arch/arm/lib/div64.S - u-boot-mtk - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 /*
  *  linux/arch/arm/lib/div64.S
  *
  *  Optimized computation of 64-bit dividend / 32-bit divisor
  *
  *  Author:	Nicolas Pitre
  *  Created:	Oct 5, 2003
  *  Copyright:	Monta Vista Software, Inc.
  */

 #include <linux/linkage.h>
 #include <asm/assembler.h>
 #ifdef __UBOOT__
 #define UNWIND(x...)
 #endif

 #ifdef __ARMEB__
 #define xh r0
 #define xl r1
 #define yh r2
 #define yl r3
 #else
 #define xl r0
 #define xh r1
 #define yl r2
 #define yh r3
 #endif

 /*
  * __do_div64: perform a division with 64-bit dividend and 32-bit divisor.
  *
  * Note: Calling convention is totally non standard for optimal code.
  *       This is meant to be used by do_div() from include/asm/div64.h only.
  *
  * Input parameters:
  * 	xh-xl	= dividend (clobbered)
  * 	r4	= divisor (preserved)
  *
  * Output values:
  * 	yh-yl	= result
  * 	xh	= remainder
  *
  * Clobbered regs: xl, ip
  */

 .pushsection .text.__do_div64, "ax"
 ENTRY(__do_div64)
 UNWIND(.fnstart)

 	@ Test for easy paths first.
 	subs	ip, r4, #1
 	bls	9f			@ divisor is 0 or 1
 	tst	ip, r4
 	beq	8f			@ divisor is power of 2

 	@ See if we need to handle upper 32-bit result.
 	cmp	xh, r4
 	mov	yh, #0
 	blo	3f

 	@ Align divisor with upper part of dividend.
 	@ The aligned divisor is stored in yl preserving the original.
 	@ The bit position is stored in ip.

 #if __LINUX_ARM_ARCH__ >= 5

 	clz	yl, r4
 	clz	ip, xh
 	sub	yl, yl, ip
 	mov	ip, #1
 	mov	ip, ip, lsl yl
 	mov	yl, r4, lsl yl

 #else

 	mov	yl, r4
 	mov	ip, #1
 1:	cmp	yl, #0x80000000
 	cmpcc	yl, xh
 	movcc	yl, yl, lsl #1
 	movcc	ip, ip, lsl #1
 	bcc	1b

 #endif

 	@ The division loop for needed upper bit positions.
  	@ Break out early if dividend reaches 0.
 2:	cmp	xh, yl
 	orrcs	yh, yh, ip
 	subscs	xh, xh, yl
 	movsne	ip, ip, lsr #1
 	mov	yl, yl, lsr #1
 	bne	2b

 	@ See if we need to handle lower 32-bit result.
 3:	cmp	xh, #0
 	mov	yl, #0
 	cmpeq	xl, r4
 	movlo	xh, xl
 	retlo	lr

 	@ The division loop for lower bit positions.
 	@ Here we shift remainer bits leftwards rather than moving the
 	@ divisor for comparisons, considering the carry-out bit as well.
 	mov	ip, #0x80000000
 4:	movs	xl, xl, lsl #1
 	adcs	xh, xh, xh
 	beq	6f
 	cmpcc	xh, r4
 5:	orrcs	yl, yl, ip
 	subcs	xh, xh, r4
 	movs	ip, ip, lsr #1
 	bne	4b
 	ret	lr

 	@ The top part of remainder became zero.  If carry is set
 	@ (the 33th bit) this is a false positive so resume the loop.
 	@ Otherwise, if lower part is also null then we are done.
 6:	bcs	5b
 	cmp	xl, #0
 	reteq	lr

 	@ We still have remainer bits in the low part.  Bring them up.

 #if __LINUX_ARM_ARCH__ >= 5

 	clz	xh, xl			@ we know xh is zero here so...
 	add	xh, xh, #1
 	mov	xl, xl, lsl xh
 	mov	ip, ip, lsr xh

 #else

 7:	movs	xl, xl, lsl #1
 	mov	ip, ip, lsr #1
 	bcc	7b

 #endif

 	@ Current remainder is now 1.  It is worthless to compare with
 	@ divisor at this point since divisor can not be smaller than 3 here.
 	@ If possible, branch for another shift in the division loop.
 	@ If no bit position left then we are done.
 	movs	ip, ip, lsr #1
 	mov	xh, #1
 	bne	4b
 	ret	lr

 8:	@ Division by a power of 2: determine what that divisor order is
 	@ then simply shift values around

 #if __LINUX_ARM_ARCH__ >= 5

 	clz	ip, r4
 	rsb	ip, ip, #31

 #else

 	mov	yl, r4
 	cmp	r4, #(1 << 16)
 	mov	ip, #0
 	movhs	yl, yl, lsr #16
 	movhs	ip, #16

 	cmp	yl, #(1 << 8)
 	movhs	yl, yl, lsr #8
 	addhs	ip, ip, #8

 	cmp	yl, #(1 << 4)
 	movhs	yl, yl, lsr #4
 	addhs	ip, ip, #4

 	cmp	yl, #(1 << 2)
 	addhi	ip, ip, #3
 	addls	ip, ip, yl, lsr #1

 #endif

 	mov	yh, xh, lsr ip
 	mov	yl, xl, lsr ip
 	rsb	ip, ip, #32
  ARM(	orr	yl, yl, xh, lsl ip	)
  THUMB(	lsl	xh, xh, ip		)
  THUMB(	orr	yl, yl, xh		)
 	mov	xh, xl, lsl ip
 	mov	xh, xh, lsr ip
 	ret	lr

 	@ eq -> division by 1: obvious enough...
 9:	moveq	yl, xl
 	moveq	yh, xh
 	moveq	xh, #0
 	reteq	lr
 UNWIND(.fnend)

 UNWIND(.fnstart)
 UNWIND(.pad #4)
 UNWIND(.save {lr})
 Ldiv0_64:
 	@ Division by 0:
 	str	lr, [sp, #-8]!
 	bl	__div0

 	@ as wrong as it could be...
 	mov	yl, #0
 	mov	yh, #0
 	mov	xh, #0
 	ldr	pc, [sp], #8

 UNWIND(.fnend)
 ENDPROC(__do_div64)
 .popsection
	/* SPDX-License-Identifier: GPL-2.0 */
	/*
	* linux/arch/arm/lib/div64.S
	*
	* Optimized computation of 64-bit dividend / 32-bit divisor
	*
	* Author: Nicolas Pitre
	* Created: Oct 5, 2003
	* Copyright: Monta Vista Software, Inc.
	*/

	#include <linux/linkage.h>
	#include <asm/assembler.h>
	#ifdef __UBOOT__
	#define UNWIND(x...)
	#endif

	#ifdef __ARMEB__
	#define xh r0
	#define xl r1
	#define yh r2
	#define yl r3
	#else
	#define xl r0
	#define xh r1
	#define yl r2
	#define yh r3
	#endif

	/*
	* __do_div64: perform a division with 64-bit dividend and 32-bit divisor.
	*
	* Note: Calling convention is totally non standard for optimal code.
	* This is meant to be used by do_div() from include/asm/div64.h only.
	*
	* Input parameters:
	* xh-xl = dividend (clobbered)
	* r4 = divisor (preserved)
	*
	* Output values:
	* yh-yl = result
	* xh = remainder
	*
	* Clobbered regs: xl, ip
	*/

	.pushsection .text.__do_div64, "ax"
	ENTRY(__do_div64)
	UNWIND(.fnstart)

	@ Test for easy paths first.
	subs ip, r4, #1
	bls 9f @ divisor is 0 or 1
	tst ip, r4
	beq 8f @ divisor is power of 2

	@ See if we need to handle upper 32-bit result.
	cmp xh, r4
	mov yh, #0
	blo 3f

	@ Align divisor with upper part of dividend.
	@ The aligned divisor is stored in yl preserving the original.
	@ The bit position is stored in ip.

	#if __LINUX_ARM_ARCH__ >= 5

	clz yl, r4
	clz ip, xh
	sub yl, yl, ip
	mov ip, #1
	mov ip, ip, lsl yl
	mov yl, r4, lsl yl

	#else

	mov yl, r4
	mov ip, #1
	1: cmp yl, #0x80000000
	cmpcc yl, xh
	movcc yl, yl, lsl #1
	movcc ip, ip, lsl #1
	bcc 1b

	#endif

	@ The division loop for needed upper bit positions.
	@ Break out early if dividend reaches 0.
	2: cmp xh, yl
	orrcs yh, yh, ip
	subscs xh, xh, yl
	movsne ip, ip, lsr #1
	mov yl, yl, lsr #1
	bne 2b

	@ See if we need to handle lower 32-bit result.
	3: cmp xh, #0
	mov yl, #0
	cmpeq xl, r4
	movlo xh, xl
	retlo lr

	@ The division loop for lower bit positions.
	@ Here we shift remainer bits leftwards rather than moving the
	@ divisor for comparisons, considering the carry-out bit as well.
	mov ip, #0x80000000
	4: movs xl, xl, lsl #1
	adcs xh, xh, xh
	beq 6f
	cmpcc xh, r4
	5: orrcs yl, yl, ip
	subcs xh, xh, r4
	movs ip, ip, lsr #1
	bne 4b
	ret lr

	@ The top part of remainder became zero. If carry is set
	@ (the 33th bit) this is a false positive so resume the loop.
	@ Otherwise, if lower part is also null then we are done.
	6: bcs 5b
	cmp xl, #0
	reteq lr

	@ We still have remainer bits in the low part. Bring them up.

	#if __LINUX_ARM_ARCH__ >= 5

	clz xh, xl @ we know xh is zero here so...
	add xh, xh, #1
	mov xl, xl, lsl xh
	mov ip, ip, lsr xh

	#else

	7: movs xl, xl, lsl #1
	mov ip, ip, lsr #1
	bcc 7b

	#endif

	@ Current remainder is now 1. It is worthless to compare with
	@ divisor at this point since divisor can not be smaller than 3 here.
	@ If possible, branch for another shift in the division loop.
	@ If no bit position left then we are done.
	movs ip, ip, lsr #1
	mov xh, #1
	bne 4b
	ret lr

	8: @ Division by a power of 2: determine what that divisor order is
	@ then simply shift values around

	#if __LINUX_ARM_ARCH__ >= 5

	clz ip, r4
	rsb ip, ip, #31

	#else

	mov yl, r4
	cmp r4, #(1 << 16)
	mov ip, #0
	movhs yl, yl, lsr #16
	movhs ip, #16

	cmp yl, #(1 << 8)
	movhs yl, yl, lsr #8
	addhs ip, ip, #8

	cmp yl, #(1 << 4)
	movhs yl, yl, lsr #4
	addhs ip, ip, #4

	cmp yl, #(1 << 2)
	addhi ip, ip, #3
	addls ip, ip, yl, lsr #1

	#endif

	mov yh, xh, lsr ip
	mov yl, xl, lsr ip
	rsb ip, ip, #32
	ARM( orr yl, yl, xh, lsl ip )
	THUMB( lsl xh, xh, ip )
	THUMB( orr yl, yl, xh )
	mov xh, xl, lsl ip
	mov xh, xh, lsr ip
	ret lr

	@ eq -> division by 1: obvious enough...
	9: moveq yl, xl
	moveq yh, xh
	moveq xh, #0
	reteq lr
	UNWIND(.fnend)

	UNWIND(.fnstart)
	UNWIND(.pad #4)
	UNWIND(.save {lr})
	Ldiv0_64:
	@ Division by 0:
	str lr, [sp, #-8]!
	bl __div0

	@ as wrong as it could be...
	mov yl, #0
	mov yh, #0
	mov xh, #0
	ldr pc, [sp], #8

	UNWIND(.fnend)
	ENDPROC(__do_div64)
	.popsection