nfc/1.0/vts/functional/VtsHalNfcV1_0TargetTest.cpp - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * Copyright (C) 2016 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.
  */

 #define LOG_TAG "nfc_hidl_hal_test"
 #include <android-base/logging.h>

 #include <android/hardware/nfc/1.0/INfc.h>
 #include <android/hardware/nfc/1.0/INfcClientCallback.h>
 #include <android/hardware/nfc/1.0/types.h>
 #include <gtest/gtest.h>
 #include <hardware/nfc.h>
 #include <hidl/GtestPrinter.h>
 #include <hidl/ServiceManagement.h>

 #include <VtsHalHidlTargetCallbackBase.h>

 using ::android::hardware::nfc::V1_0::INfc;
 using ::android::hardware::nfc::V1_0::INfcClientCallback;
 using ::android::hardware::nfc::V1_0::NfcEvent;
 using ::android::hardware::nfc::V1_0::NfcStatus;
 using ::android::hardware::nfc::V1_0::NfcData;
 using ::android::hardware::Return;
 using ::android::hardware::Void;
 using ::android::hardware::hidl_vec;
 using ::android::sp;

 /* NCI Commands */
 #define CORE_RESET_CMD \
   { 0x20, 0x00, 0x01, 0x00 }
 #define CORE_RESET_CMD_CONFIG_RESET \
   { 0x20, 0x00, 0x01, 0x01 }
 #define CORE_CONN_CREATE_CMD \
   { 0x20, 0x04, 0x02, 0x01, 0x00 }
 #define CORE_INIT_CMD \
     { 0x20, 0x01, 0x00 }
 #define CORE_INIT_CMD_NCI20 \
     { 0x20, 0x01, 0x02, 0x00, 0x00 }
 #define INVALID_COMMAND \
   { 0x20, 0x00, 0x00 }

 #define LOOP_BACK_HEADER_SIZE 3
 #define SYNTAX_ERROR 5
 #define NUMBER_LOOPS 3922
 #define NCI_VERSION_1_1 0x11
 #define NCI_VERSION_2 0x20
 #define TIMEOUT_PERIOD 5

 constexpr char kCallbackNameSendEvent[] = "sendEvent";
 constexpr char kCallbackNameSendData[] = "sendData";

 class NfcClientCallbackArgs {
    public:
     NfcEvent last_event_;
     NfcStatus last_status_;
     NfcData last_data_;
 };

 /* Callback class for data & Event. */
 class NfcClientCallback
     : public ::testing::VtsHalHidlTargetCallbackBase<NfcClientCallbackArgs>,
       public INfcClientCallback {
    public:
     virtual ~NfcClientCallback() = default;

     /* sendEvent callback function - Records the Event & Status
      * and notifies the TEST
      **/
     Return<void> sendEvent(NfcEvent event, NfcStatus event_status) override {
         NfcClientCallbackArgs args;
         args.last_event_ = event;
         args.last_status_ = event_status;
         NotifyFromCallback(kCallbackNameSendEvent, args);
         return Void();
     };

     /* sendData callback function. Records the data and notifies the TEST*/
     Return<void> sendData(const NfcData& data) override {
         NfcClientCallbackArgs args;
         args.last_data_ = data;
         NotifyFromCallback(kCallbackNameSendData, args);
         return Void();
     };
 };

 // The main test class for NFC HIDL HAL.
 class NfcHidlTest : public ::testing::TestWithParam<std::string> {
  public:
   virtual void SetUp() override {
     nfc_ = INfc::getService(GetParam());
     ASSERT_NE(nfc_, nullptr);

     nfc_cb_ = new NfcClientCallback();
     ASSERT_NE(nfc_cb_, nullptr);

     EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
     // Wait for OPEN_CPLT event
     auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
     EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

     /* Get the NCI version that the device supports */
     std::vector<uint8_t> cmd = CORE_RESET_CMD;
     NfcData data = cmd;
     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_RESET_RSP
     res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_GE(6ul, res.args->last_data_.size());
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
     if (res.args->last_data_.size() == 6) {
         nci_version = res.args->last_data_[4];
     } else {
         EXPECT_EQ(4ul, res.args->last_data_.size());
         nci_version = NCI_VERSION_2;
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
     }

     /*
      * Close the hal and then re-open to make sure we are in a predictable
      * state for all the tests.
      */
     EXPECT_EQ(NfcStatus::OK, nfc_->close());
     // Wait for CLOSE_CPLT event
     res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
     EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

     EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
     // Wait for OPEN_CPLT event
     res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
     EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
   }

   virtual void TearDown() override {
     EXPECT_EQ(NfcStatus::OK, nfc_->close());
     // Wait for CLOSE_CPLT event
     auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
     EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
   }

   /* NCI version the device supports
    * 0x11 for NCI 1.1, 0x20 for NCI 2.0 and so forth */
   uint8_t nci_version;
   sp<INfc> nfc_;
   sp<NfcClientCallback> nfc_cb_;
 };

 /*
  * OpenAndClose:
  * Makes an open call, waits for NfcEvent.OPEN_CPLT
  * Immediately calls close() and waits for NfcEvent.CLOSE_CPLT
  * Since open and close calls are a part of SetUp() and TearDown(),
  * the function definition is intentionally kept empty
  */
 TEST_P(NfcHidlTest, OpenAndClose) {}

 /*
  * WriteCoreReset:
  * Sends CORE_RESET_CMD
  * Waits for CORE_RESET_RSP
  * Checks the status, version number and configuration status
  */
 TEST_P(NfcHidlTest, WriteCoreReset) {
   std::vector<uint8_t> cmd = CORE_RESET_CMD;
   NfcData data = cmd;
   EXPECT_EQ(data.size(), nfc_->write(data));
   // Wait for CORE_RESET_RSP
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
   EXPECT_TRUE(res.no_timeout);

   /* The response/notification format for CORE_RESET_CMD differs
    * with NCI 1.0 and 2.0. */
   if (nci_version <= NCI_VERSION_1_1) {
       EXPECT_EQ(6ul, res.args->last_data_.size());
       EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
       EXPECT_GE(NCI_VERSION_1_1, res.args->last_data_[4]);
       EXPECT_GE(1ul, res.args->last_data_[5]);
   } else {
       EXPECT_EQ(4ul, res.args->last_data_.size());
       EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
       // Wait for CORE_RESET_NTF
       res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
       EXPECT_TRUE(res.no_timeout);
       // Check if reset trigger was due to CORE_RESET_CMD
       EXPECT_LE(8ul, res.args->last_data_.size());
       EXPECT_EQ(2ul, res.args->last_data_[3]);
       EXPECT_GE(1ul, res.args->last_data_[4]);
       EXPECT_EQ(NCI_VERSION_2, res.args->last_data_[5]);
   }
 }

 /*
  * WriteCoreResetConfigReset:
  * Sends CORE_RESET_CMD_CONFIG_RESET
  * Waits for CORE_RESET_RSP
  * Checks the status, version number and configuration status
  */
 TEST_P(NfcHidlTest, WriteCoreResetConfigReset) {
   std::vector<uint8_t> cmd = CORE_RESET_CMD_CONFIG_RESET;
   NfcData data = cmd;
   EXPECT_EQ(data.size(), nfc_->write(data));
   // Wait for CORE_RESET_RSP
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
   EXPECT_TRUE(res.no_timeout);

   /* The response/notification format for CORE_RESET_CMD differs
    * with NCI 1.0 and 2.0. */
   if (nci_version <= NCI_VERSION_1_1) {
       EXPECT_EQ(6ul, res.args->last_data_.size());
       EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
       EXPECT_GE(NCI_VERSION_1_1, res.args->last_data_[4]);
       EXPECT_EQ(1ul, res.args->last_data_[5]);
   } else {
       EXPECT_EQ(4ul, res.args->last_data_.size());
       EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
       // Wait for CORE_RESET_NTF
       res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
       EXPECT_TRUE(res.no_timeout);
       // Check if reset trigger was due to CORE_RESET_CMD
       EXPECT_LE(8ul, res.args->last_data_.size());
       EXPECT_EQ(2ul, res.args->last_data_[3]);
       EXPECT_EQ(1ul, res.args->last_data_[4]);
       EXPECT_EQ(NCI_VERSION_2, res.args->last_data_[5]);
   }
 }

 /*
  * WriteInvalidCommand:
  * Sends an invalid command
  * Waits for response
  * Checks SYNTAX_ERROR status
  */
 TEST_P(NfcHidlTest, WriteInvalidCommand) {
   // Send an Error Command
   std::vector<uint8_t> cmd = INVALID_COMMAND;
   NfcData data = cmd;
   EXPECT_EQ(data.size(), nfc_->write(data));
   // Wait for RSP
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(4ul, res.args->last_data_.size());
   EXPECT_EQ(SYNTAX_ERROR, res.args->last_data_[3]);
 }

 /*
  * WriteInvalidAndThenValidCommand:
  * Sends an Invalid command
  * Waits for response
  * Checks SYNTAX_ERROR status
  * Repeat for 100 times appending 0xFF each time to the packet
  * Send CORE_CONN_CREATE_CMD for loop-back mode
  * Check the response
  */
 TEST_P(NfcHidlTest, WriteInvalidAndThenValidCommand) {
     std::vector<uint8_t> cmd = CORE_RESET_CMD;
     NfcData data = cmd;
     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_RESET_RSP
     auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);

     /* NCI 2.0 sends CORE_RESET_NTF everytime. */
     if (nci_version == NCI_VERSION_2) {
         // Wait for CORE_RESET_NTF
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
         cmd = CORE_INIT_CMD_NCI20;
     } else {
         cmd = CORE_INIT_CMD;
     }
     data = cmd;

     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_INIT_RSP
     res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
     if (nci_version == NCI_VERSION_2 && res.args->last_data_.size() > 13 &&
         res.args->last_data_[13] == 0x00) {
         // Wait for CORE_CONN_CREDITS_NTF
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
     }
     // Send an Error Data Packet
     cmd = INVALID_COMMAND;
     data = cmd;
     size_t size = data.size();

     for (int i = 0; i < 100; i++) {
         data.resize(++size);
         data[size - 1] = 0xFF;
         EXPECT_EQ(data.size(), nfc_->write(data));
         // Wait for response with SYNTAX_ERROR
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
         EXPECT_EQ(4ul, res.args->last_data_.size());
         EXPECT_EQ(SYNTAX_ERROR, res.args->last_data_[3]);
   }

   cmd = CORE_CONN_CREATE_CMD;
   data = cmd;
   EXPECT_EQ(data.size(), nfc_->write(data));
   // Wait for CORE_CONN_CREATE_RSP
   res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(7ul, res.args->last_data_.size());
   EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
 }
 /*
  * Bandwidth:
  * Sets the loop-back mode using CORE_CONN_CREATE_CMD
  * Sends max payload size data
  * Waits for the response
  * Checks the data received
  * Repeat to send total of 1Mb data
  */
 TEST_P(NfcHidlTest, Bandwidth) {
     std::vector<uint8_t> cmd = CORE_RESET_CMD;
     NfcData data = cmd;
     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_RESET_RSP
     auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);

     /* NCI 2.0 sends CORE_RESET_NTF everytime. */
     if (nci_version == NCI_VERSION_2) {
         // Wait for CORE_RESET_NTF
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
         cmd = CORE_INIT_CMD_NCI20;
     } else {
         cmd = CORE_INIT_CMD;
     }
     data = cmd;

     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_INIT_RSP
     res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
     if (nci_version == NCI_VERSION_2 && res.args->last_data_.size() > 13 &&
         res.args->last_data_[13] == 0x00) {
         // Wait for CORE_CONN_CREDITS_NTF
         res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res.no_timeout);
     }

     cmd = CORE_CONN_CREATE_CMD;
     data = cmd;
     EXPECT_EQ(data.size(), nfc_->write(data));
     // Wait for CORE_CONN_CREATE_RSP
     res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_TRUE(res.no_timeout);
     EXPECT_EQ(7ul, res.args->last_data_.size());
     EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
     uint8_t conn_id = res.args->last_data_[6];
     uint32_t max_payload_size = res.args->last_data_[4];

     for (int loops = 0; loops < NUMBER_LOOPS; loops++) {
         res.args->last_data_.resize(0);
         data.resize(max_payload_size + LOOP_BACK_HEADER_SIZE);
         data[0] = conn_id;
         data[1] = 0x00;
         data[2] = max_payload_size;
         for (uint32_t i = 0; i < max_payload_size; i++) {
             data[i + LOOP_BACK_HEADER_SIZE] = i;
         }
         EXPECT_EQ(max_payload_size + LOOP_BACK_HEADER_SIZE, nfc_->write(data));
         // Wait for data and CORE_CONN_CREDITS_NTF
         auto res1 = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res1.no_timeout);
         auto res2 = nfc_cb_->WaitForCallback(kCallbackNameSendData);
         EXPECT_TRUE(res2.no_timeout);
         // Check if the same data was received back
         EXPECT_TRUE(res1.args);
         EXPECT_TRUE(res2.args);

         NfcData credits_ntf = res1.args->last_data_;
         NfcData received_data = res2.args->last_data_;
         /* It is possible that CORE_CONN_CREDITS_NTF is received before data,
          * Find the order and do further checks depending on that */
         if (received_data.size() != data.size()) {
             credits_ntf = res2.args->last_data_;
             received_data = res1.args->last_data_;
         }
         EXPECT_EQ(data.size(), received_data.size());
         for (size_t i = 0; i < data.size(); i++) {
             EXPECT_EQ(data[i], received_data[i]);
         }

         EXPECT_EQ(6ul, credits_ntf.size());
         // Check if the credit is refilled to 1
         EXPECT_EQ(1, credits_ntf[5]);
   }
 }

 /*
  * PowerCycle:
  * Calls powerCycle()
  * Waits for NfcEvent.OPEN_CPLT
  * Checks status
  */
 TEST_P(NfcHidlTest, PowerCycle) {
   EXPECT_EQ(NfcStatus::OK, nfc_->powerCycle());
   // Wait for NfcEvent.OPEN_CPLT
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
 }

 /*
  * PowerCycleAfterClose:
  * Calls powerCycle() after close()
  * Checks status
  */
 TEST_P(NfcHidlTest, PowerCycleAfterClose) {
   EXPECT_EQ(NfcStatus::OK, nfc_->close());
   // Wait for CLOSE_CPLT event
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

   EXPECT_EQ(NfcStatus::FAILED, nfc_->powerCycle());

   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
   // Wait for OPEN_CPLT event
   res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
 }

 /*
  * CoreInitialized:
  * Calls coreInitialized() with different data
  * Waits for NfcEvent.POST_INIT_CPLT
  */
 TEST_P(NfcHidlTest, CoreInitialized) {
   NfcData data;
   data.resize(1);
   // These parameters might lead to device specific proprietary behavior
   // Using > 10 values should result in predictable and common results for
   // most devices.
   for (int i = 10; i <= 16; i++) {
       data[0] = i;
       NfcStatus status = nfc_->coreInitialized(data);

       /* In case coreInitialized returned FAILED, do not wait for
        * POST_INIT_CLPT event. */
       if (status == NfcStatus::FAILED) continue;

       EXPECT_EQ(NfcStatus::OK, status);
       // Wait for NfcEvent.POST_INIT_CPLT
       auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
       EXPECT_TRUE(res.no_timeout);
       EXPECT_EQ(NfcEvent::POST_INIT_CPLT, res.args->last_event_);
   }
 }

 /*
  * ControlGranted:
  * Calls controlGranted()
  * Checks the return value
  */
 TEST_P(NfcHidlTest, ControlGranted) {
   EXPECT_EQ(NfcStatus::OK, nfc_->controlGranted());
 }

 /*
  * ControlGrantedAfterClose:
  * Call controlGranted() after close
  * Checks the return value
  */
 TEST_P(NfcHidlTest, ControlGrantedAfterClose) {
   EXPECT_EQ(NfcStatus::OK, nfc_->close());
   // Wait for CLOSE_CPLT event
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

   EXPECT_EQ(NfcStatus::OK, nfc_->controlGranted());

   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
   // Wait for OPEN_CPLT event
   res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
 }

 /* PreDiscover:
  * Calls prediscover()
  * Checks the return value
  */
 TEST_P(NfcHidlTest, PreDiscover) {
   EXPECT_EQ(NfcStatus::OK, nfc_->prediscover());
 }

 /*
  * PreDiscoverAfterClose:
  * Call prediscover() after close
  * Checks the return value
  */
 TEST_P(NfcHidlTest, PreDiscoverAfterClose) {
   EXPECT_EQ(NfcStatus::OK, nfc_->close());
   // Wait for CLOSE_CPLT event
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

   EXPECT_EQ(NfcStatus::OK, nfc_->prediscover());

   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
   // Wait for OPEN_CPLT event
   res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
 }

 /*
  * CloseAfterClose:
  * Calls close() multiple times
  * Checks status
  */
 TEST_P(NfcHidlTest, CloseAfterClose) {
   EXPECT_EQ(NfcStatus::OK, nfc_->close());
   // Wait for CLOSE_CPLT event
   auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

   EXPECT_EQ(NfcStatus::FAILED, nfc_->close());

   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
   // Wait for OPEN_CPLT event
   res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
   EXPECT_TRUE(res.no_timeout);
   EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
   EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
 }

 /*
  * OpenAfterOpen:
  * Calls open() multiple times
  * Checks status
  */
 TEST_P(NfcHidlTest, OpenAfterOpen) {
   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
   EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
 }

 GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(NfcHidlTest);
 INSTANTIATE_TEST_SUITE_P(
         PerInstance, NfcHidlTest,
         testing::ValuesIn(android::hardware::getAllHalInstanceNames(INfc::descriptor)),
         android::hardware::PrintInstanceNameToString);

 int main(int argc, char** argv) {
   ::testing::InitGoogleTest(&argc, argv);

   std::system("svc nfc disable"); /* Turn off NFC */
   sleep(5);

   int status = RUN_ALL_TESTS();
   LOG(INFO) << "Test result = " << status;

   std::system("svc nfc enable"); /* Turn on NFC */
   sleep(5);

   return status;
 }
	/*
	* Copyright (C) 2016 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.
	*/

	#define LOG_TAG "nfc_hidl_hal_test"
	#include <android-base/logging.h>

	#include <android/hardware/nfc/1.0/INfc.h>
	#include <android/hardware/nfc/1.0/INfcClientCallback.h>
	#include <android/hardware/nfc/1.0/types.h>
	#include <gtest/gtest.h>
	#include <hardware/nfc.h>
	#include <hidl/GtestPrinter.h>
	#include <hidl/ServiceManagement.h>

	#include <VtsHalHidlTargetCallbackBase.h>

	using ::android::hardware::nfc::V1_0::INfc;
	using ::android::hardware::nfc::V1_0::INfcClientCallback;
	using ::android::hardware::nfc::V1_0::NfcEvent;
	using ::android::hardware::nfc::V1_0::NfcStatus;
	using ::android::hardware::nfc::V1_0::NfcData;
	using ::android::hardware::Return;
	using ::android::hardware::Void;
	using ::android::hardware::hidl_vec;
	using ::android::sp;

	/* NCI Commands */
	#define CORE_RESET_CMD \
	{ 0x20, 0x00, 0x01, 0x00 }
	#define CORE_RESET_CMD_CONFIG_RESET \
	{ 0x20, 0x00, 0x01, 0x01 }
	#define CORE_CONN_CREATE_CMD \
	{ 0x20, 0x04, 0x02, 0x01, 0x00 }
	#define CORE_INIT_CMD \
	{ 0x20, 0x01, 0x00 }
	#define CORE_INIT_CMD_NCI20 \
	{ 0x20, 0x01, 0x02, 0x00, 0x00 }
	#define INVALID_COMMAND \
	{ 0x20, 0x00, 0x00 }

	#define LOOP_BACK_HEADER_SIZE 3
	#define SYNTAX_ERROR 5
	#define NUMBER_LOOPS 3922
	#define NCI_VERSION_1_1 0x11
	#define NCI_VERSION_2 0x20
	#define TIMEOUT_PERIOD 5

	constexpr char kCallbackNameSendEvent[] = "sendEvent";
	constexpr char kCallbackNameSendData[] = "sendData";

	class NfcClientCallbackArgs {
	public:
	NfcEvent last_event_;
	NfcStatus last_status_;
	NfcData last_data_;
	};

	/* Callback class for data & Event. */
	class NfcClientCallback
	: public ::testing::VtsHalHidlTargetCallbackBase<NfcClientCallbackArgs>,
	public INfcClientCallback {
	public:
	virtual ~NfcClientCallback() = default;

	/* sendEvent callback function - Records the Event & Status
	* and notifies the TEST
	**/
	Return<void> sendEvent(NfcEvent event, NfcStatus event_status) override {
	NfcClientCallbackArgs args;
	args.last_event_ = event;
	args.last_status_ = event_status;
	NotifyFromCallback(kCallbackNameSendEvent, args);
	return Void();
	};

	/* sendData callback function. Records the data and notifies the TEST*/
	Return<void> sendData(const NfcData& data) override {
	NfcClientCallbackArgs args;
	args.last_data_ = data;
	NotifyFromCallback(kCallbackNameSendData, args);
	return Void();
	};
	};

	// The main test class for NFC HIDL HAL.
	class NfcHidlTest : public ::testing::TestWithParam<std::string> {
	public:
	virtual void SetUp() override {
	nfc_ = INfc::getService(GetParam());
	ASSERT_NE(nfc_, nullptr);

	nfc_cb_ = new NfcClientCallback();
	ASSERT_NE(nfc_cb_, nullptr);

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	/* Get the NCI version that the device supports */
	std::vector<uint8_t> cmd = CORE_RESET_CMD;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_RESET_RSP
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_GE(6ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	if (res.args->last_data_.size() == 6) {
	nci_version = res.args->last_data_[4];
	} else {
	EXPECT_EQ(4ul, res.args->last_data_.size());
	nci_version = NCI_VERSION_2;
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	}

	/*
	* Close the hal and then re-open to make sure we are in a predictable
	* state for all the tests.
	*/
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	virtual void TearDown() override {
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/* NCI version the device supports
	* 0x11 for NCI 1.1, 0x20 for NCI 2.0 and so forth */
	uint8_t nci_version;
	sp<INfc> nfc_;
	sp<NfcClientCallback> nfc_cb_;
	};

	/*
	* OpenAndClose:
	* Makes an open call, waits for NfcEvent.OPEN_CPLT
	* Immediately calls close() and waits for NfcEvent.CLOSE_CPLT
	* Since open and close calls are a part of SetUp() and TearDown(),
	* the function definition is intentionally kept empty
	*/
	TEST_P(NfcHidlTest, OpenAndClose) {}

	/*
	* WriteCoreReset:
	* Sends CORE_RESET_CMD
	* Waits for CORE_RESET_RSP
	* Checks the status, version number and configuration status
	*/
	TEST_P(NfcHidlTest, WriteCoreReset) {
	std::vector<uint8_t> cmd = CORE_RESET_CMD;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_RESET_RSP
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);

	/* The response/notification format for CORE_RESET_CMD differs
	* with NCI 1.0 and 2.0. */
	if (nci_version <= NCI_VERSION_1_1) {
	EXPECT_EQ(6ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	EXPECT_GE(NCI_VERSION_1_1, res.args->last_data_[4]);
	EXPECT_GE(1ul, res.args->last_data_[5]);
	} else {
	EXPECT_EQ(4ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	// Wait for CORE_RESET_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	// Check if reset trigger was due to CORE_RESET_CMD
	EXPECT_LE(8ul, res.args->last_data_.size());
	EXPECT_EQ(2ul, res.args->last_data_[3]);
	EXPECT_GE(1ul, res.args->last_data_[4]);
	EXPECT_EQ(NCI_VERSION_2, res.args->last_data_[5]);
	}
	}

	/*
	* WriteCoreResetConfigReset:
	* Sends CORE_RESET_CMD_CONFIG_RESET
	* Waits for CORE_RESET_RSP
	* Checks the status, version number and configuration status
	*/
	TEST_P(NfcHidlTest, WriteCoreResetConfigReset) {
	std::vector<uint8_t> cmd = CORE_RESET_CMD_CONFIG_RESET;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_RESET_RSP
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);

	/* The response/notification format for CORE_RESET_CMD differs
	* with NCI 1.0 and 2.0. */
	if (nci_version <= NCI_VERSION_1_1) {
	EXPECT_EQ(6ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	EXPECT_GE(NCI_VERSION_1_1, res.args->last_data_[4]);
	EXPECT_EQ(1ul, res.args->last_data_[5]);
	} else {
	EXPECT_EQ(4ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	// Wait for CORE_RESET_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	// Check if reset trigger was due to CORE_RESET_CMD
	EXPECT_LE(8ul, res.args->last_data_.size());
	EXPECT_EQ(2ul, res.args->last_data_[3]);
	EXPECT_EQ(1ul, res.args->last_data_[4]);
	EXPECT_EQ(NCI_VERSION_2, res.args->last_data_[5]);
	}
	}

	/*
	* WriteInvalidCommand:
	* Sends an invalid command
	* Waits for response
	* Checks SYNTAX_ERROR status
	*/
	TEST_P(NfcHidlTest, WriteInvalidCommand) {
	// Send an Error Command
	std::vector<uint8_t> cmd = INVALID_COMMAND;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for RSP
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(4ul, res.args->last_data_.size());
	EXPECT_EQ(SYNTAX_ERROR, res.args->last_data_[3]);
	}

	/*
	* WriteInvalidAndThenValidCommand:
	* Sends an Invalid command
	* Waits for response
	* Checks SYNTAX_ERROR status
	* Repeat for 100 times appending 0xFF each time to the packet
	* Send CORE_CONN_CREATE_CMD for loop-back mode
	* Check the response
	*/
	TEST_P(NfcHidlTest, WriteInvalidAndThenValidCommand) {
	std::vector<uint8_t> cmd = CORE_RESET_CMD;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_RESET_RSP
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);

	/* NCI 2.0 sends CORE_RESET_NTF everytime. */
	if (nci_version == NCI_VERSION_2) {
	// Wait for CORE_RESET_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	cmd = CORE_INIT_CMD_NCI20;
	} else {
	cmd = CORE_INIT_CMD;
	}
	data = cmd;

	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_INIT_RSP
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	if (nci_version == NCI_VERSION_2 && res.args->last_data_.size() > 13 &&
	res.args->last_data_[13] == 0x00) {
	// Wait for CORE_CONN_CREDITS_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	}
	// Send an Error Data Packet
	cmd = INVALID_COMMAND;
	data = cmd;
	size_t size = data.size();

	for (int i = 0; i < 100; i++) {
	data.resize(++size);
	data[size - 1] = 0xFF;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for response with SYNTAX_ERROR
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(4ul, res.args->last_data_.size());
	EXPECT_EQ(SYNTAX_ERROR, res.args->last_data_[3]);
	}

	cmd = CORE_CONN_CREATE_CMD;
	data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_CONN_CREATE_RSP
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(7ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	}
	/*
	* Bandwidth:
	* Sets the loop-back mode using CORE_CONN_CREATE_CMD
	* Sends max payload size data
	* Waits for the response
	* Checks the data received
	* Repeat to send total of 1Mb data
	*/
	TEST_P(NfcHidlTest, Bandwidth) {
	std::vector<uint8_t> cmd = CORE_RESET_CMD;
	NfcData data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_RESET_RSP
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);

	/* NCI 2.0 sends CORE_RESET_NTF everytime. */
	if (nci_version == NCI_VERSION_2) {
	// Wait for CORE_RESET_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	cmd = CORE_INIT_CMD_NCI20;
	} else {
	cmd = CORE_INIT_CMD;
	}
	data = cmd;

	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_INIT_RSP
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	if (nci_version == NCI_VERSION_2 && res.args->last_data_.size() > 13 &&
	res.args->last_data_[13] == 0x00) {
	// Wait for CORE_CONN_CREDITS_NTF
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	}

	cmd = CORE_CONN_CREATE_CMD;
	data = cmd;
	EXPECT_EQ(data.size(), nfc_->write(data));
	// Wait for CORE_CONN_CREATE_RSP
	res = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(7ul, res.args->last_data_.size());
	EXPECT_EQ((int)NfcStatus::OK, res.args->last_data_[3]);
	uint8_t conn_id = res.args->last_data_[6];
	uint32_t max_payload_size = res.args->last_data_[4];

	for (int loops = 0; loops < NUMBER_LOOPS; loops++) {
	res.args->last_data_.resize(0);
	data.resize(max_payload_size + LOOP_BACK_HEADER_SIZE);
	data[0] = conn_id;
	data[1] = 0x00;
	data[2] = max_payload_size;
	for (uint32_t i = 0; i < max_payload_size; i++) {
	data[i + LOOP_BACK_HEADER_SIZE] = i;
	}
	EXPECT_EQ(max_payload_size + LOOP_BACK_HEADER_SIZE, nfc_->write(data));
	// Wait for data and CORE_CONN_CREDITS_NTF
	auto res1 = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res1.no_timeout);
	auto res2 = nfc_cb_->WaitForCallback(kCallbackNameSendData);
	EXPECT_TRUE(res2.no_timeout);
	// Check if the same data was received back
	EXPECT_TRUE(res1.args);
	EXPECT_TRUE(res2.args);

	NfcData credits_ntf = res1.args->last_data_;
	NfcData received_data = res2.args->last_data_;
	/* It is possible that CORE_CONN_CREDITS_NTF is received before data,
	* Find the order and do further checks depending on that */
	if (received_data.size() != data.size()) {
	credits_ntf = res2.args->last_data_;
	received_data = res1.args->last_data_;
	}
	EXPECT_EQ(data.size(), received_data.size());
	for (size_t i = 0; i < data.size(); i++) {
	EXPECT_EQ(data[i], received_data[i]);
	}

	EXPECT_EQ(6ul, credits_ntf.size());
	// Check if the credit is refilled to 1
	EXPECT_EQ(1, credits_ntf[5]);
	}
	}

	/*
	* PowerCycle:
	* Calls powerCycle()
	* Waits for NfcEvent.OPEN_CPLT
	* Checks status
	*/
	TEST_P(NfcHidlTest, PowerCycle) {
	EXPECT_EQ(NfcStatus::OK, nfc_->powerCycle());
	// Wait for NfcEvent.OPEN_CPLT
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/*
	* PowerCycleAfterClose:
	* Calls powerCycle() after close()
	* Checks status
	*/
	TEST_P(NfcHidlTest, PowerCycleAfterClose) {
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	EXPECT_EQ(NfcStatus::FAILED, nfc_->powerCycle());

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/*
	* CoreInitialized:
	* Calls coreInitialized() with different data
	* Waits for NfcEvent.POST_INIT_CPLT
	*/
	TEST_P(NfcHidlTest, CoreInitialized) {
	NfcData data;
	data.resize(1);
	// These parameters might lead to device specific proprietary behavior
	// Using > 10 values should result in predictable and common results for
	// most devices.
	for (int i = 10; i <= 16; i++) {
	data[0] = i;
	NfcStatus status = nfc_->coreInitialized(data);

	/* In case coreInitialized returned FAILED, do not wait for
	* POST_INIT_CLPT event. */
	if (status == NfcStatus::FAILED) continue;

	EXPECT_EQ(NfcStatus::OK, status);
	// Wait for NfcEvent.POST_INIT_CPLT
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::POST_INIT_CPLT, res.args->last_event_);
	}
	}

	/*
	* ControlGranted:
	* Calls controlGranted()
	* Checks the return value
	*/
	TEST_P(NfcHidlTest, ControlGranted) {
	EXPECT_EQ(NfcStatus::OK, nfc_->controlGranted());
	}

	/*
	* ControlGrantedAfterClose:
	* Call controlGranted() after close
	* Checks the return value
	*/
	TEST_P(NfcHidlTest, ControlGrantedAfterClose) {
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	EXPECT_EQ(NfcStatus::OK, nfc_->controlGranted());

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/* PreDiscover:
	* Calls prediscover()
	* Checks the return value
	*/
	TEST_P(NfcHidlTest, PreDiscover) {
	EXPECT_EQ(NfcStatus::OK, nfc_->prediscover());
	}

	/*
	* PreDiscoverAfterClose:
	* Call prediscover() after close
	* Checks the return value
	*/
	TEST_P(NfcHidlTest, PreDiscoverAfterClose) {
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	EXPECT_EQ(NfcStatus::OK, nfc_->prediscover());

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/*
	* CloseAfterClose:
	* Calls close() multiple times
	* Checks status
	*/
	TEST_P(NfcHidlTest, CloseAfterClose) {
	EXPECT_EQ(NfcStatus::OK, nfc_->close());
	// Wait for CLOSE_CPLT event
	auto res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::CLOSE_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);

	EXPECT_EQ(NfcStatus::FAILED, nfc_->close());

	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	// Wait for OPEN_CPLT event
	res = nfc_cb_->WaitForCallback(kCallbackNameSendEvent);
	EXPECT_TRUE(res.no_timeout);
	EXPECT_EQ(NfcEvent::OPEN_CPLT, res.args->last_event_);
	EXPECT_EQ(NfcStatus::OK, res.args->last_status_);
	}

	/*
	* OpenAfterOpen:
	* Calls open() multiple times
	* Checks status
	*/
	TEST_P(NfcHidlTest, OpenAfterOpen) {
	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	EXPECT_EQ(NfcStatus::OK, nfc_->open(nfc_cb_));
	}

	GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(NfcHidlTest);
	INSTANTIATE_TEST_SUITE_P(
	PerInstance, NfcHidlTest,
	testing::ValuesIn(android::hardware::getAllHalInstanceNames(INfc::descriptor)),
	android::hardware::PrintInstanceNameToString);

	int main(int argc, char** argv) {
	::testing::InitGoogleTest(&argc, argv);

	std::system("svc nfc disable"); /* Turn off NFC */
	sleep(5);

	int status = RUN_ALL_TESTS();
	LOG(INFO) << "Test result = " << status;

	std::system("svc nfc enable"); /* Turn on NFC */
	sleep(5);

	return status;
	}