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LeafOS / LeafOS-Project / android_hardware_interfaces / 7932707660883a1bad413caac1f42370182c8618 / . / audio / aidl / vts / VtsHalDynamicsProcessingTest.cpp
blob: 3f7a76dae6c9d6bb46089cebad7fd1cde7c67517 [file] [log] [blame]
/*
* Copyright (C) 2023 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.
*/
#include <set>
#include <string>
#include <unordered_set>
#define LOG_TAG "VtsHalDynamicsProcessingTest"
#include <android-base/logging.h>
#include <Utils.h>
#include "EffectHelper.h"
#include "EffectRangeSpecific.h"
using namespace android;
using namespace aidl::android::hardware::audio::effect::DynamicsProcessingRanges;
using aidl::android::hardware::audio::effect::Descriptor;
using aidl::android::hardware::audio::effect::DynamicsProcessing;
using aidl::android::hardware::audio::effect::getEffectTypeUuidDynamicsProcessing;
using aidl::android::hardware::audio::effect::IEffect;
using aidl::android::hardware::audio::effect::IFactory;
using aidl::android::hardware::audio::effect::Parameter;
using android::hardware::audio::common::testing::detail::TestExecutionTracer;
/**
* Here we focus on specific parameter checking, general IEffect interfaces testing performed in
* VtsAudioEffectTargetTest.
*/
class DynamicsProcessingTestHelper : public EffectHelper {
public:
DynamicsProcessingTestHelper(std::pair<std::shared_ptr<IFactory>, Descriptor> pair,
int32_t channelLayOut = AudioChannelLayout::LAYOUT_STEREO) {
std::tie(mFactory, mDescriptor) = pair;
mChannelLayout = channelLayOut;
mChannelCount = ::aidl::android::hardware::audio::common::getChannelCount(
AudioChannelLayout::make<AudioChannelLayout::layoutMask>(mChannelLayout));
}
// setup
void SetUpDynamicsProcessingEffect() {
ASSERT_NE(nullptr, mFactory);
ASSERT_NO_FATAL_FAILURE(create(mFactory, mEffect, mDescriptor));
Parameter::Specific specific = getDefaultParamSpecific();
Parameter::Common common = EffectHelper::createParamCommon(
0 /* session */, 1 /* ioHandle */, 44100 /* iSampleRate */, 44100 /* oSampleRate */,
0x100 /* iFrameCount */, 0x100 /* oFrameCount */,
AudioChannelLayout::make<AudioChannelLayout::layoutMask>(mChannelLayout),
AudioChannelLayout::make<AudioChannelLayout::layoutMask>(mChannelLayout));
IEffect::OpenEffectReturn ret;
ASSERT_NO_FATAL_FAILURE(open(mEffect, common, specific, &ret, EX_NONE));
ASSERT_NE(nullptr, mEffect);
mEngineConfigApplied = mEngineConfigPreset;
}
Parameter::Specific getDefaultParamSpecific() {
DynamicsProcessing dp = DynamicsProcessing::make<DynamicsProcessing::engineArchitecture>(
mEngineConfigPreset);
Parameter::Specific specific =
Parameter::Specific::make<Parameter::Specific::dynamicsProcessing>(dp);
return specific;
}
// teardown
void TearDownDynamicsProcessingEffect() {
ASSERT_NO_FATAL_FAILURE(close(mEffect));
ASSERT_NO_FATAL_FAILURE(destroy(mFactory, mEffect));
}
// utils functions for parameter checking
bool isParamEqual(const DynamicsProcessing::Tag& tag, const DynamicsProcessing& dpRef,
const DynamicsProcessing& dpTest);
bool isEngineConfigEqual(const DynamicsProcessing::EngineArchitecture& refCfg,
const DynamicsProcessing::EngineArchitecture& testCfg);
template <typename T>
std::vector<T> filterEnabledVector(const std::vector<T>& vec);
template <typename T>
bool isAidlVectorEqualAfterFilter(const std::vector<T>& source, const std::vector<T>& target);
template <typename T>
bool isAidlVectorEqual(const std::vector<T>& source, const std::vector<T>& target);
template <typename T>
bool isChannelConfigValid(const std::vector<T>& cfgs) {
auto& channelCount = mChannelCount;
return std::all_of(cfgs.cbegin(), cfgs.cend(), [channelCount](const T& cfg) {
return (cfg.channel >= 0 && cfg.channel < channelCount);
});
}
template <typename T>
bool isBandConfigValid(const std::vector<T>& cfgs, int bandCount);
bool isParamValid(const DynamicsProcessing::Tag& tag, const DynamicsProcessing& dp);
// get set params and validate
void SetAndGetDynamicsProcessingParameters();
// enqueue test parameters
void addEngineConfig(const DynamicsProcessing::EngineArchitecture& cfg);
void addPreEqChannelConfig(const std::vector<DynamicsProcessing::ChannelConfig>& cfg);
void addPostEqChannelConfig(const std::vector<DynamicsProcessing::ChannelConfig>& cfg);
void addMbcChannelConfig(const std::vector<DynamicsProcessing::ChannelConfig>& cfg);
void addPreEqBandConfigs(const std::vector<DynamicsProcessing::EqBandConfig>& cfgs);
void addPostEqBandConfigs(const std::vector<DynamicsProcessing::EqBandConfig>& cfgs);
void addMbcBandConfigs(const std::vector<DynamicsProcessing::MbcBandConfig>& cfgs);
void addLimiterConfig(const std::vector<DynamicsProcessing::LimiterConfig>& cfg);
void addInputGain(const std::vector<DynamicsProcessing::InputGain>& inputGain);
static constexpr float kPreferredProcessingDurationMs = 10.0f;
static constexpr int kBandCount = 5;
std::shared_ptr<IFactory> mFactory;
std::shared_ptr<IEffect> mEffect;
Descriptor mDescriptor;
DynamicsProcessing::EngineArchitecture mEngineConfigApplied;
DynamicsProcessing::EngineArchitecture mEngineConfigPreset{
.resolutionPreference =
DynamicsProcessing::ResolutionPreference::FAVOR_FREQUENCY_RESOLUTION,
.preferredProcessingDurationMs = kPreferredProcessingDurationMs,
.preEqStage = {.inUse = true, .bandCount = kBandCount},
.postEqStage = {.inUse = true, .bandCount = kBandCount},
.mbcStage = {.inUse = true, .bandCount = kBandCount},
.limiterInUse = true,
};
std::unordered_set<int /* channelId */> mPreEqChannelEnable;
std::unordered_set<int /* channelId */> mPostEqChannelEnable;
std::unordered_set<int /* channelId */> mMbcChannelEnable;
std::unordered_set<int /* channelId */> mLimiterChannelEnable;
static const std::set<std::vector<DynamicsProcessing::ChannelConfig>> kChannelConfigTestSet;
static const std::set<DynamicsProcessing::StageEnablement> kStageEnablementTestSet;
static const std::set<std::vector<DynamicsProcessing::InputGain>> kInputGainTestSet;
protected:
int mChannelCount;
private:
int32_t mChannelLayout;
std::vector<std::pair<DynamicsProcessing::Tag, DynamicsProcessing>> mTags;
void CleanUp() {
mTags.clear();
mPreEqChannelEnable.clear();
mPostEqChannelEnable.clear();
mMbcChannelEnable.clear();
mLimiterChannelEnable.clear();
}
};
// test value set for DynamicsProcessing::StageEnablement
const std::set<DynamicsProcessing::StageEnablement>
DynamicsProcessingTestHelper::kStageEnablementTestSet = {
{.inUse = true, .bandCount = DynamicsProcessingTestHelper::kBandCount},
{.inUse = true, .bandCount = 0},
{.inUse = true, .bandCount = -1},
{.inUse = false, .bandCount = 0},
{.inUse = false, .bandCount = -1},
{.inUse = false, .bandCount = DynamicsProcessingTestHelper::kBandCount}};
// test value set for DynamicsProcessing::ChannelConfig
const std::set<std::vector<DynamicsProcessing::ChannelConfig>>
DynamicsProcessingTestHelper::kChannelConfigTestSet = {
{{.channel = -1, .enable = false},
{.channel = 0, .enable = true},
{.channel = 1, .enable = false},
{.channel = 2, .enable = true}},
{{.channel = -1, .enable = false}, {.channel = 2, .enable = true}},
{{.channel = 0, .enable = true}, {.channel = 1, .enable = true}}};
// test value set for DynamicsProcessing::InputGain
const std::set<std::vector<DynamicsProcessing::InputGain>>
DynamicsProcessingTestHelper::kInputGainTestSet = {
{{.channel = 0, .gainDb = 10.f},
{.channel = 1, .gainDb = 0.f},
{.channel = 2, .gainDb = -10.f}},
{{.channel = -1, .gainDb = -10.f}, {.channel = -2, .gainDb = 10.f}},
{{.channel = -1, .gainDb = 10.f}, {.channel = 0, .gainDb = -10.f}},
{{.channel = 0, .gainDb = 10.f}, {.channel = 1, .gainDb = -10.f}}};
template <typename T>
bool DynamicsProcessingTestHelper::isBandConfigValid(const std::vector<T>& cfgs, int bandCount) {
std::vector<float> freqs(cfgs.size(), -1);
for (auto cfg : cfgs) {
if (cfg.channel < 0 || cfg.channel >= mChannelCount) return false;
if (cfg.band < 0 || cfg.band >= bandCount) return false;
freqs[cfg.band] = cfg.cutoffFrequencyHz;
}
if (std::count(freqs.begin(), freqs.end(), -1)) return false;
return std::is_sorted(freqs.begin(), freqs.end());
}
bool DynamicsProcessingTestHelper::isParamValid(const DynamicsProcessing::Tag& tag,
const DynamicsProcessing& dp) {
switch (tag) {
case DynamicsProcessing::preEq: {
if (!mEngineConfigApplied.preEqStage.inUse) return false;
return isChannelConfigValid(dp.get<DynamicsProcessing::preEq>());
}
case DynamicsProcessing::postEq: {
if (!mEngineConfigApplied.postEqStage.inUse) return false;
return isChannelConfigValid(dp.get<DynamicsProcessing::postEq>());
}
case DynamicsProcessing::mbc: {
if (!mEngineConfigApplied.mbcStage.inUse) return false;
return isChannelConfigValid(dp.get<DynamicsProcessing::mbc>());
}
case DynamicsProcessing::preEqBand: {
if (!mEngineConfigApplied.preEqStage.inUse) return false;
return isBandConfigValid(dp.get<DynamicsProcessing::preEqBand>(),
mEngineConfigApplied.preEqStage.bandCount);
}
case DynamicsProcessing::postEqBand: {
if (!mEngineConfigApplied.postEqStage.inUse) return false;
return isBandConfigValid(dp.get<DynamicsProcessing::postEqBand>(),
mEngineConfigApplied.postEqStage.bandCount);
}
case DynamicsProcessing::mbcBand: {
if (!mEngineConfigApplied.mbcStage.inUse) return false;
return isBandConfigValid(dp.get<DynamicsProcessing::mbcBand>(),
mEngineConfigApplied.mbcStage.bandCount);
}
case DynamicsProcessing::limiter: {
if (!mEngineConfigApplied.limiterInUse) return false;
return isChannelConfigValid(dp.get<DynamicsProcessing::limiter>());
}
case DynamicsProcessing::inputGain: {
return isChannelConfigValid(dp.get<DynamicsProcessing::inputGain>());
}
default: {
return true;
}
}
return true;
}
bool DynamicsProcessingTestHelper::isParamEqual(const DynamicsProcessing::Tag& tag,
const DynamicsProcessing& dpRef,
const DynamicsProcessing& dpTest) {
switch (tag) {
case DynamicsProcessing::engineArchitecture: {
return isEngineConfigEqual(dpRef.get<DynamicsProcessing::engineArchitecture>(),
dpTest.get<DynamicsProcessing::engineArchitecture>());
}
case DynamicsProcessing::preEq: {
const auto& source = dpRef.get<DynamicsProcessing::preEq>();
const auto& target = dpTest.get<DynamicsProcessing::preEq>();
return isAidlVectorEqualAfterFilter<DynamicsProcessing::ChannelConfig>(source, target);
}
case DynamicsProcessing::postEq: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::ChannelConfig>(
dpRef.get<DynamicsProcessing::postEq>(),
dpTest.get<DynamicsProcessing::postEq>());
}
case DynamicsProcessing::mbc: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::ChannelConfig>(
dpRef.get<DynamicsProcessing::mbc>(), dpTest.get<DynamicsProcessing::mbc>());
}
case DynamicsProcessing::preEqBand: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::EqBandConfig>(
dpRef.get<DynamicsProcessing::preEqBand>(),
dpTest.get<DynamicsProcessing::preEqBand>());
}
case DynamicsProcessing::postEqBand: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::EqBandConfig>(
dpRef.get<DynamicsProcessing::postEqBand>(),
dpTest.get<DynamicsProcessing::postEqBand>());
}
case DynamicsProcessing::mbcBand: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::MbcBandConfig>(
dpRef.get<DynamicsProcessing::mbcBand>(),
dpTest.get<DynamicsProcessing::mbcBand>());
}
case DynamicsProcessing::limiter: {
return isAidlVectorEqualAfterFilter<DynamicsProcessing::LimiterConfig>(
dpRef.get<DynamicsProcessing::limiter>(),
dpTest.get<DynamicsProcessing::limiter>());
}
case DynamicsProcessing::inputGain: {
return isAidlVectorEqual<DynamicsProcessing::InputGain>(
dpRef.get<DynamicsProcessing::inputGain>(),
dpTest.get<DynamicsProcessing::inputGain>());
}
case DynamicsProcessing::vendor: {
return false;
}
}
}
bool DynamicsProcessingTestHelper::isEngineConfigEqual(
const DynamicsProcessing::EngineArchitecture& ref,
const DynamicsProcessing::EngineArchitecture& test) {
return ref == test;
}
template <typename T>
std::vector<T> DynamicsProcessingTestHelper::filterEnabledVector(const std::vector<T>& vec) {
std::vector<T> ret;
std::copy_if(vec.begin(), vec.end(), std::back_inserter(ret),
[](const auto& v) { return v.enable; });
return ret;
}
template <typename T>
bool DynamicsProcessingTestHelper::isAidlVectorEqual(const std::vector<T>& source,
const std::vector<T>& target) {
if (source.size() != target.size()) return false;
auto tempS = source;
auto tempT = target;
std::sort(tempS.begin(), tempS.end());
std::sort(tempT.begin(), tempT.end());
return tempS == tempT;
}
template <typename T>
bool DynamicsProcessingTestHelper::isAidlVectorEqualAfterFilter(const std::vector<T>& source,
const std::vector<T>& target) {
return isAidlVectorEqual<T>(filterEnabledVector<T>(source), filterEnabledVector<T>(target));
}
void DynamicsProcessingTestHelper::SetAndGetDynamicsProcessingParameters() {
for (auto& it : mTags) {
auto& tag = it.first;
auto& dp = it.second;
// validate parameter
Descriptor desc;
ASSERT_STATUS(EX_NONE, mEffect->getDescriptor(&desc));
bool valid = isParamInRange(dp, desc.capability.range.get<Range::dynamicsProcessing>());
if (valid) valid = isParamValid(tag, dp);
const binder_exception_t expected = valid ? EX_NONE : EX_ILLEGAL_ARGUMENT;
// set parameter
Parameter expectParam;
Parameter::Specific specific;
specific.set<Parameter::Specific::dynamicsProcessing>(dp);
expectParam.set<Parameter::specific>(specific);
ASSERT_STATUS(expected, mEffect->setParameter(expectParam))
<< "\n"
<< expectParam.toString() << "\n"
<< desc.toString();
// only get if parameter in range and set success
if (expected == EX_NONE) {
Parameter getParam;
Parameter::Id id;
DynamicsProcessing::Id dpId;
dpId.set<DynamicsProcessing::Id::commonTag>(tag);
id.set<Parameter::Id::dynamicsProcessingTag>(dpId);
// if set success, then get should match
EXPECT_STATUS(expected, mEffect->getParameter(id, &getParam));
Parameter::Specific specificTest = getParam.get<Parameter::specific>();
const auto& target = specificTest.get<Parameter::Specific::dynamicsProcessing>();
EXPECT_TRUE(isParamEqual(tag, dp, target)) << dp.toString() << "\n"
<< target.toString();
// update mEngineConfigApplied after setting successfully
if (tag == DynamicsProcessing::engineArchitecture) {
mEngineConfigApplied = target.get<DynamicsProcessing::engineArchitecture>();
}
}
}
}
void DynamicsProcessingTestHelper::addEngineConfig(
const DynamicsProcessing::EngineArchitecture& cfg) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::engineArchitecture>(cfg);
mTags.push_back({DynamicsProcessing::engineArchitecture, dp});
}
void DynamicsProcessingTestHelper::addPreEqChannelConfig(
const std::vector<DynamicsProcessing::ChannelConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::preEq>(cfgs);
mTags.push_back({DynamicsProcessing::preEq, dp});
for (auto& cfg : cfgs) {
if (cfg.enable) mPreEqChannelEnable.insert(cfg.channel);
}
}
void DynamicsProcessingTestHelper::addPostEqChannelConfig(
const std::vector<DynamicsProcessing::ChannelConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::postEq>(cfgs);
mTags.push_back({DynamicsProcessing::postEq, dp});
for (auto& cfg : cfgs) {
if (cfg.enable) mPostEqChannelEnable.insert(cfg.channel);
}
}
void DynamicsProcessingTestHelper::addMbcChannelConfig(
const std::vector<DynamicsProcessing::ChannelConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::mbc>(cfgs);
mTags.push_back({DynamicsProcessing::mbc, dp});
for (auto& cfg : cfgs) {
if (cfg.enable) mMbcChannelEnable.insert(cfg.channel);
}
}
void DynamicsProcessingTestHelper::addPreEqBandConfigs(
const std::vector<DynamicsProcessing::EqBandConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::preEqBand>(cfgs);
mTags.push_back({DynamicsProcessing::preEqBand, dp});
}
void DynamicsProcessingTestHelper::addPostEqBandConfigs(
const std::vector<DynamicsProcessing::EqBandConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::postEqBand>(cfgs);
mTags.push_back({DynamicsProcessing::postEqBand, dp});
}
void DynamicsProcessingTestHelper::addMbcBandConfigs(
const std::vector<DynamicsProcessing::MbcBandConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::mbcBand>(cfgs);
mTags.push_back({DynamicsProcessing::mbcBand, dp});
}
void DynamicsProcessingTestHelper::addLimiterConfig(
const std::vector<DynamicsProcessing::LimiterConfig>& cfgs) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::limiter>(cfgs);
mTags.push_back({DynamicsProcessing::limiter, dp});
for (auto& cfg : cfgs) {
if (cfg.enable) mLimiterChannelEnable.insert(cfg.channel);
}
}
void DynamicsProcessingTestHelper::addInputGain(
const std::vector<DynamicsProcessing::InputGain>& inputGains) {
DynamicsProcessing dp;
dp.set<DynamicsProcessing::inputGain>(inputGains);
mTags.push_back({DynamicsProcessing::inputGain, dp});
}
/**
* Test DynamicsProcessing Engine Configuration
*/
enum EngineArchitectureTestParamName {
ENGINE_TEST_INSTANCE_NAME,
ENGINE_TEST_RESOLUTION_PREFERENCE,
ENGINE_TEST_PREFERRED_DURATION,
ENGINE_TEST_STAGE_ENABLEMENT,
ENGINE_TEST_LIMITER_IN_USE
};
using EngineArchitectureTestParams = std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>,
DynamicsProcessing::ResolutionPreference, float,
DynamicsProcessing::StageEnablement, bool>;
void fillEngineArchConfig(DynamicsProcessing::EngineArchitecture& cfg,
const EngineArchitectureTestParams& params) {
cfg.resolutionPreference = std::get<ENGINE_TEST_RESOLUTION_PREFERENCE>(params);
cfg.preferredProcessingDurationMs = std::get<ENGINE_TEST_PREFERRED_DURATION>(params);
cfg.preEqStage = cfg.postEqStage = cfg.mbcStage =
std::get<ENGINE_TEST_STAGE_ENABLEMENT>(params);
cfg.limiterInUse = std::get<ENGINE_TEST_LIMITER_IN_USE>(params);
}
class DynamicsProcessingTestEngineArchitecture
: public ::testing::TestWithParam<EngineArchitectureTestParams>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestEngineArchitecture()
: DynamicsProcessingTestHelper(std::get<ENGINE_TEST_INSTANCE_NAME>(GetParam())) {
fillEngineArchConfig(mCfg, GetParam());
};
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
DynamicsProcessing::EngineArchitecture mCfg;
};
TEST_P(DynamicsProcessingTestEngineArchitecture, SetAndGetEngineArch) {
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mCfg));
SetAndGetDynamicsProcessingParameters();
}
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestEngineArchitecture,
::testing::Combine(
testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::Values(
DynamicsProcessing::ResolutionPreference::FAVOR_TIME_RESOLUTION,
DynamicsProcessing::ResolutionPreference::FAVOR_FREQUENCY_RESOLUTION,
static_cast<DynamicsProcessing::ResolutionPreference>(-1)), // variant
testing::Values(-10.f, 0.f, 10.f), // processing duration
testing::ValuesIn(
DynamicsProcessingTestHelper::kStageEnablementTestSet), // preEQ/postEQ/mbc
testing::Bool()), // limiter enable
[](const auto& info) {
auto descriptor = std::get<ENGINE_TEST_INSTANCE_NAME>(info.param).second;
DynamicsProcessing::EngineArchitecture cfg;
fillEngineArchConfig(cfg, info.param);
std::string name = getPrefix(descriptor) + "_Cfg_" + cfg.toString();
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestEngineArchitecture);
/**
* Test DynamicsProcessing Input Gain
*/
enum InputGainTestParamName {
INPUT_GAIN_INSTANCE_NAME,
INPUT_GAIN_PARAM,
};
class DynamicsProcessingTestInputGain
: public ::testing::TestWithParam<std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>,
std::vector<DynamicsProcessing::InputGain>>>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestInputGain()
: DynamicsProcessingTestHelper(std::get<INPUT_GAIN_INSTANCE_NAME>(GetParam())),
mInputGain(std::get<INPUT_GAIN_PARAM>(GetParam())){};
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
const std::vector<DynamicsProcessing::InputGain> mInputGain;
};
TEST_P(DynamicsProcessingTestInputGain, SetAndGetInputGain) {
EXPECT_NO_FATAL_FAILURE(addInputGain(mInputGain));
SetAndGetDynamicsProcessingParameters();
}
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestInputGain,
::testing::Combine(testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::ValuesIn(DynamicsProcessingTestInputGain::kInputGainTestSet)),
[](const auto& info) {
auto descriptor = std::get<INPUT_GAIN_INSTANCE_NAME>(info.param).second;
std::string gains =
::android::internal::ToString(std::get<INPUT_GAIN_PARAM>(info.param));
std::string name = "Implementor_" + descriptor.common.implementor + "_name_" +
descriptor.common.name + "_UUID_" +
descriptor.common.id.uuid.toString() + "_inputGains_" + gains;
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestInputGain);
/**
* Test DynamicsProcessing Limiter Config
*/
enum LimiterConfigTestParamName {
LIMITER_INSTANCE_NAME,
LIMITER_CHANNEL,
LIMITER_ENABLE,
LIMITER_LINK_GROUP,
LIMITER_ENGINE_IN_USE,
LIMITER_ADDITIONAL,
};
enum LimiterConfigTestAdditionalParam {
LIMITER_ATTACK_TIME,
LIMITER_RELEASE_TIME,
LIMITER_RATIO,
LIMITER_THRESHOLD,
LIMITER_POST_GAIN,
LIMITER_MAX_NUM,
};
using LimiterConfigTestAdditional = std::array<float, LIMITER_MAX_NUM>;
// attackTime, releaseTime, ratio, thresh, postGain
static constexpr std::array<LimiterConfigTestAdditional, 4> kLimiterConfigTestAdditionalParam = {
{{-1, -60, -2.5, -2, -3.14},
{-1, 60, -2.5, 2, -3.14},
{1, -60, 2.5, -2, 3.14},
{1, 60, 2.5, -2, 3.14}}};
using LimiterConfigTestParams =
std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>, int32_t, bool, int32_t, bool,
LimiterConfigTestAdditional>;
void fillLimiterConfig(DynamicsProcessing::LimiterConfig& cfg,
const LimiterConfigTestParams& params) {
const std::array<float, LIMITER_MAX_NUM> additional = std::get<LIMITER_ADDITIONAL>(params);
cfg.channel = std::get<LIMITER_CHANNEL>(params);
cfg.enable = std::get<LIMITER_ENABLE>(params);
cfg.linkGroup = std::get<LIMITER_LINK_GROUP>(params);
cfg.attackTimeMs = additional[LIMITER_ATTACK_TIME];
cfg.releaseTimeMs = additional[LIMITER_RELEASE_TIME];
cfg.ratio = additional[LIMITER_RATIO];
cfg.thresholdDb = additional[LIMITER_THRESHOLD];
cfg.postGainDb = additional[LIMITER_POST_GAIN];
}
class DynamicsProcessingTestLimiterConfig
: public ::testing::TestWithParam<LimiterConfigTestParams>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestLimiterConfig()
: DynamicsProcessingTestHelper(std::get<LIMITER_INSTANCE_NAME>(GetParam())),
mLimiterInUseEngine(std::get<LIMITER_ENGINE_IN_USE>(GetParam())) {
fillLimiterConfig(mCfg, GetParam());
}
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
DynamicsProcessing::LimiterConfig mCfg;
bool mLimiterInUseEngine;
};
TEST_P(DynamicsProcessingTestLimiterConfig, SetAndGetLimiterConfig) {
mEngineConfigPreset.limiterInUse = mLimiterInUseEngine;
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
EXPECT_NO_FATAL_FAILURE(addLimiterConfig({mCfg}));
SetAndGetDynamicsProcessingParameters();
}
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestLimiterConfig,
::testing::Combine(testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::Values(-1, 0, 1, 2), // channel count
testing::Bool(), // enable
testing::Values(3), // link group
testing::Bool(), // engine limiter enable
testing::ValuesIn(kLimiterConfigTestAdditionalParam)), // Additional
[](const auto& info) {
auto descriptor = std::get<LIMITER_INSTANCE_NAME>(info.param).second;
DynamicsProcessing::LimiterConfig cfg;
fillLimiterConfig(cfg, info.param);
std::string engineLimiterInUse =
std::to_string(std::get<LIMITER_ENGINE_IN_USE>(info.param));
std::string name = "Implementor_" + descriptor.common.implementor + "_name_" +
descriptor.common.name + "_UUID_" +
descriptor.common.id.uuid.toString() + "_limiterConfig_" +
cfg.toString() + "_engineSetting_" + engineLimiterInUse;
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestLimiterConfig);
/**
* Test DynamicsProcessing ChannelConfig
*/
enum ChannelConfigTestParamName {
BAND_CHANNEL_TEST_INSTANCE_NAME,
BAND_CHANNEL_TEST_CHANNEL_CONFIG,
BAND_CHANNEL_TEST_ENGINE_IN_USE
};
using ChannelConfigTestParams = std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>,
std::vector<DynamicsProcessing::ChannelConfig>, bool>;
class DynamicsProcessingTestChannelConfig
: public ::testing::TestWithParam<ChannelConfigTestParams>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestChannelConfig()
: DynamicsProcessingTestHelper(std::get<BAND_CHANNEL_TEST_INSTANCE_NAME>(GetParam())),
mCfg(std::get<BAND_CHANNEL_TEST_CHANNEL_CONFIG>(GetParam())),
mInUseEngine(std::get<BAND_CHANNEL_TEST_ENGINE_IN_USE>(GetParam())) {}
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
std::vector<DynamicsProcessing::ChannelConfig> mCfg;
const bool mInUseEngine;
};
TEST_P(DynamicsProcessingTestChannelConfig, SetAndGetPreEqChannelConfig) {
mEngineConfigPreset.preEqStage.inUse = mInUseEngine;
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
EXPECT_NO_FATAL_FAILURE(addPreEqChannelConfig(mCfg));
SetAndGetDynamicsProcessingParameters();
}
TEST_P(DynamicsProcessingTestChannelConfig, SetAndGetPostEqChannelConfig) {
mEngineConfigPreset.postEqStage.inUse = mInUseEngine;
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
EXPECT_NO_FATAL_FAILURE(addPostEqChannelConfig(mCfg));
SetAndGetDynamicsProcessingParameters();
}
TEST_P(DynamicsProcessingTestChannelConfig, SetAndGetMbcChannelConfig) {
mEngineConfigPreset.mbcStage.inUse = mInUseEngine;
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
EXPECT_NO_FATAL_FAILURE(addMbcChannelConfig(mCfg));
SetAndGetDynamicsProcessingParameters();
}
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestChannelConfig,
::testing::Combine(
testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::ValuesIn(
DynamicsProcessingTestHelper::kChannelConfigTestSet), // channel config
testing::Bool()), // Engine inUse
[](const auto& info) {
auto descriptor = std::get<BAND_CHANNEL_TEST_INSTANCE_NAME>(info.param).second;
std::string engineInUse =
std::to_string(std::get<BAND_CHANNEL_TEST_ENGINE_IN_USE>(info.param));
std::string channelConfig = ::android::internal::ToString(
std::get<BAND_CHANNEL_TEST_CHANNEL_CONFIG>(info.param));
std::string name = "Implementor_" + descriptor.common.implementor + "_name_" +
descriptor.common.name + "_UUID_" +
descriptor.common.id.uuid.toString() + "_" + channelConfig +
"_engineInUse_" + engineInUse;
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestChannelConfig);
/**
* Test DynamicsProcessing EqBandConfig
*/
enum EqBandConfigTestParamName {
EQ_BAND_INSTANCE_NAME,
EQ_BAND_CHANNEL,
EQ_BAND_ENABLE,
EQ_BAND_CUT_OFF_FREQ,
EQ_BAND_GAIN,
EQ_BAND_STAGE_IN_USE
};
using EqBandConfigTestParams = std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>, int32_t,
bool, std::vector<std::pair<int, float>>, float, bool>;
void fillEqBandConfig(std::vector<DynamicsProcessing::EqBandConfig>& cfgs,
const EqBandConfigTestParams& params) {
const std::vector<std::pair<int, float>> cutOffFreqs = std::get<EQ_BAND_CUT_OFF_FREQ>(params);
int bandCount = cutOffFreqs.size();
cfgs.resize(bandCount);
for (int i = 0; i < bandCount; i++) {
cfgs[i].channel = std::get<EQ_BAND_CHANNEL>(params);
cfgs[i].band = cutOffFreqs[i].first;
cfgs[i].enable = std::get<EQ_BAND_ENABLE>(params);
cfgs[i].cutoffFrequencyHz = cutOffFreqs[i].second;
cfgs[i].gainDb = std::get<EQ_BAND_GAIN>(params);
}
}
class DynamicsProcessingTestEqBandConfig : public ::testing::TestWithParam<EqBandConfigTestParams>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestEqBandConfig()
: DynamicsProcessingTestHelper(std::get<EQ_BAND_INSTANCE_NAME>(GetParam())),
mStageInUse(std::get<EQ_BAND_STAGE_IN_USE>(GetParam())) {
fillEqBandConfig(mCfgs, GetParam());
}
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
std::vector<DynamicsProcessing::EqBandConfig> mCfgs;
const bool mStageInUse;
};
TEST_P(DynamicsProcessingTestEqBandConfig, SetAndGetPreEqBandConfig) {
mEngineConfigPreset.preEqStage.inUse = mStageInUse;
mEngineConfigPreset.preEqStage.bandCount = mCfgs.size();
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
std::vector<DynamicsProcessing::ChannelConfig> cfgs(mChannelCount);
for (int i = 0; i < mChannelCount; i++) {
cfgs[i].channel = i;
cfgs[i].enable = true;
}
EXPECT_NO_FATAL_FAILURE(addPreEqChannelConfig(cfgs));
EXPECT_NO_FATAL_FAILURE(addPreEqBandConfigs(mCfgs));
SetAndGetDynamicsProcessingParameters();
}
TEST_P(DynamicsProcessingTestEqBandConfig, SetAndGetPostEqBandConfig) {
mEngineConfigPreset.postEqStage.inUse = mStageInUse;
mEngineConfigPreset.postEqStage.bandCount = mCfgs.size();
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
std::vector<DynamicsProcessing::ChannelConfig> cfgs(mChannelCount);
for (int i = 0; i < mChannelCount; i++) {
cfgs[i].channel = i;
cfgs[i].enable = true;
}
EXPECT_NO_FATAL_FAILURE(addPostEqChannelConfig(cfgs));
EXPECT_NO_FATAL_FAILURE(addPostEqBandConfigs(mCfgs));
SetAndGetDynamicsProcessingParameters();
}
std::vector<std::vector<std::pair<int, float>>> kBands{
{
{0, 600},
{1, 2000},
{2, 6000},
{3, 10000},
{4, 16000},
}, // 5 bands
{
{0, 800},
{3, 15000},
{2, 6000},
{1, 2000},
}, // 4 bands, unsorted
{
{0, 650},
{1, 2000},
{2, 6000},
{3, 10000},
{3, 16000},
}, // 5 bands, missing band
{
{0, 900},
{1, 8000},
{2, 4000},
{3, 12000},
}, // 4 bands, cutoff freq not increasing
{
{0, 450},
{1, 2000},
{7, 6000},
{3, 10000},
{4, 16000},
}, // bad band index
{
{0, 1},
{1, 8000},
}, // too low cutoff freq
{
{0, 1200},
{1, 80000},
}, // too high cutoff freq
};
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestEqBandConfig,
::testing::Combine(testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::Values(-1, 0, 10), // channel ID
testing::Bool(), // band enable
testing::ValuesIn(kBands), // cut off frequencies
testing::Values(-3.14f, 3.14f), // gain
testing::Values(true)), // stage in use
[](const auto& info) {
auto descriptor = std::get<EQ_BAND_INSTANCE_NAME>(info.param).second;
std::vector<DynamicsProcessing::EqBandConfig> cfgs;
fillEqBandConfig(cfgs, info.param);
std::string bands = ::android::internal::ToString(cfgs);
std::string stageInUse = std::to_string(std::get<EQ_BAND_STAGE_IN_USE>(info.param));
std::string name = "Implementor_" + descriptor.common.implementor + "_name_" +
descriptor.common.name + "_UUID_" +
descriptor.common.id.uuid.toString() + "_bands_" + bands +
"_stageInUse_" + stageInUse;
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestEqBandConfig);
/**
* Test DynamicsProcessing MbcBandConfig
*/
enum MbcBandConfigParamName {
MBC_BAND_INSTANCE_NAME,
MBC_BAND_CHANNEL,
MBC_BAND_ENABLE,
MBC_BAND_CUTOFF_FREQ,
MBC_BAND_STAGE_IN_USE,
MBC_BAND_ADDITIONAL
};
enum MbcBandConfigAdditional {
MBC_ADD_ATTACK_TIME,
MBC_ADD_RELEASE_TIME,
MBC_ADD_RATIO,
MBC_ADD_THRESHOLD,
MBC_ADD_KNEE_WIDTH,
MBC_ADD_NOISE_GATE_THRESHOLD,
MBC_ADD_EXPENDER_RATIO,
MBC_ADD_PRE_GAIN,
MBC_ADD_POST_GAIN,
MBC_ADD_MAX_NUM
};
using TestParamsMbcBandConfigAdditional = std::array<float, MBC_ADD_MAX_NUM>;
// attackTime, releaseTime, ratio, thresh, kneeWidth, noise, expander, preGain, postGain
static constexpr std::array<TestParamsMbcBandConfigAdditional, 4> kMbcBandConfigAdditionalParam = {
{{-3, -10, -2, -2, -5, -90, -2.5, -2, -2},
{0, 0, 0, 0, 0, 0, 0, 0, 0},
{-3, 10, -2, 2, -5, 90, -2.5, 2, -2},
{3, 10, 2, -2, -5, 90, 2.5, 2, 2}}};
using TestParamsMbcBandConfig =
std::tuple<std::pair<std::shared_ptr<IFactory>, Descriptor>, int32_t, bool,
std::vector<std::pair<int, float>>, bool, TestParamsMbcBandConfigAdditional>;
void fillMbcBandConfig(std::vector<DynamicsProcessing::MbcBandConfig>& cfgs,
const TestParamsMbcBandConfig& params) {
const std::vector<std::pair<int, float>> cutOffFreqs = std::get<MBC_BAND_CUTOFF_FREQ>(params);
const std::array<float, MBC_ADD_MAX_NUM> additional = std::get<MBC_BAND_ADDITIONAL>(params);
int bandCount = cutOffFreqs.size();
cfgs.resize(bandCount);
for (int i = 0; i < bandCount; i++) {
cfgs[i] = DynamicsProcessing::MbcBandConfig{
.channel = std::get<MBC_BAND_CHANNEL>(params),
.band = cutOffFreqs[i].first,
.enable = std::get<MBC_BAND_ENABLE>(params),
.cutoffFrequencyHz = cutOffFreqs[i].second,
.attackTimeMs = additional[MBC_ADD_ATTACK_TIME],
.releaseTimeMs = additional[MBC_ADD_RELEASE_TIME],
.ratio = additional[MBC_ADD_RATIO],
.thresholdDb = additional[MBC_ADD_THRESHOLD],
.kneeWidthDb = additional[MBC_ADD_KNEE_WIDTH],
.noiseGateThresholdDb = additional[MBC_ADD_NOISE_GATE_THRESHOLD],
.expanderRatio = additional[MBC_ADD_EXPENDER_RATIO],
.preGainDb = additional[MBC_ADD_PRE_GAIN],
.postGainDb = additional[MBC_ADD_POST_GAIN]};
}
}
class DynamicsProcessingTestMbcBandConfig
: public ::testing::TestWithParam<TestParamsMbcBandConfig>,
public DynamicsProcessingTestHelper {
public:
DynamicsProcessingTestMbcBandConfig()
: DynamicsProcessingTestHelper(std::get<MBC_BAND_INSTANCE_NAME>(GetParam())),
mStageInUse(std::get<MBC_BAND_STAGE_IN_USE>(GetParam())) {
fillMbcBandConfig(mCfgs, GetParam());
}
void SetUp() override { SetUpDynamicsProcessingEffect(); }
void TearDown() override { TearDownDynamicsProcessingEffect(); }
std::vector<DynamicsProcessing::MbcBandConfig> mCfgs;
const bool mStageInUse;
};
TEST_P(DynamicsProcessingTestMbcBandConfig, SetAndGetMbcBandConfig) {
mEngineConfigPreset.mbcStage.inUse = mStageInUse;
mEngineConfigPreset.mbcStage.bandCount = mCfgs.size();
EXPECT_NO_FATAL_FAILURE(addEngineConfig(mEngineConfigPreset));
std::vector<DynamicsProcessing::ChannelConfig> cfgs(mChannelCount);
for (int i = 0; i < mChannelCount; i++) {
cfgs[i].channel = i;
cfgs[i].enable = true;
}
EXPECT_NO_FATAL_FAILURE(addMbcChannelConfig(cfgs));
EXPECT_NO_FATAL_FAILURE(addMbcBandConfigs(mCfgs));
SetAndGetDynamicsProcessingParameters();
}
INSTANTIATE_TEST_SUITE_P(
DynamicsProcessingTest, DynamicsProcessingTestMbcBandConfig,
::testing::Combine(testing::ValuesIn(EffectFactoryHelper::getAllEffectDescriptors(
IFactory::descriptor, getEffectTypeUuidDynamicsProcessing())),
testing::Values(-1, 0, 10), // channel count
testing::Bool(), // enable
testing::ValuesIn(kBands), // cut off frequencies
testing::Bool(), // stage in use
testing::ValuesIn(kMbcBandConfigAdditionalParam)), // Additional
[](const auto& info) {
auto descriptor = std::get<MBC_BAND_INSTANCE_NAME>(info.param).second;
std::vector<DynamicsProcessing::MbcBandConfig> cfgs;
fillMbcBandConfig(cfgs, info.param);
std::string mbcBands = ::android::internal::ToString(cfgs);
std::string stageInUse = std::to_string(std::get<MBC_BAND_STAGE_IN_USE>(info.param));
std::string name = "Implementor_" + descriptor.common.implementor + "_name_" +
descriptor.common.name + "_UUID_" +
descriptor.common.id.uuid.toString() + "_bands_" + mbcBands +
"_stageInUse_" + stageInUse;
std::replace_if(
name.begin(), name.end(), [](const char c) { return !std::isalnum(c); }, '_');
return name;
});
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(DynamicsProcessingTestMbcBandConfig);
int main(int argc, char** argv) {
::testing::InitGoogleTest(&argc, argv);
::testing::UnitTest::GetInstance()->listeners().Append(new TestExecutionTracer());
ABinderProcess_setThreadPoolMaxThreadCount(1);
ABinderProcess_startThreadPool();
return RUN_ALL_TESTS();
}