/* * Copyright 2020 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. */ // TODO(b/129481165): remove the #pragma below and fix conversion issues #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wconversion" #undef LOG_TAG #define LOG_TAG "LibSurfaceFlingerUnittests" #include #include // StrictMock derives from T and is not marked final, so the destructor of T is expected to be // virtual in case StrictMock is used as a polymorphic base class. That is not the case here. #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wnon-virtual-dtor" #include #pragma clang diagnostic pop #include #include #include #include #include #include "DisplayHardware/DisplayMode.h" #include "DisplayHardware/HWComposer.h" #include "DisplayHardware/Hal.h" #include "DisplayIdentificationTestHelpers.h" #include "mock/DisplayHardware/MockComposer.h" #include "mock/DisplayHardware/MockHWC2.h" #include // TODO(b/129481165): remove the #pragma below and fix conversion issues #pragma clang diagnostic pop // ignored "-Wconversion" namespace android { namespace V2_1 = hardware::graphics::composer::V2_1; namespace V2_4 = hardware::graphics::composer::V2_4; namespace aidl = aidl::android::hardware::graphics::composer3; using namespace std::chrono_literals; using Hwc2::Config; using ::aidl::android::hardware::graphics::common::DisplayHotplugEvent; using ::aidl::android::hardware::graphics::composer3::RefreshRateChangedDebugData; using hal::IComposerClient; using ::testing::_; using ::testing::DoAll; using ::testing::Return; using ::testing::SetArgPointee; using ::testing::StrictMock; struct HWComposerTest : testing::Test { using HalError = hardware::graphics::composer::V2_1::Error; Hwc2::mock::Composer* const mHal = new StrictMock(); impl::HWComposer mHwc{std::unique_ptr(mHal)}; void expectHotplugConnect(hal::HWDisplayId hwcDisplayId) { constexpr uint8_t kPort = 255; EXPECT_CALL(*mHal, getDisplayIdentificationData(hwcDisplayId, _, _)) .WillOnce(DoAll(SetArgPointee<1>(kPort), SetArgPointee<2>(getExternalEdid()), Return(HalError::NONE))); EXPECT_CALL(*mHal, setClientTargetSlotCount(_)); EXPECT_CALL(*mHal, setVsyncEnabled(hwcDisplayId, Hwc2::IComposerClient::Vsync::DISABLE)); EXPECT_CALL(*mHal, onHotplugConnect(hwcDisplayId)); } void setVrrTimeoutHint(bool status) { mHwc.mEnableVrrTimeout = status; } }; TEST_F(HWComposerTest, isHeadless) { ASSERT_TRUE(mHwc.isHeadless()); constexpr hal::HWDisplayId kHwcDisplayId = 1; expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); ASSERT_FALSE(mHwc.isHeadless()); mHwc.disconnectDisplay(info->id); ASSERT_TRUE(mHwc.isHeadless()); } TEST_F(HWComposerTest, getDisplayConnectionType) { // Unknown display. EXPECT_EQ(mHwc.getDisplayConnectionType(PhysicalDisplayId::fromPort(0)), ui::DisplayConnectionType::Internal); constexpr hal::HWDisplayId kHwcDisplayId = 1; expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); EXPECT_CALL(*mHal, getDisplayConnectionType(kHwcDisplayId, _)) .WillOnce(DoAll(SetArgPointee<1>(IComposerClient::DisplayConnectionType::EXTERNAL), Return(V2_4::Error::NONE))); // The first call caches the connection type. EXPECT_EQ(mHwc.getDisplayConnectionType(info->id), ui::DisplayConnectionType::External); // Subsequent calls return the cached connection type. EXPECT_EQ(mHwc.getDisplayConnectionType(info->id), ui::DisplayConnectionType::External); EXPECT_EQ(mHwc.getDisplayConnectionType(info->id), ui::DisplayConnectionType::External); } TEST_F(HWComposerTest, getActiveMode) { // Unknown display. EXPECT_EQ(mHwc.getActiveMode(PhysicalDisplayId::fromPort(0)), ftl::Unexpected(BAD_INDEX)); constexpr hal::HWDisplayId kHwcDisplayId = 2; expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); { // Display is known to SF but not HWC, e.g. the hotplug disconnect is pending. EXPECT_CALL(*mHal, getActiveConfig(kHwcDisplayId, _)) .WillOnce(Return(HalError::BAD_DISPLAY)); EXPECT_EQ(mHwc.getActiveMode(info->id), ftl::Unexpected(UNKNOWN_ERROR)); } { EXPECT_CALL(*mHal, getActiveConfig(kHwcDisplayId, _)) .WillOnce(Return(HalError::BAD_CONFIG)); EXPECT_EQ(mHwc.getActiveMode(info->id), ftl::Unexpected(NO_INIT)); } { constexpr hal::HWConfigId kConfigId = 42; EXPECT_CALL(*mHal, getActiveConfig(kHwcDisplayId, _)) .WillOnce(DoAll(SetArgPointee<1>(kConfigId), Return(HalError::NONE))); EXPECT_EQ(mHwc.getActiveMode(info->id).value_opt(), kConfigId); } } TEST_F(HWComposerTest, getModesWithLegacyDisplayConfigs) { constexpr hal::HWDisplayId kHwcDisplayId = 2; constexpr hal::HWConfigId kConfigId = 42; constexpr int32_t kMaxFrameIntervalNs = 50000000; // 20Fps expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); EXPECT_CALL(*mHal, isVrrSupported()).WillRepeatedly(Return(false)); { EXPECT_CALL(*mHal, getDisplayConfigs(kHwcDisplayId, _)) .WillOnce(Return(HalError::BAD_DISPLAY)); EXPECT_TRUE(mHwc.getModes(info->id, kMaxFrameIntervalNs).empty()); } { constexpr int32_t kWidth = 480; constexpr int32_t kHeight = 720; constexpr int32_t kConfigGroup = 1; constexpr int32_t kVsyncPeriod = 16666667; EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::WIDTH, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kWidth), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::HEIGHT, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kHeight), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::CONFIG_GROUP, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kConfigGroup), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::VSYNC_PERIOD, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kVsyncPeriod), Return(HalError::NONE))); // Optional Parameters UNSUPPORTED EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_X, _)) .WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_Y, _)) .WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, getDisplayConfigs(kHwcDisplayId, _)) .WillRepeatedly(DoAll(SetArgPointee<1>(std::vector{kConfigId}), Return(HalError::NONE))); auto modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); EXPECT_EQ(modes.front().dpiX, -1); EXPECT_EQ(modes.front().dpiY, -1); // Optional parameters are supported constexpr int32_t kDpi = 320; EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_X, _)) .WillOnce(DoAll(SetArgPointee<3>(kDpi), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_Y, _)) .WillOnce(DoAll(SetArgPointee<3>(kDpi), Return(HalError::NONE))); modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); // DPI values are scaled by 1000 in the legacy implementation. EXPECT_EQ(modes.front().dpiX, kDpi / 1000.f); EXPECT_EQ(modes.front().dpiY, kDpi / 1000.f); } } TEST_F(HWComposerTest, getModesWithDisplayConfigurations_VRR_OFF) { // if vrr_config is off, getDisplayConfigurationsSupported() is off as well // then getModesWithLegacyDisplayConfigs should be called instead SET_FLAG_FOR_TEST(com::android::graphics::surfaceflinger::flags::vrr_config, false); ASSERT_FALSE(FlagManager::getInstance().vrr_config()); constexpr hal::HWDisplayId kHwcDisplayId = 2; constexpr hal::HWConfigId kConfigId = 42; constexpr int32_t kMaxFrameIntervalNs = 50000000; // 20Fps expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); EXPECT_CALL(*mHal, isVrrSupported()).WillRepeatedly(Return(false)); { EXPECT_CALL(*mHal, getDisplayConfigs(kHwcDisplayId, _)) .WillOnce(Return(HalError::BAD_DISPLAY)); EXPECT_TRUE(mHwc.getModes(info->id, kMaxFrameIntervalNs).empty()); } { constexpr int32_t kWidth = 480; constexpr int32_t kHeight = 720; constexpr int32_t kConfigGroup = 1; constexpr int32_t kVsyncPeriod = 16666667; EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::WIDTH, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kWidth), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::HEIGHT, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kHeight), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::CONFIG_GROUP, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kConfigGroup), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::VSYNC_PERIOD, _)) .WillRepeatedly(DoAll(SetArgPointee<3>(kVsyncPeriod), Return(HalError::NONE))); // Optional Parameters UNSUPPORTED EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_X, _)) .WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_Y, _)) .WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, getDisplayConfigs(kHwcDisplayId, _)) .WillRepeatedly(DoAll(SetArgPointee<1>(std::vector{kConfigId}), Return(HalError::NONE))); auto modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); EXPECT_EQ(modes.front().dpiX, -1); EXPECT_EQ(modes.front().dpiY, -1); // Optional parameters are supported constexpr int32_t kDpi = 320; EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_X, _)) .WillOnce(DoAll(SetArgPointee<3>(kDpi), Return(HalError::NONE))); EXPECT_CALL(*mHal, getDisplayAttribute(kHwcDisplayId, kConfigId, IComposerClient::Attribute::DPI_Y, _)) .WillOnce(DoAll(SetArgPointee<3>(kDpi), Return(HalError::NONE))); modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); // DPI values are scaled by 1000 in the legacy implementation. EXPECT_EQ(modes.front().dpiX, kDpi / 1000.f); EXPECT_EQ(modes.front().dpiY, kDpi / 1000.f); } } TEST_F(HWComposerTest, getModesWithDisplayConfigurations_VRR_ON) { SET_FLAG_FOR_TEST(com::android::graphics::surfaceflinger::flags::vrr_config, true); ASSERT_TRUE(FlagManager::getInstance().vrr_config()); constexpr hal::HWDisplayId kHwcDisplayId = 2; constexpr hal::HWConfigId kConfigId = 42; constexpr int32_t kMaxFrameIntervalNs = 50000000; // 20Fps expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); EXPECT_CALL(*mHal, isVrrSupported()).WillRepeatedly(Return(true)); { EXPECT_CALL(*mHal, getDisplayConfigurations(kHwcDisplayId, _, _)) .WillOnce(Return(HalError::BAD_DISPLAY)); EXPECT_TRUE(mHwc.getModes(info->id, kMaxFrameIntervalNs).empty()); } { setVrrTimeoutHint(true); constexpr int32_t kWidth = 480; constexpr int32_t kHeight = 720; constexpr int32_t kConfigGroup = 1; constexpr int32_t kVsyncPeriod = 16666667; const hal::VrrConfig vrrConfig = hal::VrrConfig{.minFrameIntervalNs = static_cast(120_Hz).getPeriodNsecs(), .notifyExpectedPresentConfig = hal::VrrConfig:: NotifyExpectedPresentConfig{.headsUpNs = ms2ns(30), .timeoutNs = ms2ns(30)}}; hal::DisplayConfiguration displayConfiguration{.configId = kConfigId, .width = kWidth, .height = kHeight, .configGroup = kConfigGroup, .vsyncPeriod = kVsyncPeriod, .vrrConfig = vrrConfig}; EXPECT_CALL(*mHal, getDisplayConfigurations(kHwcDisplayId, _, _)) .WillOnce(DoAll(SetArgPointee<2>(std::vector{ displayConfiguration}), Return(HalError::NONE))); // Optional dpi not supported auto modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); EXPECT_EQ(modes.front().vrrConfig, vrrConfig); EXPECT_EQ(modes.front().dpiX, -1); EXPECT_EQ(modes.front().dpiY, -1); // Supports optional dpi parameter constexpr int32_t kDpi = 320; displayConfiguration.dpi = {kDpi, kDpi}; EXPECT_CALL(*mHal, getDisplayConfigurations(kHwcDisplayId, _, _)) .WillRepeatedly(DoAll(SetArgPointee<2>(std::vector{ displayConfiguration}), Return(HalError::NONE))); modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.size(), size_t{1}); EXPECT_EQ(modes.front().hwcId, kConfigId); EXPECT_EQ(modes.front().width, kWidth); EXPECT_EQ(modes.front().height, kHeight); EXPECT_EQ(modes.front().configGroup, kConfigGroup); EXPECT_EQ(modes.front().vsyncPeriod, kVsyncPeriod); EXPECT_EQ(modes.front().vrrConfig, vrrConfig); EXPECT_EQ(modes.front().dpiX, kDpi); EXPECT_EQ(modes.front().dpiY, kDpi); setVrrTimeoutHint(false); modes = mHwc.getModes(info->id, kMaxFrameIntervalNs); EXPECT_EQ(modes.front().vrrConfig->notifyExpectedPresentConfig, std::nullopt); } } TEST_F(HWComposerTest, onVsync) { constexpr hal::HWDisplayId kHwcDisplayId = 1; expectHotplugConnect(kHwcDisplayId); const auto info = mHwc.onHotplug(kHwcDisplayId, hal::Connection::CONNECTED); ASSERT_TRUE(info); const auto physicalDisplayId = info->id; // Deliberately chosen not to match DisplayData.lastPresentTimestamp's // initial value. constexpr nsecs_t kTimestamp = 1; auto displayIdOpt = mHwc.onVsync(kHwcDisplayId, kTimestamp); ASSERT_TRUE(displayIdOpt); EXPECT_EQ(physicalDisplayId, displayIdOpt); // Attempt to send the same time stamp again. displayIdOpt = mHwc.onVsync(kHwcDisplayId, kTimestamp); EXPECT_FALSE(displayIdOpt); } TEST_F(HWComposerTest, onVsyncInvalid) { constexpr hal::HWDisplayId kInvalidHwcDisplayId = 2; constexpr nsecs_t kTimestamp = 1; const auto displayIdOpt = mHwc.onVsync(kInvalidHwcDisplayId, kTimestamp); EXPECT_FALSE(displayIdOpt); } struct MockHWC2ComposerCallback final : StrictMock { MOCK_METHOD(void, onComposerHalHotplugEvent, (hal::HWDisplayId, DisplayHotplugEvent), (override)); MOCK_METHOD1(onComposerHalRefresh, void(hal::HWDisplayId)); MOCK_METHOD3(onComposerHalVsync, void(hal::HWDisplayId, int64_t timestamp, std::optional)); MOCK_METHOD2(onComposerHalVsyncPeriodTimingChanged, void(hal::HWDisplayId, const hal::VsyncPeriodChangeTimeline&)); MOCK_METHOD1(onComposerHalSeamlessPossible, void(hal::HWDisplayId)); MOCK_METHOD1(onComposerHalVsyncIdle, void(hal::HWDisplayId)); MOCK_METHOD(void, onRefreshRateChangedDebug, (const RefreshRateChangedDebugData&), (override)); }; struct HWComposerSetCallbackTest : HWComposerTest { MockHWC2ComposerCallback mCallback; }; TEST_F(HWComposerSetCallbackTest, loadsLayerMetadataSupport) { const std::string kMetadata1Name = "com.example.metadata.1"; constexpr bool kMetadata1Mandatory = false; const std::string kMetadata2Name = "com.example.metadata.2"; constexpr bool kMetadata2Mandatory = true; EXPECT_CALL(*mHal, getCapabilities()).WillOnce(Return(std::vector{})); EXPECT_CALL(*mHal, getLayerGenericMetadataKeys(_)) .WillOnce(DoAll(SetArgPointee<0>(std::vector{ {kMetadata1Name, kMetadata1Mandatory}, {kMetadata2Name, kMetadata2Mandatory}, }), Return(V2_4::Error::NONE))); EXPECT_CALL(*mHal, getOverlaySupport(_)).WillOnce(Return(HalError::NONE)); EXPECT_CALL(*mHal, getHdrConversionCapabilities(_)).WillOnce(Return(HalError::NONE)); EXPECT_CALL(*mHal, registerCallback(_)); mHwc.setCallback(mCallback); const auto& supported = mHwc.getSupportedLayerGenericMetadata(); EXPECT_EQ(2u, supported.size()); EXPECT_EQ(1u, supported.count(kMetadata1Name)); EXPECT_EQ(kMetadata1Mandatory, supported.find(kMetadata1Name)->second); EXPECT_EQ(1u, supported.count(kMetadata2Name)); EXPECT_EQ(kMetadata2Mandatory, supported.find(kMetadata2Name)->second); } TEST_F(HWComposerSetCallbackTest, handlesUnsupportedCallToGetLayerGenericMetadataKeys) { EXPECT_CALL(*mHal, getCapabilities()).WillOnce(Return(std::vector{})); EXPECT_CALL(*mHal, getLayerGenericMetadataKeys(_)).WillOnce(Return(V2_4::Error::UNSUPPORTED)); EXPECT_CALL(*mHal, getOverlaySupport(_)).WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, getHdrConversionCapabilities(_)).WillOnce(Return(HalError::UNSUPPORTED)); EXPECT_CALL(*mHal, registerCallback(_)); mHwc.setCallback(mCallback); const auto& supported = mHwc.getSupportedLayerGenericMetadata(); EXPECT_TRUE(supported.empty()); } struct HWComposerLayerTest : public testing::Test { static constexpr hal::HWDisplayId kDisplayId = static_cast(1001); static constexpr hal::HWLayerId kLayerId = static_cast(1002); HWComposerLayerTest(const std::unordered_set& capabilities) : mCapabilies(capabilities) { EXPECT_CALL(mDisplay, getId()).WillRepeatedly(Return(kDisplayId)); } ~HWComposerLayerTest() override { EXPECT_CALL(mDisplay, onLayerDestroyed(kLayerId)); EXPECT_CALL(*mHal, destroyLayer(kDisplayId, kLayerId)); } std::unique_ptr mHal{new StrictMock()}; const std::unordered_set mCapabilies; StrictMock mDisplay; HWC2::impl::Layer mLayer{*mHal, mCapabilies, mDisplay, kLayerId}; }; struct HWComposerLayerGenericMetadataTest : public HWComposerLayerTest { static const std::string kLayerGenericMetadata1Name; static constexpr bool kLayerGenericMetadata1Mandatory = false; static const std::vector kLayerGenericMetadata1Value; static const std::string kLayerGenericMetadata2Name; static constexpr bool kLayerGenericMetadata2Mandatory = true; static const std::vector kLayerGenericMetadata2Value; HWComposerLayerGenericMetadataTest() : HWComposerLayerTest({}) {} }; const std::string HWComposerLayerGenericMetadataTest::kLayerGenericMetadata1Name = "com.example.metadata.1"; const std::vector HWComposerLayerGenericMetadataTest::kLayerGenericMetadata1Value = {1u, 2u, 3u}; const std::string HWComposerLayerGenericMetadataTest::kLayerGenericMetadata2Name = "com.example.metadata.2"; const std::vector HWComposerLayerGenericMetadataTest::kLayerGenericMetadata2Value = {45u, 67u}; TEST_F(HWComposerLayerGenericMetadataTest, forwardsSupportedMetadata) { EXPECT_CALL(*mHal, setLayerGenericMetadata(kDisplayId, kLayerId, kLayerGenericMetadata1Name, kLayerGenericMetadata1Mandatory, kLayerGenericMetadata1Value)) .WillOnce(Return(V2_4::Error::NONE)); auto result = mLayer.setLayerGenericMetadata(kLayerGenericMetadata1Name, kLayerGenericMetadata1Mandatory, kLayerGenericMetadata1Value); EXPECT_EQ(hal::Error::NONE, result); EXPECT_CALL(*mHal, setLayerGenericMetadata(kDisplayId, kLayerId, kLayerGenericMetadata2Name, kLayerGenericMetadata2Mandatory, kLayerGenericMetadata2Value)) .WillOnce(Return(V2_4::Error::UNSUPPORTED)); result = mLayer.setLayerGenericMetadata(kLayerGenericMetadata2Name, kLayerGenericMetadata2Mandatory, kLayerGenericMetadata2Value); EXPECT_EQ(hal::Error::UNSUPPORTED, result); } } // namespace android