double diff_in_secs = difftime(curr_time, gce_ril_start_time); gRilConnected = new_conn_state; if (new_conn_state) { ALOGV("MOBILE_DATA_CONNECTED %.2lf seconds", diff_in_secs); } else { ALOGV("MOBILE_DATA_DISCONNECTED %.2lf seconds", diff_in_secs); } if (property_set("ril.net_connected", new_conn_state ? "1" : "0")) { ALOGE("Couldn't set a system property ril.net_connected."); } } if (t != NULL) { gce_ril_env->OnRequestComplete(*t, RIL_E_SUCCESS, responses, gDataCalls.size() * sizeof(*responses)); } else { gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_DATA_CALL_LIST_CHANGED, responses, gDataCalls.size() * sizeof(*responses)); } delete[] responses; return 0; } static void request_datacall_fail_cause(RIL_Token t) { RIL_DataCallFailCause fail = PDP_FAIL_DATA_REGISTRATION_FAIL; if (gDataCalls.size() > 0) { fail = gDataCalls.rbegin()->second.fail_cause_; } ALOGV("Requesting last data call setup fail cause (%d)", fail); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &fail, sizeof(fail)); }; static void request_data_calllist(void* /*data*/, size_t /*datalen*/, RIL_Token t) { request_or_send_data_calllist(&t); } static void request_setup_data_call(void* data, size_t datalen, RIL_Token t) { char** details = static_cast(data); const size_t fields = datalen / sizeof(details[0]); // There are two different versions of this interface, one providing 7 strings // and the other providing 8. The code below will assume the presence of 7 // strings in all cases, so bail out here if things appear to be wrong. We // protect the 8 string case below. if (fields < 7) { ALOGE("%s returning: called with small datalen %zu", __FUNCTION__, datalen); return; } DataCall call; int tech = atoi(details[0]); switch (tech) { case 0: case 2 + RADIO_TECH_1xRTT: call.technology_ = RADIO_TECH_1xRTT; break; case 1: case 2 + RADIO_TECH_EDGE: call.technology_ = RADIO_TECH_EDGE; break; default: call.technology_ = RIL_RadioTechnology(tech - 2); break; } int profile = atoi(details[1]); call.profile_ = RIL_DataProfile(profile); if (details[2]) call.access_point_ = details[2]; if (details[3]) call.username_ = details[3]; if (details[4]) call.password_ = details[4]; int auth_type = atoi(details[5]); call.auth_type_ = DataCall::AllowedAuthenticationType(auth_type); if (!strcmp("IP", details[6])) { call.connection_type_ = DataCall::kConnTypeIPv4; } else if (!strcmp("IPV6", details[6])) { call.connection_type_ = DataCall::kConnTypeIPv6; } else if (!strcmp("IPV4V6", details[6])) { call.connection_type_ = DataCall::kConnTypeIPv4v6; } else if (!strcmp("PPP", details[6])) { call.connection_type_ = DataCall::kConnTypePPP; } else { ALOGW("Unknown / unsupported connection type %s. Falling back to IPv4", details[6]); call.connection_type_ = DataCall::kConnTypeIPv4; } if (call.connection_type_ != DataCall::kConnTypeIPv4) { ALOGE("Non-IPv4 connections are not supported by Cuttlefish RIL."); gce_ril_env->OnRequestComplete(t, RIL_E_INVALID_ARGUMENTS, NULL, 0); return; } call.link_state_ = DataCall::kLinkStateUp; call.fail_cause_ = PDP_FAIL_NONE; if (fields > 7) { if (details[7]) call.other_properties_ = details[7]; } if (gDataCalls.empty()) { SetUpNetworkInterface(global_ril_config->ril_ipaddr(), global_ril_config->ril_prefixlen(), global_ril_config->ril_broadcast()); } gDataCalls[gNextDataCallId] = call; gNextDataCallId++; ALOGV("Requesting data call setup to APN %s, technology %s, prof %s", details[2], details[0], details[1]); request_or_send_data_calllist(&t); gRilConnected = (gDataCalls.size() > 0); } static void request_teardown_data_call(void* data, size_t /*datalen*/, RIL_Token t) { char** data_strs = (char**)data; int call_id = atoi(data_strs[0]); int reason = atoi(data_strs[1]); ALOGV("Tearing down data call %d, reason: %d", call_id, reason); gDataCalls.erase(call_id); gRilConnected = (gDataCalls.size() > 0); if (!gRilConnected) { TearDownNetworkInterface(); } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void set_radio_state(RIL_RadioState new_state, RIL_Token t) { // From header: // Toggle radio on and off (for "airplane" mode) // If the radio is is turned off/on the radio modem subsystem // is expected return to an initialized state. For instance, // any voice and data calls will be terminated and all associated // lists emptied. gDataCalls.clear(); gSimStatus = SIM_NOT_READY; ALOGV("RIL_RadioState change %d to %d", gRadioPowerState, new_state); gRadioPowerState = new_state; if (new_state == RADIO_STATE_OFF) { TearDownNetworkInterface(); } if (t != NULL) { gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED, NULL, 0); pollSIMState(NULL); } // returns 1 if on, 0 if off, and -1 on error static void request_radio_power(void* data, size_t /*datalen*/, RIL_Token t) { int on = ((int*)data)[0]; set_radio_state(on ? RADIO_STATE_ON : RADIO_STATE_OFF, t); } // TODO(ender): this should be a class member. Move where it belongs. struct CallState { RIL_CallState state; // e.g. RIL_CALL_HOLDING; bool isInternational; bool isMobileTerminated; bool isVoice; bool isMultiParty; std::string number; std::string name; std::string dtmf; bool canPresentNumber; bool canPresentName; CallState() : state(RIL_CallState(0)), isInternational(false), isMobileTerminated(true), isVoice(true), isMultiParty(false), canPresentNumber(true), canPresentName(true) {} CallState(const std::string& number) : state(RIL_CALL_INCOMING), isInternational(false), isMobileTerminated(true), isVoice(true), isMultiParty(false), number(number), name(number), canPresentNumber(true), canPresentName(true) {} bool isBackground() { return state == RIL_CALL_HOLDING; } bool isActive() { return state == RIL_CALL_ACTIVE; } bool isDialing() { return state == RIL_CALL_DIALING; } bool isIncoming() { return state == RIL_CALL_INCOMING; } bool isWaiting() { return state == RIL_CALL_WAITING; } void addDtmfDigit(char c) { dtmf.push_back(c); ALOGV("Call to %s: DTMF %s", number.c_str(), dtmf.c_str()); } bool makeBackground() { if (state == RIL_CALL_ACTIVE) { state = RIL_CALL_HOLDING; return true; } return false; } bool makeActive() { if (state == RIL_CALL_INCOMING || state == RIL_CALL_WAITING || state == RIL_CALL_DIALING || state == RIL_CALL_HOLDING) { state = RIL_CALL_ACTIVE; return true; } return false; } }; static int gLastActiveCallIndex = 1; static int gMicrophoneMute = 0; static std::map gActiveCalls; static void request_get_current_calls(void* /*data*/, size_t /*datalen*/, RIL_Token t) { const int countCalls = gActiveCalls.size(); RIL_Call** pp_calls = (RIL_Call**)alloca(countCalls * sizeof(RIL_Call*)); RIL_Call* p_calls = (RIL_Call*)alloca(countCalls * sizeof(RIL_Call)); memset(p_calls, 0, countCalls * sizeof(RIL_Call)); /* init the pointer array */ for (int i = 0; i < countCalls; i++) { pp_calls[i] = &(p_calls[i]); } // TODO(ender): This should be built from calls requested via RequestDial. for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter, ++p_calls) { p_calls->state = iter->second.state; p_calls->index = iter->first; p_calls->toa = iter->second.isInternational ? 145 : 129; p_calls->isMpty = iter->second.isMultiParty; p_calls->isMT = iter->second.isMobileTerminated; p_calls->als = iter->first; p_calls->isVoice = iter->second.isVoice; p_calls->isVoicePrivacy = 0; p_calls->number = strdup(iter->second.number.c_str()); p_calls->numberPresentation = iter->second.canPresentNumber ? 0 : 1; p_calls->name = strdup(iter->second.name.c_str()); p_calls->namePresentation = iter->second.canPresentName ? 0 : 1; p_calls->uusInfo = NULL; ALOGV("Call to %s (%s): voice=%d mt=%d type=%d state=%d index=%d", p_calls->name, p_calls->number, p_calls->isVoice, p_calls->isMT, p_calls->toa, p_calls->state, p_calls->index); } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, pp_calls, countCalls * sizeof(RIL_Call*)); ALOGV("Get Current calls: %d calls found.\n", countCalls); } static void simulate_pending_calls_answered(void* /*ignore*/) { ALOGV("Simulating outgoing call answered."); // This also resumes held calls. for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { if (iter->second.isDialing()) { iter->second.makeActive(); } } // Only unsolicited here. gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_RESPONSE_CALL_STATE_CHANGED, NULL, 0); } static void request_dial(void* data, size_t /*datalen*/, RIL_Token t) { RIL_Dial* p_dial = (RIL_Dial*)data; ALOGV("Dialing %s, number presentation is %s.", p_dial->address, (p_dial->clir == 0) ? "defined by operator" : (p_dial->clir == 1) ? "allowed" : "restricted"); CallState state(p_dial->address); state.isMobileTerminated = false; state.state = RIL_CALL_DIALING; switch (p_dial->clir) { case 0: // default case 1: // allow state.canPresentNumber = true; break; case 2: // restrict state.canPresentNumber = false; break; } int call_index = gLastActiveCallIndex++; gActiveCalls[call_index] = state; static const struct timeval kAnswerTime = {5, 0}; gce_ril_env->RequestTimedCallback(simulate_pending_calls_answered, NULL, &kAnswerTime); // success or failure is ignored by the upper layer here. // it will call GET_CURRENT_CALLS and determine success that way gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } void request_set_mute(void* data, size_t /*datalen*/, RIL_Token t) { gMicrophoneMute = ((int*)data)[0] != 0; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } void request_get_mute(RIL_Token t) { gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &gMicrophoneMute, sizeof(gMicrophoneMute)); } // TODO(ender): this should be a class member. Move where it belongs. struct SmsMessage { enum SmsStatus { kUnread = 0, kRead = 1, kUnsent = 2, kSent = 3 }; std::string message; SmsStatus status; }; static int gNextMessageId = 1; static std::map gMessagesOnSimCard; static void request_write_sms_to_sim(void* data, size_t /*datalen*/, RIL_Token t) { RIL_SMS_WriteArgs* p_args = (RIL_SMS_WriteArgs*)data; SmsMessage message; message.status = SmsMessage::SmsStatus(p_args->status); message.message = p_args->pdu; ALOGV("Storing SMS message: '%s' with state: %s.", message.message.c_str(), (message.status < SmsMessage::kUnsent) ? ((message.status == SmsMessage::kRead) ? "READ" : "UNREAD") : ((message.status == SmsMessage::kSent) ? "SENT" : "UNSENT")); // TODO(ender): simulate SIM FULL? int index = gNextMessageId++; gMessagesOnSimCard[index] = message; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &index, sizeof(index)); } static void request_delete_sms_on_sim(void* data, size_t /*datalen*/, RIL_Token t) { int index = *(int*)data; ALOGV("Delete SMS message %d", index); if (gMessagesOnSimCard.erase(index) == 0) { // No such message gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); return; } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_hangup(void* data, size_t /*datalen*/, RIL_Token t) { int* p_line = (int*)data; ALOGV("Hanging up call %d.", *p_line); std::map::iterator iter = gActiveCalls.find(*p_line); if (iter == gActiveCalls.end()) { ALOGV("No such call: %d.", *p_line); gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } else { gActiveCalls.erase(iter); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } } static void request_hangup_waiting(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Hanging up background/held calls."); for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end();) { if (iter->second.isBackground()) { // C++98 -- std::map::erase doesn't return iterator. std::map::iterator temp = iter++; gActiveCalls.erase(temp); } else { ++iter; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_hangup_current(RIL_Token t) { ALOGV("Hanging up foreground/active calls."); // This also resumes held calls. for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end();) { if (iter->second.isBackground()) { iter->second.makeActive(); ++iter; } else { // C++98 -- std::map::erase doesn't return iterator. std::map::iterator temp = iter++; gActiveCalls.erase(temp); } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_switch_current_and_waiting(RIL_Token t) { ALOGV("Toggle foreground and background calls."); // TODO(ender): fix all states. Max 2 calls. // BEFORE AFTER // Call 1 Call 2 Call 1 Call 2 // ACTIVE HOLDING HOLDING ACTIVE // ACTIVE WAITING HOLDING ACTIVE // HOLDING WAITING HOLDING ACTIVE // ACTIVE IDLE HOLDING IDLE // IDLE IDLE IDLE IDLE for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { // TODO(ender): call could also be waiting or dialing or... if (iter->second.isBackground()) { iter->second.makeActive(); } else { iter->second.makeBackground(); } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_answer_incoming(RIL_Token t) { ALOGV("Answering incoming call."); // There's two types of incoming calls: // - incoming: we are receiving this call while nothing happens, // - waiting: we are receiving this call while we're already talking. // We only accept the incoming ones. for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { if (iter->second.isIncoming()) { iter->second.makeActive(); } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_combine_multiparty_call(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGW("Combine a held call to conversation."); for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { if (!iter->second.isVoice) { continue; } if (iter->second.isBackground()) { iter->second.makeActive(); break; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_split_multiparty_call(void* data, size_t /*datalen*/, RIL_Token t) { int index = *(int*)data; ALOGW("Hold all active call except given call: %d", index); for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { if (!iter->second.isVoice) { continue; } if (iter->second.isActive() && index != iter->first) { iter->second.makeBackground(); break; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_udub_on_incoming_calls(RIL_Token t) { // UDUB = user determined user busy. // We don't exactly do that. We simply drop these calls. ALOGV("Reporting busy signal to incoming calls."); for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end();) { // If we have an incoming call, there should be no waiting call. // If we have a waiting call, then previous incoming call has been answered. if (iter->second.isIncoming() || iter->second.isWaiting()) { // C++98 -- std::map::erase doesn't return iterator. std::map::iterator temp = iter++; gActiveCalls.erase(temp); } else { ++iter; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_send_dtmf(void* data, size_t /*datalen*/, RIL_Token t) { char c = ((char*)data)[0]; ALOGV("Sending DTMF digit '%c'", c); for (std::map::iterator iter = gActiveCalls.begin(); iter != gActiveCalls.end(); ++iter) { if (iter->second.isActive()) { iter->second.addDtmfDigit(c); break; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_send_dtmf_stop(RIL_Token t) { ALOGV("DTMF tone end."); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } // Check SignalStrength.java file for more details on how these map to signal // strength bars. const int kGatewaySignalStrengthMin = 4; const int kGatewaySignalStrengthMax = 30; const int kCDMASignalStrengthMin = -110; const int kCDMASignalStrengthMax = -60; const int kEVDOSignalStrengthMin = -160; const int kEVDOSignalStrengthMax = -70; const int kLTESignalStrengthMin = 4; const int kLTESignalStrengthMax = 30; static int gGatewaySignalStrength = kGatewaySignalStrengthMax; static int gCDMASignalStrength = kCDMASignalStrengthMax; static int gEVDOSignalStrength = kEVDOSignalStrengthMax; static int gLTESignalStrength = kLTESignalStrengthMax; static void request_signal_strength(void* /*data*/, size_t /*datalen*/, RIL_Token t) { // TODO(ender): possible to support newer APIs here. RIL_SignalStrength_v10 strength; gGatewaySignalStrength += (rand() % 3 - 1); gCDMASignalStrength += (rand() % 3 - 1); gEVDOSignalStrength += (rand() % 3 - 1); gLTESignalStrength += (rand() % 3 - 1); if (gGatewaySignalStrength < kGatewaySignalStrengthMin) gGatewaySignalStrength = kGatewaySignalStrengthMin; if (gGatewaySignalStrength > kGatewaySignalStrengthMax) gGatewaySignalStrength = kGatewaySignalStrengthMax; if (gCDMASignalStrength < kCDMASignalStrengthMin) gCDMASignalStrength = kCDMASignalStrengthMin; if (gCDMASignalStrength > kCDMASignalStrengthMax) gCDMASignalStrength = kCDMASignalStrengthMax; if (gEVDOSignalStrength < kEVDOSignalStrengthMin) gEVDOSignalStrength = kEVDOSignalStrengthMin; if (gEVDOSignalStrength > kEVDOSignalStrengthMax) gEVDOSignalStrength = kEVDOSignalStrengthMax; if (gLTESignalStrength < kLTESignalStrengthMin) gLTESignalStrength = kLTESignalStrengthMin; if (gLTESignalStrength > kLTESignalStrengthMax) gLTESignalStrength = kLTESignalStrengthMax; strength.GW_SignalStrength.signalStrength = gGatewaySignalStrength; strength.GW_SignalStrength.bitErrorRate = 0; // 0..7% strength.CDMA_SignalStrength.dbm = gCDMASignalStrength; strength.CDMA_SignalStrength.ecio = 0; // Ec/Io; keep high to use dbm. strength.EVDO_SignalStrength.dbm = gEVDOSignalStrength; strength.EVDO_SignalStrength.ecio = 0; // Ec/Io; keep high to use dbm. strength.LTE_SignalStrength.signalStrength = gLTESignalStrength; strength.LTE_SignalStrength.rsrp = INT_MAX; // Invalid = Use signalStrength. strength.LTE_SignalStrength.rsrq = INT_MAX; // Invalid = Use signalStrength. strength.LTE_SignalStrength.rssnr = INT_MAX; // Invalid = Use signalStrength. strength.LTE_SignalStrength.cqi = INT_MAX; // Invalid = Use signalStrength. ALOGV("Reporting signal strength: GW=%d CDMA=%d EVDO=%d LTE=%d", gGatewaySignalStrength, gCDMASignalStrength, gEVDOSignalStrength, gLTESignalStrength); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &strength, sizeof(strength)); } static std::map gModemSupportedNetworkTypes; static void init_modem_supported_network_types() { gModemSupportedNetworkTypes[PREF_NET_TYPE_GSM_WCDMA] = MDM_GSM | MDM_WCDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_GSM_ONLY] = MDM_GSM; gModemSupportedNetworkTypes[PREF_NET_TYPE_WCDMA] = MDM_WCDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_GSM_WCDMA_AUTO] = MDM_GSM | MDM_WCDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_CDMA_EVDO_AUTO] = MDM_CDMA | MDM_EVDO; gModemSupportedNetworkTypes[PREF_NET_TYPE_CDMA_ONLY] = MDM_CDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_EVDO_ONLY] = MDM_EVDO; gModemSupportedNetworkTypes[PREF_NET_TYPE_GSM_WCDMA_CDMA_EVDO_AUTO] = MDM_GSM | MDM_WCDMA | MDM_CDMA | MDM_EVDO; gModemSupportedNetworkTypes[PREF_NET_TYPE_LTE_CDMA_EVDO] = MDM_LTE | MDM_CDMA | MDM_EVDO; gModemSupportedNetworkTypes[PREF_NET_TYPE_LTE_GSM_WCDMA] = MDM_LTE | MDM_GSM | MDM_WCDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_LTE_CMDA_EVDO_GSM_WCDMA] = MDM_LTE | MDM_CDMA | MDM_EVDO | MDM_GSM | MDM_WCDMA; gModemSupportedNetworkTypes[PREF_NET_TYPE_LTE_ONLY] = MDM_LTE; } static std::map gModemTechnologies; RIL_RadioTechnology gDataTechnologiesPreferenceOrder[] = { RADIO_TECH_LTE, RADIO_TECH_EHRPD, RADIO_TECH_HSPAP, RADIO_TECH_HSPA, RADIO_TECH_HSDPA, RADIO_TECH_HSUPA, RADIO_TECH_EVDO_B, RADIO_TECH_EVDO_A, RADIO_TECH_EVDO_0, RADIO_TECH_1xRTT, RADIO_TECH_UMTS, RADIO_TECH_EDGE, RADIO_TECH_GPRS}; RIL_RadioTechnology gVoiceTechnologiesPreferenceOrder[] = { RADIO_TECH_LTE, RADIO_TECH_EHRPD, RADIO_TECH_EVDO_B, RADIO_TECH_EVDO_A, RADIO_TECH_EVDO_0, RADIO_TECH_1xRTT, RADIO_TECH_IS95B, RADIO_TECH_IS95A, RADIO_TECH_UMTS, RADIO_TECH_GSM}; static void init_modem_technologies() { gModemTechnologies[PREF_NET_TYPE_GSM_WCDMA] = (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS); gModemTechnologies[PREF_NET_TYPE_GSM_ONLY] = (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE); gModemTechnologies[PREF_NET_TYPE_WCDMA] = (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS); gModemTechnologies[PREF_NET_TYPE_GSM_WCDMA_AUTO] = (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS); gModemTechnologies[PREF_NET_TYPE_CDMA_EVDO_AUTO] = (1 << RADIO_TECH_IS95A) | (1 << RADIO_TECH_IS95B) | (1 << RADIO_TECH_1xRTT) | (1 << RADIO_TECH_EVDO_0) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_HSDPA) | (1 << RADIO_TECH_HSUPA) | (1 << RADIO_TECH_HSPA) | (1 << RADIO_TECH_EVDO_B); gModemTechnologies[PREF_NET_TYPE_CDMA_ONLY] = (1 << RADIO_TECH_IS95A) | (1 << RADIO_TECH_IS95B) | (1 << RADIO_TECH_1xRTT); gModemTechnologies[PREF_NET_TYPE_EVDO_ONLY] = (1 << RADIO_TECH_EVDO_0) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_HSDPA) | (1 << RADIO_TECH_HSUPA) | (1 << RADIO_TECH_HSPA) | (1 << RADIO_TECH_EVDO_B); gModemTechnologies[PREF_NET_TYPE_GSM_WCDMA_CDMA_EVDO_AUTO] = (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS) | (1 << RADIO_TECH_IS95A) | (1 << RADIO_TECH_IS95B) | (1 << RADIO_TECH_1xRTT) | (1 << RADIO_TECH_EVDO_0) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_HSDPA) | (1 << RADIO_TECH_HSUPA) | (1 << RADIO_TECH_HSPA) | (1 << RADIO_TECH_EVDO_B); gModemTechnologies[PREF_NET_TYPE_LTE_CDMA_EVDO] = (1 << RADIO_TECH_HSPAP) | (1 << RADIO_TECH_LTE) | (1 << RADIO_TECH_EHRPD) | (1 << RADIO_TECH_IS95A) | (1 << RADIO_TECH_IS95B) | (1 << RADIO_TECH_1xRTT) | (1 << RADIO_TECH_EVDO_0) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_HSDPA) | (1 << RADIO_TECH_HSUPA) | (1 << RADIO_TECH_HSPA) | (1 << RADIO_TECH_EVDO_B); gModemTechnologies[PREF_NET_TYPE_LTE_GSM_WCDMA] = (1 << RADIO_TECH_HSPAP) | (1 << RADIO_TECH_LTE) | (1 << RADIO_TECH_EHRPD) | (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS); gModemTechnologies[PREF_NET_TYPE_LTE_CMDA_EVDO_GSM_WCDMA] = (1 << RADIO_TECH_HSPAP) | (1 << RADIO_TECH_LTE) | (1 << RADIO_TECH_EHRPD) | (1 << RADIO_TECH_IS95A) | (1 << RADIO_TECH_IS95B) | (1 << RADIO_TECH_1xRTT) | (1 << RADIO_TECH_EVDO_0) | (1 << RADIO_TECH_EVDO_A) | (1 << RADIO_TECH_HSDPA) | (1 << RADIO_TECH_HSUPA) | (1 << RADIO_TECH_HSPA) | (1 << RADIO_TECH_EVDO_B) | (1 << RADIO_TECH_GSM) | (1 << RADIO_TECH_GPRS) | (1 << RADIO_TECH_EDGE) | (1 << RADIO_TECH_UMTS); gModemTechnologies[PREF_NET_TYPE_LTE_ONLY] = (1 << RADIO_TECH_HSPAP) | (1 << RADIO_TECH_LTE) | (1 << RADIO_TECH_EHRPD); } static const RIL_PreferredNetworkType gModemDefaultType = PREF_NET_TYPE_LTE_GSM_WCDMA; static RIL_PreferredNetworkType gModemCurrentType = gModemDefaultType; static RIL_RadioTechnology gModemVoiceTechnology = RADIO_TECH_LTE; // Report technology change. // Select best technology from the list of supported techs. // Demotes RADIO_TECH_GSM as it's voice-only. static RIL_RadioTechnology getBestDataTechnology( RIL_PreferredNetworkType network_type) { RIL_RadioTechnology technology = RADIO_TECH_GPRS; std::map::iterator iter = gModemTechnologies.find(network_type); ALOGV("Searching for best data technology for network type %d...", network_type); // Find which technology bits are lit. Pick the top most. for (size_t tech_index = 0; tech_index < sizeof(gDataTechnologiesPreferenceOrder) / sizeof(gDataTechnologiesPreferenceOrder[0]); ++tech_index) { if (iter->second & (1 << gDataTechnologiesPreferenceOrder[tech_index])) { technology = gDataTechnologiesPreferenceOrder[tech_index]; break; } } ALOGV("Best data technology: %d.", technology); return technology; } static RIL_RadioTechnology getBestVoiceTechnology( RIL_PreferredNetworkType network_type) { RIL_RadioTechnology technology = RADIO_TECH_GSM; std::map::iterator iter = gModemTechnologies.find(network_type); ALOGV("Searching for best voice technology for network type %d...", network_type); // Find which technology bits are lit. Pick the top most. for (size_t tech_index = 0; tech_index < sizeof(gVoiceTechnologiesPreferenceOrder) / sizeof(gVoiceTechnologiesPreferenceOrder[0]); ++tech_index) { if (iter->second & (1 << gVoiceTechnologiesPreferenceOrder[tech_index])) { technology = gVoiceTechnologiesPreferenceOrder[tech_index]; break; } } ALOGV("Best voice technology: %d.", technology); return technology; } static void setRadioTechnology(RIL_PreferredNetworkType network_type) { RIL_RadioTechnology technology = getBestVoiceTechnology(network_type); if (technology != gModemVoiceTechnology) { gModemVoiceTechnology = technology; gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_VOICE_RADIO_TECH_CHANGED, &gModemVoiceTechnology, sizeof(gModemVoiceTechnology)); } } static void request_get_radio_capability(RIL_Token t) { ALOGV("Requesting radio capability."); RIL_RadioCapability rc; rc.version = RIL_RADIO_CAPABILITY_VERSION; rc.session = 1; rc.phase = RC_PHASE_CONFIGURED; rc.rat = RAF_HSPAP; strncpy(rc.logicalModemUuid, "com.google.cvdgce1.modem", MAX_UUID_LENGTH); rc.status = RC_STATUS_SUCCESS; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &rc, sizeof(rc)); } static void request_set_radio_capability(void* data, size_t datalen, RIL_Token t) { RIL_RadioCapability* rc = (RIL_RadioCapability*)data; ALOGV( "RadioCapability version %d session %d phase %d rat %d " "logicalModemUuid %s status %d", rc->version, rc->session, rc->phase, rc->rat, rc->logicalModemUuid, rc->status); // TODO(ender): do something about these numbers. gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, rc, datalen); } static void request_set_preferred_network_type(int /*request*/, void* data, size_t /*datalen*/, RIL_Token t) { RIL_PreferredNetworkType desired_type = *(RIL_PreferredNetworkType*)(data); // TODO(ender): telephony still believes this phone is GSM only. ALOGV("Requesting modem technology change -> %d", desired_type); if (gModemSupportedNetworkTypes.find(desired_type) == gModemSupportedNetworkTypes.end()) { desired_type = gModemSupportedNetworkTypes.begin()->first; } if (gModemCurrentType == desired_type) { ALOGV("Modem technology already set to %d.", desired_type); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } int supported_technologies = gModemSupportedNetworkTypes[gModemDefaultType]; int desired_technologies = gModemSupportedNetworkTypes[desired_type]; ALOGV("Requesting modem technology change %d -> %d", gModemCurrentType, desired_type); // Check if we support this technology. if ((supported_technologies & desired_technologies) != desired_technologies) { ALOGV("Desired technology is not supported."); gce_ril_env->OnRequestComplete(t, RIL_E_MODE_NOT_SUPPORTED, NULL, 0); return; } gModemCurrentType = desired_type; setRadioTechnology(desired_type); ALOGV("Technology change successful."); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_get_preferred_network_type(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { gce_ril_env->OnRequestComplete( t, RIL_E_SUCCESS, const_cast(&gModemDefaultType), sizeof(gModemDefaultType)); } enum RegistrationState { kUnregistered = 0, kRegisteredInHomeNetwork = 1, kSearchingForOperators = 2, kRegistrationDenied = 3, kUnknown = 4, kRegisteredInRoamingMode = 5, kUnregistered_EmergencyCallsOnly = 10, kSearchingForOperators_EmergencyCallsOnly = 12, kRegistrationDenied_EmergencyCallsOnly = 13, kUnknown_EmergencyCallsOnly = 14 }; static const char kCdmaMobileDeviceNumber[] = "5551234567"; static const char kCdmaSID[] = "123"; static const char kCdmaNID[] = "65535"; // special: indicates free roaming. static void request_registration_state(int request, void* /*data*/, size_t /*datalen*/, RIL_Token t) { char** responseStr = NULL; int numElements = 0; // See RIL_REQUEST_VOICE_REGISTRATION_STATE and // RIL_REQUEST_DATA_REGISTRATION_STATE. numElements = (request == RIL_REQUEST_VOICE_REGISTRATION_STATE) ? 15 : 6; responseStr = (char**)malloc(numElements * sizeof(char*)); asprintf(&responseStr[0], "%d", kRegisteredInHomeNetwork); responseStr[1] = NULL; // LAC - needed for GSM / WCDMA only. responseStr[2] = NULL; // CID - needed for GSM / WCDMA only. // This is (and always has been) a huge memory leak. if (request == RIL_REQUEST_VOICE_REGISTRATION_STATE) { ALOGV("Requesting voice registration state."); asprintf(&responseStr[3], "%d", getBestVoiceTechnology(gModemCurrentType)); responseStr[4] = strdup("1"); // BSID responseStr[5] = strdup("123"); // Latitude responseStr[6] = strdup("222"); // Longitude responseStr[7] = strdup("0"); // CSS Indicator responseStr[8] = strdup(kCdmaSID); // SID responseStr[9] = strdup(kCdmaNID); // NID responseStr[10] = strdup("0"); // Roaming indicator responseStr[11] = strdup("1"); // System is in PRL responseStr[12] = strdup("0"); // Default Roaming indicator responseStr[13] = strdup("0"); // Reason for denial responseStr[14] = strdup("0"); // Primary Scrambling Code of Current } else if (request == RIL_REQUEST_DATA_REGISTRATION_STATE) { ALOGV("Requesting data registration state."); asprintf(&responseStr[3], "%d", getBestDataTechnology(gModemCurrentType)); responseStr[4] = strdup(""); // DataServiceDenyReason responseStr[5] = strdup("1"); // Max simultaneous data calls. } else { ALOGV("Unexpected request type: %d", request); return; } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, responseStr, numElements * sizeof(responseStr)); } static void request_baseband_version(RIL_Token t) { const char* response_str = "CVD_R1.0.0"; ALOGV("Requested phone baseband version."); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, strdup(response_str), sizeof(response_str)); } // Returns true, if modem is CDMA capable. static bool isCDMA() { switch (gModemCurrentType) { case PREF_NET_TYPE_GSM_WCDMA: case PREF_NET_TYPE_GSM_ONLY: case PREF_NET_TYPE_WCDMA: case PREF_NET_TYPE_GSM_WCDMA_AUTO: case PREF_NET_TYPE_LTE_GSM_WCDMA: case PREF_NET_TYPE_LTE_ONLY: return false; case PREF_NET_TYPE_CDMA_EVDO_AUTO: case PREF_NET_TYPE_CDMA_ONLY: case PREF_NET_TYPE_EVDO_ONLY: case PREF_NET_TYPE_LTE_CDMA_EVDO: case PREF_NET_TYPE_LTE_CMDA_EVDO_GSM_WCDMA: case PREF_NET_TYPE_GSM_WCDMA_CDMA_EVDO_AUTO: return true; default: break; } ALOGE("INVALID MODEM TYPE: %d", gModemCurrentType); return false; } // Returns true, if modem is GSM capable. // Note, this is not same as !isCDMA(). static bool isGSM() { switch (gModemCurrentType) { case PREF_NET_TYPE_GSM_WCDMA: case PREF_NET_TYPE_GSM_ONLY: case PREF_NET_TYPE_WCDMA: case PREF_NET_TYPE_GSM_WCDMA_AUTO: case PREF_NET_TYPE_LTE_GSM_WCDMA: case PREF_NET_TYPE_LTE_ONLY: case PREF_NET_TYPE_GSM_WCDMA_CDMA_EVDO_AUTO: return true; case PREF_NET_TYPE_CDMA_EVDO_AUTO: case PREF_NET_TYPE_CDMA_ONLY: case PREF_NET_TYPE_EVDO_ONLY: case PREF_NET_TYPE_LTE_CDMA_EVDO: case PREF_NET_TYPE_LTE_CMDA_EVDO_GSM_WCDMA: return false; default: break; } ALOGE("INVALID MODEM TYPE: %d", gModemCurrentType); return false; } static const char gIdentityGsmImei[] = "12345678902468"; // Luhn cksum = 0. static const char gIdentityGsmImeiSv[] = "01"; // Arbitrary version. static const char gIdentityCdmaEsn[] = "A0123456"; // 8 digits, ^[A-F].* static const char gIdentityCdmaMeid[] = "A0123456789012"; // 14 digits, ^[A-F].* static void request_get_imei(RIL_Token t) { ALOGV("Requesting IMEI"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, const_cast(gIdentityGsmImei), strlen(gIdentityGsmImei)); } static void request_get_imei_sv(RIL_Token t) { ALOGV("Requesting IMEI SV"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, const_cast(gIdentityGsmImeiSv), strlen(gIdentityGsmImeiSv)); } static void request_device_identity(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { char* response[4] = {NULL}; ALOGV("Requesting device identity..."); if (isCDMA()) { response[2] = strdup(&gIdentityCdmaEsn[0]); response[3] = strdup(&gIdentityCdmaMeid[0]); } if (isGSM()) { response[0] = strdup(&gIdentityGsmImei[0]); response[1] = strdup(&gIdentityGsmImeiSv[0]); } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &response, sizeof(response)); free(response[0]); free(response[1]); } // Let's pretend we have SIM for CDMA (by default). static bool gCdmaHasSim = true; static RIL_CdmaSubscriptionSource gCdmaSubscriptionType = CDMA_SUBSCRIPTION_SOURCE_RUIM_SIM; static void request_cdma_get_subscription_source(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Requesting CDMA Subscription source."); if (!isCDMA()) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &gCdmaSubscriptionType, sizeof(gCdmaSubscriptionType)); } static void request_cdma_set_subscription_source(int /*request*/, void* data, size_t /*datalen*/, RIL_Token t) { ALOGV("Setting CDMA Subscription source."); if (!isCDMA()) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } RIL_CdmaSubscriptionSource new_source = *(RIL_CdmaSubscriptionSource*)(data); if (new_source == CDMA_SUBSCRIPTION_SOURCE_RUIM_SIM && !gCdmaHasSim) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_SIM_ABSENT, NULL, 0); return; } ALOGV("Changed CDMA subscription type from %d to %d", gCdmaSubscriptionType, new_source); gCdmaSubscriptionType = new_source; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED, &gCdmaSubscriptionType, sizeof(gCdmaSubscriptionType)); } static void request_cdma_subscription(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Requesting CDMA Subscription."); if (!isCDMA()) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } char* responseStr[5] = {NULL}; responseStr[0] = strdup(&kCdmaMobileDeviceNumber[0]); // MDN responseStr[1] = strdup(&kCdmaSID[0]); // SID responseStr[2] = strdup(&kCdmaNID[0]); // NID responseStr[3] = strdup(&kCdmaMobileDeviceNumber[0]); // MIN responseStr[4] = strdup("1"); // PRL Version gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, responseStr, sizeof(responseStr)); } static const int gMaxConcurrentVoiceCalls = 4; static const int gMaxConcurrentDataCalls = 4; static const int gMaxConcurrentStandbyConnections = 4; static void request_hardware_config(RIL_Token t) { RIL_HardwareConfig hw_cfg[2]; ALOGV("Requesting hardware configuration."); strncpy(hw_cfg[0].uuid, "com.google.cvdgce1.modem", sizeof(hw_cfg[0].uuid)); strncpy(hw_cfg[1].uuid, "com.google.cvdgce1.sim", sizeof(hw_cfg[1].uuid)); int technologies = 0; // = unknown. std::map::iterator iter = gModemTechnologies.find(gModemDefaultType); if (iter != gModemTechnologies.end()) { technologies = iter->second; } hw_cfg[0].type = RIL_HARDWARE_CONFIG_MODEM; hw_cfg[0].state = RIL_HARDWARE_CONFIG_STATE_ENABLED; hw_cfg[0].cfg.modem.rilModel = 0; hw_cfg[0].cfg.modem.rat = technologies; hw_cfg[0].cfg.modem.maxVoice = gMaxConcurrentVoiceCalls; hw_cfg[0].cfg.modem.maxData = gMaxConcurrentDataCalls; hw_cfg[0].cfg.modem.maxStandby = gMaxConcurrentStandbyConnections; hw_cfg[1].type = RIL_HARDWARE_CONFIG_SIM; hw_cfg[1].state = RIL_HARDWARE_CONFIG_STATE_ENABLED; memcpy(hw_cfg[1].cfg.sim.modemUuid, hw_cfg[0].uuid, sizeof(hw_cfg[1].cfg.sim.modemUuid)); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &hw_cfg, sizeof(hw_cfg)); } // 0 = Home network only, 1 = preferred networks only, 2 = all networks. static int gCdmaRoamingPreference = 2; static void request_cdma_get_roaming_preference(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { if (!isCDMA()) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } ALOGV("Requesting CDMA Roaming preference"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &gCdmaRoamingPreference, sizeof(gCdmaRoamingPreference)); } static void request_cdma_set_roaming_preference(int /*request*/, void* data, size_t /*datalen*/, RIL_Token t) { if (!isCDMA()) { // No such radio. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } int pref = *(int*)data; ALOGV("Changing CDMA roaming preference: %d -> %d", gCdmaRoamingPreference, pref); if ((pref < 0) || (pref > 2)) { ALOGV("Unsupported roaming preference: %d", pref); gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); return; } gCdmaRoamingPreference = pref; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_send_ussd(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Sending USSD code is currently not supported"); // TODO(ender): support this feature gce_ril_env->OnRequestComplete(t, RIL_E_REQUEST_NOT_SUPPORTED, NULL, 0); } static void request_cancel_ussd(RIL_Token t) { ALOGV("Cancelling USSD code is currently not supported"); // TODO(ender): support this feature gce_ril_env->OnRequestComplete(t, RIL_E_REQUEST_NOT_SUPPORTED, NULL, 0); } static void request_exit_emergency_mode(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Exiting emergency callback mode."); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static RIL_RadioState gce_ril_current_state() { ALOGV("Reporting radio state %d", gRadioPowerState); return gRadioPowerState; } static int gce_ril_on_supports(int requestCode) { ALOGE("%s: Request code %d not implemented", __FUNCTION__, requestCode); return 1; } static void gce_ril_on_cancel(RIL_Token /*t*/) { ALOGE("Cancel operation not implemented"); } static const char* gce_ril_get_version(void) { ALOGV("Reporting Cuttlefish version " CUTTLEFISH_RIL_VERSION_STRING); return CUTTLEFISH_RIL_VERSION_STRING; } static int s_cell_info_rate_ms = INT_MAX; static int s_mcc = 0; static int s_mnc = 0; static int s_lac = 0; static int s_cid = 0; std::vector gGSMNeighboringCells; static void request_get_neighboring_cell_ids(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Requesting GSM neighboring cell ids"); if (!isGSM() || gGSMNeighboringCells.empty()) { gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); return; } RIL_NeighboringCell** cells = new RIL_NeighboringCell*[gGSMNeighboringCells.size()]; for (size_t index = 0; index < gGSMNeighboringCells.size(); ++index) { cells[index] = &gGSMNeighboringCells[index]; } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, cells, sizeof(RIL_NeighboringCell*)); delete[] cells; } static void request_get_cell_info_list(void* /*data*/, size_t /*datalen*/, RIL_Token t) { struct timespec now; uint64_t curTime; ALOGV("Requesting Cell Info List"); clock_gettime(CLOCK_MONOTONIC, &now); curTime = now.tv_sec * 1000000000LL + now.tv_nsec; RIL_CellInfo_v12 ci; if (isGSM()) { ci.cellInfoType = RIL_CELL_INFO_TYPE_GSM; ci.registered = 1; ci.timeStampType = RIL_TIMESTAMP_TYPE_ANTENNA; // Our own timestamp. ci.timeStamp = curTime - 1000; // Fake time in the past. ci.CellInfo.gsm.cellIdentityGsm.mcc = s_mcc; ci.CellInfo.gsm.cellIdentityGsm.mnc = s_mnc; ci.CellInfo.gsm.cellIdentityGsm.lac = s_lac; ci.CellInfo.gsm.cellIdentityGsm.cid = s_cid; ci.CellInfo.gsm.signalStrengthGsm.signalStrength = 10; ci.CellInfo.gsm.signalStrengthGsm.bitErrorRate = 0; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &ci, sizeof(ci)); } else if (isCDMA()) { // TODO(ender): CDMA cell support. And LTE. gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); } else { gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } } struct NetworkOperator { std::string long_name; std::string short_name; bool is_accessible; NetworkOperator() {} NetworkOperator(const std::string& long_name, const std::string& short_name, bool is_accessible) : long_name(long_name), short_name(short_name), is_accessible(is_accessible) {} }; static std::map gNetworkOperators; static std::string gCurrentNetworkOperator = ""; enum OperatorSelectionMethod { kOperatorAutomatic = 0, kOperatorManual = 1, kOperatorDeregistered = 2, kOperatorManualThenAutomatic = 4 }; static void init_virtual_network() { gGSMNeighboringCells.resize(1); gGSMNeighboringCells[0].cid = (char*)"0000"; gGSMNeighboringCells[0].rssi = 75; gNetworkOperators["311740"] = NetworkOperator("Android Virtual Operator", "Android", true); gNetworkOperators["310300"] = NetworkOperator("Alternative Operator", "Alternative", true); gNetworkOperators["310400"] = NetworkOperator("Hermetic Network Operator", "Hermetic", false); } static OperatorSelectionMethod gOperatorSelectionMethod = kOperatorDeregistered; static void request_query_network_selection_mode(void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Query operator selection mode (%d)", gOperatorSelectionMethod); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &gOperatorSelectionMethod, sizeof(gOperatorSelectionMethod)); } static void request_operator(void* /*data*/, size_t /*datalen*/, RIL_Token t) { std::map::iterator iter = gNetworkOperators.find(gCurrentNetworkOperator); ALOGV("Requesting current operator info"); if (iter == gNetworkOperators.end()) { gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } const char* response[] = {iter->second.long_name.c_str(), iter->second.short_name.c_str(), iter->first.c_str()}; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, response, sizeof(response)); } static void request_query_available_networks(void* /*data*/, size_t /*datalen*/, RIL_Token t) { const char** available_networks = new const char*[gNetworkOperators.size() * 4]; ALOGV("Querying available networks."); // TODO(ender): this should only respond once operator is selected and // registered. int index = 0; for (std::map::iterator iter = gNetworkOperators.begin(); iter != gNetworkOperators.end(); ++iter) { // TODO(ender): wrap in a neat structure maybe? available_networks[index++] = iter->second.long_name.c_str(); available_networks[index++] = iter->second.short_name.c_str(); available_networks[index++] = iter->first.c_str(); if (!iter->second.is_accessible) { available_networks[index++] = "forbidden"; } else if (iter->first == gCurrentNetworkOperator) { available_networks[index++] = "current"; } else { available_networks[index++] = "available"; } } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &available_networks, 4 * gNetworkOperators.size()); delete[] available_networks; } static void request_set_automatic_network_selection(RIL_Token t) { ALOGV("Requesting automatic operator selection"); gCurrentNetworkOperator = gNetworkOperators.begin()->first; gOperatorSelectionMethod = kOperatorAutomatic; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_set_manual_network_selection(void* data, size_t /*datalen*/, RIL_Token t) { char* mccmnc = (char*)data; ALOGV("Requesting manual operator selection: %s", mccmnc); std::map::iterator iter = gNetworkOperators.find(mccmnc); if (iter == gNetworkOperators.end() || iter->second.is_accessible) { gce_ril_env->OnRequestComplete(t, RIL_E_ILLEGAL_SIM_OR_ME, NULL, 0); return; } gCurrentNetworkOperator = mccmnc; gOperatorSelectionMethod = kOperatorManual; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static const char kDefaultSMSC[] = "00"; static int gNextSmsMessageId = 1; static void request_cdma_send_SMS(void* /*data*/, RIL_Token t) { RIL_SMS_Response response = {0, 0, 0}; // RIL_CDMA_SMS_Message* rcsm = (RIL_CDMA_SMS_Message*) data; ALOGW("CDMA SMS Send is currently not implemented."); // Cdma Send SMS implementation will go here: // But it is not implemented yet. memset(&response, 0, sizeof(response)); response.messageRef = -1; // This must be BearerData MessageId. gce_ril_env->OnRequestComplete(t, RIL_E_SMS_SEND_FAIL_RETRY, &response, sizeof(response)); } static void request_send_SMS(void* data, RIL_Token t) { RIL_SMS_Response response = {0, 0, 0}; ALOGV("Send GSM SMS Message"); // SMSC is an address of SMS center or NULL for default. const char* smsc = ((const char**)data)[0]; if (smsc == NULL) smsc = &kDefaultSMSC[0]; response.messageRef = gNextSmsMessageId++; response.ackPDU = NULL; response.errorCode = 0; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &response, sizeof(response)); // response.messageRef = -1; // gce_ril_env->OnRequestComplete(t, RIL_E_SMS_SEND_FAIL_RETRY, &response, // sizeof(response)); } static void request_set_cell_info_list_rate(void* data, size_t /*datalen*/, RIL_Token t) { // For now we'll save the rate but no RIL_UNSOL_CELL_INFO_LIST messages // will be sent. ALOGV("Setting cell info list rate."); s_cell_info_rate_ms = ((int*)data)[0]; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_ims_send_SMS(void* data, size_t /*datalen*/, RIL_Token t) { RIL_IMS_SMS_Message* args = (RIL_IMS_SMS_Message*)data; RIL_SMS_Response response{}; ALOGV("Send IMS SMS Message"); switch (args->tech) { case RADIO_TECH_3GPP: return request_send_SMS(args->message.gsmMessage, t); case RADIO_TECH_3GPP2: return request_cdma_send_SMS(args->message.gsmMessage, t); default: ALOGE("Invalid SMS format value: %d", args->tech); response.messageRef = -2; gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, &response, sizeof(response)); } } static void request_SMS_acknowledge(void* data, size_t /*datalen*/, RIL_Token t) { int* ack = (int*)data; // TODO(ender): we should retain "incoming" sms for later reception. ALOGV("SMS receipt %ssuccessful (reason %d).", ack[0] ? "" : "un", ack[1]); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } struct SimFileCommand { uint8_t command; uint16_t efid; uint8_t param1; uint8_t param2; uint8_t param3; bool operator<(const SimFileCommand& other) const { uint64_t sum1, sum2; sum1 = (command * 1ull << 40) | (efid * 1ull << 24) | (param1 << 16) | (param2 << 8) | (param3); sum2 = (other.command * 1ull << 40) | (other.efid * 1ull << 24) | (other.param1 << 16) | (other.param2 << 8) | (other.param3); return sum1 < sum2; } SimFileCommand(uint8_t cmd, uint16_t efid, uint8_t p1, uint8_t p2, uint8_t p3) : command(cmd), efid(efid), param1(p1), param2(p2), param3(p3) {} }; struct SimFileResponse { uint8_t sw1; uint8_t sw2; const char* data; SimFileResponse() : sw1(0), sw2(0), data(NULL) {} SimFileResponse(uint8_t sw1, uint8_t sw2, const char* data) : sw1(sw1), sw2(sw2), data(data) {} }; // TODO(ender): Double check & rewrite these. std::map gSimFileSystem; static void init_sim_file_system() { gSimFileSystem[SimFileCommand(192, 28436, 0, 0, 15)] = SimFileResponse(144, 0, "000000146f1404001aa0aa01020000"); gSimFileSystem[SimFileCommand(176, 28436, 0, 0, 20)] = SimFileResponse(144, 0, "416e64726f6964ffffffffffffffffffffffffff"); gSimFileSystem[SimFileCommand(192, 28433, 0, 0, 15)] = SimFileResponse(144, 0, "000000016f11040011a0aa01020000"); gSimFileSystem[SimFileCommand(176, 28433, 0, 0, 1)] = SimFileResponse(144, 0, "55"); gSimFileSystem[SimFileCommand(192, 12258, 0, 0, 15)] = SimFileResponse(144, 0, "0000000a2fe204000fa0aa01020000"); gSimFileSystem[SimFileCommand(176, 12258, 0, 0, 10)] = SimFileResponse(144, 0, "98101430121181157002"); gSimFileSystem[SimFileCommand(192, 28435, 0, 0, 15)] = SimFileResponse(144, 0, "000000016f13040011a0aa01020000"); gSimFileSystem[SimFileCommand(176, 28435, 0, 0, 1)] = SimFileResponse(144, 0, "55"); gSimFileSystem[SimFileCommand(192, 28472, 0, 0, 15)] = SimFileResponse(144, 0, "0000000f6f3804001aa0aa01020000"); gSimFileSystem[SimFileCommand(176, 28472, 0, 0, 15)] = SimFileResponse(144, 0, "ff30ffff3c003c03000c0000f03f00"); gSimFileSystem[SimFileCommand(192, 28617, 0, 0, 15)] = SimFileResponse(144, 0, "000000086fc9040011a0aa01020104"); gSimFileSystem[SimFileCommand(178, 28617, 1, 4, 4)] = SimFileResponse(144, 0, "01000000"); gSimFileSystem[SimFileCommand(192, 28618, 0, 0, 15)] = SimFileResponse(144, 0, "0000000a6fca040011a0aa01020105"); gSimFileSystem[SimFileCommand(178, 28618, 1, 4, 5)] = SimFileResponse(144, 0, "0000000000"); gSimFileSystem[SimFileCommand(192, 28589, 0, 0, 15)] = SimFileResponse(144, 0, "000000046fad04000aa0aa01020000"); gSimFileSystem[SimFileCommand(176, 28589, 0, 0, 4)] = SimFileResponse(144, 0, "00000003"); gSimFileSystem[SimFileCommand(192, 28438, 0, 0, 15)] = SimFileResponse(144, 0, "000000026f1604001aa0aa01020000"); gSimFileSystem[SimFileCommand(176, 28438, 0, 0, 2)] = SimFileResponse(144, 0, "0233"); gSimFileSystem[SimFileCommand(192, 28486, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28621, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28613, 0, 0, 15)] = SimFileResponse(144, 0, "000000f06fc504000aa0aa01020118"); gSimFileSystem[SimFileCommand(178, 28613, 1, 4, 24)] = SimFileResponse( 144, 0, "43058441aa890affffffffffffffffffffffffffffffffff"); gSimFileSystem[SimFileCommand(192, 28480, 0, 0, 15)] = SimFileResponse(144, 0, "000000806f40040011a0aa01020120"); // Primary phone number encapsulated // [51][55][21][43][65][f7] = 1 555 1234 567$ gSimFileSystem[SimFileCommand(178, 28480, 1, 4, 32)] = SimFileResponse( 144, 0, "ffffffffffffffffffffffffffffffffffff07915155214365f7ffffffffffff"); gSimFileSystem[SimFileCommand(192, 28615, 0, 0, 15)] = SimFileResponse(144, 0, "000000406fc7040011a0aa01020120"); // Voice mail number encapsulated // [56][6f][69][63][65][6d][61][69][6c] = 'Voicemail' // [51][55][67][45][23][f1] = 1 555 7654 321$ gSimFileSystem[SimFileCommand(178, 28615, 1, 4, 32)] = SimFileResponse( 144, 0, "566f6963656d61696cffffffffffffffffff07915155674523f1ffffffffffff"); gSimFileSystem[SimFileCommand(192, 12037, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28437, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28478, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28450, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28456, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28474, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28481, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28484, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28493, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(192, 28619, 0, 0, 15)] = SimFileResponse(148, 4, NULL); gSimFileSystem[SimFileCommand(176, 28506, 0, 0, 4)] = SimFileResponse(144, 0, "00000013"); } static void request_SIM_IO(void* data, size_t /*datalen*/, RIL_Token t) { const RIL_SIM_IO_v6& args = *(RIL_SIM_IO_v6*)data; RIL_SIM_IO_Response sr = {0, 0, 0}; ALOGV( "Requesting SIM File IO: %d EFID %x, Params: %d, %d, %d, path: %s, " "data %s PIN: %s AID: %s", args.command, args.fileid, args.p1, args.p2, args.p3, args.path, args.data, args.pin2, args.aidPtr); SimFileCommand cmd(args.command, args.fileid, args.p1, args.p2, args.p3); std::map::iterator resp = gSimFileSystem.find(cmd); if (resp != gSimFileSystem.end()) { sr.sw1 = resp->second.sw1; sr.sw2 = resp->second.sw2; if (resp->second.data) sr.simResponse = strdup(resp->second.data); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &sr, sizeof(sr)); return; } ALOGW("Unsupported SIM File IO command."); gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } static void request_enter_sim_pin(void* data, size_t /*datalen*/, RIL_Token t) { const char** pin_aid = (const char**)data; ALOGV("Entering PIN: %s / %s", pin_aid[0], pin_aid[1]); ++gSimPINAttempts; int remaining_attempts = gSimPINAttemptsMax - gSimPINAttempts; bool is_valid = false; if (gSimStatus == SIM_PIN) { is_valid = (gSimPIN == pin_aid[0]); } else if (gSimStatus == SIM_PUK) { is_valid = (gSimPUK == pin_aid[0]); } else { ALOGV("Unexpected SIM status for unlock: %d", gSimStatus); gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); return; } if (!is_valid) { if (gSimPINAttempts == gSimPINAttemptsMax) { if (gSimStatus == SIM_PIN) { gSimStatus = SIM_PUK; gSimPINAttempts = 0; } else { ALOGV("PIN and PUK verification failed; locking SIM card."); gSimStatus = SIM_NOT_READY; gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); return; } } gce_ril_env->OnRequestComplete(t, RIL_E_PASSWORD_INCORRECT, &remaining_attempts, sizeof(remaining_attempts)); } else { if (gSimStatus == SIM_PUK) { ALOGV("Resetting SIM PIN to %s", pin_aid[1]); gSimPIN = pin_aid[1]; } gSimPINAttempts = 0; gSimStatus = SIM_READY; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &remaining_attempts, sizeof(remaining_attempts)); } pollSIMState(NULL); } /** * No longer POLL. */ static void pollSIMState(void* /*param*/) { // TODO(ender): check radio state? ALOGV("Polling SIM Status."); switch (gSimStatus) { case SIM_ABSENT: case SIM_PIN: case SIM_PUK: case SIM_NETWORK_PERSONALIZATION: default: ALOGV("SIM Absent or Locked"); break; case SIM_NOT_READY: // Transition directly to READY. Set default network operator. if (gRadioPowerState == RADIO_STATE_ON) { gSimStatus = SIM_READY; gCurrentNetworkOperator = "311740"; } gce_ril_env->RequestTimedCallback(pollSIMState, NULL, &TIMEVAL_SIMPOLL); break; case SIM_READY: ALOGV("SIM Ready. Notifying network state changed."); break; } if (gRadioPowerState != RADIO_STATE_OFF) { gce_ril_env->OnUnsolicitedResponse(RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED, NULL, 0); gce_ril_env->OnUnsolicitedResponse( RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED, NULL, 0); } } std::map gRilAppStatus; static void init_sim_status() { gRilAppStatus[SIM_ABSENT] = (RIL_AppStatus){RIL_APPTYPE_UNKNOWN, RIL_APPSTATE_UNKNOWN, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_UNKNOWN, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[SIM_NOT_READY] = (RIL_AppStatus){RIL_APPTYPE_SIM, RIL_APPSTATE_DETECTED, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_ENABLED_NOT_VERIFIED, RIL_PINSTATE_ENABLED_NOT_VERIFIED}; gRilAppStatus[SIM_READY] = (RIL_AppStatus){ RIL_APPTYPE_SIM, RIL_APPSTATE_READY, RIL_PERSOSUBSTATE_READY, NULL, NULL, 0, RIL_PINSTATE_ENABLED_VERIFIED, RIL_PINSTATE_ENABLED_VERIFIED, }; gRilAppStatus[SIM_PIN] = (RIL_AppStatus){RIL_APPTYPE_SIM, RIL_APPSTATE_PIN, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_ENABLED_NOT_VERIFIED, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[SIM_PUK] = (RIL_AppStatus){RIL_APPTYPE_SIM, RIL_APPSTATE_PUK, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_ENABLED_BLOCKED, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[SIM_NETWORK_PERSONALIZATION] = (RIL_AppStatus){RIL_APPTYPE_SIM, RIL_APPSTATE_SUBSCRIPTION_PERSO, RIL_PERSOSUBSTATE_SIM_NETWORK, NULL, NULL, 0, RIL_PINSTATE_ENABLED_NOT_VERIFIED, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_ABSENT] = (RIL_AppStatus){RIL_APPTYPE_UNKNOWN, RIL_APPSTATE_UNKNOWN, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_UNKNOWN, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_NOT_READY] = (RIL_AppStatus){RIL_APPTYPE_RUIM, RIL_APPSTATE_DETECTED, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_UNKNOWN, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_READY] = (RIL_AppStatus){RIL_APPTYPE_RUIM, RIL_APPSTATE_READY, RIL_PERSOSUBSTATE_READY, NULL, NULL, 0, RIL_PINSTATE_UNKNOWN, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_PIN] = (RIL_AppStatus){RIL_APPTYPE_RUIM, RIL_APPSTATE_PIN, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_ENABLED_NOT_VERIFIED, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_PUK] = (RIL_AppStatus){RIL_APPTYPE_RUIM, RIL_APPSTATE_PUK, RIL_PERSOSUBSTATE_UNKNOWN, NULL, NULL, 0, RIL_PINSTATE_ENABLED_BLOCKED, RIL_PINSTATE_UNKNOWN}; gRilAppStatus[RUIM_NETWORK_PERSONALIZATION] = (RIL_AppStatus){RIL_APPTYPE_RUIM, RIL_APPSTATE_SUBSCRIPTION_PERSO, RIL_PERSOSUBSTATE_SIM_NETWORK, NULL, NULL, 0, RIL_PINSTATE_ENABLED_NOT_VERIFIED, RIL_PINSTATE_UNKNOWN}; } /** * Get the current card status. */ static void getCardStatus(RIL_Token t) { ALOGV("Querying SIM status."); RIL_CardStatus_v6 card_status; if (gSimStatus == SIM_ABSENT) { card_status.card_state = RIL_CARDSTATE_ABSENT; card_status.num_applications = 0; } else { card_status.card_state = RIL_CARDSTATE_PRESENT; card_status.num_applications = 1; } card_status.universal_pin_state = RIL_PINSTATE_UNKNOWN; card_status.gsm_umts_subscription_app_index = -1; card_status.cdma_subscription_app_index = -1; card_status.ims_subscription_app_index = -1; // Initialize application status for (int i = 0; i < RIL_CARD_MAX_APPS; i++) { card_status.applications[i] = gRilAppStatus[SIM_ABSENT]; } if (card_status.num_applications > 0) { card_status.gsm_umts_subscription_app_index = 0; card_status.applications[0] = gRilAppStatus[gSimStatus]; card_status.universal_pin_state = card_status.applications[0].pin1; // To enable basic CDMA (currently neither supported nor functional): // card_status.num_applications = 2; // card_status.cdma_subscription_app_index = 1; // card_status.applications[1] = // gRilAppStatus[SIM_Status(gSimStatus + RUIM_ABSENT)]; } gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &card_status, sizeof(card_status)); } struct SimSession { std::string aid; }; static int gNextSimSessionId = 1; static std::map gSimSessions; static void request_sim_open_channel(void* data, size_t /*datalen*/, RIL_Token t) { char* aid = (char*)data; SimSession session; ALOGV("Requesting new SIM session"); if (aid != NULL) { session.aid = aid; } int response = gNextSimSessionId++; gSimSessions[response] = session; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &response, sizeof(response)); } static void request_sim_close_channel(void* data, size_t /*datalen*/, RIL_Token t) { int session = *(int*)(data); ALOGV("Closing SIM session %d", session); if (gSimSessions.erase(session) == 0) { // No such session. gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } else { gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } } static void request_sim_apdu(void* data, size_t /*datalen*/, RIL_Token t) { RIL_SIM_APDU* apdu = (RIL_SIM_APDU*)data; ALOGV("Requesting APDU: Session %d CLA %d INST %d Params: %d %d %d, data %s", apdu->sessionid, apdu->cla, apdu->instruction, apdu->p1, apdu->p2, apdu->p3, apdu->data); if (gSimSessions.find(apdu->sessionid) != gSimSessions.end()) { RIL_SIM_IO_Response sr{}; // Fallback / default behavior. sr.sw1 = 144; sr.sw2 = 0; sr.simResponse = NULL; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &sr, sizeof(sr)); } else { gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } } // 0 = Lock is available, but disabled. // 1 = Lock is available and enabled, // 2 = lock is neither available nor enabled static const int kFacilityLockAllDisabled = 0; static void request_facility_lock(void* data, size_t /*datalen*/, RIL_Token t) { char** data_vec = (char**)data; // TODO(ender): implement this; essentially: AT+CLCK // See http://www.activexperts.com/sms-component/at/commands/?at=%2BCLCK // and // opt/telephony/src/java/com/android/internal/telephony/CommandsInterface.java // opt/telephony/src/java/com/android/internal/telephony/uicc/UiccCardApplication.java ALOGV("Query Facility Lock Code: %s PIN2: %s Service(s): %s AID: %s", data_vec[0], data_vec[1], data_vec[2], data_vec[3]); // TODO(ender): there should be a bit vector of responses for each of the // services requested. // Depending on lock code, facilities may be unlocked or locked. We report // these are all unlocked, regardless of the query. gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, const_cast(&kFacilityLockAllDisabled), sizeof(kFacilityLockAllDisabled)); } static void request_international_subscriber_id_number(RIL_Token t) { // TODO(ender): Reuse MCC and MNC. std::string subscriber_id = gCurrentNetworkOperator.c_str(); subscriber_id += "123456789"; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, strdup(subscriber_id.c_str()), sizeof(char*)); } static bool gScreenIsOn = true; static void request_set_screen_state(void* data, size_t /*datalen*/, RIL_Token t) { gScreenIsOn = *(int*)data ? true : false; ALOGV("Screen is %s", gScreenIsOn ? "on" : "off"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } // Unsure which section this belongs in. static int gModemTtyMode = 1; // 0 = off, 1 = full, 2 = HCO, 3 = VCO. static void request_set_tty_mode(void* data, size_t /*datalen*/, RIL_Token t) { int new_tty_mode = *(int*)(data); ALOGV("Switching modem TTY mode %d -> %d", gModemTtyMode, new_tty_mode); if (new_tty_mode >= 0 && new_tty_mode <= 3) { gModemTtyMode = new_tty_mode; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } else { gce_ril_env->OnRequestComplete(t, RIL_E_GENERIC_FAILURE, NULL, 0); } } static void request_get_tty_mode(RIL_Token t) { ALOGV("Querying TTY mode"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &gModemTtyMode, sizeof(gModemTtyMode)); } static bool gImsRegistered = false; static int gImsFormat = RADIO_TECH_3GPP; static void request_ims_registration_state(RIL_Token t) { ALOGV("Querying IMS mode"); int reply[2]; reply[0] = gImsRegistered; reply[1] = gImsFormat; ALOGV("Requesting IMS Registration state: %d, format=%d ", reply[0], reply[1]); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, reply, sizeof(reply)); } // New functions after P. static void request_start_network_scan(RIL_Token t) { ALOGV("Scanning network - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_set_preferred_network_type_bitmap(int /*request*/, void* data, size_t /*datalen*/, RIL_Token t) { RIL_RadioAccessFamily desired_access = *(RIL_RadioAccessFamily*)(data); ALOGV("Requesting modem technology change %d -> %d", default_access, desired_access); /** TODO future implementation: set modem type based on radio access family. * 1) find supported_technologies and desired_technologies * 2) return RIL_E_MODE_NOT_SUPPORTED error if not supported */ default_access = desired_access; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_get_preferred_network_type_bitmap(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Requesting modem radio access family: %d", default_access); gce_ril_env->OnRequestComplete( t, RIL_E_SUCCESS, (RIL_RadioAccessFamily*)(&default_access), sizeof(default_access)); } static void request_emergency_dial(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Emergency dial"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_set_sim_card_power(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Set sim card power - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_get_modem_stack_status(int /*request*/, RIL_Token t) { ALOGV("Getting modem stack status - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_enable_modem(int /*request*/, RIL_Token t) { ALOGV("Enabling modem - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_set_system_selection_channels(int /*request*/, RIL_Token t) { ALOGV("request_set_system_selection_channels - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } // New functions after Q. static void request_set_signal_strength_reporting_criteria(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("request_set_signal_strength_reporting_criteria - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_set_link_capacity_reporting_criteria(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("request_set_link_capacity_reporting_criteria - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_enable_uicc_applications(int /*request*/, void* data, size_t datalen, RIL_Token t) { ALOGV("Enable uicc applications."); if (data == NULL || datalen != sizeof(int)) { gce_ril_env->OnRequestComplete(t, RIL_E_INTERNAL_ERR, NULL, 0); return; } bool enable = *(int *)(data) != 0; ALOGV("areUiccApplicationsEnabled change from %d to %d", areUiccApplicationsEnabled, enable); areUiccApplicationsEnabled = enable; gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); } static void request_are_uicc_applications_enabled(int /*request*/, void* /*data*/, size_t /*datalen*/, RIL_Token t) { ALOGV("Getting whether uicc applications are enabled."); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &areUiccApplicationsEnabled, sizeof(bool)); } static void request_enter_sim_depersonalization(RIL_Token t) { ALOGV("request_enter_sim_depersonalization - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void request_cdma_send_sms_expect_more(RIL_Token t) { ALOGV("request_cdma_send_sms_expect_more - void"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); return; } static void gce_ril_on_request(int request, void* data, size_t datalen, RIL_Token t) { // Ignore all requests except RIL_REQUEST_GET_SIM_STATUS // when RADIO_STATE_UNAVAILABLE. if (gRadioPowerState == RADIO_STATE_UNAVAILABLE && request != RIL_REQUEST_GET_SIM_STATUS) { gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } // Ignore all non-power requests when RADIO_STATE_OFF. if (gRadioPowerState == RADIO_STATE_OFF) { switch (request) { case RIL_REQUEST_GET_SIM_STATUS: case RIL_REQUEST_OPERATOR: case RIL_REQUEST_RADIO_POWER: case RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE: // Process all the above, even though the radio is off break; default: gce_ril_env->OnRequestComplete(t, RIL_E_RADIO_NOT_AVAILABLE, NULL, 0); return; } } ALOGV("Received request %d", request); switch (request) { case RIL_REQUEST_QUERY_AVAILABLE_NETWORKS: request_query_available_networks(data, datalen, t); break; case RIL_REQUEST_GET_IMEI: request_get_imei(t); break; case RIL_REQUEST_GET_IMEISV: request_get_imei_sv(t); break; case RIL_REQUEST_DEACTIVATE_DATA_CALL: request_teardown_data_call(data, datalen, t); break; case RIL_REQUEST_SCREEN_STATE: request_set_screen_state(data, datalen, t); break; case RIL_REQUEST_GET_SIM_STATUS: getCardStatus(t); break; case RIL_REQUEST_GET_CURRENT_CALLS: request_get_current_calls(data, datalen, t); break; case RIL_REQUEST_DIAL: request_dial(data, datalen, t); break; case RIL_REQUEST_HANGUP: request_hangup(data, datalen, t); break; case RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND: request_hangup_waiting(data, datalen, t); break; case RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND: request_hangup_current(t); break; case RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE: request_switch_current_and_waiting(t); break; case RIL_REQUEST_ANSWER: request_answer_incoming(t); break; case RIL_REQUEST_SET_MUTE: request_set_mute(data, datalen, t); break; case RIL_REQUEST_GET_MUTE: request_get_mute(t); break; case RIL_REQUEST_CONFERENCE: request_combine_multiparty_call(data, datalen, t); break; case RIL_REQUEST_SEPARATE_CONNECTION: request_split_multiparty_call(data, datalen, t); break; case RIL_REQUEST_UDUB: request_udub_on_incoming_calls(t); break; case RIL_REQUEST_SIGNAL_STRENGTH: request_signal_strength(data, datalen, t); break; case RIL_REQUEST_VOICE_REGISTRATION_STATE: case RIL_REQUEST_DATA_REGISTRATION_STATE: request_registration_state(request, data, datalen, t); break; case RIL_REQUEST_OPERATOR: request_operator(data, datalen, t); break; case RIL_REQUEST_RADIO_POWER: request_radio_power(data, datalen, t); break; case RIL_REQUEST_DTMF: case RIL_REQUEST_DTMF_START: request_send_dtmf(data, datalen, t); break; case RIL_REQUEST_DTMF_STOP: request_send_dtmf_stop(t); break; case RIL_REQUEST_SEND_SMS: request_send_SMS(data, t); break; case RIL_REQUEST_CDMA_SEND_SMS: request_cdma_send_SMS(data, t); break; case RIL_REQUEST_SETUP_DATA_CALL: request_setup_data_call(data, datalen, t); break; case RIL_REQUEST_SMS_ACKNOWLEDGE: request_SMS_acknowledge(data, datalen, t); break; case RIL_REQUEST_GET_IMSI: request_international_subscriber_id_number(t); break; case RIL_REQUEST_QUERY_FACILITY_LOCK: request_facility_lock(data, datalen, t); break; case RIL_REQUEST_SIM_IO: request_SIM_IO(data, datalen, t); break; case RIL_REQUEST_SEND_USSD: request_send_ussd(data, datalen, t); break; case RIL_REQUEST_CANCEL_USSD: request_cancel_ussd(t); break; case RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC: request_set_automatic_network_selection(t); break; case RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL: request_set_manual_network_selection(data, datalen, t); break; case RIL_REQUEST_DATA_CALL_LIST: request_data_calllist(data, datalen, t); break; case RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE: request_datacall_fail_cause(t); break; case RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE: request_query_network_selection_mode(data, datalen, t); break; case RIL_REQUEST_OEM_HOOK_RAW: case RIL_REQUEST_OEM_HOOK_STRINGS: ALOGV("OEM Hooks not supported!"); gce_ril_env->OnRequestComplete(t, RIL_E_REQUEST_NOT_SUPPORTED, NULL, 0); break; case RIL_REQUEST_WRITE_SMS_TO_SIM: request_write_sms_to_sim(data, datalen, t); break; case RIL_REQUEST_DELETE_SMS_ON_SIM: request_delete_sms_on_sim(data, datalen, t); break; case RIL_REQUEST_ENTER_SIM_PIN: case RIL_REQUEST_ENTER_SIM_PUK: case RIL_REQUEST_ENTER_SIM_PIN2: case RIL_REQUEST_ENTER_SIM_PUK2: case RIL_REQUEST_CHANGE_SIM_PIN: case RIL_REQUEST_CHANGE_SIM_PIN2: request_enter_sim_pin(data, datalen, t); break; case RIL_REQUEST_VOICE_RADIO_TECH: { RIL_RadioTechnology tech = getBestVoiceTechnology(gModemCurrentType); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, &tech, sizeof(tech)); break; } case RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE: request_set_preferred_network_type(request, data, datalen, t); break; case RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE: request_get_preferred_network_type(request, data, datalen, t); break; case RIL_REQUEST_GET_NEIGHBORING_CELL_IDS: request_get_neighboring_cell_ids(data, datalen, t); break; case RIL_REQUEST_GET_CELL_INFO_LIST: request_get_cell_info_list(data, datalen, t); break; case RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE: request_set_cell_info_list_rate(data, datalen, t); break; case RIL_REQUEST_BASEBAND_VERSION: request_baseband_version(t); break; case RIL_REQUEST_SET_TTY_MODE: request_set_tty_mode(data, datalen, t); break; case RIL_REQUEST_QUERY_TTY_MODE: request_get_tty_mode(t); break; case RIL_REQUEST_GET_RADIO_CAPABILITY: request_get_radio_capability(t); break; case RIL_REQUEST_SET_RADIO_CAPABILITY: request_set_radio_capability(data, datalen, t); break; case RIL_REQUEST_SET_DATA_PROFILE: gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); break; case RIL_REQUEST_GET_HARDWARE_CONFIG: request_hardware_config(t); break; case RIL_REQUEST_IMS_REGISTRATION_STATE: request_ims_registration_state(t); break; case RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL: request_sim_apdu(data, datalen, t); break; case RIL_REQUEST_SIM_OPEN_CHANNEL: request_sim_open_channel(data, datalen, t); break; case RIL_REQUEST_SIM_CLOSE_CHANNEL: request_sim_close_channel(data, datalen, t); break; case RIL_REQUEST_IMS_SEND_SMS: request_ims_send_SMS(data, datalen, t); break; case RIL_REQUEST_SET_INITIAL_ATTACH_APN: ALOGW("INITIAL ATTACH APN"); gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); break; // New requests after P. case RIL_REQUEST_START_NETWORK_SCAN: request_start_network_scan(t); break; case RIL_REQUEST_GET_MODEM_STACK_STATUS: request_get_modem_stack_status(request, t); break; case RIL_REQUEST_ENABLE_MODEM: request_enable_modem(request, t); break; case RIL_REQUEST_EMERGENCY_DIAL: request_emergency_dial(request, data, datalen, t); break; case RIL_REQUEST_SET_SIM_CARD_POWER: request_set_sim_card_power(request, data, datalen, t); break; case RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE_BITMAP: request_get_preferred_network_type_bitmap(request, data, datalen, t); break; case RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE_BITMAP: request_set_preferred_network_type_bitmap(request, data, datalen, t); break; case RIL_REQUEST_SET_SYSTEM_SELECTION_CHANNELS: request_set_system_selection_channels(request, t); break; case RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING: gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0); break; case RIL_REQUEST_DEVICE_IDENTITY: request_device_identity(request, data, datalen, t); break; case RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE: request_cdma_get_subscription_source(request, data, datalen, t); break; case RIL_REQUEST_CDMA_SUBSCRIPTION: request_cdma_subscription(request, data, datalen, t); break; case RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE: request_cdma_set_subscription_source(request, data, datalen, t); break; case RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE: request_cdma_get_roaming_preference(request, data, datalen, t); break; case RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE: request_cdma_set_roaming_preference(request, data, datalen, t); break; case RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE: request_exit_emergency_mode(data, datalen, t); break; // New requests after Q. case RIL_REQUEST_SET_SIGNAL_STRENGTH_REPORTING_CRITERIA: request_set_signal_strength_reporting_criteria(request, data, datalen, t); break; case RIL_REQUEST_SET_LINK_CAPACITY_REPORTING_CRITERIA: request_set_link_capacity_reporting_criteria(request, data, datalen, t); break; case RIL_REQUEST_ENABLE_UICC_APPLICATIONS: request_enable_uicc_applications(request, data, datalen, t); break; case RIL_REQUEST_ARE_UICC_APPLICATIONS_ENABLED: request_are_uicc_applications_enabled(request, data, datalen, t); break; case RIL_REQUEST_ENTER_SIM_DEPERSONALIZATION: request_enter_sim_depersonalization(t); break; case RIL_REQUEST_CDMA_SEND_SMS_EXPECT_MORE: request_cdma_send_sms_expect_more(t); break; default: ALOGE("Request %d not supported.", request); gce_ril_env->OnRequestComplete(t, RIL_E_REQUEST_NOT_SUPPORTED, NULL, 0); break; } } #define CUTTLEFISH_RIL_VERSION 6 static const RIL_RadioFunctions ril_callbacks = { CUTTLEFISH_RIL_VERSION, gce_ril_on_request, gce_ril_current_state, gce_ril_on_supports, gce_ril_on_cancel, gce_ril_get_version}; extern "C" { const RIL_RadioFunctions* RIL_Init(const struct RIL_Env* env, int /*argc*/, char** /*argv*/) { time(&gce_ril_start_time); gce_ril_env = env; global_ril_config = cuttlefish::DeviceConfig::Get(); if (!global_ril_config) { ALOGE("Failed to open device configuration!!!"); return nullptr; } TearDownNetworkInterface(); init_modem_supported_network_types(); init_modem_technologies(); init_virtual_network(); init_sim_file_system(); init_sim_status(); return &ril_callbacks; } } // extern "C"