arch/h8300/lib/udivsi3.S - linux-mtk - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 #include "libgcc.h"

 	;; This function also computes the remainder and stores it in er3.
 	.global	__udivsi3
 __udivsi3:
 	mov.w	A1E,A1E		; denominator top word 0?
 	bne	DenHighNonZero

 	; do it the easy way, see page 107 in manual
 	mov.w	A0E,A2
 	extu.l	A2P
 	divxu.w	A1,A2P
 	mov.w	A2E,A0E
 	divxu.w	A1,A0P
 	mov.w	A0E,A3
 	mov.w	A2,A0E
 	extu.l	A3P
 	rts

 	; er0 = er0 / er1
 	; er3 = er0 % er1
 	; trashes er1 er2
 	; expects er1 >= 2^16
 DenHighNonZero:
 	mov.l	er0,er3
 	mov.l	er1,er2
 #ifdef CONFIG_CPU_H8300H
 divmod_L21:
 	shlr.l	er0
 	shlr.l	er2		; make divisor < 2^16
 	mov.w	e2,e2
 	bne	divmod_L21
 #else
 	shlr.l	#2,er2		; make divisor < 2^16
 	mov.w	e2,e2
 	beq	divmod_L22A
 divmod_L21:
 	shlr.l	#2,er0
 divmod_L22:
 	shlr.l	#2,er2		; make divisor < 2^16
 	mov.w	e2,e2
 	bne	divmod_L21
 divmod_L22A:
 	rotxl.w	r2
 	bcs	divmod_L23
 	shlr.l	er0
 	bra	divmod_L24
 divmod_L23:
 	rotxr.w	r2
 	shlr.l	#2,er0
 divmod_L24:
 #endif
 	;; At this point,
 	;;  er0 contains shifted dividend
 	;;  er1 contains divisor
 	;;  er2 contains shifted divisor
 	;;  er3 contains dividend, later remainder
 	divxu.w	r2,er0		; r0 now contains the approximate quotient (AQ)
 	extu.l	er0
 	beq	divmod_L25
 	subs	#1,er0		; er0 = AQ - 1
 	mov.w	e1,r2
 	mulxu.w	r0,er2		; er2 = upper (AQ - 1) * divisor
 	sub.w	r2,e3		; dividend - 65536 * er2
 	mov.w	r1,r2
 	mulxu.w	r0,er2		; compute er3 = remainder (tentative)
 	sub.l	er2,er3		; er3 = dividend - (AQ - 1) * divisor
 divmod_L25:
 	cmp.l	er1,er3		; is divisor < remainder?
 	blo	divmod_L26
 	adds	#1,er0
 	sub.l	er1,er3		; correct the remainder
 divmod_L26:
 	rts

 	.end
	/* SPDX-License-Identifier: GPL-2.0 */
	#include "libgcc.h"

	;; This function also computes the remainder and stores it in er3.
	.global __udivsi3
	__udivsi3:
	mov.w A1E,A1E ; denominator top word 0?
	bne DenHighNonZero

	; do it the easy way, see page 107 in manual
	mov.w A0E,A2
	extu.l A2P
	divxu.w A1,A2P
	mov.w A2E,A0E
	divxu.w A1,A0P
	mov.w A0E,A3
	mov.w A2,A0E
	extu.l A3P
	rts

	; er0 = er0 / er1
	; er3 = er0 % er1
	; trashes er1 er2
	; expects er1 >= 2^16
	DenHighNonZero:
	mov.l er0,er3
	mov.l er1,er2
	#ifdef CONFIG_CPU_H8300H
	divmod_L21:
	shlr.l er0
	shlr.l er2 ; make divisor < 2^16
	mov.w e2,e2
	bne divmod_L21
	#else
	shlr.l #2,er2 ; make divisor < 2^16
	mov.w e2,e2
	beq divmod_L22A
	divmod_L21:
	shlr.l #2,er0
	divmod_L22:
	shlr.l #2,er2 ; make divisor < 2^16
	mov.w e2,e2
	bne divmod_L21
	divmod_L22A:
	rotxl.w r2
	bcs divmod_L23
	shlr.l er0
	bra divmod_L24
	divmod_L23:
	rotxr.w r2
	shlr.l #2,er0
	divmod_L24:
	#endif
	;; At this point,
	;; er0 contains shifted dividend
	;; er1 contains divisor
	;; er2 contains shifted divisor
	;; er3 contains dividend, later remainder
	divxu.w r2,er0 ; r0 now contains the approximate quotient (AQ)
	extu.l er0
	beq divmod_L25
	subs #1,er0 ; er0 = AQ - 1
	mov.w e1,r2
	mulxu.w r0,er2 ; er2 = upper (AQ - 1) * divisor
	sub.w r2,e3 ; dividend - 65536 * er2
	mov.w r1,r2
	mulxu.w r0,er2 ; compute er3 = remainder (tentative)
	sub.l er2,er3 ; er3 = dividend - (AQ - 1) * divisor
	divmod_L25:
	cmp.l er1,er3 ; is divisor < remainder?
	blo divmod_L26
	adds #1,er0
	sub.l er1,er3 ; correct the remainder
	divmod_L26:
	rts

	.end