/* * Copyright (C) 2013 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 is 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. */ /* * Manage the listen-mode routing table. */ #include <cutils/log.h> #include <ScopedLocalRef.h> #include <JNIHelp.h> #include "config.h" #include "JavaClassConstants.h" #include "RoutingManager.h" extern "C" { #include "nfa_ee_api.h" #include "nfa_ce_api.h" } extern bool gActivated; extern SyncEvent gDeactivatedEvent; const JNINativeMethod RoutingManager::sMethods [] = { {"doGetDefaultRouteDestination", "()I", (void*) RoutingManager::com_android_nfc_cardemulation_doGetDefaultRouteDestination}, {"doGetDefaultOffHostRouteDestination", "()I", (void*) RoutingManager::com_android_nfc_cardemulation_doGetDefaultOffHostRouteDestination}, {"doGetAidMatchingMode", "()I", (void*) RoutingManager::com_android_nfc_cardemulation_doGetAidMatchingMode} }; static const int MAX_NUM_EE = 5; RoutingManager::RoutingManager () { static const char fn [] = "RoutingManager::RoutingManager()"; unsigned long num = 0; // Get the active SE if (GetNumValue("ACTIVE_SE", &num, sizeof(num))) mActiveSe = num; else mActiveSe = 0x00; // Get the active SE for Nfc-F if (GetNumValue("ACTIVE_SE_NFCF", &num, sizeof(num))) mActiveSeNfcF = num; else mActiveSeNfcF = 0x00; ALOGD("%s: Active SE for Nfc-F is 0x%02X", fn, mActiveSeNfcF); // Get the "default" route if (GetNumValue("DEFAULT_ISODEP_ROUTE", &num, sizeof(num))) mDefaultEe = num; else mDefaultEe = 0x00; ALOGD("%s: default route is 0x%02X", fn, mDefaultEe); // Get the "default" route for Nfc-F if (GetNumValue("DEFAULT_NFCF_ROUTE", &num, sizeof(num))) mDefaultEeNfcF = num; else mDefaultEeNfcF = 0x00; ALOGD("%s: default route for Nfc-F is 0x%02X", fn, mDefaultEeNfcF); // Get the default "off-host" route. This is hard-coded at the Java layer // but we can override it here to avoid forcing Java changes. if (GetNumValue("DEFAULT_OFFHOST_ROUTE", &num, sizeof(num))) mOffHostEe = num; else mOffHostEe = 0xf4; if (GetNumValue("AID_MATCHING_MODE", &num, sizeof(num))) mAidMatchingMode = num; else mAidMatchingMode = AID_MATCHING_EXACT_ONLY; ALOGD("%s: mOffHostEe=0x%02X", fn, mOffHostEe); memset (&mEeInfo, 0, sizeof(mEeInfo)); mReceivedEeInfo = false; mSeTechMask = 0x00; mNfcFOnDhHandle = NFA_HANDLE_INVALID; } RoutingManager::~RoutingManager () { NFA_EeDeregister (nfaEeCallback); } bool RoutingManager::initialize (nfc_jni_native_data* native) { static const char fn [] = "RoutingManager::initialize()"; mNativeData = native; tNFA_STATUS nfaStat; { SyncEventGuard guard (mEeRegisterEvent); ALOGD ("%s: try ee register", fn); nfaStat = NFA_EeRegister (nfaEeCallback); if (nfaStat != NFA_STATUS_OK) { ALOGE ("%s: fail ee register; error=0x%X", fn, nfaStat); return false; } mEeRegisterEvent.wait (); } mRxDataBuffer.clear (); if ((mActiveSe != 0) || (mActiveSeNfcF != 0)) { ALOGD ("%s: Technology Routing (NfcASe:0x%02x, NfcFSe:0x%02x)", fn, mActiveSe, mActiveSeNfcF); { // Wait for EE info if needed SyncEventGuard guard (mEeInfoEvent); if (!mReceivedEeInfo) { ALOGE("Waiting for EE info"); mEeInfoEvent.wait(); } } ALOGD ("%s: Number of EE is %d", fn, mEeInfo.num_ee); for (UINT8 i = 0; i < mEeInfo.num_ee; i++) { tNFA_HANDLE eeHandle = mEeInfo.ee_disc_info[i].ee_handle; tNFA_TECHNOLOGY_MASK seTechMask = 0; ALOGD ("%s EE[%u] Handle: 0x%04x techA: 0x%02x techB: 0x%02x techF: 0x%02x techBprime: 0x%02x", fn, i, eeHandle, mEeInfo.ee_disc_info[i].la_protocol, mEeInfo.ee_disc_info[i].lb_protocol, mEeInfo.ee_disc_info[i].lf_protocol, mEeInfo.ee_disc_info[i].lbp_protocol); if ((mActiveSe != 0) && (eeHandle == (mActiveSe | NFA_HANDLE_GROUP_EE))) { if (mEeInfo.ee_disc_info[i].la_protocol != 0) seTechMask |= NFA_TECHNOLOGY_MASK_A; } if ((mActiveSeNfcF != 0) && (eeHandle == (mActiveSeNfcF | NFA_HANDLE_GROUP_EE))) { if (mEeInfo.ee_disc_info[i].lf_protocol != 0) seTechMask |= NFA_TECHNOLOGY_MASK_F; } ALOGD ("%s: seTechMask[%u]=0x%02x", fn, i, seTechMask); if (seTechMask != 0x00) { ALOGD("Configuring tech mask 0x%02x on EE 0x%04x", seTechMask, eeHandle); nfaStat = NFA_CeConfigureUiccListenTech(eeHandle, seTechMask); if (nfaStat != NFA_STATUS_OK) ALOGE ("Failed to configure UICC listen technologies."); // Set technology routes to UICC if it's there nfaStat = NFA_EeSetDefaultTechRouting(eeHandle, seTechMask, seTechMask, seTechMask); if (nfaStat != NFA_STATUS_OK) ALOGE ("Failed to configure UICC technology routing."); mSeTechMask |= seTechMask; } } } // Tell the host-routing to only listen on Nfc-A nfaStat = NFA_CeSetIsoDepListenTech(NFA_TECHNOLOGY_MASK_A); if (nfaStat != NFA_STATUS_OK) ALOGE ("Failed to configure CE IsoDep technologies"); // Register a wild-card for AIDs routed to the host nfaStat = NFA_CeRegisterAidOnDH (NULL, 0, stackCallback); if (nfaStat != NFA_STATUS_OK) ALOGE("Failed to register wildcard AID for DH"); return true; } RoutingManager& RoutingManager::getInstance () { static RoutingManager manager; return manager; } void RoutingManager::enableRoutingToHost() { tNFA_STATUS nfaStat; tNFA_TECHNOLOGY_MASK techMask; tNFA_PROTOCOL_MASK protoMask; SyncEventGuard guard (mRoutingEvent); // Set default routing at one time when the NFCEE IDs for Nfc-A and Nfc-F are same if (mDefaultEe == mDefaultEeNfcF) { // Route Nfc-A/Nfc-F to host if we don't have a SE techMask = (mSeTechMask ^ (NFA_TECHNOLOGY_MASK_A | NFA_TECHNOLOGY_MASK_F)); if (techMask != 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEe, techMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-A/Nfc-F"); } // Default routing for IsoDep and T3T protocol protoMask = (NFA_PROTOCOL_MASK_ISO_DEP | NFA_PROTOCOL_MASK_T3T); nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEe, protoMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for IsoDep and T3T"); } else { // Route Nfc-A to host if we don't have a SE techMask = NFA_TECHNOLOGY_MASK_A; if ((mSeTechMask & NFA_TECHNOLOGY_MASK_A) == 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEe, techMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-A"); } // Default routing for IsoDep protocol protoMask = NFA_PROTOCOL_MASK_ISO_DEP; nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEe, protoMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for IsoDep"); // Route Nfc-F to host if we don't have a SE techMask = NFA_TECHNOLOGY_MASK_F; if ((mSeTechMask & NFA_TECHNOLOGY_MASK_F) == 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEeNfcF, techMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-F"); } // Default routing for T3T protocol protoMask = NFA_PROTOCOL_MASK_T3T; nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEeNfcF, protoMask, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for T3T"); } } void RoutingManager::disableRoutingToHost() { tNFA_STATUS nfaStat; tNFA_TECHNOLOGY_MASK techMask; SyncEventGuard guard (mRoutingEvent); // Set default routing at one time when the NFCEE IDs for Nfc-A and Nfc-F are same if (mDefaultEe == mDefaultEeNfcF) { // Default routing for Nfc-A/Nfc-F technology if we don't have a SE techMask = (mSeTechMask ^ (NFA_TECHNOLOGY_MASK_A | NFA_TECHNOLOGY_MASK_F)); if (techMask != 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEe, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-A/Nfc-F"); } // Default routing for IsoDep and T3T protocol nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEe, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for IsoDep and T3T"); } else { // Default routing for Nfc-A technology if we don't have a SE if ((mSeTechMask & NFA_TECHNOLOGY_MASK_A) == 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEe, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-A"); } // Default routing for IsoDep protocol nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEe, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for IsoDep"); // Default routing for Nfc-F technology if we don't have a SE if ((mSeTechMask & NFA_TECHNOLOGY_MASK_F) == 0) { nfaStat = NFA_EeSetDefaultTechRouting (mDefaultEeNfcF, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default tech routing for Nfc-F"); } // Default routing for T3T protocol nfaStat = NFA_EeSetDefaultProtoRouting(mDefaultEeNfcF, 0, 0, 0); if (nfaStat == NFA_STATUS_OK) mRoutingEvent.wait (); else ALOGE ("Fail to set default proto routing for T3T"); } } bool RoutingManager::addAidRouting(const UINT8* aid, UINT8 aidLen, int route) { static const char fn [] = "RoutingManager::addAidRouting"; ALOGD ("%s: enter", fn); tNFA_STATUS nfaStat = NFA_EeAddAidRouting(route, aidLen, (UINT8*) aid, 0x01); if (nfaStat == NFA_STATUS_OK) { ALOGD ("%s: routed AID", fn); return true; } else { ALOGE ("%s: failed to route AID", fn); return false; } } bool RoutingManager::removeAidRouting(const UINT8* aid, UINT8 aidLen) { static const char fn [] = "RoutingManager::removeAidRouting"; ALOGD ("%s: enter", fn); tNFA_STATUS nfaStat = NFA_EeRemoveAidRouting(aidLen, (UINT8*) aid); if (nfaStat == NFA_STATUS_OK) { ALOGD ("%s: removed AID", fn); return true; } else { ALOGE ("%s: failed to remove AID", fn); return false; } } bool RoutingManager::commitRouting() { static const char fn [] = "RoutingManager::commitRouting"; tNFA_STATUS nfaStat = 0; ALOGD ("%s", fn); { SyncEventGuard guard (mEeUpdateEvent); nfaStat = NFA_EeUpdateNow(); if (nfaStat == NFA_STATUS_OK) { mEeUpdateEvent.wait (); //wait for NFA_EE_UPDATED_EVT } } return (nfaStat == NFA_STATUS_OK); } void RoutingManager::onNfccShutdown () { static const char fn [] = "RoutingManager:onNfccShutdown"; if (mActiveSe == 0x00) return; tNFA_STATUS nfaStat = NFA_STATUS_FAILED; UINT8 actualNumEe = MAX_NUM_EE; tNFA_EE_INFO eeInfo[MAX_NUM_EE]; memset (&eeInfo, 0, sizeof(eeInfo)); if ((nfaStat = NFA_EeGetInfo (&actualNumEe, eeInfo)) != NFA_STATUS_OK) { ALOGE ("%s: fail get info; error=0x%X", fn, nfaStat); return; } if (actualNumEe != 0) { for (UINT8 xx = 0; xx < actualNumEe; xx++) { if ((eeInfo[xx].num_interface != 0) && (eeInfo[xx].ee_interface[0] != NCI_NFCEE_INTERFACE_HCI_ACCESS) && (eeInfo[xx].ee_status == NFA_EE_STATUS_ACTIVE)) { ALOGD ("%s: Handle: 0x%04x Change Status Active to Inactive", fn, eeInfo[xx].ee_handle); SyncEventGuard guard (mEeSetModeEvent); if ((nfaStat = NFA_EeModeSet (eeInfo[xx].ee_handle, NFA_EE_MD_DEACTIVATE)) == NFA_STATUS_OK) { mEeSetModeEvent.wait (); //wait for NFA_EE_MODE_SET_EVT } else { ALOGE ("Failed to set EE inactive"); } } } } else { ALOGD ("%s: No active EEs found", fn); } } void RoutingManager::notifyActivated (UINT8 technology) { JNIEnv* e = NULL; ScopedAttach attach(mNativeData->vm, &e); if (e == NULL) { ALOGE ("jni env is null"); return; } e->CallVoidMethod (mNativeData->manager, android::gCachedNfcManagerNotifyHostEmuActivated, (int)technology); if (e->ExceptionCheck()) { e->ExceptionClear(); ALOGE ("fail notify"); } } void RoutingManager::notifyDeactivated (UINT8 technology) { mRxDataBuffer.clear(); JNIEnv* e = NULL; ScopedAttach attach(mNativeData->vm, &e); if (e == NULL) { ALOGE ("jni env is null"); return; } e->CallVoidMethod (mNativeData->manager, android::gCachedNfcManagerNotifyHostEmuDeactivated, (int)technology); if (e->ExceptionCheck()) { e->ExceptionClear(); ALOGE ("fail notify"); } } void RoutingManager::handleData (UINT8 technology, const UINT8* data, UINT32 dataLen, tNFA_STATUS status) { if (dataLen <= 0) { ALOGE("no data"); goto TheEnd; } if (status == NFA_STATUS_CONTINUE) { mRxDataBuffer.insert (mRxDataBuffer.end(), &data[0], &data[dataLen]); //append data; more to come return; //expect another NFA_CE_DATA_EVT to come } else if (status == NFA_STATUS_OK) { mRxDataBuffer.insert (mRxDataBuffer.end(), &data[0], &data[dataLen]); //append data //entire data packet has been received; no more NFA_CE_DATA_EVT } else if (status == NFA_STATUS_FAILED) { ALOGE("RoutingManager::handleData: read data fail"); goto TheEnd; } { JNIEnv* e = NULL; ScopedAttach attach(mNativeData->vm, &e); if (e == NULL) { ALOGE ("jni env is null"); goto TheEnd; } ScopedLocalRef<jobject> dataJavaArray(e, e->NewByteArray(mRxDataBuffer.size())); if (dataJavaArray.get() == NULL) { ALOGE ("fail allocate array"); goto TheEnd; } e->SetByteArrayRegion ((jbyteArray)dataJavaArray.get(), 0, mRxDataBuffer.size(), (jbyte *)(&mRxDataBuffer[0])); if (e->ExceptionCheck()) { e->ExceptionClear(); ALOGE ("fail fill array"); goto TheEnd; } e->CallVoidMethod (mNativeData->manager, android::gCachedNfcManagerNotifyHostEmuData, (int)technology, dataJavaArray.get()); if (e->ExceptionCheck()) { e->ExceptionClear(); ALOGE ("fail notify"); } } TheEnd: mRxDataBuffer.clear(); } void RoutingManager::stackCallback (UINT8 event, tNFA_CONN_EVT_DATA* eventData) { static const char fn [] = "RoutingManager::stackCallback"; ALOGD("%s: event=0x%X", fn, event); RoutingManager& routingManager = RoutingManager::getInstance(); switch (event) { case NFA_CE_REGISTERED_EVT: { tNFA_CE_REGISTERED& ce_registered = eventData->ce_registered; ALOGD("%s: NFA_CE_REGISTERED_EVT; status=0x%X; h=0x%X", fn, ce_registered.status, ce_registered.handle); } break; case NFA_CE_DEREGISTERED_EVT: { tNFA_CE_DEREGISTERED& ce_deregistered = eventData->ce_deregistered; ALOGD("%s: NFA_CE_DEREGISTERED_EVT; h=0x%X", fn, ce_deregistered.handle); } break; case NFA_CE_ACTIVATED_EVT: { routingManager.notifyActivated(NFA_TECHNOLOGY_MASK_A); } break; case NFA_DEACTIVATED_EVT: case NFA_CE_DEACTIVATED_EVT: { ALOGD("%s: NFA_DEACTIVATED_EVT, NFA_CE_DEACTIVATED_EVT", fn); routingManager.notifyDeactivated(NFA_TECHNOLOGY_MASK_A); SyncEventGuard g (gDeactivatedEvent); gActivated = false; //guard this variable from multi-threaded access gDeactivatedEvent.notifyOne (); } break; case NFA_CE_DATA_EVT: { tNFA_CE_DATA& ce_data = eventData->ce_data; ALOGD("%s: NFA_CE_DATA_EVT; stat=0x%X; h=0x%X; data len=%u", fn, ce_data.status, ce_data.handle, ce_data.len); getInstance().handleData(NFA_TECHNOLOGY_MASK_A, ce_data.p_data, ce_data.len, ce_data.status); } break; } } /******************************************************************************* ** ** Function: nfaEeCallback ** ** Description: Receive execution environment-related events from stack. ** event: Event code. ** eventData: Event data. ** ** Returns: None ** *******************************************************************************/ void RoutingManager::nfaEeCallback (tNFA_EE_EVT event, tNFA_EE_CBACK_DATA* eventData) { static const char fn [] = "RoutingManager::nfaEeCallback"; RoutingManager& routingManager = RoutingManager::getInstance(); switch (event) { case NFA_EE_REGISTER_EVT: { SyncEventGuard guard (routingManager.mEeRegisterEvent); ALOGD ("%s: NFA_EE_REGISTER_EVT; status=%u", fn, eventData->ee_register); routingManager.mEeRegisterEvent.notifyOne(); } break; case NFA_EE_MODE_SET_EVT: { SyncEventGuard guard (routingManager.mEeSetModeEvent); ALOGD ("%s: NFA_EE_MODE_SET_EVT; status: 0x%04X handle: 0x%04X ", fn, eventData->mode_set.status, eventData->mode_set.ee_handle); routingManager.mEeSetModeEvent.notifyOne(); } break; case NFA_EE_SET_TECH_CFG_EVT: { ALOGD ("%s: NFA_EE_SET_TECH_CFG_EVT; status=0x%X", fn, eventData->status); SyncEventGuard guard(routingManager.mRoutingEvent); routingManager.mRoutingEvent.notifyOne(); } break; case NFA_EE_SET_PROTO_CFG_EVT: { ALOGD ("%s: NFA_EE_SET_PROTO_CFG_EVT; status=0x%X", fn, eventData->status); SyncEventGuard guard(routingManager.mRoutingEvent); routingManager.mRoutingEvent.notifyOne(); } break; case NFA_EE_ACTION_EVT: { tNFA_EE_ACTION& action = eventData->action; if (action.trigger == NFC_EE_TRIG_SELECT) ALOGD ("%s: NFA_EE_ACTION_EVT; h=0x%X; trigger=select (0x%X)", fn, action.ee_handle, action.trigger); else if (action.trigger == NFC_EE_TRIG_APP_INIT) { tNFC_APP_INIT& app_init = action.param.app_init; ALOGD ("%s: NFA_EE_ACTION_EVT; h=0x%X; trigger=app-init (0x%X); aid len=%u; data len=%u", fn, action.ee_handle, action.trigger, app_init.len_aid, app_init.len_data); } else if (action.trigger == NFC_EE_TRIG_RF_PROTOCOL) ALOGD ("%s: NFA_EE_ACTION_EVT; h=0x%X; trigger=rf protocol (0x%X)", fn, action.ee_handle, action.trigger); else if (action.trigger == NFC_EE_TRIG_RF_TECHNOLOGY) ALOGD ("%s: NFA_EE_ACTION_EVT; h=0x%X; trigger=rf tech (0x%X)", fn, action.ee_handle, action.trigger); else ALOGE ("%s: NFA_EE_ACTION_EVT; h=0x%X; unknown trigger (0x%X)", fn, action.ee_handle, action.trigger); } break; case NFA_EE_DISCOVER_REQ_EVT: { ALOGD ("%s: NFA_EE_DISCOVER_REQ_EVT; status=0x%X; num ee=%u", __FUNCTION__, eventData->discover_req.status, eventData->discover_req.num_ee); SyncEventGuard guard (routingManager.mEeInfoEvent); memcpy (&routingManager.mEeInfo, &eventData->discover_req, sizeof(routingManager.mEeInfo)); routingManager.mReceivedEeInfo = true; routingManager.mEeInfoEvent.notifyOne(); } break; case NFA_EE_NO_CB_ERR_EVT: ALOGD ("%s: NFA_EE_NO_CB_ERR_EVT status=%u", fn, eventData->status); break; case NFA_EE_ADD_AID_EVT: { ALOGD ("%s: NFA_EE_ADD_AID_EVT status=%u", fn, eventData->status); } break; case NFA_EE_REMOVE_AID_EVT: { ALOGD ("%s: NFA_EE_REMOVE_AID_EVT status=%u", fn, eventData->status); } break; case NFA_EE_NEW_EE_EVT: { ALOGD ("%s: NFA_EE_NEW_EE_EVT h=0x%X; status=%u", fn, eventData->new_ee.ee_handle, eventData->new_ee.ee_status); } break; case NFA_EE_UPDATED_EVT: { ALOGD("%s: NFA_EE_UPDATED_EVT", fn); SyncEventGuard guard(routingManager.mEeUpdateEvent); routingManager.mEeUpdateEvent.notifyOne(); } break; default: ALOGE ("%s: unknown event=%u ????", fn, event); break; } } int RoutingManager::registerT3tIdentifier(UINT8* t3tId, UINT8 t3tIdLen) { static const char fn [] = "RoutingManager::registerT3tIdentifier"; ALOGD ("%s: Start to register NFC-F system on DH", fn); if (t3tIdLen != (2 + NCI_RF_F_UID_LEN)) { ALOGE ("%s: Invalid length of T3T Identifier", fn); return NFA_HANDLE_INVALID; } SyncEventGuard guard (mRoutingEvent); mNfcFOnDhHandle = NFA_HANDLE_INVALID; int systemCode; UINT8 nfcid2[NCI_RF_F_UID_LEN]; systemCode = (((int)t3tId[0] << 8) | ((int)t3tId[1] << 0)); memcpy(nfcid2, t3tId + 2, NCI_RF_F_UID_LEN); tNFA_STATUS nfaStat = NFA_CeRegisterFelicaSystemCodeOnDH (systemCode, nfcid2, nfcFCeCallback); if (nfaStat == NFA_STATUS_OK) { mRoutingEvent.wait (); } else { ALOGE ("%s: Fail to register NFC-F system on DH", fn); return NFA_HANDLE_INVALID; } ALOGD ("%s: Succeed to register NFC-F system on DH", fn); return mNfcFOnDhHandle; } void RoutingManager::deregisterT3tIdentifier(int handle) { static const char fn [] = "RoutingManager::deregisterT3tIdentifier"; ALOGD ("%s: Start to deregister NFC-F system on DH", fn); SyncEventGuard guard (mRoutingEvent); tNFA_STATUS nfaStat = NFA_CeDeregisterFelicaSystemCodeOnDH (handle); if (nfaStat == NFA_STATUS_OK) { mRoutingEvent.wait (); ALOGD ("%s: Succeeded in deregistering NFC-F system on DH", fn); } else { ALOGE ("%s: Fail to deregister NFC-F system on DH", fn); } } void RoutingManager::nfcFCeCallback (UINT8 event, tNFA_CONN_EVT_DATA* eventData) { static const char fn [] = "RoutingManager::nfcFCeCallback"; RoutingManager& routingManager = RoutingManager::getInstance(); ALOGD("%s: 0x%x", __FUNCTION__, event); switch (event) { case NFA_CE_REGISTERED_EVT: { ALOGD ("%s: registerd event notified", fn); routingManager.mNfcFOnDhHandle = eventData->ce_registered.handle; SyncEventGuard guard(routingManager.mRoutingEvent); routingManager.mRoutingEvent.notifyOne(); } break; case NFA_CE_DEREGISTERED_EVT: { ALOGD ("%s: deregisterd event notified", fn); SyncEventGuard guard(routingManager.mRoutingEvent); routingManager.mRoutingEvent.notifyOne(); } break; case NFA_CE_ACTIVATED_EVT: { ALOGD ("%s: activated event notified", fn); routingManager.notifyActivated(NFA_TECHNOLOGY_MASK_F); } break; case NFA_CE_DEACTIVATED_EVT: { ALOGD ("%s: deactivated event notified", fn); routingManager.notifyDeactivated(NFA_TECHNOLOGY_MASK_F); } break; case NFA_CE_DATA_EVT: { ALOGD ("%s: data event notified", fn); tNFA_CE_DATA& ce_data = eventData->ce_data; routingManager.handleData(NFA_TECHNOLOGY_MASK_F, ce_data.p_data, ce_data.len, ce_data.status); } break; default: { ALOGE ("%s: unknown event=%u ????", fn, event); } break; } } int RoutingManager::registerJniFunctions (JNIEnv* e) { static const char fn [] = "RoutingManager::registerJniFunctions"; ALOGD ("%s", fn); return jniRegisterNativeMethods (e, "com/android/nfc/cardemulation/AidRoutingManager", sMethods, NELEM(sMethods)); } int RoutingManager::com_android_nfc_cardemulation_doGetDefaultRouteDestination (JNIEnv*) { return getInstance().mDefaultEe; } int RoutingManager::com_android_nfc_cardemulation_doGetDefaultOffHostRouteDestination (JNIEnv*) { return getInstance().mOffHostEe; } int RoutingManager::com_android_nfc_cardemulation_doGetAidMatchingMode (JNIEnv*) { return getInstance().mAidMatchingMode; }