llvm-gcc-4.2/gcc/testsuite/gcc.target/i386/sse4_2-pcmpistrm-2.c - llvm-archive - Git at Google

 /* APPLE LOCAL file 5612787 mainline sse4 */
 /* { dg-do run { target i?86-*-* x86_64-*-* } } */
 /* { dg-require-effective-target sse4 } */
 /* { dg-options "-O2 -msse4.2" } */

 #include "sse4_2-check.h"
 #include "sse4_2-pcmpstr.h"

 #define NUM 1024

 #define IMM_VAL0 \
   (SIDD_SBYTE_OPS | SIDD_CMP_RANGES | SIDD_MASKED_POSITIVE_POLARITY)
 #define IMM_VAL1 \
   (SIDD_UBYTE_OPS | SIDD_CMP_EQUAL_EACH | SIDD_NEGATIVE_POLARITY \
    | SIDD_BIT_MASK)
 #define IMM_VAL2 \
   (SIDD_UWORD_OPS | SIDD_CMP_EQUAL_ANY | SIDD_MASKED_NEGATIVE_POLARITY)
 #define IMM_VAL3 \
   (SIDD_SWORD_OPS | SIDD_CMP_EQUAL_ORDERED \
    | SIDD_POSITIVE_POLARITY | SIDD_UNIT_MASK)

 static void
 sse4_2_test (void)
 {
   union
     {
       __m128i x[NUM];
       char c[NUM *16];
     } src1, src2;
   __m128i res, correct;
   int correct_flags;
   int flags, cf, zf, sf, of, af;
   int i;

   for (i = 0; i < NUM *16; i++)
     {
       src1.c[i] = rand ();
       src2.c[i] = rand ();
     }

   for (i = 0; i < NUM; i++)
     {
       switch ((rand () % 4))
 	{
 	case 0:
 	  res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL0);
 	  cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL0);
 	  zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL0);
 	  sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL0);
 	  of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL0);
 	  af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL0);
 	  correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL0,
 			    &correct_flags);
 	  break;

 	case 1:
 	  res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL1);
 	  cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL1);
 	  zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL1);
 	  sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL1);
 	  of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL1);
 	  af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL1);
 	  correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL1,
 			    &correct_flags);
 	  break;

 	case 2:
 	  res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL2);
 	  cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL2);
 	  zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL2);
 	  sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL2);
 	  of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL2);
 	  af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL2);
 	  correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL2,
 			    &correct_flags);
 	  break;

 	default:
 	  res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL3);
 	  cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL3);
 	  zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL3);
 	  sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL3);
 	  of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL3);
 	  af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL3);
 	  correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL3,
 			    &correct_flags);
 	  break;
 	}

       if (memcmp (&correct, &res, sizeof (res)))
 	abort ();

       flags = 0;
       if (cf)
 	flags |= CFLAG;
       if (zf)
 	flags |= ZFLAG;
       if (sf)
 	flags |= SFLAG;
       if (of)
 	flags |= OFLAG;

       if (flags != correct_flags
 	  || (af && (cf || zf))
 	  || (!af && !(cf || zf)))
 	abort ();
     }
 }
	/* APPLE LOCAL file 5612787 mainline sse4 */
	/* { dg-do run { target i?86-- x86_64-- } } */
	/* { dg-require-effective-target sse4 } */
	/* { dg-options "-O2 -msse4.2" } */

	#include "sse4_2-check.h"
	#include "sse4_2-pcmpstr.h"

	#define NUM 1024

	#define IMM_VAL0 \
	(SIDD_SBYTE_OPS \| SIDD_CMP_RANGES \| SIDD_MASKED_POSITIVE_POLARITY)
	#define IMM_VAL1 \
	(SIDD_UBYTE_OPS \| SIDD_CMP_EQUAL_EACH \| SIDD_NEGATIVE_POLARITY \
	\| SIDD_BIT_MASK)
	#define IMM_VAL2 \
	(SIDD_UWORD_OPS \| SIDD_CMP_EQUAL_ANY \| SIDD_MASKED_NEGATIVE_POLARITY)
	#define IMM_VAL3 \
	(SIDD_SWORD_OPS \| SIDD_CMP_EQUAL_ORDERED \
	\| SIDD_POSITIVE_POLARITY \| SIDD_UNIT_MASK)

	static void
	sse4_2_test (void)
	{
	union
	{
	__m128i x[NUM];
	char c[NUM *16];
	} src1, src2;
	__m128i res, correct;
	int correct_flags;
	int flags, cf, zf, sf, of, af;
	int i;

	for (i = 0; i < NUM *16; i++)
	{
	src1.c[i] = rand ();
	src2.c[i] = rand ();
	}

	for (i = 0; i < NUM; i++)
	{
	switch ((rand () % 4))
	{
	case 0:
	res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL0);
	cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL0);
	zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL0);
	sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL0);
	of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL0);
	af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL0);
	correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL0,
	&correct_flags);
	break;

	case 1:
	res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL1);
	cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL1);
	zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL1);
	sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL1);
	of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL1);
	af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL1);
	correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL1,
	&correct_flags);
	break;

	case 2:
	res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL2);
	cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL2);
	zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL2);
	sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL2);
	of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL2);
	af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL2);
	correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL2,
	&correct_flags);
	break;

	default:
	res = _mm_cmpistrm (src1.x[i], src2.x[i], IMM_VAL3);
	cf = _mm_cmpistrc (src1.x[i], src2.x[i], IMM_VAL3);
	zf = _mm_cmpistrz (src1.x[i], src2.x[i], IMM_VAL3);
	sf = _mm_cmpistrs (src1.x[i], src2.x[i], IMM_VAL3);
	of = _mm_cmpistro (src1.x[i], src2.x[i], IMM_VAL3);
	af = _mm_cmpistra (src1.x[i], src2.x[i], IMM_VAL3);
	correct = cmp_im (&src1.x[i], &src2.x[i], IMM_VAL3,
	&correct_flags);
	break;
	}

	if (memcmp (&correct, &res, sizeof (res)))
	abort ();

	flags = 0;
	if (cf)
	flags \|= CFLAG;
	if (zf)
	flags \|= ZFLAG;
	if (sf)
	flags \|= SFLAG;
	if (of)
	flags \|= OFLAG;

	if (flags != correct_flags
	\|\| (af && (cf \|\| zf))
	\|\| (!af && !(cf \|\| zf)))
	abort ();
	}
	}