device_google_lynx/vibrator/cs40l26/tests/test-hwcal.cpp

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/*
* Copyright (C) 2022 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 <android-base/file.h>
#include <gtest/gtest.h>
#include <fstream>
#include "Hardware.h"
namespace aidl {
namespace android {
namespace hardware {
namespace vibrator {
using ::testing::Test;
class HwCalTest : public Test {
protected:
static constexpr std::array<uint32_t, 2> V_TICK_DEFAULT = {1, 100};
static constexpr std::array<uint32_t, 2> V_CLICK_DEFAULT = {1, 100};
static constexpr std::array<uint32_t, 2> V_LONG_DEFAULT = {1, 100};
public:
void SetUp() override { setenv("CALIBRATION_FILEPATH", mCalFile.path, true); }
private:
template <typename T>
static void pack(std::ostream &stream, const T &value, std::string lpad, std::string rpad) {
stream << lpad << value << rpad;
}
template <typename T, typename std::array<T, 0>::size_type N>
static void pack(std::ostream &stream, const std::array<T, N> &value, std::string lpad,
std::string rpad) {
for (auto &entry : value) {
pack(stream, entry, lpad, rpad);
}
}
protected:
void createHwCal() { mHwCal = std::make_unique<HwCal>(); }
template <typename T>
void write(const std::string key, const T &value, std::string lpad = " ",
std::string rpad = "") {
std::ofstream calfile{mCalFile.path, std::ios_base::app};
calfile << key << ":";
pack(calfile, value, lpad, rpad);
calfile << std::endl;
}
void unlink() { ::unlink(mCalFile.path); }
protected:
std::unique_ptr<Vibrator::HwCal> mHwCal;
TemporaryFile mCalFile;
};
TEST_F(HwCalTest, f0_measured) {
uint32_t randInput = std::rand();
std::string expect = std::to_string(randInput);
std::string actual = std::to_string(~randInput);
write("f0_measured", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getF0(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, f0_missing) {
std::string actual;
createHwCal();
EXPECT_FALSE(mHwCal->getF0(&actual));
}
TEST_F(HwCalTest, redc_measured) {
uint32_t randInput = std::rand();
std::string expect = std::to_string(randInput);
std::string actual = std::to_string(~randInput);
write("redc_measured", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getRedc(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, redc_missing) {
std::string actual;
createHwCal();
EXPECT_FALSE(mHwCal->getRedc(&actual));
}
TEST_F(HwCalTest, q_measured) {
uint32_t randInput = std::rand();
std::string expect = std::to_string(randInput);
std::string actual = std::to_string(~randInput);
write("q_measured", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getQ(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, q_missing) {
std::string actual;
createHwCal();
EXPECT_FALSE(mHwCal->getQ(&actual));
}
TEST_F(HwCalTest, v_levels) {
std::array<uint32_t, 2> expect;
std::array<uint32_t, 2> actual;
// voltage for tick effects
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_tick", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getTickVolLevels(&actual));
EXPECT_EQ(expect, actual);
// voltage for click effects
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_click", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getClickVolLevels(&actual));
EXPECT_EQ(expect, actual);
// voltage for long effects
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_long", expect);
createHwCal();
EXPECT_TRUE(mHwCal->getLongVolLevels(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, v_missing) {
std::array<uint32_t, 2> expect = V_TICK_DEFAULT;
std::array<uint32_t, 2> actual;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
createHwCal();
EXPECT_TRUE(mHwCal->getTickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_CLICK_DEFAULT;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
createHwCal();
EXPECT_TRUE(mHwCal->getClickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_LONG_DEFAULT;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
createHwCal();
EXPECT_TRUE(mHwCal->getLongVolLevels(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, v_short) {
std::array<uint32_t, 2> expect = V_TICK_DEFAULT;
std::array<uint32_t, 2> actual;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
write("v_tick", std::array<uint32_t, expect.size() - 1>());
write("v_click", std::array<uint32_t, expect.size() - 1>());
write("v_long", std::array<uint32_t, expect.size() - 1>());
createHwCal();
EXPECT_TRUE(mHwCal->getTickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_CLICK_DEFAULT;
EXPECT_TRUE(mHwCal->getClickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_LONG_DEFAULT;
EXPECT_TRUE(mHwCal->getLongVolLevels(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, v_long) {
std::array<uint32_t, 2> expect = V_TICK_DEFAULT;
std::array<uint32_t, 2> actual;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
write("v_tick", std::array<uint32_t, expect.size() + 1>());
write("v_click", std::array<uint32_t, expect.size() + 1>());
write("v_long", std::array<uint32_t, expect.size() + 1>());
createHwCal();
EXPECT_TRUE(mHwCal->getTickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_CLICK_DEFAULT;
EXPECT_TRUE(mHwCal->getClickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_LONG_DEFAULT;
EXPECT_TRUE(mHwCal->getLongVolLevels(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, v_nofile) {
std::array<uint32_t, 2> expect = V_TICK_DEFAULT;
std::array<uint32_t, 2> actual;
std::transform(expect.begin(), expect.end(), actual.begin(), [](uint32_t &e) { return ~e; });
write("v_tick", actual);
write("v_click", actual);
write("v_long", actual);
unlink();
createHwCal();
EXPECT_TRUE(mHwCal->getTickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_CLICK_DEFAULT;
EXPECT_TRUE(mHwCal->getClickVolLevels(&actual));
EXPECT_EQ(expect, actual);
expect = V_LONG_DEFAULT;
EXPECT_TRUE(mHwCal->getLongVolLevels(&actual));
EXPECT_EQ(expect, actual);
}
TEST_F(HwCalTest, multiple) {
uint32_t randInput = std::rand();
std::string f0Expect = std::to_string(randInput);
std::string f0Actual = std::to_string(~randInput);
randInput = std::rand();
std::string redcExpect = std::to_string(randInput);
std::string redcActual = std::to_string(~randInput);
randInput = std::rand();
std::string qExpect = std::to_string(randInput);
std::string qActual = std::to_string(~randInput);
std::array<uint32_t, 2> volTickExpect, volClickExpect, volLongExpect;
std::array<uint32_t, 2> volActual;
std::transform(volTickExpect.begin(), volTickExpect.end(), volActual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("f0_measured", f0Expect);
write("redc_measured", redcExpect);
write("q_measured", qExpect);
write("v_tick", volTickExpect);
std::transform(volClickExpect.begin(), volClickExpect.end(), volActual.begin(),
[](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_click", volClickExpect);
std::transform(volLongExpect.begin(), volLongExpect.end(), volActual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_long", volLongExpect);
createHwCal();
EXPECT_TRUE(mHwCal->getF0(&f0Actual));
EXPECT_EQ(f0Expect, f0Actual);
EXPECT_TRUE(mHwCal->getRedc(&redcActual));
EXPECT_EQ(redcExpect, redcActual);
EXPECT_TRUE(mHwCal->getQ(&qActual));
EXPECT_EQ(qExpect, qActual);
EXPECT_TRUE(mHwCal->getTickVolLevels(&volActual));
EXPECT_EQ(volTickExpect, volActual);
EXPECT_TRUE(mHwCal->getClickVolLevels(&volActual));
EXPECT_EQ(volClickExpect, volActual);
EXPECT_TRUE(mHwCal->getLongVolLevels(&volActual));
EXPECT_EQ(volLongExpect, volActual);
}
TEST_F(HwCalTest, trimming) {
uint32_t randInput = std::rand();
std::string f0Expect = std::to_string(randInput);
std::string f0Actual = std::to_string(~randInput);
randInput = std::rand();
std::string redcExpect = std::to_string(randInput);
std::string redcActual = std::to_string(randInput);
randInput = std::rand();
std::string qExpect = std::to_string(randInput);
std::string qActual = std::to_string(randInput);
std::array<uint32_t, 2> volTickExpect, volClickExpect, volLongExpect;
std::array<uint32_t, 2> volActual;
std::transform(volTickExpect.begin(), volTickExpect.end(), volActual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("f0_measured", f0Expect, " \t", "\t ");
write("redc_measured", redcExpect, " \t", "\t ");
write("q_measured", qExpect, " \t", "\t ");
write("v_tick", volTickExpect, " \t", "\t ");
std::transform(volClickExpect.begin(), volClickExpect.end(), volActual.begin(),
[](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_click", volClickExpect, " \t", "\t ");
std::transform(volLongExpect.begin(), volLongExpect.end(), volActual.begin(), [](uint32_t &e) {
e = std::rand();
return ~e;
});
write("v_long", volLongExpect, " \t", "\t ");
createHwCal();
EXPECT_TRUE(mHwCal->getF0(&f0Actual));
EXPECT_EQ(f0Expect, f0Actual);
EXPECT_TRUE(mHwCal->getRedc(&redcActual));
EXPECT_EQ(redcExpect, redcActual);
EXPECT_TRUE(mHwCal->getQ(&qActual));
EXPECT_EQ(qExpect, qActual);
EXPECT_TRUE(mHwCal->getTickVolLevels(&volActual));
EXPECT_EQ(volTickExpect, volActual);
EXPECT_TRUE(mHwCal->getClickVolLevels(&volActual));
EXPECT_EQ(volClickExpect, volActual);
EXPECT_TRUE(mHwCal->getLongVolLevels(&volActual));
EXPECT_EQ(volLongExpect, volActual);
}
} // namespace vibrator
} // namespace hardware
} // namespace android
} // namespace aidl