/** * Math test suite */ #include #include "SDL.h" #include "SDL_test.h" /* Range tests parameters */ #define RANGE_TEST_ITERATIONS 10000000 #define RANGE_TEST_STEP SDL_MAX_UINT32 / RANGE_TEST_ITERATIONS /* ================= Test Structs ================== */ /** * Stores a single input and the expected result */ typedef struct { double input; double expected; } d_to_d; /** * Stores a pair of inputs and the expected result */ typedef struct { double x_input, y_input; double expected; } dd_to_d; /* NB: You cannot create an array of these structures containing INFINITY or NAN. On platforms such as OS/2, they are defined as 'extern const double' making them not compile-time constant. */ /* ================= Test Helpers ================== */ typedef double(SDLCALL *d_to_d_func)(double); typedef double(SDLCALL *dd_to_d_func)(double, double); /** * \brief Runs all the cases on a given function with a signature double -> double * * \param func_name, the name of the tested function. * \param func, the function to call. * \param cases, an array of all the cases. * \param cases_size, the size of the cases array. */ static int helper_dtod(const char *func_name, d_to_d_func func, const d_to_d *cases, const size_t cases_size) { Uint32 i; for (i = 0; i < cases_size; i++) { const double result = func(cases[i].input); SDLTest_AssertCheck(result == cases[i].expected, "%s(%f), expected %f, got %f", func_name, cases[i].input, cases[i].expected, result); } return TEST_COMPLETED; } /** * \brief Runs all the cases on a given function with a signature (double, double) -> double * * \param func_name, the name of the tested function. * \param func, the function to call. * \param cases, an array of all the cases. * \param cases_size, the size of the cases array. */ static int helper_ddtod(const char *func_name, dd_to_d_func func, const dd_to_d *cases, const size_t cases_size) { Uint32 i; for (i = 0; i < cases_size; i++) { const double result = func(cases[i].x_input, cases[i].y_input); SDLTest_AssertCheck(result == cases[i].expected, "%s(%f,%f), expected %f, got %f", func_name, cases[i].x_input, cases[i].y_input, cases[i].expected, result); } return TEST_COMPLETED; } /** * \brief Runs a range of values on a given function with a signature double -> double * * This function is only meant to test functions that returns the input value if it is * integral: f(x) -> x for x in N. * * \param func_name, the name of the tested function. * \param func, the function to call. */ static int helper_range(const char *func_name, d_to_d_func func) { Uint32 i; double test_value = 0.0; SDLTest_AssertPass("%s: Testing a range of %u values with steps of %u", func_name, RANGE_TEST_ITERATIONS, RANGE_TEST_STEP); for (i = 0; i < RANGE_TEST_ITERATIONS; i++, test_value += RANGE_TEST_STEP) { double result; /* These are tested elsewhere */ if (isnan(test_value) || isinf(test_value)) { continue; } result = func(test_value); if (result != test_value) { /* Only log failures to save performances */ SDLTest_AssertPass("%s(%.1f), expected %.1f, got %.1f", func_name, test_value, test_value, result); return TEST_ABORTED; } } return TEST_COMPLETED; } /* ================= Test Case Implementation ================== */ /* SDL_floor tests functions */ /** * \brief Checks positive and negative infinity. */ static int floor_infCases(void *args) { double result; result = SDL_floor(INFINITY); SDLTest_AssertCheck(INFINITY == result, "Floor(%f), expected %f, got %f", INFINITY, INFINITY, result); result = SDL_floor(-INFINITY); SDLTest_AssertCheck(-INFINITY == result, "Floor(%f), expected %f, got %f", -INFINITY, -INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero. */ static int floor_zeroCases(void *args) { const d_to_d zero_cases[] = { { 0.0, 0.0 }, { -0.0, -0.0 } }; return helper_dtod("Floor", SDL_floor, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN case. */ static int floor_nanCase(void *args) { const double result = SDL_floor(NAN); SDLTest_AssertCheck(isnan(result), "Floor(nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks round values (x.0) for themselves */ static int floor_roundNumbersCases(void *args) { const d_to_d round_cases[] = { { 1.0, 1.0 }, { -1.0, -1.0 }, { 15.0, 15.0 }, { -15.0, -15.0 }, { 125.0, 125.0 }, { -125.0, -125.0 }, { 1024.0, 1024.0 }, { -1024.0, -1024.0 } }; return helper_dtod("Floor", SDL_floor, round_cases, SDL_arraysize(round_cases)); } /** * \brief Checks a set of fractions */ static int floor_fractionCases(void *args) { const d_to_d frac_cases[] = { { 1.0 / 2.0, 0.0 }, { -1.0 / 2.0, -1.0 }, { 4.0 / 3.0, 1.0 }, { -4.0 / 3.0, -2.0 }, { 76.0 / 7.0, 10.0 }, { -76.0 / 7.0, -11.0 }, { 535.0 / 8.0, 66.0 }, { -535.0 / 8.0, -67.0 }, { 19357.0 / 53.0, 365.0 }, { -19357.0 / 53.0, -366.0 } }; return helper_dtod("Floor", SDL_floor, frac_cases, SDL_arraysize(frac_cases)); } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int floor_rangeTest(void *args) { return helper_range("Floor", SDL_floor); } /* SDL_ceil tests functions */ /** * \brief Checks positive and negative infinity. */ static int ceil_infCases(void *args) { double result; result = SDL_ceil(INFINITY); SDLTest_AssertCheck(INFINITY == result, "Ceil(%f), expected %f, got %f", INFINITY, INFINITY, result); result = SDL_ceil(-INFINITY); SDLTest_AssertCheck(-INFINITY == result, "Ceil(%f), expected %f, got %f", -INFINITY, -INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero. */ static int ceil_zeroCases(void *args) { const d_to_d zero_cases[] = { { 0.0, 0.0 }, { -0.0, -0.0 } }; return helper_dtod("Ceil", SDL_ceil, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN case. */ static int ceil_nanCase(void *args) { const double result = SDL_ceil(NAN); SDLTest_AssertCheck(isnan(result), "Ceil(nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks round values (x.0) for themselves */ static int ceil_roundNumbersCases(void *args) { const d_to_d round_cases[] = { { 1.0, 1.0 }, { -1.0, -1.0 }, { 15.0, 15.0 }, { -15.0, -15.0 }, { 125.0, 125.0 }, { -125.0, -125.0 }, { 1024.0, 1024.0 }, { -1024.0, -1024.0 } }; return helper_dtod("Ceil", SDL_ceil, round_cases, SDL_arraysize(round_cases)); } /** * \brief Checks a set of fractions */ static int ceil_fractionCases(void *args) { const d_to_d frac_cases[] = { { 1.0 / 2.0, 1.0 }, { -1.0 / 2.0, -0.0 }, { 4.0 / 3.0, 2.0 }, { -4.0 / 3.0, -1.0 }, { 76.0 / 7.0, 11.0 }, { -76.0 / 7.0, -10.0 }, { 535.0 / 8.0, 67.0 }, { -535.0 / 8.0, -66.0 }, { 19357.0 / 53.0, 366.0 }, { -19357.0 / 53.0, -365.0 } }; return helper_dtod("Ceil", SDL_ceil, frac_cases, SDL_arraysize(frac_cases)); } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int ceil_rangeTest(void *args) { return helper_range("Ceil", SDL_ceil); } /* SDL_trunc tests functions */ /** * \brief Checks positive and negative infinity. */ static int trunc_infCases(void *args) { double result; result = SDL_trunc(INFINITY); SDLTest_AssertCheck(INFINITY == result, "Trunc(%f), expected %f, got %f", INFINITY, INFINITY, result); result = SDL_trunc(-INFINITY); SDLTest_AssertCheck(-INFINITY == result, "Trunc(%f), expected %f, got %f", -INFINITY, -INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero. */ static int trunc_zeroCases(void *args) { const d_to_d zero_cases[] = { { 0.0, 0.0 }, { -0.0, -0.0 } }; return helper_dtod("Trunc", SDL_trunc, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN case. */ static int trunc_nanCase(void *args) { const double result = SDL_trunc(NAN); SDLTest_AssertCheck(isnan(result), "Trunc(nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks round values (x.0) for themselves */ static int trunc_roundNumbersCases(void *args) { const d_to_d round_cases[] = { { 1.0, 1.0 }, { -1.0, -1.0 }, { 15.0, 15.0 }, { -15.0, -15.0 }, { 125.0, 125.0 }, { -125.0, -125.0 }, { 1024.0, 1024.0 }, { -1024.0, -1024.0 } }; return helper_dtod("Trunc", SDL_trunc, round_cases, SDL_arraysize(round_cases)); } /** * \brief Checks a set of fractions */ static int trunc_fractionCases(void *args) { const d_to_d frac_cases[] = { { 1.0 / 2.0, 0.0 }, { -1.0 / 2.0, -0.0 }, { 4.0 / 3.0, 1.0 }, { -4.0 / 3.0, -1.0 }, { 76.0 / 7.0, 10.0 }, { -76.0 / 7.0, -10.0 }, { 535.0 / 8.0, 66.0 }, { -535.0 / 8.0, -66.0 }, { 19357.0 / 53.0, 365.0 }, { -19357.0 / 53.0, -365.0 } }; return helper_dtod("Trunc", SDL_trunc, frac_cases, SDL_arraysize(frac_cases)); } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int trunc_rangeTest(void *args) { return helper_range("Trunc", SDL_trunc); } /* SDL_round tests functions */ /** * \brief Checks positive and negative infinity. */ static int round_infCases(void *args) { double result; result = SDL_round(INFINITY); SDLTest_AssertCheck(INFINITY == result, "Round(%f), expected %f, got %f", INFINITY, INFINITY, result); result = SDL_round(-INFINITY); SDLTest_AssertCheck(-INFINITY == result, "Round(%f), expected %f, got %f", -INFINITY, -INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero. */ static int round_zeroCases(void *args) { const d_to_d zero_cases[] = { { 0.0, 0.0 }, { -0.0, -0.0 } }; return helper_dtod("Round", SDL_round, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN case. */ static int round_nanCase(void *args) { const double result = SDL_round(NAN); SDLTest_AssertCheck(isnan(result), "Round(nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks round values (x.0) for themselves */ static int round_roundNumbersCases(void *args) { const d_to_d round_cases[] = { { 1.0, 1.0 }, { -1.0, -1.0 }, { 15.0, 15.0 }, { -15.0, -15.0 }, { 125.0, 125.0 }, { -125.0, -125.0 }, { 1024.0, 1024.0 }, { -1024.0, -1024.0 } }; return helper_dtod("Round", SDL_round, round_cases, SDL_arraysize(round_cases)); } /** * \brief Checks a set of fractions */ static int round_fractionCases(void *args) { const d_to_d frac_cases[] = { { 1.0 / 2.0, 1.0 }, { -1.0 / 2.0, -1.0 }, { 4.0 / 3.0, 1.0 }, { -4.0 / 3.0, -1.0 }, { 76.0 / 7.0, 11.0 }, { -76.0 / 7.0, -11.0 }, { 535.0 / 8.0, 67.0 }, { -535.0 / 8.0, -67.0 }, { 19357.0 / 53.0, 365.0 }, { -19357.0 / 53.0, -365.0 } }; return helper_dtod("Round", SDL_round, frac_cases, SDL_arraysize(frac_cases)); } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int round_rangeTest(void *args) { return helper_range("Round", SDL_round); } /* SDL_fabs tests functions */ /** * \brief Checks positive and negative infinity. */ static int fabs_infCases(void *args) { double result; result = SDL_fabs(INFINITY); SDLTest_AssertCheck(INFINITY == result, "Fabs(%f), expected %f, got %f", INFINITY, INFINITY, result); result = SDL_fabs(-INFINITY); SDLTest_AssertCheck(INFINITY == result, "Fabs(%f), expected %f, got %f", -INFINITY, INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero */ static int fabs_zeroCases(void *args) { const d_to_d zero_cases[] = { { 0.0, 0.0 }, { -0.0, 0.0 } }; return helper_dtod("Fabs", SDL_fabs, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN case. */ static int fabs_nanCase(void *args) { const double result = SDL_fabs(NAN); SDLTest_AssertCheck(isnan(result), "Fabs(nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int fabs_rangeTest(void *args) { return helper_range("Fabs", SDL_fabs); } /* SDL_copysign tests functions */ /** * \brief Checks positive and negative inifnity. */ static int copysign_infCases(void *args) { double result; result = SDL_copysign(INFINITY, -1.0); SDLTest_AssertCheck(-INFINITY == result, "Copysign(%f,%.1f), expected %f, got %f", INFINITY, -1.0, -INFINITY, result); result = SDL_copysign(INFINITY, 1.0); SDLTest_AssertCheck(INFINITY == result, "Copysign(%f,%.1f), expected %f, got %f", INFINITY, 1.0, INFINITY, result); result = SDL_copysign(-INFINITY, -1.0); SDLTest_AssertCheck(-INFINITY == result, "Copysign(%f,%.1f), expected %f, got %f", -INFINITY, -1.0, -INFINITY, result); result = SDL_copysign(-INFINITY, 1.0); SDLTest_AssertCheck(INFINITY == result, "Copysign(%f,%.1f), expected %f, got %f", -INFINITY, 1.0, INFINITY, result); return TEST_COMPLETED; } /** * \brief Checks positive and negative zero. */ static int copysign_zeroCases(void *args) { const dd_to_d zero_cases[] = { { 0.0, 1.0, 0.0 }, { 0.0, -1.0, -0.0 }, { -0.0, 1.0, 0.0 }, { -0.0, -1.0, -0.0 } }; return helper_ddtod("Copysign", SDL_copysign, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks the NaN cases. */ static int copysign_nanCases(void *args) { double result; result = SDL_copysign(NAN, 1.0); SDLTest_AssertCheck(isnan(result), "Copysign(nan,1.0), expected nan, got %f", result); result = SDL_copysign(NAN, -1.0); SDLTest_AssertCheck(isnan(result), "Copysign(nan,-1.0), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int copysign_rangeTest(void *args) { Uint32 i; double test_value = 0.0; SDLTest_AssertPass("Copysign: Testing a range of %u values with steps of %u", RANGE_TEST_ITERATIONS, RANGE_TEST_STEP); for (i = 0; i < RANGE_TEST_ITERATIONS; i++, test_value += RANGE_TEST_STEP) { double result; /* These are tested elsewhere */ if (isnan(test_value) || isinf(test_value)) { continue; } /* Only log failures to save performances */ result = SDL_copysign(test_value, 1.0); if (result != test_value) { SDLTest_AssertPass("Copysign(%.1f,%.1f), expected %.1f, got %.1f", test_value, 1.0, test_value, result); return TEST_ABORTED; } result = SDL_copysign(test_value, -1.0); if (result != -test_value) { SDLTest_AssertPass("Copysign(%.1f,%.1f), expected %.1f, got %.1f", test_value, -1.0, -test_value, result); return TEST_ABORTED; } } return TEST_COMPLETED; } /* SDL_fmod tests functions */ /** * \brief Checks division of positive and negative inifnity. */ static int fmod_divOfInfCases(void *args) { double result; result = SDL_fmod(INFINITY, -1.0); SDLTest_AssertCheck(isnan(result), "Fmod(%f,%.1f), expected %f, got %f", INFINITY, -1.0, NAN, result); result = SDL_fmod(INFINITY, 1.0); SDLTest_AssertCheck(isnan(result), "Fmod(%f,%.1f), expected %f, got %f", INFINITY, 1.0, NAN, result); result = SDL_fmod(-INFINITY, -1.0); SDLTest_AssertCheck(isnan(result), "Fmod(%f,%.1f), expected %f, got %f", -INFINITY, -1.0, NAN, result); result = SDL_fmod(-INFINITY, 1.0); SDLTest_AssertCheck(isnan(result), "Fmod(%f,%.1f), expected %f, got %f", -INFINITY, 1.0, NAN, result); return TEST_COMPLETED; } /** * \brief Checks division by positive and negative inifnity. */ static int fmod_divByInfCases(void *args) { double result; result = SDL_fmod(1.0, INFINITY); SDLTest_AssertCheck(1.0 == result, "Fmod(%.1f,%f), expected %f, got %f", 1.0, INFINITY, 1.0, result); result = SDL_fmod(-1.0, INFINITY); SDLTest_AssertCheck(-1.0 == result, "Fmod(%.1f,%f), expected %f, got %f", -1.0, INFINITY, -1.0, result); result = SDL_fmod(1.0, -INFINITY); SDLTest_AssertCheck(1.0 == result, "Fmod(%.1f,%f), expected %f, got %f", 1.0, -INFINITY, 1.0, result); result = SDL_fmod(-1.0, -INFINITY); SDLTest_AssertCheck(-1.0 == result, "Fmod(%.1f,%f), expected %f, got %f", -1.0, -INFINITY, -1.0, result); return TEST_COMPLETED; } /** * \brief Checks division of positive and negative zero. */ static int fmod_divOfZeroCases(void *args) { const dd_to_d zero_cases[] = { { 0.0, 1.0, 0.0 }, { 0.0, -1.0, 0.0 }, { -0.0, 1.0, -0.0 }, { -0.0, -1.0, -0.0 } }; return helper_ddtod("Fmod", SDL_fmod, zero_cases, SDL_arraysize(zero_cases)); } /** * \brief Checks division by positive and negative zero. */ static int fmod_divByZeroCases(void *args) { double result; result = SDL_fmod(1.0, 0.0); SDLTest_AssertCheck(isnan(result), "Fmod(1.0,0.0), expected nan, got %f", result); result = SDL_fmod(-1.0, 0.0); SDLTest_AssertCheck(isnan(result), "Fmod(-1.0,0.0), expected nan, got %f", result); result = SDL_fmod(1.0, -0.0); SDLTest_AssertCheck(isnan(result), "Fmod(1.0,-0.0), expected nan, got %f", result); result = SDL_fmod(-1.0, -0.0); SDLTest_AssertCheck(isnan(result), "Fmod(-1.0,-0.0), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks the NaN cases. */ static int fmod_nanCases(void *args) { double result; result = SDL_fmod(NAN, 1.0); SDLTest_AssertCheck(isnan(result), "Fmod(nan,1.0), expected nan, got %f", result); result = SDL_fmod(NAN, -1.0); SDLTest_AssertCheck(isnan(result), "Fmod(nan,-1.0), expected nan, got %f", result); result = SDL_fmod(1.0, NAN); SDLTest_AssertCheck(isnan(result), "Fmod(1.0,nan), expected nan, got %f", result); result = SDL_fmod(-1.0, NAN); SDLTest_AssertCheck(isnan(result), "Fmod(-1.0,nan), expected nan, got %f", result); return TEST_COMPLETED; } /** * \brief Checks a set of regular values. */ static int fmod_regularCases(void *args) { const dd_to_d regular_cases[] = { { 3.5, 2.0, 1.5 }, { -6.25, 3.0, -0.25 }, { 7.5, 2.5, 0.0 }, { 2.0 / 3.0, -1.0 / 3.0, 0.0 } }; return helper_ddtod("Fmod", SDL_fmod, regular_cases, SDL_arraysize(regular_cases)); } /** * \brief Checks a range of values between 0 and UINT32_MAX */ static int fmod_rangeTest(void *args) { Uint32 i; double test_value = 0.0; SDLTest_AssertPass("Fmod: Testing a range of %u values with steps of %u", RANGE_TEST_ITERATIONS, RANGE_TEST_STEP); for (i = 0; i < RANGE_TEST_ITERATIONS; i++, test_value += RANGE_TEST_STEP) { double result; /* These are tested elsewhere */ if (isnan(test_value) || isinf(test_value)) { continue; } /* Only log failures to save performances */ result = SDL_fmod(test_value, 1.0); if (0.0 != result) { SDLTest_AssertPass("Fmod(%.1f,%.1f), expected %.1f, got %.1f", test_value, 1.0, 0.0, result); return TEST_ABORTED; } } return TEST_COMPLETED; } /* ================= Test References ================== */ /* SDL_floor test cases */ static const SDLTest_TestCaseReference floorTestInf = { (SDLTest_TestCaseFp) floor_infCases, "floor_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference floorTestZero = { (SDLTest_TestCaseFp) floor_zeroCases, "floor_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference floorTestNan = { (SDLTest_TestCaseFp) floor_nanCase, "floor_nanCase", "Check the NaN special case", TEST_ENABLED }; static const SDLTest_TestCaseReference floorTestRound = { (SDLTest_TestCaseFp) floor_roundNumbersCases, "floor_roundNumberCases", "Check a set of round numbers", TEST_ENABLED }; static const SDLTest_TestCaseReference floorTestFraction = { (SDLTest_TestCaseFp) floor_fractionCases, "floor_fractionCases", "Check a set of fractions", TEST_ENABLED }; static const SDLTest_TestCaseReference floorTestRange = { (SDLTest_TestCaseFp) floor_rangeTest, "floor_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_ceil test cases */ static const SDLTest_TestCaseReference ceilTestInf = { (SDLTest_TestCaseFp) ceil_infCases, "ceil_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference ceilTestZero = { (SDLTest_TestCaseFp) ceil_zeroCases, "ceil_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference ceilTestNan = { (SDLTest_TestCaseFp) ceil_nanCase, "ceil_nanCase", "Check the NaN special case", TEST_ENABLED }; static const SDLTest_TestCaseReference ceilTestRound = { (SDLTest_TestCaseFp) ceil_roundNumbersCases, "ceil_roundNumberCases", "Check a set of round numbers", TEST_ENABLED }; static const SDLTest_TestCaseReference ceilTestFraction = { (SDLTest_TestCaseFp) ceil_fractionCases, "ceil_fractionCases", "Check a set of fractions", TEST_ENABLED }; static const SDLTest_TestCaseReference ceilTestRange = { (SDLTest_TestCaseFp) ceil_rangeTest, "ceil_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_trunc test cases */ static const SDLTest_TestCaseReference truncTestInf = { (SDLTest_TestCaseFp) trunc_infCases, "trunc_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference truncTestZero = { (SDLTest_TestCaseFp) trunc_zeroCases, "trunc_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference truncTestNan = { (SDLTest_TestCaseFp) trunc_nanCase, "trunc_nanCase", "Check the NaN special case", TEST_ENABLED }; static const SDLTest_TestCaseReference truncTestRound = { (SDLTest_TestCaseFp) trunc_roundNumbersCases, "trunc_roundNumberCases", "Check a set of round numbers", TEST_ENABLED }; static const SDLTest_TestCaseReference truncTestFraction = { (SDLTest_TestCaseFp) trunc_fractionCases, "trunc_fractionCases", "Check a set of fractions", TEST_ENABLED }; static const SDLTest_TestCaseReference truncTestRange = { (SDLTest_TestCaseFp) trunc_rangeTest, "trunc_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_round test cases */ static const SDLTest_TestCaseReference roundTestInf = { (SDLTest_TestCaseFp) round_infCases, "round_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference roundTestZero = { (SDLTest_TestCaseFp) round_zeroCases, "round_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference roundTestNan = { (SDLTest_TestCaseFp) round_nanCase, "round_nanCase", "Check the NaN special case", TEST_ENABLED }; static const SDLTest_TestCaseReference roundTestRound = { (SDLTest_TestCaseFp) round_roundNumbersCases, "round_roundNumberCases", "Check a set of round numbers", TEST_ENABLED }; static const SDLTest_TestCaseReference roundTestFraction = { (SDLTest_TestCaseFp) round_fractionCases, "round_fractionCases", "Check a set of fractions", TEST_ENABLED }; static const SDLTest_TestCaseReference roundTestRange = { (SDLTest_TestCaseFp) round_rangeTest, "round_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_fabs test cases */ static const SDLTest_TestCaseReference fabsTestInf = { (SDLTest_TestCaseFp) fabs_infCases, "fabs_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference fabsTestZero = { (SDLTest_TestCaseFp) fabs_zeroCases, "fabs_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference fabsTestNan = { (SDLTest_TestCaseFp) fabs_nanCase, "fabs_nanCase", "Check the NaN special case", TEST_ENABLED }; static const SDLTest_TestCaseReference fabsTestRange = { (SDLTest_TestCaseFp) fabs_rangeTest, "fabs_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_copysign test cases */ static const SDLTest_TestCaseReference copysignTestInf = { (SDLTest_TestCaseFp) copysign_infCases, "copysign_infCases", "Check positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference copysignTestZero = { (SDLTest_TestCaseFp) copysign_zeroCases, "copysign_zeroCases", "Check positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference copysignTestNan = { (SDLTest_TestCaseFp) copysign_nanCases, "copysign_nanCases", "Check the NaN special cases", TEST_ENABLED }; static const SDLTest_TestCaseReference copysignTestRange = { (SDLTest_TestCaseFp) copysign_rangeTest, "copysign_rangeTest", "Check a range of positive integer", TEST_ENABLED }; /* SDL_fmod test cases */ static const SDLTest_TestCaseReference fmodTestDivOfInf = { (SDLTest_TestCaseFp) fmod_divOfInfCases, "fmod_divOfInfCases", "Check division of positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestDivByInf = { (SDLTest_TestCaseFp) fmod_divByInfCases, "fmod_divByInfCases", "Check division by positive and negative infinity", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestDivOfZero = { (SDLTest_TestCaseFp) fmod_divOfZeroCases, "fmod_divOfZeroCases", "Check division of positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestDivByZero = { (SDLTest_TestCaseFp) fmod_divByZeroCases, "fmod_divByZeroCases", "Check division by positive and negative zero", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestNan = { (SDLTest_TestCaseFp) fmod_nanCases, "fmod_nanCases", "Check the NaN special cases", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestRegular = { (SDLTest_TestCaseFp) fmod_regularCases, "fmod_regularCases", "Check a set of regular values", TEST_ENABLED }; static const SDLTest_TestCaseReference fmodTestRange = { (SDLTest_TestCaseFp) fmod_rangeTest, "fmod_rangeTest", "Check a range of positive integer", TEST_ENABLED }; static const SDLTest_TestCaseReference *mathTests[] = { &floorTestInf, &floorTestZero, &floorTestNan, &floorTestRound, &floorTestFraction, &floorTestRange, &ceilTestInf, &ceilTestZero, &ceilTestNan, &ceilTestRound, &ceilTestFraction, &ceilTestRange, &truncTestInf, &truncTestZero, &truncTestNan, &truncTestRound, &truncTestFraction, &truncTestRange, &roundTestInf, &roundTestZero, &roundTestNan, &roundTestRound, &roundTestFraction, &roundTestRange, &fabsTestInf, &fabsTestZero, &fabsTestNan, &fabsTestRange, ©signTestInf, ©signTestZero, ©signTestNan, ©signTestRange, &fmodTestDivOfInf, &fmodTestDivByInf, &fmodTestDivOfZero, &fmodTestDivByZero, &fmodTestNan, &fmodTestRegular, &fmodTestRange, NULL }; SDLTest_TestSuiteReference mathTestSuite = { "Math", NULL, mathTests, NULL };