arch/x86/math-emu/div_Xsig.S - third_party/kernel - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 	.file	"div_Xsig.S"
 /*---------------------------------------------------------------------------+
  |  div_Xsig.S                                                               |
  |                                                                           |
  | Division subroutine for 96 bit quantities                                 |
  |                                                                           |
  | Copyright (C) 1994,1995                                                   |
  |                       W. Metzenthen, 22 Parker St, Ormond, Vic 3163,      |
  |                       Australia.  E-mail billm@jacobi.maths.monash.edu.au |
  |                                                                           |
  |                                                                           |
  +---------------------------------------------------------------------------*/

 /*---------------------------------------------------------------------------+
  | Divide the 96 bit quantity pointed to by a, by that pointed to by b, and  |
  | put the 96 bit result at the location d.                                  |
  |                                                                           |
  | The result may not be accurate to 96 bits. It is intended for use where   |
  | a result better than 64 bits is required. The result should usually be    |
  | good to at least 94 bits.                                                 |
  | The returned result is actually divided by one half. This is done to      |
  | prevent overflow.                                                         |
  |                                                                           |
  |  .aaaaaaaaaaaaaa / .bbbbbbbbbbbbb  ->  .dddddddddddd                      |
  |                                                                           |
  |  void div_Xsig(Xsig *a, Xsig *b, Xsig *dest)                              |
  |                                                                           |
  +---------------------------------------------------------------------------*/

 #include "exception.h"
 #include "fpu_emu.h"


 #define	XsigLL(x)	(x)
 #define	XsigL(x)	4(x)
 #define	XsigH(x)	8(x)


 #ifndef NON_REENTRANT_FPU
 /*
 	Local storage on the stack:
 	Accumulator:	FPU_accum_3:FPU_accum_2:FPU_accum_1:FPU_accum_0
  */
 #define FPU_accum_3	-4(%ebp)
 #define FPU_accum_2	-8(%ebp)
 #define FPU_accum_1	-12(%ebp)
 #define FPU_accum_0	-16(%ebp)
 #define FPU_result_3	-20(%ebp)
 #define FPU_result_2	-24(%ebp)
 #define FPU_result_1	-28(%ebp)

 #else
 .data
 /*
 	Local storage in a static area:
 	Accumulator:	FPU_accum_3:FPU_accum_2:FPU_accum_1:FPU_accum_0
  */
 	.align 4,0
 FPU_accum_3:
 	.long	0
 FPU_accum_2:
 	.long	0
 FPU_accum_1:
 	.long	0
 FPU_accum_0:
 	.long	0
 FPU_result_3:
 	.long	0
 FPU_result_2:
 	.long	0
 FPU_result_1:
 	.long	0
 #endif /* NON_REENTRANT_FPU */


 .text
 SYM_FUNC_START(div_Xsig)
 	pushl	%ebp
 	movl	%esp,%ebp
 #ifndef NON_REENTRANT_FPU
 	subl	$28,%esp
 #endif /* NON_REENTRANT_FPU */

 	pushl	%esi
 	pushl	%edi
 	pushl	%ebx

 	movl	PARAM1,%esi	/* pointer to num */
 	movl	PARAM2,%ebx	/* pointer to denom */

 #ifdef PARANOID
 	testl	$0x80000000, XsigH(%ebx)	/* Divisor */
 	je	L_bugged
 #endif /* PARANOID */


 /*---------------------------------------------------------------------------+
  |  Divide:   Return  arg1/arg2 to arg3.                                     |
  |                                                                           |
  |  The maximum returned value is (ignoring exponents)                       |
  |               .ffffffff ffffffff                                          |
  |               ------------------  =  1.ffffffff fffffffe                  |
  |               .80000000 00000000                                          |
  | and the minimum is                                                        |
  |               .80000000 00000000                                          |
  |               ------------------  =  .80000000 00000001   (rounded)       |
  |               .ffffffff ffffffff                                          |
  |                                                                           |
  +---------------------------------------------------------------------------*/

 	/* Save extended dividend in local register */

 	/* Divide by 2 to prevent overflow */
 	clc
 	movl	XsigH(%esi),%eax
 	rcrl	%eax
 	movl	%eax,FPU_accum_3
 	movl	XsigL(%esi),%eax
 	rcrl	%eax
 	movl	%eax,FPU_accum_2
 	movl	XsigLL(%esi),%eax
 	rcrl	%eax
 	movl	%eax,FPU_accum_1
 	movl	$0,%eax
 	rcrl	%eax
 	movl	%eax,FPU_accum_0

 	movl	FPU_accum_2,%eax	/* Get the current num */
 	movl	FPU_accum_3,%edx

 /*----------------------------------------------------------------------*/
 /* Initialization done.
    Do the first 32 bits. */

 	/* We will divide by a number which is too large */
 	movl	XsigH(%ebx),%ecx
 	addl	$1,%ecx
 	jnc	LFirst_div_not_1

 	/* here we need to divide by 100000000h,
 	   i.e., no division at all.. */
 	mov	%edx,%eax
 	jmp	LFirst_div_done

 LFirst_div_not_1:
 	divl	%ecx		/* Divide the numerator by the augmented
 				   denom ms dw */

 LFirst_div_done:
 	movl	%eax,FPU_result_3	/* Put the result in the answer */

 	mull	XsigH(%ebx)	/* mul by the ms dw of the denom */

 	subl	%eax,FPU_accum_2	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_3

 	movl	FPU_result_3,%eax	/* Get the result back */
 	mull	XsigL(%ebx)	/* now mul the ls dw of the denom */

 	subl	%eax,FPU_accum_1	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_2
 	sbbl	$0,FPU_accum_3
 	je	LDo_2nd_32_bits		/* Must check for non-zero result here */

 #ifdef PARANOID
 	jb	L_bugged_1
 #endif /* PARANOID */

 	/* need to subtract another once of the denom */
 	incl	FPU_result_3	/* Correct the answer */

 	movl	XsigL(%ebx),%eax
 	movl	XsigH(%ebx),%edx
 	subl	%eax,FPU_accum_1	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_2

 #ifdef PARANOID
 	sbbl	$0,FPU_accum_3
 	jne	L_bugged_1	/* Must check for non-zero result here */
 #endif /* PARANOID */

 /*----------------------------------------------------------------------*/
 /* Half of the main problem is done, there is just a reduced numerator
    to handle now.
    Work with the second 32 bits, FPU_accum_0 not used from now on */
 LDo_2nd_32_bits:
 	movl	FPU_accum_2,%edx	/* get the reduced num */
 	movl	FPU_accum_1,%eax

 	/* need to check for possible subsequent overflow */
 	cmpl	XsigH(%ebx),%edx
 	jb	LDo_2nd_div
 	ja	LPrevent_2nd_overflow

 	cmpl	XsigL(%ebx),%eax
 	jb	LDo_2nd_div

 LPrevent_2nd_overflow:
 /* The numerator is greater or equal, would cause overflow */
 	/* prevent overflow */
 	subl	XsigL(%ebx),%eax
 	sbbl	XsigH(%ebx),%edx
 	movl	%edx,FPU_accum_2
 	movl	%eax,FPU_accum_1

 	incl	FPU_result_3	/* Reflect the subtraction in the answer */

 #ifdef PARANOID
 	je	L_bugged_2	/* Can't bump the result to 1.0 */
 #endif /* PARANOID */

 LDo_2nd_div:
 	cmpl	$0,%ecx		/* augmented denom msw */
 	jnz	LSecond_div_not_1

 	/* %ecx == 0, we are dividing by 1.0 */
 	mov	%edx,%eax
 	jmp	LSecond_div_done

 LSecond_div_not_1:
 	divl	%ecx		/* Divide the numerator by the denom ms dw */

 LSecond_div_done:
 	movl	%eax,FPU_result_2	/* Put the result in the answer */

 	mull	XsigH(%ebx)	/* mul by the ms dw of the denom */

 	subl	%eax,FPU_accum_1	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_2

 #ifdef PARANOID
 	jc	L_bugged_2
 #endif /* PARANOID */

 	movl	FPU_result_2,%eax	/* Get the result back */
 	mull	XsigL(%ebx)	/* now mul the ls dw of the denom */

 	subl	%eax,FPU_accum_0	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_1	/* Subtract from the num local reg */
 	sbbl	$0,FPU_accum_2

 #ifdef PARANOID
 	jc	L_bugged_2
 #endif /* PARANOID */

 	jz	LDo_3rd_32_bits

 #ifdef PARANOID
 	cmpl	$1,FPU_accum_2
 	jne	L_bugged_2
 #endif /* PARANOID */

 	/* need to subtract another once of the denom */
 	movl	XsigL(%ebx),%eax
 	movl	XsigH(%ebx),%edx
 	subl	%eax,FPU_accum_0	/* Subtract from the num local reg */
 	sbbl	%edx,FPU_accum_1
 	sbbl	$0,FPU_accum_2

 #ifdef PARANOID
 	jc	L_bugged_2
 	jne	L_bugged_2
 #endif /* PARANOID */

 	addl	$1,FPU_result_2	/* Correct the answer */
 	adcl	$0,FPU_result_3

 #ifdef PARANOID
 	jc	L_bugged_2	/* Must check for non-zero result here */
 #endif /* PARANOID */

 /*----------------------------------------------------------------------*/
 /* The division is essentially finished here, we just need to perform
    tidying operations.
    Deal with the 3rd 32 bits */
 LDo_3rd_32_bits:
 	/* We use an approximation for the third 32 bits.
 	To take account of the 3rd 32 bits of the divisor
 	(call them del), we subtract  del * (a/b) */

 	movl	FPU_result_3,%eax	/* a/b */
 	mull	XsigLL(%ebx)		/* del */

 	subl	%edx,FPU_accum_1

 	/* A borrow indicates that the result is negative */
 	jnb	LTest_over

 	movl	XsigH(%ebx),%edx
 	addl	%edx,FPU_accum_1

 	subl	$1,FPU_result_2		/* Adjust the answer */
 	sbbl	$0,FPU_result_3

 	/* The above addition might not have been enough, check again. */
 	movl	FPU_accum_1,%edx	/* get the reduced num */
 	cmpl	XsigH(%ebx),%edx	/* denom */
 	jb	LDo_3rd_div

 	movl	XsigH(%ebx),%edx
 	addl	%edx,FPU_accum_1

 	subl	$1,FPU_result_2		/* Adjust the answer */
 	sbbl	$0,FPU_result_3
 	jmp	LDo_3rd_div

 LTest_over:
 	movl	FPU_accum_1,%edx	/* get the reduced num */

 	/* need to check for possible subsequent overflow */
 	cmpl	XsigH(%ebx),%edx	/* denom */
 	jb	LDo_3rd_div

 	/* prevent overflow */
 	subl	XsigH(%ebx),%edx
 	movl	%edx,FPU_accum_1

 	addl	$1,FPU_result_2	/* Reflect the subtraction in the answer */
 	adcl	$0,FPU_result_3

 LDo_3rd_div:
 	movl	FPU_accum_0,%eax
 	movl	FPU_accum_1,%edx
 	divl	XsigH(%ebx)

 	movl    %eax,FPU_result_1       /* Rough estimate of third word */

 	movl	PARAM3,%esi		/* pointer to answer */

 	movl	FPU_result_1,%eax
 	movl	%eax,XsigLL(%esi)
 	movl	FPU_result_2,%eax
 	movl	%eax,XsigL(%esi)
 	movl	FPU_result_3,%eax
 	movl	%eax,XsigH(%esi)

 L_exit:
 	popl	%ebx
 	popl	%edi
 	popl	%esi

 	leave
 	RET


 #ifdef PARANOID
 /* The logic is wrong if we got here */
 L_bugged:
 	pushl	EX_INTERNAL|0x240
 	call	EXCEPTION
 	pop	%ebx
 	jmp	L_exit

 L_bugged_1:
 	pushl	EX_INTERNAL|0x241
 	call	EXCEPTION
 	pop	%ebx
 	jmp	L_exit

 L_bugged_2:
 	pushl	EX_INTERNAL|0x242
 	call	EXCEPTION
 	pop	%ebx
 	jmp	L_exit
 #endif /* PARANOID */
 SYM_FUNC_END(div_Xsig)
	/* SPDX-License-Identifier: GPL-2.0 */
	.file "div_Xsig.S"
	/*---------------------------------------------------------------------------+
	\| div_Xsig.S \|
	\| \|
	\| Division subroutine for 96 bit quantities \|
	\| \|
	\| Copyright (C) 1994,1995 \|
	\| W. Metzenthen, 22 Parker St, Ormond, Vic 3163, \|
	\| Australia. E-mail billm@jacobi.maths.monash.edu.au \|
	\| \|
	\| \|
	+---------------------------------------------------------------------------*/

	/*---------------------------------------------------------------------------+
	\| Divide the 96 bit quantity pointed to by a, by that pointed to by b, and \|
	\| put the 96 bit result at the location d. \|
	\| \|
	\| The result may not be accurate to 96 bits. It is intended for use where \|
	\| a result better than 64 bits is required. The result should usually be \|
	\| good to at least 94 bits. \|
	\| The returned result is actually divided by one half. This is done to \|
	\| prevent overflow. \|
	\| \|
	\| .aaaaaaaaaaaaaa / .bbbbbbbbbbbbb -> .dddddddddddd \|
	\| \|
	\| void div_Xsig(Xsig a, Xsig b, Xsig *dest) \|
	\| \|
	+---------------------------------------------------------------------------*/

	#include "exception.h"
	#include "fpu_emu.h"


	#define XsigLL(x) (x)
	#define XsigL(x) 4(x)
	#define XsigH(x) 8(x)


	#ifndef NON_REENTRANT_FPU
	/*
	Local storage on the stack:
	Accumulator: FPU_accum_3:FPU_accum_2:FPU_accum_1:FPU_accum_0
	*/
	#define FPU_accum_3 -4(%ebp)
	#define FPU_accum_2 -8(%ebp)
	#define FPU_accum_1 -12(%ebp)
	#define FPU_accum_0 -16(%ebp)
	#define FPU_result_3 -20(%ebp)
	#define FPU_result_2 -24(%ebp)
	#define FPU_result_1 -28(%ebp)

	#else
	.data
	/*
	Local storage in a static area:
	Accumulator: FPU_accum_3:FPU_accum_2:FPU_accum_1:FPU_accum_0
	*/
	.align 4,0
	FPU_accum_3:
	.long 0
	FPU_accum_2:
	.long 0
	FPU_accum_1:
	.long 0
	FPU_accum_0:
	.long 0
	FPU_result_3:
	.long 0
	FPU_result_2:
	.long 0
	FPU_result_1:
	.long 0
	#endif /* NON_REENTRANT_FPU */


	.text
	SYM_FUNC_START(div_Xsig)
	pushl %ebp
	movl %esp,%ebp
	#ifndef NON_REENTRANT_FPU
	subl $28,%esp
	#endif /* NON_REENTRANT_FPU */

	pushl %esi
	pushl %edi
	pushl %ebx

	movl PARAM1,%esi /* pointer to num */
	movl PARAM2,%ebx /* pointer to denom */

	#ifdef PARANOID
	testl $0x80000000, XsigH(%ebx) /* Divisor */
	je L_bugged
	#endif /* PARANOID */


	/*---------------------------------------------------------------------------+
	\| Divide: Return arg1/arg2 to arg3. \|
	\| \|
	\| The maximum returned value is (ignoring exponents) \|
	\| .ffffffff ffffffff \|
	\| ------------------ = 1.ffffffff fffffffe \|
	\| .80000000 00000000 \|
	\| and the minimum is \|
	\| .80000000 00000000 \|
	\| ------------------ = .80000000 00000001 (rounded) \|
	\| .ffffffff ffffffff \|
	\| \|
	+---------------------------------------------------------------------------*/

	/* Save extended dividend in local register */

	/* Divide by 2 to prevent overflow */
	clc
	movl XsigH(%esi),%eax
	rcrl %eax
	movl %eax,FPU_accum_3
	movl XsigL(%esi),%eax
	rcrl %eax
	movl %eax,FPU_accum_2
	movl XsigLL(%esi),%eax
	rcrl %eax
	movl %eax,FPU_accum_1
	movl $0,%eax
	rcrl %eax
	movl %eax,FPU_accum_0

	movl FPU_accum_2,%eax /* Get the current num */
	movl FPU_accum_3,%edx

	/----------------------------------------------------------------------/
	/* Initialization done.
	Do the first 32 bits. */

	/* We will divide by a number which is too large */
	movl XsigH(%ebx),%ecx
	addl $1,%ecx
	jnc LFirst_div_not_1

	/* here we need to divide by 100000000h,
	i.e., no division at all.. */
	mov %edx,%eax
	jmp LFirst_div_done

	LFirst_div_not_1:
	divl %ecx /* Divide the numerator by the augmented
	denom ms dw */

	LFirst_div_done:
	movl %eax,FPU_result_3 /* Put the result in the answer */

	mull XsigH(%ebx) /* mul by the ms dw of the denom */

	subl %eax,FPU_accum_2 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_3

	movl FPU_result_3,%eax /* Get the result back */
	mull XsigL(%ebx) /* now mul the ls dw of the denom */

	subl %eax,FPU_accum_1 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_2
	sbbl $0,FPU_accum_3
	je LDo_2nd_32_bits /* Must check for non-zero result here */

	#ifdef PARANOID
	jb L_bugged_1
	#endif /* PARANOID */

	/* need to subtract another once of the denom */
	incl FPU_result_3 /* Correct the answer */

	movl XsigL(%ebx),%eax
	movl XsigH(%ebx),%edx
	subl %eax,FPU_accum_1 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_2

	#ifdef PARANOID
	sbbl $0,FPU_accum_3
	jne L_bugged_1 /* Must check for non-zero result here */
	#endif /* PARANOID */

	/----------------------------------------------------------------------/
	/* Half of the main problem is done, there is just a reduced numerator
	to handle now.
	Work with the second 32 bits, FPU_accum_0 not used from now on */
	LDo_2nd_32_bits:
	movl FPU_accum_2,%edx /* get the reduced num */
	movl FPU_accum_1,%eax

	/* need to check for possible subsequent overflow */
	cmpl XsigH(%ebx),%edx
	jb LDo_2nd_div
	ja LPrevent_2nd_overflow

	cmpl XsigL(%ebx),%eax
	jb LDo_2nd_div

	LPrevent_2nd_overflow:
	/* The numerator is greater or equal, would cause overflow */
	/* prevent overflow */
	subl XsigL(%ebx),%eax
	sbbl XsigH(%ebx),%edx
	movl %edx,FPU_accum_2
	movl %eax,FPU_accum_1

	incl FPU_result_3 /* Reflect the subtraction in the answer */

	#ifdef PARANOID
	je L_bugged_2 /* Can't bump the result to 1.0 */
	#endif /* PARANOID */

	LDo_2nd_div:
	cmpl $0,%ecx /* augmented denom msw */
	jnz LSecond_div_not_1

	/* %ecx == 0, we are dividing by 1.0 */
	mov %edx,%eax
	jmp LSecond_div_done

	LSecond_div_not_1:
	divl %ecx /* Divide the numerator by the denom ms dw */

	LSecond_div_done:
	movl %eax,FPU_result_2 /* Put the result in the answer */

	mull XsigH(%ebx) /* mul by the ms dw of the denom */

	subl %eax,FPU_accum_1 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_2

	#ifdef PARANOID
	jc L_bugged_2
	#endif /* PARANOID */

	movl FPU_result_2,%eax /* Get the result back */
	mull XsigL(%ebx) /* now mul the ls dw of the denom */

	subl %eax,FPU_accum_0 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_1 /* Subtract from the num local reg */
	sbbl $0,FPU_accum_2

	#ifdef PARANOID
	jc L_bugged_2
	#endif /* PARANOID */

	jz LDo_3rd_32_bits

	#ifdef PARANOID
	cmpl $1,FPU_accum_2
	jne L_bugged_2
	#endif /* PARANOID */

	/* need to subtract another once of the denom */
	movl XsigL(%ebx),%eax
	movl XsigH(%ebx),%edx
	subl %eax,FPU_accum_0 /* Subtract from the num local reg */
	sbbl %edx,FPU_accum_1
	sbbl $0,FPU_accum_2

	#ifdef PARANOID
	jc L_bugged_2
	jne L_bugged_2
	#endif /* PARANOID */

	addl $1,FPU_result_2 /* Correct the answer */
	adcl $0,FPU_result_3

	#ifdef PARANOID
	jc L_bugged_2 /* Must check for non-zero result here */
	#endif /* PARANOID */

	/----------------------------------------------------------------------/
	/* The division is essentially finished here, we just need to perform
	tidying operations.
	Deal with the 3rd 32 bits */
	LDo_3rd_32_bits:
	/* We use an approximation for the third 32 bits.
	To take account of the 3rd 32 bits of the divisor
	(call them del), we subtract del * (a/b) */

	movl FPU_result_3,%eax /* a/b */
	mull XsigLL(%ebx) /* del */

	subl %edx,FPU_accum_1

	/* A borrow indicates that the result is negative */
	jnb LTest_over

	movl XsigH(%ebx),%edx
	addl %edx,FPU_accum_1

	subl $1,FPU_result_2 /* Adjust the answer */
	sbbl $0,FPU_result_3

	/* The above addition might not have been enough, check again. */
	movl FPU_accum_1,%edx /* get the reduced num */
	cmpl XsigH(%ebx),%edx /* denom */
	jb LDo_3rd_div

	movl XsigH(%ebx),%edx
	addl %edx,FPU_accum_1

	subl $1,FPU_result_2 /* Adjust the answer */
	sbbl $0,FPU_result_3
	jmp LDo_3rd_div

	LTest_over:
	movl FPU_accum_1,%edx /* get the reduced num */

	/* need to check for possible subsequent overflow */
	cmpl XsigH(%ebx),%edx /* denom */
	jb LDo_3rd_div

	/* prevent overflow */
	subl XsigH(%ebx),%edx
	movl %edx,FPU_accum_1

	addl $1,FPU_result_2 /* Reflect the subtraction in the answer */
	adcl $0,FPU_result_3

	LDo_3rd_div:
	movl FPU_accum_0,%eax
	movl FPU_accum_1,%edx
	divl XsigH(%ebx)

	movl %eax,FPU_result_1 /* Rough estimate of third word */

	movl PARAM3,%esi /* pointer to answer */

	movl FPU_result_1,%eax
	movl %eax,XsigLL(%esi)
	movl FPU_result_2,%eax
	movl %eax,XsigL(%esi)
	movl FPU_result_3,%eax
	movl %eax,XsigH(%esi)

	L_exit:
	popl %ebx
	popl %edi
	popl %esi

	leave
	RET


	#ifdef PARANOID
	/* The logic is wrong if we got here */
	L_bugged:
	pushl EX_INTERNAL\|0x240
	call EXCEPTION
	pop %ebx
	jmp L_exit

	L_bugged_1:
	pushl EX_INTERNAL\|0x241
	call EXCEPTION
	pop %ebx
	jmp L_exit

	L_bugged_2:
	pushl EX_INTERNAL\|0x242
	call EXCEPTION
	pop %ebx
	jmp L_exit
	#endif /* PARANOID */
	SYM_FUNC_END(div_Xsig)