test/Unit/muldc3_test.c - platform/external/compiler-rt - Gitiles

 //===-- muldc3_test.c - Test __muldc3 -------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file tests __muldc3 for the compiler_rt library.
 //
 //===----------------------------------------------------------------------===//

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

 // Returns: the product of a + ib and c + id

 double _Complex __muldc3(double __a, double __b, double __c, double __d);

 enum {zero, non_zero, inf, NaN, non_zero_nan};

 int
 classify(double _Complex x)
 {
     if (x == 0)
         return zero;
     if (isinf(creal(x)) || isinf(cimag(x)))
         return inf;
     if (isnan(creal(x)) && isnan(cimag(x)))
         return NaN;
     if (isnan(creal(x)))
     {
         if (cimag(x) == 0)
             return NaN;
         return non_zero_nan;
     }
     if (isnan(cimag(x)))
     {
         if (creal(x) == 0)
             return NaN;
         return non_zero_nan;
     }
     return non_zero;
 }

 int test__muldc3(double a, double b, double c, double d)
 {
     double _Complex r = __muldc3(a, b, c, d);
 //     printf("test__muldc3(%f, %f, %f, %f) = %f + I%f\n",
 //             a, b, c, d, creal(r), cimag(r));
 	double _Complex dividend;
 	double _Complex divisor;

 	__real__ dividend = a;
 	__imag__ dividend = b;
 	__real__ divisor = c;
 	__imag__ divisor = d;

     switch (classify(dividend))
     {
     case zero:
         switch (classify(divisor))
         {
         case zero:
             if (classify(r) != zero)
                 return 1;
             break;
         case non_zero:
             if (classify(r) != zero)
                 return 1;
             break;
         case inf:
             if (classify(r) != NaN)
                 return 1;
             break;
         case NaN:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero_nan:
             if (classify(r) != NaN)
                 return 1;
             break;
         }
         break;
     case non_zero:
         switch (classify(divisor))
         {
         case zero:
             if (classify(r) != zero)
                 return 1;
             break;
         case non_zero:
             if (classify(r) != non_zero)
                 return 1;
             if (r != a * c - b * d + _Complex_I*(a * d + b * c))
                 return 1;
             break;
         case inf:
             if (classify(r) != inf)
                 return 1;
             break;
         case NaN:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero_nan:
             if (classify(r) != NaN)
                 return 1;
             break;
         }
         break;
     case inf:
         switch (classify(divisor))
         {
         case zero:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero:
             if (classify(r) != inf)
                 return 1;
             break;
         case inf:
             if (classify(r) != inf)
                 return 1;
             break;
         case NaN:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero_nan:
             if (classify(r) != inf)
                 return 1;
             break;
         }
         break;
     case NaN:
         switch (classify(divisor))
         {
         case zero:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero:
             if (classify(r) != NaN)
                 return 1;
             break;
         case inf:
             if (classify(r) != NaN)
                 return 1;
             break;
         case NaN:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero_nan:
             if (classify(r) != NaN)
                 return 1;
             break;
         }
         break;
     case non_zero_nan:
         switch (classify(divisor))
         {
         case zero:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero:
             if (classify(r) != NaN)
                 return 1;
             break;
         case inf:
             if (classify(r) != inf)
                 return 1;
             break;
         case NaN:
             if (classify(r) != NaN)
                 return 1;
             break;
         case non_zero_nan:
             if (classify(r) != NaN)
                 return 1;
             break;
         }
         break;
     }

     return 0;
 }

 double x[][2] =
 {
     { 1.e-6,  1.e-6},
     {-1.e-6,  1.e-6},
     {-1.e-6, -1.e-6},
     { 1.e-6, -1.e-6},

     { 1.e+6,  1.e-6},
     {-1.e+6,  1.e-6},
     {-1.e+6, -1.e-6},
     { 1.e+6, -1.e-6},

     { 1.e-6,  1.e+6},
     {-1.e-6,  1.e+6},
     {-1.e-6, -1.e+6},
     { 1.e-6, -1.e+6},

     { 1.e+6,  1.e+6},
     {-1.e+6,  1.e+6},
     {-1.e+6, -1.e+6},
     { 1.e+6, -1.e+6},

     {NAN, NAN},
     {-INFINITY, NAN},
     {-2, NAN},
     {-1, NAN},
     {-0.5, NAN},
     {-0., NAN},
     {+0., NAN},
     {0.5, NAN},
     {1, NAN},
     {2, NAN},
     {INFINITY, NAN},

     {NAN, -INFINITY},
     {-INFINITY, -INFINITY},
     {-2, -INFINITY},
     {-1, -INFINITY},
     {-0.5, -INFINITY},
     {-0., -INFINITY},
     {+0., -INFINITY},
     {0.5, -INFINITY},
     {1, -INFINITY},
     {2, -INFINITY},
     {INFINITY, -INFINITY},

     {NAN, -2},
     {-INFINITY, -2},
     {-2, -2},
     {-1, -2},
     {-0.5, -2},
     {-0., -2},
     {+0., -2},
     {0.5, -2},
     {1, -2},
     {2, -2},
     {INFINITY, -2},

     {NAN, -1},
     {-INFINITY, -1},
     {-2, -1},
     {-1, -1},
     {-0.5, -1},
     {-0., -1},
     {+0., -1},
     {0.5, -1},
     {1, -1},
     {2, -1},
     {INFINITY, -1},

     {NAN, -0.5},
     {-INFINITY, -0.5},
     {-2, -0.5},
     {-1, -0.5},
     {-0.5, -0.5},
     {-0., -0.5},
     {+0., -0.5},
     {0.5, -0.5},
     {1, -0.5},
     {2, -0.5},
     {INFINITY, -0.5},

     {NAN, -0.},
     {-INFINITY, -0.},
     {-2, -0.},
     {-1, -0.},
     {-0.5, -0.},
     {-0., -0.},
     {+0., -0.},
     {0.5, -0.},
     {1, -0.},
     {2, -0.},
     {INFINITY, -0.},

     {NAN, 0.},
     {-INFINITY, 0.},
     {-2, 0.},
     {-1, 0.},
     {-0.5, 0.},
     {-0., 0.},
     {+0., 0.},
     {0.5, 0.},
     {1, 0.},
     {2, 0.},
     {INFINITY, 0.},

     {NAN, 0.5},
     {-INFINITY, 0.5},
     {-2, 0.5},
     {-1, 0.5},
     {-0.5, 0.5},
     {-0., 0.5},
     {+0., 0.5},
     {0.5, 0.5},
     {1, 0.5},
     {2, 0.5},
     {INFINITY, 0.5},

     {NAN, 1},
     {-INFINITY, 1},
     {-2, 1},
     {-1, 1},
     {-0.5, 1},
     {-0., 1},
     {+0., 1},
     {0.5, 1},
     {1, 1},
     {2, 1},
     {INFINITY, 1},

     {NAN, 2},
     {-INFINITY, 2},
     {-2, 2},
     {-1, 2},
     {-0.5, 2},
     {-0., 2},
     {+0., 2},
     {0.5, 2},
     {1, 2},
     {2, 2},
     {INFINITY, 2},

     {NAN, INFINITY},
     {-INFINITY, INFINITY},
     {-2, INFINITY},
     {-1, INFINITY},
     {-0.5, INFINITY},
     {-0., INFINITY},
     {+0., INFINITY},
     {0.5, INFINITY},
     {1, INFINITY},
     {2, INFINITY},
     {INFINITY, INFINITY}

 };

 int main()
 {
     const unsigned N = sizeof(x) / sizeof(x[0]);
     unsigned i, j;
     for (i = 0; i < N; ++i)
     {
         for (j = 0; j < N; ++j)
         {
             if (test__muldc3(x[i][0], x[i][1], x[j][0], x[j][1]))
                 return 1;
         }
     }

     return 0;
 }
	//===-- muldc3_test.c - Test __muldc3 -------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file tests __muldc3 for the compiler_rt library.
	//
	//===----------------------------------------------------------------------===//

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

	// Returns: the product of a + ib and c + id

	double _Complex __muldc3(double __a, double __b, double __c, double __d);

	enum {zero, non_zero, inf, NaN, non_zero_nan};

	int
	classify(double _Complex x)
	{
	if (x == 0)
	return zero;
	if (isinf(creal(x)) \|\| isinf(cimag(x)))
	return inf;
	if (isnan(creal(x)) && isnan(cimag(x)))
	return NaN;
	if (isnan(creal(x)))
	{
	if (cimag(x) == 0)
	return NaN;
	return non_zero_nan;
	}
	if (isnan(cimag(x)))
	{
	if (creal(x) == 0)
	return NaN;
	return non_zero_nan;
	}
	return non_zero;
	}

	int test__muldc3(double a, double b, double c, double d)
	{
	double _Complex r = __muldc3(a, b, c, d);
	// printf("test__muldc3(%f, %f, %f, %f) = %f + I%f\n",
	// a, b, c, d, creal(r), cimag(r));
	double _Complex dividend;
	double _Complex divisor;

	__real__ dividend = a;
	__imag__ dividend = b;
	__real__ divisor = c;
	__imag__ divisor = d;

	switch (classify(dividend))
	{
	case zero:
	switch (classify(divisor))
	{
	case zero:
	if (classify(r) != zero)
	return 1;
	break;
	case non_zero:
	if (classify(r) != zero)
	return 1;
	break;
	case inf:
	if (classify(r) != NaN)
	return 1;
	break;
	case NaN:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero_nan:
	if (classify(r) != NaN)
	return 1;
	break;
	}
	break;
	case non_zero:
	switch (classify(divisor))
	{
	case zero:
	if (classify(r) != zero)
	return 1;
	break;
	case non_zero:
	if (classify(r) != non_zero)
	return 1;
	if (r != a * c - b * d + _Complex_I(a d + b * c))
	return 1;
	break;
	case inf:
	if (classify(r) != inf)
	return 1;
	break;
	case NaN:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero_nan:
	if (classify(r) != NaN)
	return 1;
	break;
	}
	break;
	case inf:
	switch (classify(divisor))
	{
	case zero:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero:
	if (classify(r) != inf)
	return 1;
	break;
	case inf:
	if (classify(r) != inf)
	return 1;
	break;
	case NaN:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero_nan:
	if (classify(r) != inf)
	return 1;
	break;
	}
	break;
	case NaN:
	switch (classify(divisor))
	{
	case zero:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero:
	if (classify(r) != NaN)
	return 1;
	break;
	case inf:
	if (classify(r) != NaN)
	return 1;
	break;
	case NaN:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero_nan:
	if (classify(r) != NaN)
	return 1;
	break;
	}
	break;
	case non_zero_nan:
	switch (classify(divisor))
	{
	case zero:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero:
	if (classify(r) != NaN)
	return 1;
	break;
	case inf:
	if (classify(r) != inf)
	return 1;
	break;
	case NaN:
	if (classify(r) != NaN)
	return 1;
	break;
	case non_zero_nan:
	if (classify(r) != NaN)
	return 1;
	break;
	}
	break;
	}

	return 0;
	}

	double x[][2] =
	{
	{ 1.e-6, 1.e-6},
	{-1.e-6, 1.e-6},
	{-1.e-6, -1.e-6},
	{ 1.e-6, -1.e-6},

	{ 1.e+6, 1.e-6},
	{-1.e+6, 1.e-6},
	{-1.e+6, -1.e-6},
	{ 1.e+6, -1.e-6},

	{ 1.e-6, 1.e+6},
	{-1.e-6, 1.e+6},
	{-1.e-6, -1.e+6},
	{ 1.e-6, -1.e+6},

	{ 1.e+6, 1.e+6},
	{-1.e+6, 1.e+6},
	{-1.e+6, -1.e+6},
	{ 1.e+6, -1.e+6},

	{NAN, NAN},
	{-INFINITY, NAN},
	{-2, NAN},
	{-1, NAN},
	{-0.5, NAN},
	{-0., NAN},
	{+0., NAN},
	{0.5, NAN},
	{1, NAN},
	{2, NAN},
	{INFINITY, NAN},

	{NAN, -INFINITY},
	{-INFINITY, -INFINITY},
	{-2, -INFINITY},
	{-1, -INFINITY},
	{-0.5, -INFINITY},
	{-0., -INFINITY},
	{+0., -INFINITY},
	{0.5, -INFINITY},
	{1, -INFINITY},
	{2, -INFINITY},
	{INFINITY, -INFINITY},

	{NAN, -2},
	{-INFINITY, -2},
	{-2, -2},
	{-1, -2},
	{-0.5, -2},
	{-0., -2},
	{+0., -2},
	{0.5, -2},
	{1, -2},
	{2, -2},
	{INFINITY, -2},

	{NAN, -1},
	{-INFINITY, -1},
	{-2, -1},
	{-1, -1},
	{-0.5, -1},
	{-0., -1},
	{+0., -1},
	{0.5, -1},
	{1, -1},
	{2, -1},
	{INFINITY, -1},

	{NAN, -0.5},
	{-INFINITY, -0.5},
	{-2, -0.5},
	{-1, -0.5},
	{-0.5, -0.5},
	{-0., -0.5},
	{+0., -0.5},
	{0.5, -0.5},
	{1, -0.5},
	{2, -0.5},
	{INFINITY, -0.5},

	{NAN, -0.},
	{-INFINITY, -0.},
	{-2, -0.},
	{-1, -0.},
	{-0.5, -0.},
	{-0., -0.},
	{+0., -0.},
	{0.5, -0.},
	{1, -0.},
	{2, -0.},
	{INFINITY, -0.},

	{NAN, 0.},
	{-INFINITY, 0.},
	{-2, 0.},
	{-1, 0.},
	{-0.5, 0.},
	{-0., 0.},
	{+0., 0.},
	{0.5, 0.},
	{1, 0.},
	{2, 0.},
	{INFINITY, 0.},

	{NAN, 0.5},
	{-INFINITY, 0.5},
	{-2, 0.5},
	{-1, 0.5},
	{-0.5, 0.5},
	{-0., 0.5},
	{+0., 0.5},
	{0.5, 0.5},
	{1, 0.5},
	{2, 0.5},
	{INFINITY, 0.5},

	{NAN, 1},
	{-INFINITY, 1},
	{-2, 1},
	{-1, 1},
	{-0.5, 1},
	{-0., 1},
	{+0., 1},
	{0.5, 1},
	{1, 1},
	{2, 1},
	{INFINITY, 1},

	{NAN, 2},
	{-INFINITY, 2},
	{-2, 2},
	{-1, 2},
	{-0.5, 2},
	{-0., 2},
	{+0., 2},
	{0.5, 2},
	{1, 2},
	{2, 2},
	{INFINITY, 2},

	{NAN, INFINITY},
	{-INFINITY, INFINITY},
	{-2, INFINITY},
	{-1, INFINITY},
	{-0.5, INFINITY},
	{-0., INFINITY},
	{+0., INFINITY},
	{0.5, INFINITY},
	{1, INFINITY},
	{2, INFINITY},
	{INFINITY, INFINITY}

	};

	int main()
	{
	const unsigned N = sizeof(x) / sizeof(x[0]);
	unsigned i, j;
	for (i = 0; i < N; ++i)
	{
	for (j = 0; j < N; ++j)
	{
	if (test__muldc3(x[i][0], x[i][1], x[j][0], x[j][1]))
	return 1;
	}
	}

	return 0;
	}