/* * Copyright 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ //#define LOG_NDEBUG 0 #define LOG_TAG "audio_utils_variadic_tests" #include #include #include // Our near expectation is 16x the bit that doesn't fit the mantissa. // this works so long as we add values close in exponent with each other // realizing that errors accumulate as the sqrt of N (random walk, lln, etc). #define TEST_EXPECT_NEAR(e, v) \ EXPECT_NEAR((e), (v), abs((e) * std::numeric_limits::epsilon() * 8)) #define PRINT_AND_EXPECT_EQ(expected, expr) { \ auto value = (expr); \ printf("(%s): %s\n", #expr, std::to_string(value).c_str()); \ if ((expected) == (expected)) { EXPECT_EQ((expected), (value)); } \ EXPECT_EQ((expected) != (expected), (value) != (value)); /* nan check */\ } #define PRINT_AND_EXPECT_NEAR(expected, expr) { \ auto ref = (expected); \ auto value = (expr); \ printf("(%s): %s\n", #expr, std::to_string(value).c_str()); \ TEST_EXPECT_NEAR(ref, value); \ } TEST(variadic_tests, printing) { // for operator overloading... using namespace android::audio_utils; // print simple, deep value std::cout << "std::make_tuple(1, 2, 3)= " << std::make_tuple(1, 2, 3) << "\n"; std::cout << "std::make_pair(1, std::make_pair(0, 1))= " << std::make_pair(1, std::make_pair(0, 1)) << "\n"; } TEST(variadic_tests, equivalence) { using android::audio_utils::equivalent; auto deep = std::make_pair(1., std::make_pair(2, 3)); EXPECT_TRUE(equivalent(deep, deep)); EXPECT_TRUE(equivalent(std::make_pair(1, 2), std::make_tuple(1, 2))); EXPECT_FALSE(equivalent(std::make_pair(1, 2), std::make_pair(0, 2))); EXPECT_FALSE(equivalent(std::make_pair(1, 2), 1)); EXPECT_FALSE(equivalent(0, 2)); EXPECT_TRUE(equivalent(1, 1.)); } TEST(variadic_tests, template_checks) { EXPECT_FALSE(android::audio_utils::is_variadic::value); using tuple_t = std::tuple; EXPECT_TRUE(android::audio_utils::is_variadic::value); EXPECT_TRUE(android::audio_utils::is_tuple::value); EXPECT_FALSE(android::audio_utils::is_pair::value); EXPECT_FALSE(android::audio_utils::is_array::value); EXPECT_FALSE(std::is_array::value); using pair_t = std::pair; EXPECT_TRUE(android::audio_utils::is_variadic::value); EXPECT_FALSE(android::audio_utils::is_tuple::value); EXPECT_TRUE(android::audio_utils::is_pair::value); EXPECT_FALSE(android::audio_utils::is_array::value); EXPECT_FALSE(std::is_array::value); using array_t = std::array; EXPECT_TRUE(android::audio_utils::is_variadic::value); EXPECT_FALSE(android::audio_utils::is_tuple::value); EXPECT_FALSE(android::audio_utils::is_pair::value); EXPECT_TRUE(android::audio_utils::is_array::value); EXPECT_FALSE(std::is_array::value); EXPECT_FALSE(android::audio_utils::is_iterator::value); EXPECT_TRUE(android::audio_utils::is_iterator::value); EXPECT_TRUE(android::audio_utils::is_iterator{}.begin())>::value); } TEST(variadic_tests, basic_math) { // for operator overloading... using namespace android::audio_utils; using tuple_t = std::tuple; tuple_t x{1, 2}; tuple_t y{0, 3}; double z = 3; std::cout << "x=" << x << " y=" << y << " x+y=" << (x + y) << "\n"; std::cout << "x=" << x << " y=" << y << " x*y=" << (x * y) << "\n"; std::cout << "x=" << x << " z=" << z << " x+z=" << (x + z) << "\n"; std::cout << "x=" << x << " z=" << z << " x*z=" << (x * z) << "\n"; std::cout << "x=" << x << " y=" << y << " innerProduct(x, y)=" << innerProduct(x, y) << "\n"; std::cout << "x=" << x << " y=" << y << " outerProduct(x, y)=" << outerProduct(x, y) << "\n"; std::cout << "x=" << x << " sqrt(x)=" << android::audio_utils::sqrt(x) << "\n"; std::cout << "x=" << x << " y=" << y << " min(x, y)" << android::audio_utils::min(x, y) << "\n"; // check opequals mode std::cout << "x=" << x; std::cout << " x+=2" << (x += 2) << "\n"; std::cout << "x=" << x << " y=" << y; std::cout << " x*=y" << (x *= y) << "\n"; using pair_t = std::pair; pair_t px{1, 2}; pair_t py{0, 3}; std::cout << "px=" << px << " py=" << py << " px+py=" << (px + py) << "\n"; std::cout << "px=" << px << " py=" << py << " px*py=" << (px * py) << "\n"; std::cout << "px=" << px << " z=" << z << " px+z=" << (px + z) << "\n"; std::cout << "px=" << px << " z=" << z << " px*z=" << (px * z) << "\n"; std::cout << "px=" << px << " py=" << py << " innerProduct(px, py)=" << innerProduct(px, py) << "\n"; std::cout << "px=" << px << " py=" << py << " outerProduct(px, py)=" << outerProduct(px, py) << "\n"; using array_t = std::array; array_t ax{1, 2}; array_t ay{0, 3}; std::cout << "ax=" << ax << " ay=" << ay << " ax+ay=" << (ax + ay) << "\n"; std::cout << "ax=" << ax << " ay=" << ay << " ax*ay=" << (ax * ay) << "\n"; std::cout << "ax=" << ax << " z=" << z << " ax+z=" << (ax + z) << "\n"; std::cout << "ax=" << ax << " z=" << z << " ax*z=" << (ax * z) << "\n"; std::cout << "ax=" << px << " ay=" << ay << " innerProduct(ax, ay)=" << innerProduct(ax, ay) << "\n"; std::cout << "ax=" << px << " ay=" << ay << " outerProduct(ax, ay)=" << outerProduct(ax, ay) << "\n"; // deep math auto deep = std::make_pair(1., std::make_pair(2, 3)); std::cout << "deep= " << deep << "\n"; std::cout << "deep + deep= " << deep + deep << "\n"; std::cout << "deep + 1= " << deep + 1 << "\n"; }