compiler-rt/test/builtins/Unit/divtf3_test.c - llvm-project - Git at Google

 // RUN: %clang_builtins %s %librt -o %t && %run %t
 // REQUIRES: librt_has_divtf3

 #include "int_lib.h"
 #include <stdio.h>

 // The testcase currently assumes IEEE TF format, once that has been
 // fixed the defined(CRT_HAS_IEEE_TF) guard can be removed to enable it for
 // IBM 128 floats as well.
 #if defined(CRT_HAS_IEEE_TF)

 #  include "fp_test.h"

 // Returns: a / b
 COMPILER_RT_ABI tf_float __divtf3(tf_float a, tf_float b);

 int test__divtf3(tf_float a, tf_float b, uint64_t expectedHi,
                  uint64_t expectedLo) {
   tf_float x = __divtf3(a, b);
   int ret = compareResultF128(x, expectedHi, expectedLo);

   if (ret) {
     printf("error in test__divtf3(%.20Le, %.20Le) = %.20Le, "
            "expected %.20Le\n",
            a, b, x, fromRep128(expectedHi, expectedLo));
   }
   return ret;
 }

 char assumption_1[sizeof(tf_float) * CHAR_BIT == 128] = {0};

 #endif

 int main() {
 #if defined(CRT_HAS_IEEE_TF)
   // Returned NaNs are assumed to be qNaN by default

   // qNaN / any = qNaN
   if (test__divtf3(makeQNaN128(), TF_C(0x1.23456789abcdefp+5),
                    UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
     return 1;
   // NaN / any = NaN
   if (test__divtf3(makeNaN128(UINT64_C(0x30000000)),
                    TF_C(0x1.23456789abcdefp+5), UINT64_C(0x7fff800000000000),
                    UINT64_C(0x0)))
     return 1;
   // any / qNaN = qNaN
   if (test__divtf3(TF_C(0x1.23456789abcdefp+5), makeQNaN128(),
                    UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
     return 1;
   // any / NaN = NaN
   if (test__divtf3(TF_C(0x1.23456789abcdefp+5),
                    makeNaN128(UINT64_C(0x30000000)),
                    UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
     return 1;

   // +Inf / positive = +Inf
   if (test__divtf3(makeInf128(), TF_C(3.), UINT64_C(0x7fff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // +Inf / negative = -Inf
   if (test__divtf3(makeInf128(), -TF_C(3.), UINT64_C(0xffff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // -Inf / positive = -Inf
   if (test__divtf3(makeNegativeInf128(), TF_C(3.), UINT64_C(0xffff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // -Inf / negative = +Inf
   if (test__divtf3(makeNegativeInf128(), -TF_C(3.),
                    UINT64_C(0x7fff000000000000), UINT64_C(0x0)))
     return 1;

   // Inf / Inf = NaN
   if (test__divtf3(makeInf128(), makeInf128(), UINT64_C(0x7fff800000000000),
                    UINT64_C(0x0)))
     return 1;
   // 0.0 / 0.0 = NaN
   if (test__divtf3(+TF_C(0x0.0p+0), +TF_C(0x0.0p+0),
                    UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
     return 1;
   // +0.0 / +Inf = +0.0
   if (test__divtf3(+TF_C(0x0.0p+0), makeInf128(), UINT64_C(0x0), UINT64_C(0x0)))
     return 1;
   // +Inf / +0.0 = +Inf
   if (test__divtf3(makeInf128(), +TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
                    UINT64_C(0x0)))
     return 1;

   // positive / +0.0 = +Inf
   if (test__divtf3(+TF_C(1.0), +TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // positive / -0.0 = -Inf
   if (test__divtf3(+1.0L, -TF_C(0x0.0p+0), UINT64_C(0xffff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // negative / +0.0 = -Inf
   if (test__divtf3(-1.0L, +TF_C(0x0.0p+0), UINT64_C(0xffff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // negative / -0.0 = +Inf
   if (test__divtf3(TF_C(-1.0), -TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
                    UINT64_C(0x0)))
     return 1;

   // 1/3
   if (test__divtf3(TF_C(1.), TF_C(3.), UINT64_C(0x3ffd555555555555),
                    UINT64_C(0x5555555555555555)))
     return 1;
   // smallest normal result
   if (test__divtf3(TF_C(0x1.0p-16381), TF_C(2.), UINT64_C(0x0001000000000000),
                    UINT64_C(0x0)))
     return 1;

   // divisor is exactly 1.0
   if (test__divtf3(TF_C(0x1.0p+0), TF_C(0x1.0p+0), UINT64_C(0x3fff000000000000),
                    UINT64_C(0x0)))
     return 1;
   // divisor is truncated to exactly 1.0 in UQ1.63
   if (test__divtf3(TF_C(0x1.0p+0), TF_C(0x1.0000000000000001p+0),
                    UINT64_C(0x3ffeffffffffffff), UINT64_C(0xfffe000000000000)))
     return 1;

   // smallest normal value divided by 2.0
   if (test__divtf3(TF_C(0x1.0p-16382), 2.L, UINT64_C(0x0000800000000000),
                    UINT64_C(0x0)))
     return 1;
   // smallest subnormal result
   if (test__divtf3(TF_C(0x1.0p-16382), TF_C(0x1p+112), UINT64_C(0x0),
                    UINT64_C(0x1)))
     return 1;

   // any / any
   if (test__divtf3(TF_C(0x1.a23b45362464523375893ab4cdefp+5),
                    TF_C(0x1.eedcbaba3a94546558237654321fp-1),
                    UINT64_C(0x4004b0b72924d407), UINT64_C(0x0717e84356c6eba2)))
     return 1;
   if (test__divtf3(TF_C(0x1.a2b34c56d745382f9abf2c3dfeffp-50),
                    TF_C(0x1.ed2c3ba15935332532287654321fp-9),
                    UINT64_C(0x3fd5b2af3f828c9b), UINT64_C(0x40e51f64cde8b1f2)))
     return 15;
   if (test__divtf3(TF_C(0x1.2345f6aaaa786555f42432abcdefp+456),
                    TF_C(0x1.edacbba9874f765463544dd3621fp+6400),
                    UINT64_C(0x28c62e15dc464466), UINT64_C(0xb5a07586348557ac)))
     return 1;
   if (test__divtf3(TF_C(0x1.2d3456f789ba6322bc665544edefp-234),
                    TF_C(0x1.eddcdba39f3c8b7a36564354321fp-4455),
                    UINT64_C(0x507b38442b539266), UINT64_C(0x22ce0f1d024e1252)))
     return 1;
   if (test__divtf3(TF_C(0x1.2345f6b77b7a8953365433abcdefp+234),
                    TF_C(0x1.edcba987d6bb3aa467754354321fp-4055),
                    UINT64_C(0x50bf2e02f0798d36), UINT64_C(0x5e6fcb6b60044078)))
     return 1;
   if (test__divtf3(TF_C(6.72420628622418701252535563464350521E-4932), TF_C(2.),
                    UINT64_C(0x0001000000000000), UINT64_C(0)))
     return 1;

 #else
   printf("skipped\n");

 #endif
   return 0;
 }
	// RUN: %clang_builtins %s %librt -o %t && %run %t
	// REQUIRES: librt_has_divtf3

	#include "int_lib.h"
	#include <stdio.h>

	// The testcase currently assumes IEEE TF format, once that has been
	// fixed the defined(CRT_HAS_IEEE_TF) guard can be removed to enable it for
	// IBM 128 floats as well.
	#if defined(CRT_HAS_IEEE_TF)

	# include "fp_test.h"

	// Returns: a / b
	COMPILER_RT_ABI tf_float __divtf3(tf_float a, tf_float b);

	int test__divtf3(tf_float a, tf_float b, uint64_t expectedHi,
	uint64_t expectedLo) {
	tf_float x = __divtf3(a, b);
	int ret = compareResultF128(x, expectedHi, expectedLo);

	if (ret) {
	printf("error in test__divtf3(%.20Le, %.20Le) = %.20Le, "
	"expected %.20Le\n",
	a, b, x, fromRep128(expectedHi, expectedLo));
	}
	return ret;
	}

	char assumption_1[sizeof(tf_float) * CHAR_BIT == 128] = {0};

	#endif

	int main() {
	#if defined(CRT_HAS_IEEE_TF)
	// Returned NaNs are assumed to be qNaN by default

	// qNaN / any = qNaN
	if (test__divtf3(makeQNaN128(), TF_C(0x1.23456789abcdefp+5),
	UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
	return 1;
	// NaN / any = NaN
	if (test__divtf3(makeNaN128(UINT64_C(0x30000000)),
	TF_C(0x1.23456789abcdefp+5), UINT64_C(0x7fff800000000000),
	UINT64_C(0x0)))
	return 1;
	// any / qNaN = qNaN
	if (test__divtf3(TF_C(0x1.23456789abcdefp+5), makeQNaN128(),
	UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
	return 1;
	// any / NaN = NaN
	if (test__divtf3(TF_C(0x1.23456789abcdefp+5),
	makeNaN128(UINT64_C(0x30000000)),
	UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
	return 1;

	// +Inf / positive = +Inf
	if (test__divtf3(makeInf128(), TF_C(3.), UINT64_C(0x7fff000000000000),
	UINT64_C(0x0)))
	return 1;
	// +Inf / negative = -Inf
	if (test__divtf3(makeInf128(), -TF_C(3.), UINT64_C(0xffff000000000000),
	UINT64_C(0x0)))
	return 1;
	// -Inf / positive = -Inf
	if (test__divtf3(makeNegativeInf128(), TF_C(3.), UINT64_C(0xffff000000000000),
	UINT64_C(0x0)))
	return 1;
	// -Inf / negative = +Inf
	if (test__divtf3(makeNegativeInf128(), -TF_C(3.),
	UINT64_C(0x7fff000000000000), UINT64_C(0x0)))
	return 1;

	// Inf / Inf = NaN
	if (test__divtf3(makeInf128(), makeInf128(), UINT64_C(0x7fff800000000000),
	UINT64_C(0x0)))
	return 1;
	// 0.0 / 0.0 = NaN
	if (test__divtf3(+TF_C(0x0.0p+0), +TF_C(0x0.0p+0),
	UINT64_C(0x7fff800000000000), UINT64_C(0x0)))
	return 1;
	// +0.0 / +Inf = +0.0
	if (test__divtf3(+TF_C(0x0.0p+0), makeInf128(), UINT64_C(0x0), UINT64_C(0x0)))
	return 1;
	// +Inf / +0.0 = +Inf
	if (test__divtf3(makeInf128(), +TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
	UINT64_C(0x0)))
	return 1;

	// positive / +0.0 = +Inf
	if (test__divtf3(+TF_C(1.0), +TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
	UINT64_C(0x0)))
	return 1;
	// positive / -0.0 = -Inf
	if (test__divtf3(+1.0L, -TF_C(0x0.0p+0), UINT64_C(0xffff000000000000),
	UINT64_C(0x0)))
	return 1;
	// negative / +0.0 = -Inf
	if (test__divtf3(-1.0L, +TF_C(0x0.0p+0), UINT64_C(0xffff000000000000),
	UINT64_C(0x0)))
	return 1;
	// negative / -0.0 = +Inf
	if (test__divtf3(TF_C(-1.0), -TF_C(0x0.0p+0), UINT64_C(0x7fff000000000000),
	UINT64_C(0x0)))
	return 1;

	// 1/3
	if (test__divtf3(TF_C(1.), TF_C(3.), UINT64_C(0x3ffd555555555555),
	UINT64_C(0x5555555555555555)))
	return 1;
	// smallest normal result
	if (test__divtf3(TF_C(0x1.0p-16381), TF_C(2.), UINT64_C(0x0001000000000000),
	UINT64_C(0x0)))
	return 1;

	// divisor is exactly 1.0
	if (test__divtf3(TF_C(0x1.0p+0), TF_C(0x1.0p+0), UINT64_C(0x3fff000000000000),
	UINT64_C(0x0)))
	return 1;
	// divisor is truncated to exactly 1.0 in UQ1.63
	if (test__divtf3(TF_C(0x1.0p+0), TF_C(0x1.0000000000000001p+0),
	UINT64_C(0x3ffeffffffffffff), UINT64_C(0xfffe000000000000)))
	return 1;

	// smallest normal value divided by 2.0
	if (test__divtf3(TF_C(0x1.0p-16382), 2.L, UINT64_C(0x0000800000000000),
	UINT64_C(0x0)))
	return 1;
	// smallest subnormal result
	if (test__divtf3(TF_C(0x1.0p-16382), TF_C(0x1p+112), UINT64_C(0x0),
	UINT64_C(0x1)))
	return 1;

	// any / any
	if (test__divtf3(TF_C(0x1.a23b45362464523375893ab4cdefp+5),
	TF_C(0x1.eedcbaba3a94546558237654321fp-1),
	UINT64_C(0x4004b0b72924d407), UINT64_C(0x0717e84356c6eba2)))
	return 1;
	if (test__divtf3(TF_C(0x1.a2b34c56d745382f9abf2c3dfeffp-50),
	TF_C(0x1.ed2c3ba15935332532287654321fp-9),
	UINT64_C(0x3fd5b2af3f828c9b), UINT64_C(0x40e51f64cde8b1f2)))
	return 15;
	if (test__divtf3(TF_C(0x1.2345f6aaaa786555f42432abcdefp+456),
	TF_C(0x1.edacbba9874f765463544dd3621fp+6400),
	UINT64_C(0x28c62e15dc464466), UINT64_C(0xb5a07586348557ac)))
	return 1;
	if (test__divtf3(TF_C(0x1.2d3456f789ba6322bc665544edefp-234),
	TF_C(0x1.eddcdba39f3c8b7a36564354321fp-4455),
	UINT64_C(0x507b38442b539266), UINT64_C(0x22ce0f1d024e1252)))
	return 1;
	if (test__divtf3(TF_C(0x1.2345f6b77b7a8953365433abcdefp+234),
	TF_C(0x1.edcba987d6bb3aa467754354321fp-4055),
	UINT64_C(0x50bf2e02f0798d36), UINT64_C(0x5e6fcb6b60044078)))
	return 1;
	if (test__divtf3(TF_C(6.72420628622418701252535563464350521E-4932), TF_C(2.),
	UINT64_C(0x0001000000000000), UINT64_C(0)))
	return 1;

	#else
	printf("skipped\n");

	#endif
	return 0;
	}