arch/i386/math-emu/reg_compare.c - kernel/msm-4.9 - Gitiles

 /*---------------------------------------------------------------------------+
  |  reg_compare.c                                                            |
  |                                                                           |
  | Compare two floating point registers                                      |
  |                                                                           |
  | Copyright (C) 1992,1993,1994,1997                                         |
  |                  W. Metzenthen, 22 Parker St, Ormond, Vic 3163, Australia |
  |                  E-mail   billm@suburbia.net                              |
  |                                                                           |
  |                                                                           |
  +---------------------------------------------------------------------------*/

 /*---------------------------------------------------------------------------+
  | compare() is the core FPU_REG comparison function                         |
  +---------------------------------------------------------------------------*/

 #include "fpu_system.h"
 #include "exception.h"
 #include "fpu_emu.h"
 #include "control_w.h"
 #include "status_w.h"


 static int compare(FPU_REG const *b, int tagb)
 {
   int diff, exp0, expb;
   u_char	  	st0_tag;
   FPU_REG  	*st0_ptr;
   FPU_REG	x, y;
   u_char		st0_sign, signb = getsign(b);

   st0_ptr = &st(0);
   st0_tag = FPU_gettag0();
   st0_sign = getsign(st0_ptr);

   if ( tagb == TAG_Special )
     tagb = FPU_Special(b);
   if ( st0_tag == TAG_Special )
     st0_tag = FPU_Special(st0_ptr);

   if ( ((st0_tag != TAG_Valid) && (st0_tag != TW_Denormal))
        || ((tagb != TAG_Valid) && (tagb != TW_Denormal)) )
     {
       if ( st0_tag == TAG_Zero )
 	{
 	  if ( tagb == TAG_Zero ) return COMP_A_eq_B;
 	  if ( tagb == TAG_Valid )
 	    return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B);
 	  if ( tagb == TW_Denormal )
 	    return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
 	    | COMP_Denormal;
 	}
       else if ( tagb == TAG_Zero )
 	{
 	  if ( st0_tag == TAG_Valid )
 	    return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
 	  if ( st0_tag == TW_Denormal )
 	    return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
 	    | COMP_Denormal;
 	}

       if ( st0_tag == TW_Infinity )
 	{
 	  if ( (tagb == TAG_Valid) || (tagb == TAG_Zero) )
 	    return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
 	  else if ( tagb == TW_Denormal )
 	    return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
 	      | COMP_Denormal;
 	  else if ( tagb == TW_Infinity )
 	    {
 	      /* The 80486 book says that infinities can be equal! */
 	      return (st0_sign == signb) ? COMP_A_eq_B :
 		((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
 	    }
 	  /* Fall through to the NaN code */
 	}
       else if ( tagb == TW_Infinity )
 	{
 	  if ( (st0_tag == TAG_Valid) || (st0_tag == TAG_Zero) )
 	    return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B);
 	  if ( st0_tag == TW_Denormal )
 	    return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
 		| COMP_Denormal;
 	  /* Fall through to the NaN code */
 	}

       /* The only possibility now should be that one of the arguments
 	 is a NaN */
       if ( (st0_tag == TW_NaN) || (tagb == TW_NaN) )
 	{
 	  int signalling = 0, unsupported = 0;
 	  if ( st0_tag == TW_NaN )
 	    {
 	      signalling = (st0_ptr->sigh & 0xc0000000) == 0x80000000;
 	      unsupported = !((exponent(st0_ptr) == EXP_OVER)
 			      && (st0_ptr->sigh & 0x80000000));
 	    }
 	  if ( tagb == TW_NaN )
 	    {
 	      signalling |= (b->sigh & 0xc0000000) == 0x80000000;
 	      unsupported |= !((exponent(b) == EXP_OVER)
 			       && (b->sigh & 0x80000000));
 	    }
 	  if ( signalling || unsupported )
 	    return COMP_No_Comp | COMP_SNaN | COMP_NaN;
 	  else
 	    /* Neither is a signaling NaN */
 	    return COMP_No_Comp | COMP_NaN;
 	}

       EXCEPTION(EX_Invalid);
     }

   if (st0_sign != signb)
     {
       return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
 	| ( ((st0_tag == TW_Denormal) || (tagb == TW_Denormal)) ?
 	    COMP_Denormal : 0);
     }

   if ( (st0_tag == TW_Denormal) || (tagb == TW_Denormal) )
     {
       FPU_to_exp16(st0_ptr, &x);
       FPU_to_exp16(b, &y);
       st0_ptr = &x;
       b = &y;
       exp0 = exponent16(st0_ptr);
       expb = exponent16(b);
     }
   else
     {
       exp0 = exponent(st0_ptr);
       expb = exponent(b);
     }

 #ifdef PARANOID
   if (!(st0_ptr->sigh & 0x80000000)) EXCEPTION(EX_Invalid);
   if (!(b->sigh & 0x80000000)) EXCEPTION(EX_Invalid);
 #endif /* PARANOID */

   diff = exp0 - expb;
   if ( diff == 0 )
     {
       diff = st0_ptr->sigh - b->sigh;  /* Works only if ms bits are
 					      identical */
       if ( diff == 0 )
 	{
 	diff = st0_ptr->sigl > b->sigl;
 	if ( diff == 0 )
 	  diff = -(st0_ptr->sigl < b->sigl);
 	}
     }

   if ( diff > 0 )
     {
       return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
 	| ( ((st0_tag == TW_Denormal) || (tagb == TW_Denormal)) ?
 	    COMP_Denormal : 0);
     }
   if ( diff < 0 )
     {
       return ((st0_sign == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
 	| ( ((st0_tag == TW_Denormal) || (tagb == TW_Denormal)) ?
 	    COMP_Denormal : 0);
     }

   return COMP_A_eq_B
     | ( ((st0_tag == TW_Denormal) || (tagb == TW_Denormal)) ?
 	COMP_Denormal : 0);

 }


 /* This function requires that st(0) is not empty */
 int FPU_compare_st_data(FPU_REG const *loaded_data, u_char loaded_tag)
 {
   int f = 0, c;

   c = compare(loaded_data, loaded_tag);

   if (c & COMP_NaN)
     {
       EXCEPTION(EX_Invalid);
       f = SW_C3 | SW_C2 | SW_C0;
     }
   else
     switch (c & 7)
       {
       case COMP_A_lt_B:
 	f = SW_C0;
 	break;
       case COMP_A_eq_B:
 	f = SW_C3;
 	break;
       case COMP_A_gt_B:
 	f = 0;
 	break;
       case COMP_No_Comp:
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #ifdef PARANOID
       default:
 	EXCEPTION(EX_INTERNAL|0x121);
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #endif /* PARANOID */
       }
   setcc(f);
   if (c & COMP_Denormal)
     {
       return denormal_operand() < 0;
     }
   return 0;
 }


 static int compare_st_st(int nr)
 {
   int f = 0, c;
   FPU_REG *st_ptr;

   if ( !NOT_EMPTY(0) || !NOT_EMPTY(nr) )
     {
       setcc(SW_C3 | SW_C2 | SW_C0);
       /* Stack fault */
       EXCEPTION(EX_StackUnder);
       return !(control_word & CW_Invalid);
     }

   st_ptr = &st(nr);
   c = compare(st_ptr, FPU_gettagi(nr));
   if (c & COMP_NaN)
     {
       setcc(SW_C3 | SW_C2 | SW_C0);
       EXCEPTION(EX_Invalid);
       return !(control_word & CW_Invalid);
     }
   else
     switch (c & 7)
       {
       case COMP_A_lt_B:
 	f = SW_C0;
 	break;
       case COMP_A_eq_B:
 	f = SW_C3;
 	break;
       case COMP_A_gt_B:
 	f = 0;
 	break;
       case COMP_No_Comp:
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #ifdef PARANOID
       default:
 	EXCEPTION(EX_INTERNAL|0x122);
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #endif /* PARANOID */
       }
   setcc(f);
   if (c & COMP_Denormal)
     {
       return denormal_operand() < 0;
     }
   return 0;
 }


 static int compare_u_st_st(int nr)
 {
   int f = 0, c;
   FPU_REG *st_ptr;

   if ( !NOT_EMPTY(0) || !NOT_EMPTY(nr) )
     {
       setcc(SW_C3 | SW_C2 | SW_C0);
       /* Stack fault */
       EXCEPTION(EX_StackUnder);
       return !(control_word & CW_Invalid);
     }

   st_ptr = &st(nr);
   c = compare(st_ptr, FPU_gettagi(nr));
   if (c & COMP_NaN)
     {
       setcc(SW_C3 | SW_C2 | SW_C0);
       if (c & COMP_SNaN)       /* This is the only difference between
 				  un-ordered and ordinary comparisons */
 	{
 	  EXCEPTION(EX_Invalid);
 	  return !(control_word & CW_Invalid);
 	}
       return 0;
     }
   else
     switch (c & 7)
       {
       case COMP_A_lt_B:
 	f = SW_C0;
 	break;
       case COMP_A_eq_B:
 	f = SW_C3;
 	break;
       case COMP_A_gt_B:
 	f = 0;
 	break;
       case COMP_No_Comp:
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #ifdef PARANOID
       default:
 	EXCEPTION(EX_INTERNAL|0x123);
 	f = SW_C3 | SW_C2 | SW_C0;
 	break;
 #endif /* PARANOID */
       }
   setcc(f);
   if (c & COMP_Denormal)
     {
       return denormal_operand() < 0;
     }
   return 0;
 }

 /*---------------------------------------------------------------------------*/

 void fcom_st(void)
 {
   /* fcom st(i) */
   compare_st_st(FPU_rm);
 }


 void fcompst(void)
 {
   /* fcomp st(i) */
   if ( !compare_st_st(FPU_rm) )
     FPU_pop();
 }


 void fcompp(void)
 {
   /* fcompp */
   if (FPU_rm != 1)
     {
       FPU_illegal();
       return;
     }
   if ( !compare_st_st(1) )
       poppop();
 }


 void fucom_(void)
 {
   /* fucom st(i) */
   compare_u_st_st(FPU_rm);

 }


 void fucomp(void)
 {
   /* fucomp st(i) */
   if ( !compare_u_st_st(FPU_rm) )
     FPU_pop();
 }


 void fucompp(void)
 {
   /* fucompp */
   if (FPU_rm == 1)
     {
       if ( !compare_u_st_st(1) )
 	poppop();
     }
   else
     FPU_illegal();
 }
	/*---------------------------------------------------------------------------+
	\| reg_compare.c \|
	\| \|
	\| Compare two floating point registers \|
	\| \|
	\| Copyright (C) 1992,1993,1994,1997 \|
	\| W. Metzenthen, 22 Parker St, Ormond, Vic 3163, Australia \|
	\| E-mail billm@suburbia.net \|
	\| \|
	\| \|
	+---------------------------------------------------------------------------*/

	/*---------------------------------------------------------------------------+
	\| compare() is the core FPU_REG comparison function \|
	+---------------------------------------------------------------------------*/

	#include "fpu_system.h"
	#include "exception.h"
	#include "fpu_emu.h"
	#include "control_w.h"
	#include "status_w.h"


	static int compare(FPU_REG const *b, int tagb)
	{
	int diff, exp0, expb;
	u_char st0_tag;
	FPU_REG *st0_ptr;
	FPU_REG x, y;
	u_char st0_sign, signb = getsign(b);

	st0_ptr = &st(0);
	st0_tag = FPU_gettag0();
	st0_sign = getsign(st0_ptr);

	if ( tagb == TAG_Special )
	tagb = FPU_Special(b);
	if ( st0_tag == TAG_Special )
	st0_tag = FPU_Special(st0_ptr);

	if ( ((st0_tag != TAG_Valid) && (st0_tag != TW_Denormal))
	\|\| ((tagb != TAG_Valid) && (tagb != TW_Denormal)) )
	{
	if ( st0_tag == TAG_Zero )
	{
	if ( tagb == TAG_Zero ) return COMP_A_eq_B;
	if ( tagb == TAG_Valid )
	return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B);
	if ( tagb == TW_Denormal )
	return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
	\| COMP_Denormal;
	}
	else if ( tagb == TAG_Zero )
	{
	if ( st0_tag == TAG_Valid )
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
	if ( st0_tag == TW_Denormal )
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
	\| COMP_Denormal;
	}

	if ( st0_tag == TW_Infinity )
	{
	if ( (tagb == TAG_Valid) \|\| (tagb == TAG_Zero) )
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
	else if ( tagb == TW_Denormal )
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
	\| COMP_Denormal;
	else if ( tagb == TW_Infinity )
	{
	/* The 80486 book says that infinities can be equal! */
	return (st0_sign == signb) ? COMP_A_eq_B :
	((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B);
	}
	/* Fall through to the NaN code */
	}
	else if ( tagb == TW_Infinity )
	{
	if ( (st0_tag == TAG_Valid) \|\| (st0_tag == TAG_Zero) )
	return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B);
	if ( st0_tag == TW_Denormal )
	return ((signb == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
	\| COMP_Denormal;
	/* Fall through to the NaN code */
	}

	/* The only possibility now should be that one of the arguments
	is a NaN */
	if ( (st0_tag == TW_NaN) \|\| (tagb == TW_NaN) )
	{
	int signalling = 0, unsupported = 0;
	if ( st0_tag == TW_NaN )
	{
	signalling = (st0_ptr->sigh & 0xc0000000) == 0x80000000;
	unsupported = !((exponent(st0_ptr) == EXP_OVER)
	&& (st0_ptr->sigh & 0x80000000));
	}
	if ( tagb == TW_NaN )
	{
	signalling \|= (b->sigh & 0xc0000000) == 0x80000000;
	unsupported \|= !((exponent(b) == EXP_OVER)
	&& (b->sigh & 0x80000000));
	}
	if ( signalling \|\| unsupported )
	return COMP_No_Comp \| COMP_SNaN \| COMP_NaN;
	else
	/* Neither is a signaling NaN */
	return COMP_No_Comp \| COMP_NaN;
	}

	EXCEPTION(EX_Invalid);
	}

	if (st0_sign != signb)
	{
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
	\| ( ((st0_tag == TW_Denormal) \|\| (tagb == TW_Denormal)) ?
	COMP_Denormal : 0);
	}

	if ( (st0_tag == TW_Denormal) \|\| (tagb == TW_Denormal) )
	{
	FPU_to_exp16(st0_ptr, &x);
	FPU_to_exp16(b, &y);
	st0_ptr = &x;
	b = &y;
	exp0 = exponent16(st0_ptr);
	expb = exponent16(b);
	}
	else
	{
	exp0 = exponent(st0_ptr);
	expb = exponent(b);
	}

	#ifdef PARANOID
	if (!(st0_ptr->sigh & 0x80000000)) EXCEPTION(EX_Invalid);
	if (!(b->sigh & 0x80000000)) EXCEPTION(EX_Invalid);
	#endif /* PARANOID */

	diff = exp0 - expb;
	if ( diff == 0 )
	{
	diff = st0_ptr->sigh - b->sigh; /* Works only if ms bits are
	identical */
	if ( diff == 0 )
	{
	diff = st0_ptr->sigl > b->sigl;
	if ( diff == 0 )
	diff = -(st0_ptr->sigl < b->sigl);
	}
	}

	if ( diff > 0 )
	{
	return ((st0_sign == SIGN_POS) ? COMP_A_gt_B : COMP_A_lt_B)
	\| ( ((st0_tag == TW_Denormal) \|\| (tagb == TW_Denormal)) ?
	COMP_Denormal : 0);
	}
	if ( diff < 0 )
	{
	return ((st0_sign == SIGN_POS) ? COMP_A_lt_B : COMP_A_gt_B)
	\| ( ((st0_tag == TW_Denormal) \|\| (tagb == TW_Denormal)) ?
	COMP_Denormal : 0);
	}

	return COMP_A_eq_B
	\| ( ((st0_tag == TW_Denormal) \|\| (tagb == TW_Denormal)) ?
	COMP_Denormal : 0);

	}


	/* This function requires that st(0) is not empty */
	int FPU_compare_st_data(FPU_REG const *loaded_data, u_char loaded_tag)
	{
	int f = 0, c;

	c = compare(loaded_data, loaded_tag);

	if (c & COMP_NaN)
	{
	EXCEPTION(EX_Invalid);
	f = SW_C3 \| SW_C2 \| SW_C0;
	}
	else
	switch (c & 7)
	{
	case COMP_A_lt_B:
	f = SW_C0;
	break;
	case COMP_A_eq_B:
	f = SW_C3;
	break;
	case COMP_A_gt_B:
	f = 0;
	break;
	case COMP_No_Comp:
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#ifdef PARANOID
	default:
	EXCEPTION(EX_INTERNAL\|0x121);
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#endif /* PARANOID */
	}
	setcc(f);
	if (c & COMP_Denormal)
	{
	return denormal_operand() < 0;
	}
	return 0;
	}


	static int compare_st_st(int nr)
	{
	int f = 0, c;
	FPU_REG *st_ptr;

	if ( !NOT_EMPTY(0) \|\| !NOT_EMPTY(nr) )
	{
	setcc(SW_C3 \| SW_C2 \| SW_C0);
	/* Stack fault */
	EXCEPTION(EX_StackUnder);
	return !(control_word & CW_Invalid);
	}

	st_ptr = &st(nr);
	c = compare(st_ptr, FPU_gettagi(nr));
	if (c & COMP_NaN)
	{
	setcc(SW_C3 \| SW_C2 \| SW_C0);
	EXCEPTION(EX_Invalid);
	return !(control_word & CW_Invalid);
	}
	else
	switch (c & 7)
	{
	case COMP_A_lt_B:
	f = SW_C0;
	break;
	case COMP_A_eq_B:
	f = SW_C3;
	break;
	case COMP_A_gt_B:
	f = 0;
	break;
	case COMP_No_Comp:
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#ifdef PARANOID
	default:
	EXCEPTION(EX_INTERNAL\|0x122);
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#endif /* PARANOID */
	}
	setcc(f);
	if (c & COMP_Denormal)
	{
	return denormal_operand() < 0;
	}
	return 0;
	}


	static int compare_u_st_st(int nr)
	{
	int f = 0, c;
	FPU_REG *st_ptr;

	if ( !NOT_EMPTY(0) \|\| !NOT_EMPTY(nr) )
	{
	setcc(SW_C3 \| SW_C2 \| SW_C0);
	/* Stack fault */
	EXCEPTION(EX_StackUnder);
	return !(control_word & CW_Invalid);
	}

	st_ptr = &st(nr);
	c = compare(st_ptr, FPU_gettagi(nr));
	if (c & COMP_NaN)
	{
	setcc(SW_C3 \| SW_C2 \| SW_C0);
	if (c & COMP_SNaN) /* This is the only difference between
	un-ordered and ordinary comparisons */
	{
	EXCEPTION(EX_Invalid);
	return !(control_word & CW_Invalid);
	}
	return 0;
	}
	else
	switch (c & 7)
	{
	case COMP_A_lt_B:
	f = SW_C0;
	break;
	case COMP_A_eq_B:
	f = SW_C3;
	break;
	case COMP_A_gt_B:
	f = 0;
	break;
	case COMP_No_Comp:
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#ifdef PARANOID
	default:
	EXCEPTION(EX_INTERNAL\|0x123);
	f = SW_C3 \| SW_C2 \| SW_C0;
	break;
	#endif /* PARANOID */
	}
	setcc(f);
	if (c & COMP_Denormal)
	{
	return denormal_operand() < 0;
	}
	return 0;
	}

	/---------------------------------------------------------------------------/

	void fcom_st(void)
	{
	/* fcom st(i) */
	compare_st_st(FPU_rm);
	}


	void fcompst(void)
	{
	/* fcomp st(i) */
	if ( !compare_st_st(FPU_rm) )
	FPU_pop();
	}


	void fcompp(void)
	{
	/* fcompp */
	if (FPU_rm != 1)
	{
	FPU_illegal();
	return;
	}
	if ( !compare_st_st(1) )
	poppop();
	}


	void fucom_(void)
	{
	/* fucom st(i) */
	compare_u_st_st(FPU_rm);

	}


	void fucomp(void)
	{
	/* fucomp st(i) */
	if ( !compare_u_st_st(FPU_rm) )
	FPU_pop();
	}


	void fucompp(void)
	{
	/* fucompp */
	if (FPU_rm == 1)
	{
	if ( !compare_u_st_st(1) )
	poppop();
	}
	else
	FPU_illegal();
	}