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

 /* SPDX-License-Identifier: GPL-2.0 */
 /*---------------------------------------------------------------------------+
  |  polynomial_Xsig.S                                                        |
  |                                                                           |
  | Fixed point arithmetic polynomial evaluation.                             |
  |                                                                           |
  | Copyright (C) 1992,1993,1994,1995                                         |
  |                       W. Metzenthen, 22 Parker St, Ormond, Vic 3163,      |
  |                       Australia.  E-mail billm@jacobi.maths.monash.edu.au |
  |                                                                           |
  | Call from C as:                                                           |
  |   void polynomial_Xsig(Xsig *accum, unsigned long long x,                 |
  |                        unsigned long long terms[], int n)                 |
  |                                                                           |
  | Computes:                                                                 |
  | terms[0] + (terms[1] + (terms[2] + ... + (terms[n-1]*x)*x)*x)*x) ... )*x  |
  | and adds the result to the 12 byte Xsig.                                  |
  | The terms[] are each 8 bytes, but all computation is performed to 12 byte |
  | precision.                                                                |
  |                                                                           |
  | This function must be used carefully: most overflow of intermediate       |
  | results is controlled, but overflow of the result is not.                 |
  |                                                                           |
  +---------------------------------------------------------------------------*/
 	.file	"polynomial_Xsig.S"

 #include "fpu_emu.h"


 #define	TERM_SIZE	$8
 #define	SUM_MS		-20(%ebp)	/* sum ms long */
 #define SUM_MIDDLE	-24(%ebp)	/* sum middle long */
 #define	SUM_LS		-28(%ebp)	/* sum ls long */
 #define	ACCUM_MS	-4(%ebp)	/* accum ms long */
 #define	ACCUM_MIDDLE	-8(%ebp)	/* accum middle long */
 #define	ACCUM_LS	-12(%ebp)	/* accum ls long */
 #define OVERFLOWED      -16(%ebp)	/* addition overflow flag */

 .text
 SYM_FUNC_START(polynomial_Xsig)
 	pushl	%ebp
 	movl	%esp,%ebp
 	subl	$32,%esp
 	pushl	%esi
 	pushl	%edi
 	pushl	%ebx

 	movl	PARAM2,%esi		/* x */
 	movl	PARAM3,%edi		/* terms */

 	movl	TERM_SIZE,%eax
 	mull	PARAM4			/* n */
 	addl	%eax,%edi

 	movl	4(%edi),%edx		/* terms[n] */
 	movl	%edx,SUM_MS
 	movl	(%edi),%edx		/* terms[n] */
 	movl	%edx,SUM_MIDDLE
 	xor	%eax,%eax
 	movl	%eax,SUM_LS
 	movb	%al,OVERFLOWED

 	subl	TERM_SIZE,%edi
 	decl	PARAM4
 	js	L_accum_done

 L_accum_loop:
 	xor	%eax,%eax
 	movl	%eax,ACCUM_MS
 	movl	%eax,ACCUM_MIDDLE

 	movl	SUM_MIDDLE,%eax
 	mull	(%esi)			/* x ls long */
 	movl	%edx,ACCUM_LS

 	movl	SUM_MIDDLE,%eax
 	mull	4(%esi)			/* x ms long */
 	addl	%eax,ACCUM_LS
 	adcl	%edx,ACCUM_MIDDLE
 	adcl	$0,ACCUM_MS

 	movl	SUM_MS,%eax
 	mull	(%esi)			/* x ls long */
 	addl	%eax,ACCUM_LS
 	adcl	%edx,ACCUM_MIDDLE
 	adcl	$0,ACCUM_MS

 	movl	SUM_MS,%eax
 	mull	4(%esi)			/* x ms long */
 	addl	%eax,ACCUM_MIDDLE
 	adcl	%edx,ACCUM_MS

 	testb	$0xff,OVERFLOWED
 	jz	L_no_overflow

 	movl	(%esi),%eax
 	addl	%eax,ACCUM_MIDDLE
 	movl	4(%esi),%eax
 	adcl	%eax,ACCUM_MS		/* This could overflow too */

 L_no_overflow:

 /*
  * Now put the sum of next term and the accumulator
  * into the sum register
  */
 	movl	ACCUM_LS,%eax
 	addl	(%edi),%eax		/* term ls long */
 	movl	%eax,SUM_LS
 	movl	ACCUM_MIDDLE,%eax
 	adcl	(%edi),%eax		/* term ls long */
 	movl	%eax,SUM_MIDDLE
 	movl	ACCUM_MS,%eax
 	adcl	4(%edi),%eax		/* term ms long */
 	movl	%eax,SUM_MS
 	sbbb	%al,%al
 	movb	%al,OVERFLOWED		/* Used in the next iteration */

 	subl	TERM_SIZE,%edi
 	decl	PARAM4
 	jns	L_accum_loop

 L_accum_done:
 	movl	PARAM1,%edi		/* accum */
 	movl	SUM_LS,%eax
 	addl	%eax,(%edi)
 	movl	SUM_MIDDLE,%eax
 	adcl	%eax,4(%edi)
 	movl	SUM_MS,%eax
 	adcl	%eax,8(%edi)

 	popl	%ebx
 	popl	%edi
 	popl	%esi
 	leave
 	ret
 SYM_FUNC_END(polynomial_Xsig)
	/* SPDX-License-Identifier: GPL-2.0 */
	/*---------------------------------------------------------------------------+
	\| polynomial_Xsig.S \|
	\| \|
	\| Fixed point arithmetic polynomial evaluation. \|
	\| \|
	\| Copyright (C) 1992,1993,1994,1995 \|
	\| W. Metzenthen, 22 Parker St, Ormond, Vic 3163, \|
	\| Australia. E-mail billm@jacobi.maths.monash.edu.au \|
	\| \|
	\| Call from C as: \|
	\| void polynomial_Xsig(Xsig *accum, unsigned long long x, \|
	\| unsigned long long terms[], int n) \|
	\| \|
	\| Computes: \|
	\| terms[0] + (terms[1] + (terms[2] + ... + (terms[n-1]x)x)x)x) ... )*x \|
	\| and adds the result to the 12 byte Xsig. \|
	\| The terms[] are each 8 bytes, but all computation is performed to 12 byte \|
	\| precision. \|
	\| \|
	\| This function must be used carefully: most overflow of intermediate \|
	\| results is controlled, but overflow of the result is not. \|
	\| \|
	+---------------------------------------------------------------------------*/
	.file "polynomial_Xsig.S"

	#include "fpu_emu.h"


	#define TERM_SIZE $8
	#define SUM_MS -20(%ebp) /* sum ms long */
	#define SUM_MIDDLE -24(%ebp) /* sum middle long */
	#define SUM_LS -28(%ebp) /* sum ls long */
	#define ACCUM_MS -4(%ebp) /* accum ms long */
	#define ACCUM_MIDDLE -8(%ebp) /* accum middle long */
	#define ACCUM_LS -12(%ebp) /* accum ls long */
	#define OVERFLOWED -16(%ebp) /* addition overflow flag */

	.text
	SYM_FUNC_START(polynomial_Xsig)
	pushl %ebp
	movl %esp,%ebp
	subl $32,%esp
	pushl %esi
	pushl %edi
	pushl %ebx

	movl PARAM2,%esi /* x */
	movl PARAM3,%edi /* terms */

	movl TERM_SIZE,%eax
	mull PARAM4 /* n */
	addl %eax,%edi

	movl 4(%edi),%edx /* terms[n] */
	movl %edx,SUM_MS
	movl (%edi),%edx /* terms[n] */
	movl %edx,SUM_MIDDLE
	xor %eax,%eax
	movl %eax,SUM_LS
	movb %al,OVERFLOWED

	subl TERM_SIZE,%edi
	decl PARAM4
	js L_accum_done

	L_accum_loop:
	xor %eax,%eax
	movl %eax,ACCUM_MS
	movl %eax,ACCUM_MIDDLE

	movl SUM_MIDDLE,%eax
	mull (%esi) /* x ls long */
	movl %edx,ACCUM_LS

	movl SUM_MIDDLE,%eax
	mull 4(%esi) /* x ms long */
	addl %eax,ACCUM_LS
	adcl %edx,ACCUM_MIDDLE
	adcl $0,ACCUM_MS

	movl SUM_MS,%eax
	mull (%esi) /* x ls long */
	addl %eax,ACCUM_LS
	adcl %edx,ACCUM_MIDDLE
	adcl $0,ACCUM_MS

	movl SUM_MS,%eax
	mull 4(%esi) /* x ms long */
	addl %eax,ACCUM_MIDDLE
	adcl %edx,ACCUM_MS

	testb $0xff,OVERFLOWED
	jz L_no_overflow

	movl (%esi),%eax
	addl %eax,ACCUM_MIDDLE
	movl 4(%esi),%eax
	adcl %eax,ACCUM_MS /* This could overflow too */

	L_no_overflow:

	/*
	* Now put the sum of next term and the accumulator
	* into the sum register
	*/
	movl ACCUM_LS,%eax
	addl (%edi),%eax /* term ls long */
	movl %eax,SUM_LS
	movl ACCUM_MIDDLE,%eax
	adcl (%edi),%eax /* term ls long */
	movl %eax,SUM_MIDDLE
	movl ACCUM_MS,%eax
	adcl 4(%edi),%eax /* term ms long */
	movl %eax,SUM_MS
	sbbb %al,%al
	movb %al,OVERFLOWED /* Used in the next iteration */

	subl TERM_SIZE,%edi
	decl PARAM4
	jns L_accum_loop

	L_accum_done:
	movl PARAM1,%edi /* accum */
	movl SUM_LS,%eax
	addl %eax,(%edi)
	movl SUM_MIDDLE,%eax
	adcl %eax,4(%edi)
	movl SUM_MS,%eax
	adcl %eax,8(%edi)

	popl %ebx
	popl %edi
	popl %esi
	leave
	ret
	SYM_FUNC_END(polynomial_Xsig)