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LeafOS / LeafOS-Project / android_hardware_interfaces / 7932707660883a1bad413caac1f42370182c8618 / . / usb / aidl / vts / VtsAidlUsbTargetTest.cpp
blob: 7b7269df6a927cc72982ad7acb3db26e6500f83f [file] [log] [blame]
/*
* Copyright (C) 2021 The Android Open Source Probject
*
* 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 "UsbAidlTest"
#include <android-base/logging.h>
#include <aidl/android/hardware/usb/IUsb.h>
#include <aidl/android/hardware/usb/IUsbCallback.h>
#include <aidl/android/hardware/usb/BnUsbCallback.h>
#include <aidl/android/hardware/usb/PortDataRole.h>
#include <aidl/android/hardware/usb/PortMode.h>
#include <aidl/android/hardware/usb/PortPowerRole.h>
#include <aidl/android/hardware/usb/PortRole.h>
#include <aidl/android/hardware/usb/PortStatus.h>
#include <aidl/android/hardware/usb/Status.h>
#include <aidl/Vintf.h>
#include <aidl/Gtest.h>
#include <android/binder_auto_utils.h>
#include <android/binder_manager.h>
#include <android/binder_process.h>
#include <gtest/gtest.h>
#include <log/log.h>
#include <stdlib.h>
#include <chrono>
#include <condition_variable>
#include <mutex>
#define TIMEOUT_PERIOD 10
using ::aidl::android::hardware::usb::AltModeData;
using ::aidl::android::hardware::usb::BnUsbCallback;
using ::aidl::android::hardware::usb::ComplianceWarning;
using ::aidl::android::hardware::usb::DisplayPortAltModePinAssignment;
using ::aidl::android::hardware::usb::DisplayPortAltModeStatus;
using ::aidl::android::hardware::usb::IUsb;
using ::aidl::android::hardware::usb::IUsbCallback;
using ::aidl::android::hardware::usb::LinkTrainingStatus;
using ::aidl::android::hardware::usb::PlugOrientation;
using ::aidl::android::hardware::usb::PortDataRole;
using ::aidl::android::hardware::usb::PortMode;
using ::aidl::android::hardware::usb::PortPowerRole;
using ::aidl::android::hardware::usb::PortRole;
using ::aidl::android::hardware::usb::PortStatus;
using ::aidl::android::hardware::usb::Status;
using ::aidl::android::hardware::usb::UsbDataStatus;
using ::ndk::ScopedAStatus;
using ::ndk::SpAIBinder;
using std::vector;
using std::shared_ptr;
using std::string;
// The main test class for the USB aidl hal
class UsbAidlTest : public testing::TestWithParam<std::string> {
public:
// Callback class for the USB aidl hal.
// Usb Hal will call this object upon role switch or port query.
class UsbCallback : public BnUsbCallback {
UsbAidlTest& parent_;
int cookie;
public:
UsbCallback(UsbAidlTest& parent, int cookie)
: parent_(parent), cookie(cookie){};
virtual ~UsbCallback() = default;
// Callback method for the port status.
ScopedAStatus notifyPortStatusChange(const vector<PortStatus>& currentPortStatus,
Status retval) override {
if (retval == Status::SUCCESS && currentPortStatus.size() > 0) {
parent_.usb_last_port_status.portName =
currentPortStatus[0].portName.c_str();
parent_.usb_last_port_status.currentDataRole =
currentPortStatus[0].currentDataRole;
parent_.usb_last_port_status.currentPowerRole =
currentPortStatus[0].currentPowerRole;
parent_.usb_last_port_status.currentMode =
currentPortStatus[0].currentMode;
}
parent_.usb_last_cookie = cookie;
return ScopedAStatus::ok();
}
// Callback method for the status of role switch operation.
ScopedAStatus notifyRoleSwitchStatus(const string& /*portName*/, const PortRole& newRole,
Status retval, int64_t transactionId) override {
parent_.usb_last_status = retval;
parent_.usb_last_cookie = cookie;
parent_.usb_last_port_role = newRole;
parent_.usb_role_switch_done = true;
parent_.last_transactionId = transactionId;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of enableUsbData operation
ScopedAStatus notifyEnableUsbDataStatus(const string& /*portName*/, bool /*enable*/,
Status /*retval*/, int64_t transactionId) override {
parent_.last_transactionId = transactionId;
parent_.usb_last_cookie = cookie;
parent_.enable_usb_data_done = true;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of enableUsbData operation
ScopedAStatus notifyEnableUsbDataWhileDockedStatus(const string& /*portName*/,
Status /*retval*/,
int64_t transactionId) override {
parent_.last_transactionId = transactionId;
parent_.usb_last_cookie = cookie;
parent_.enable_usb_data_while_docked_done = true;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of enableContaminantPresenceDetection
ScopedAStatus notifyContaminantEnabledStatus(const string& /*portName*/, bool /*enable*/,
Status /*retval*/, int64_t transactionId) override {
parent_.last_transactionId = transactionId;
parent_.usb_last_cookie = cookie;
parent_.enable_contaminant_done = true;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of queryPortStatus operation
ScopedAStatus notifyQueryPortStatus(const string& /*portName*/, Status /*retval*/,
int64_t transactionId) override {
parent_.last_transactionId = transactionId;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of limitPowerTransfer operation
ScopedAStatus notifyLimitPowerTransferStatus(const string& /*portName*/, bool /*limit*/,
Status /*retval*/, int64_t transactionId) override {
parent_.last_transactionId = transactionId;
parent_.usb_last_cookie = cookie;
parent_.limit_power_transfer_done = true;
parent_.notify();
return ScopedAStatus::ok();
}
// Callback method for the status of resetUsbPortStatus operation
ScopedAStatus notifyResetUsbPortStatus(const string& /*portName*/, Status /*retval*/,
int64_t transactionId) override {
ALOGI("enter notifyResetUsbPortStatus");
parent_.last_transactionId = transactionId;
parent_.usb_last_cookie = cookie;
parent_.reset_usb_port_done = true;
parent_.notify();
return ScopedAStatus::ok();
}
};
virtual void SetUp() override {
ALOGI("Setup");
usb = IUsb::fromBinder(
SpAIBinder(AServiceManager_waitForService(GetParam().c_str())));
ASSERT_NE(usb, nullptr);
usb_cb_2 = ::ndk::SharedRefBase::make<UsbCallback>(*this, 2);
ASSERT_NE(usb_cb_2, nullptr);
const auto& ret = usb->setCallback(usb_cb_2);
ASSERT_TRUE(ret.isOk());
}
virtual void TearDown() override { ALOGI("Teardown"); }
// Used as a mechanism to inform the test about data/event callback.
inline void notify() {
std::unique_lock<std::mutex> lock(usb_mtx);
usb_count++;
usb_cv.notify_one();
}
// Test code calls this function to wait for data/event callback.
inline std::cv_status wait() {
std::unique_lock<std::mutex> lock(usb_mtx);
std::cv_status status = std::cv_status::no_timeout;
auto now = std::chrono::system_clock::now();
while (usb_count == 0) {
status =
usb_cv.wait_until(lock, now + std::chrono::seconds(TIMEOUT_PERIOD));
if (status == std::cv_status::timeout) {
ALOGI("timeout");
return status;
}
}
usb_count--;
return status;
}
// USB aidl hal Proxy
shared_ptr<IUsb> usb;
// Callback objects for usb aidl
// Methods of these objects are called to notify port status updates.
shared_ptr<IUsbCallback> usb_cb_1, usb_cb_2;
// The last conveyed status of the USB ports.
// Stores information of currentt_data_role, power_role for all the USB ports
PortStatus usb_last_port_status;
// Status of the last role switch operation.
Status usb_last_status;
// Port role information of the last role switch operation.
PortRole usb_last_port_role;
// Flag to indicate the invocation of role switch callback.
bool usb_role_switch_done;
// Flag to indicate the invocation of notifyContaminantEnabledStatus callback.
bool enable_contaminant_done;
// Flag to indicate the invocation of notifyEnableUsbDataStatus callback.
bool enable_usb_data_done;
// Flag to indicate the invocation of notifyEnableUsbDataWhileDockedStatus callback.
bool enable_usb_data_while_docked_done;
// Flag to indicate the invocation of notifyLimitPowerTransferStatus callback.
bool limit_power_transfer_done;
// Flag to indicate the invocation of notifyResetUsbPort callback.
bool reset_usb_port_done;
// Stores the cookie of the last invoked usb callback object.
int usb_last_cookie;
// Last transaction ID that was recorded.
int64_t last_transactionId;
// synchronization primitives to coordinate between main test thread
// and the callback thread.
std::mutex usb_mtx;
std::condition_variable usb_cv;
int usb_count = 0;
// Stores usb version
int32_t usb_version;
};
/*
* Test to see if setCallback succeeds.
* Callback object is created and registered.
*/
TEST_P(UsbAidlTest, setCallback) {
ALOGI("UsbAidlTest setCallback start");
usb_cb_1 = ::ndk::SharedRefBase::make<UsbCallback>(*this, 1);
ASSERT_NE(usb_cb_1, nullptr);
const auto& ret = usb->setCallback(usb_cb_1);
ASSERT_TRUE(ret.isOk());
ALOGI("UsbAidlTest setCallback end");
}
/*
* Check to see if querying type-c
* port status succeeds.
* The callback parameters are checked to see if the transaction id
* matches.
*/
TEST_P(UsbAidlTest, queryPortStatus) {
ALOGI("UsbAidlTest queryPortStatus start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
ALOGI("UsbAidlTest queryPortStatus end: %s", usb_last_port_status.portName.c_str());
}
/*
* Query port status to Check to see whether only one of DISABLED_DOCK,
* DISABLED_DOCK_DEVICE_MODE, DISABLED_DOCK_HOST_MODE is set at the most.
* The callback parameters are checked to see if the transaction id
* matches.
*/
TEST_P(UsbAidlTest, DisabledDataStatusCheck) {
int disabledCount = 0;
ALOGI("UsbAidlTest DataStatusCheck start");
auto retVersion = usb->getInterfaceVersion(&usb_version);
ASSERT_TRUE(retVersion.isOk()) << retVersion;
if (usb_version < 2) {
ALOGI("UsbAidlTest skipping DataStatusCheck on older interface versions");
GTEST_SKIP();
}
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
ALOGI("UsbAidlTest DataStatusCheck portName: %s", usb_last_port_status.portName.c_str());
if (usb_last_port_status.usbDataStatus.size() > 1) {
for (UsbDataStatus dataStatus : usb_last_port_status.usbDataStatus) {
if (dataStatus == UsbDataStatus::DISABLED_DOCK ||
dataStatus == UsbDataStatus::DISABLED_DOCK_DEVICE_MODE ||
dataStatus == UsbDataStatus::DISABLED_DOCK_HOST_MODE) {
disabledCount++;
}
}
}
EXPECT_GE(1, disabledCount);
ALOGI("UsbAidlTest DataStatusCheck end");
}
/*
* Trying to switch a non-existent port should fail.
* This test case tried to switch the port with empty
* name which is expected to fail.
* The callback parameters are checked to see if the transaction id
* matches.
*/
TEST_P(UsbAidlTest, switchEmptyPort) {
ALOGI("UsbAidlTest switchEmptyPort start");
PortRole role;
role.set<PortRole::powerRole>(PortPowerRole::SOURCE);
int64_t transactionId = rand() % 10000;
const auto& ret = usb->switchRole("", role, transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(Status::ERROR, usb_last_status);
EXPECT_EQ(transactionId, last_transactionId);
EXPECT_EQ(2, usb_last_cookie);
ALOGI("UsbAidlTest switchEmptyPort end");
}
/*
* Test switching the power role of usb port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, a power role switch
* to SOURCE is attempted for the port.
* The callback parameters are checked to see if the transaction id
* matches.
*/
TEST_P(UsbAidlTest, switchPowerRole) {
ALOGI("UsbAidlTest switchPowerRole start");
PortRole role;
role.set<PortRole::powerRole>(PortPowerRole::SOURCE);
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
string portBeingSwitched = usb_last_port_status.portName;
ALOGI("switchPower role portname:%s", portBeingSwitched.c_str());
usb_role_switch_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->switchRole(portBeingSwitched, role, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
usb_role_switch_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest switchPowerRole end");
}
/*
* Test switching the data role of usb port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, a data role switch
* to device is attempted for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, switchDataRole) {
ALOGI("UsbAidlTest switchDataRole start");
PortRole role;
role.set<PortRole::dataRole>(PortDataRole::DEVICE);
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
string portBeingSwitched = usb_last_port_status.portName;
ALOGI("portname:%s", portBeingSwitched.c_str());
usb_role_switch_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->switchRole(portBeingSwitched, role, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
usb_role_switch_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest switchDataRole end");
}
/*
* Test enabling contaminant presence detection of the port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, enabling contaminant detection
* is attempted for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, enableContaminantPresenceDetection) {
ALOGI("UsbAidlTest enableContaminantPresenceDetection start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
ALOGI("portname:%s", usb_last_port_status.portName.c_str());
enable_contaminant_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->enableContaminantPresenceDetection(usb_last_port_status.portName,
true, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
enable_contaminant_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest enableContaminantPresenceDetection end");
}
/*
* Test enabling Usb data of the port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, enabling Usb data is attempted
* for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, enableUsbData) {
ALOGI("UsbAidlTest enableUsbData start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
ALOGI("portname:%s", usb_last_port_status.portName.c_str());
enable_usb_data_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->enableUsbData(usb_last_port_status.portName, true, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
enable_usb_data_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest enableUsbData end");
}
/*
* Test enabling Usb data while being docked.
* Test case queries the usb ports present in device.
* If there is at least one usb port, enabling Usb data while docked
* is attempted for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, enableUsbDataWhileDocked) {
ALOGI("UsbAidlTest enableUsbDataWhileDocked start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
ALOGI("portname:%s", usb_last_port_status.portName.c_str());
enable_usb_data_while_docked_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->enableUsbDataWhileDocked(usb_last_port_status.portName, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
enable_usb_data_while_docked_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest enableUsbDataWhileDocked end");
}
/*
* Test enabling Usb data of the port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, relaxing limit power transfer
* is attempted for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, limitPowerTransfer) {
ALOGI("UsbAidlTest limitPowerTransfer start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
ALOGI("portname:%s", usb_last_port_status.portName.c_str());
limit_power_transfer_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->limitPowerTransfer(usb_last_port_status.portName, false, transactionId);
ASSERT_TRUE(ret.isOk());
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
limit_power_transfer_done == false)
waitStatus = wait();
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest limitPowerTransfer end");
}
/*
* Test reset Usb data of the port.
* Test case queries the usb ports present in device.
* If there is at least one usb port, reset Usb data for the port.
* The callback parameters are checked to see if transaction id
* matches.
*/
TEST_P(UsbAidlTest, DISABLED_resetUsbPort) {
ALOGI("UsbAidlTest resetUsbPort start");
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.portName.empty()) {
ALOGI("portname:%s", usb_last_port_status.portName.c_str());
reset_usb_port_done = false;
transactionId = rand() % 10000;
const auto& ret = usb->resetUsbPort(usb_last_port_status.portName, transactionId);
ASSERT_TRUE(ret.isOk());
ALOGI("UsbAidlTest resetUsbPort ret.isOk");
std::cv_status waitStatus = wait();
while (waitStatus == std::cv_status::no_timeout &&
reset_usb_port_done == false)
waitStatus = wait();
ALOGI("UsbAidlTest resetUsbPort wait()");
EXPECT_EQ(std::cv_status::no_timeout, waitStatus);
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
}
ALOGI("UsbAidlTest resetUsbPort end");
}
/*
* Test charger compliance warning
* The test asserts that complianceWarnings is
* empty when the feature is not supported. i.e.
* supportsComplianceWarning is false.
*/
TEST_P(UsbAidlTest, nonCompliantChargerStatus) {
ALOGI("UsbAidlTest nonCompliantChargerStatus start");
auto retVersion = usb->getInterfaceVersion(&usb_version);
ASSERT_TRUE(retVersion.isOk()) << retVersion;
if (usb_version < 2) {
ALOGI("UsbAidlTest skipping nonCompliantChargerStatus on older interface versions");
GTEST_SKIP();
}
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (!usb_last_port_status.supportsComplianceWarnings) {
EXPECT_TRUE(usb_last_port_status.complianceWarnings.empty());
}
ALOGI("UsbAidlTest nonCompliantChargerStatus end");
}
/*
* Test charger compliance warning values
* The test asserts that complianceWarning values
* are valid.
*/
TEST_P(UsbAidlTest, nonCompliantChargerValues) {
ALOGI("UsbAidlTest nonCompliantChargerValues start");
auto retVersion = usb->getInterfaceVersion(&usb_version);
ASSERT_TRUE(retVersion.isOk()) << retVersion;
if (usb_version < 2) {
ALOGI("UsbAidlTest skipping nonCompliantChargerValues on older interface versions");
GTEST_SKIP();
}
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
if (usb_last_port_status.supportsComplianceWarnings) {
for (auto warning : usb_last_port_status.complianceWarnings) {
EXPECT_TRUE((int)warning >= (int)ComplianceWarning::OTHER);
/*
* Version 2 compliance values range from [1, 4]
* Version 3 compliance values range from [1, 9]
*/
if (usb_version < 3) {
EXPECT_TRUE((int)warning <= (int)ComplianceWarning::MISSING_RP);
} else {
EXPECT_TRUE((int)warning <= (int)ComplianceWarning::UNRELIABLE_IO);
}
}
}
ALOGI("UsbAidlTest nonCompliantChargerValues end");
}
/*
* Test PlugOrientation Values are within range in PortStatus
*/
TEST_P(UsbAidlTest, plugOrientationValues) {
ALOGI("UsbAidlTest plugOrientationValues start");
auto retVersion = usb->getInterfaceVersion(&usb_version);
ASSERT_TRUE(retVersion.isOk()) << retVersion;
if (usb_version < 2) {
ALOGI("UsbAidlTest skipping plugOrientationValues on older interface versions");
GTEST_SKIP();
}
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
EXPECT_TRUE((int)usb_last_port_status.plugOrientation >= (int)PlugOrientation::UNKNOWN);
EXPECT_TRUE((int)usb_last_port_status.plugOrientation <= (int)PlugOrientation::PLUGGED_FLIPPED);
}
/*
* Test DisplayPortAltMode Values when DisplayPort Alt Mode
* is active.
*/
TEST_P(UsbAidlTest, dpAltModeValues) {
ALOGI("UsbAidlTest dpAltModeValues start");
auto retVersion = usb->getInterfaceVersion(&usb_version);
ASSERT_TRUE(retVersion.isOk()) << retVersion;
if (usb_version < 2) {
ALOGI("UsbAidlTest skipping dpAltModeValues on older interface versions");
GTEST_SKIP();
}
int64_t transactionId = rand() % 10000;
const auto& ret = usb->queryPortStatus(transactionId);
ASSERT_TRUE(ret.isOk());
EXPECT_EQ(std::cv_status::no_timeout, wait());
EXPECT_EQ(2, usb_last_cookie);
EXPECT_EQ(transactionId, last_transactionId);
// Discover DisplayPort Alt Mode
for (AltModeData altMode : usb_last_port_status.supportedAltModes) {
if (altMode.getTag() == AltModeData::displayPortAltModeData) {
AltModeData::DisplayPortAltModeData displayPortAltModeData =
altMode.get<AltModeData::displayPortAltModeData>();
EXPECT_TRUE((int)displayPortAltModeData.partnerSinkStatus >=
(int)DisplayPortAltModeStatus::UNKNOWN);
EXPECT_TRUE((int)displayPortAltModeData.partnerSinkStatus <=
(int)DisplayPortAltModeStatus::ENABLED);
EXPECT_TRUE((int)displayPortAltModeData.cableStatus >=
(int)DisplayPortAltModeStatus::UNKNOWN);
EXPECT_TRUE((int)displayPortAltModeData.cableStatus <=
(int)DisplayPortAltModeStatus::ENABLED);
EXPECT_TRUE((int)displayPortAltModeData.pinAssignment >=
(int)DisplayPortAltModePinAssignment::NONE);
EXPECT_TRUE((int)displayPortAltModeData.pinAssignment <=
(int)DisplayPortAltModePinAssignment::F);
EXPECT_TRUE((int)displayPortAltModeData.linkTrainingStatus >=
(int)LinkTrainingStatus::UNKNOWN);
EXPECT_TRUE((int)displayPortAltModeData.pinAssignment <= (int)LinkTrainingStatus::FAILURE);
}
}
ALOGI("UsbAidlTest dpAltModeValues end");
}
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(UsbAidlTest);
INSTANTIATE_TEST_SUITE_P(
PerInstance, UsbAidlTest,
testing::ValuesIn(::android::getAidlHalInstanceNames(IUsb::descriptor)),
::android::PrintInstanceNameToString);
int main(int argc, char** argv) {
::testing::InitGoogleTest(&argc, argv);
ABinderProcess_setThreadPoolMaxThreadCount(1);
ABinderProcess_startThreadPool();
return RUN_ALL_TESTS();
}