libgcc/config/h8300/lib1funcs.S - gcc - Git at Google

 ;; libgcc routines for the Renesas H8/300 CPU.
 ;; Contributed by Steve Chamberlain <sac@cygnus.com>
 ;; Optimizations by Toshiyasu Morita <toshiyasu.morita@renesas.com>

 /* Copyright (C) 1994-2021 Free Software Foundation, Inc.

 This file is free software; you can redistribute it and/or modify it
 under the terms of the GNU General Public License as published by the
 Free Software Foundation; either version 3, or (at your option) any
 later version.

 This file is distributed in the hope that it will be useful, but
 WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 General Public License for more details.

 Under Section 7 of GPL version 3, you are granted additional
 permissions described in the GCC Runtime Library Exception, version
 3.1, as published by the Free Software Foundation.

 You should have received a copy of the GNU General Public License and
 a copy of the GCC Runtime Library Exception along with this program;
 see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
 <http://www.gnu.org/licenses/>.  */

 /* Assembler register definitions.  */

 #define A0 r0
 #define A0L r0l
 #define A0H r0h

 #define A1 r1
 #define A1L r1l
 #define A1H r1h

 #define A2 r2
 #define A2L r2l
 #define A2H r2h

 #define A3 r3
 #define A3L r3l
 #define A3H r3h

 #define S0 r4
 #define S0L r4l
 #define S0H r4h

 #define S1 r5
 #define S1L r5l
 #define S1H r5h

 #define S2 r6
 #define S2L r6l
 #define S2H r6h

 #ifdef __H8300__
 #define PUSHP	push
 #define POPP	pop

 #define A0P	r0
 #define A1P	r1
 #define A2P	r2
 #define A3P	r3
 #define S0P	r4
 #define S1P	r5
 #define S2P	r6
 #endif

 #if defined (__H8300H__) || defined (__H8300S__) || defined (__H8300SX__)
 #define PUSHP	push.l
 #define POPP	pop.l

 #define A0P	er0
 #define A1P	er1
 #define A2P	er2
 #define A3P	er3
 #define S0P	er4
 #define S1P	er5
 #define S2P	er6

 #define A0E	e0
 #define A1E	e1
 #define A2E	e2
 #define A3E	e3
 #endif

 #define CONCAT(A,B)     A##B
 #define LABEL0(U,X)    CONCAT(U,__##X)
 #define LABEL0_DEF(U,X)    CONCAT(U,__##X##:)
 #define LABEL_DEF(X)       LABEL0_DEF(__USER_LABEL_PREFIX__,X)
 #define LABEL(X)       LABEL0(__USER_LABEL_PREFIX__,X)

 #ifdef __H8300H__
 #ifdef __NORMAL_MODE__
 	.h8300hn
 #else
 	.h8300h
 #endif
 #endif

 #ifdef __H8300S__
 #ifdef __NORMAL_MODE__
 	.h8300sn
 #else
 	.h8300s
 #endif
 #endif
 #ifdef __H8300SX__
 #ifdef __NORMAL_MODE__
 	.h8300sxn
 #else
 	.h8300sx
 #endif
 #endif

 #ifdef L_cmpsi2
 #ifdef __H8300__
 	.section .text
 	.align 2
 	.global LABEL(cmpsi2)
 LABEL_DEF(cmpsi2)
 	cmp.w	A0,A2
 	bne	.L2
 	cmp.w	A1,A3
 	bne	.L4
 	mov.w	#1,A0
 	rts
 .L2:
 	bgt	.L5
 .L3:
 	mov.w	#2,A0
 	rts
 .L4:
 	bls	.L3
 .L5:
 	sub.w	A0,A0
 	rts
 	.end
 #endif
 #endif /* L_cmpsi2 */

 #ifdef L_ucmpsi2
 #ifdef __H8300__
 	.section .text
 	.align 2
 	.global LABEL(ucmpsi2)
 LABEL_DEF(ucmpsi2)
 	cmp.w	A0,A2
 	bne	.L2
 	cmp.w	A1,A3
 	bne	.L4
 	mov.w	#1,A0
 	rts
 .L2:
 	bhi	.L5
 .L3:
 	mov.w	#2,A0
 	rts
 .L4:
 	bls	.L3
 .L5:
 	sub.w	A0,A0
 	rts
 	.end
 #endif
 #endif /* L_ucmpsi2 */

 #ifdef L_divhi3

 ;; HImode divides for the H8/300.
 ;; We bunch all of this into one object file since there are several
 ;; "supporting routines".

 ; general purpose normalize routine
 ;
 ; divisor in A0
 ; dividend in A1
 ; turns both into +ve numbers, and leaves what the answer sign
 ; should be in A2L

 #ifdef __H8300__
 	.section .text
 	.align 2
 divnorm:
 	or	A0H,A0H		; is divisor > 0
 	stc	ccr,A2L
 	bge	_lab1
 	not	A0H		; no - then make it +ve
 	not	A0L
 	adds	#1,A0
 _lab1:	or	A1H,A1H	; look at dividend
 	bge	_lab2
 	not	A1H		; it is -ve, make it positive
 	not	A1L
 	adds	#1,A1
 	xor	#0x8,A2L; and toggle sign of result
 _lab2:	rts
 ;; Basically the same, except that the sign of the divisor determines
 ;; the sign.
 modnorm:
 	or	A0H,A0H		; is divisor > 0
 	stc	ccr,A2L
 	bge	_lab7
 	not	A0H		; no - then make it +ve
 	not	A0L
 	adds	#1,A0
 _lab7:	or	A1H,A1H	; look at dividend
 	bge	_lab8
 	not	A1H		; it is -ve, make it positive
 	not	A1L
 	adds	#1,A1
 _lab8:	rts

 ; A0=A0/A1 signed

 	.global	LABEL(divhi3)
 LABEL_DEF(divhi3)
 	bsr	divnorm
 	bsr	LABEL(udivhi3)
 negans:	btst	#3,A2L	; should answer be negative ?
 	beq	_lab4
 	not	A0H	; yes, so make it so
 	not	A0L
 	adds	#1,A0
 _lab4:	rts

 ; A0=A0%A1 signed

 	.global	LABEL(modhi3)
 LABEL_DEF(modhi3)
 	bsr	modnorm
 	bsr	LABEL(udivhi3)
 	mov	A3,A0
 	bra	negans

 ; A0=A0%A1 unsigned

 	.global	LABEL(umodhi3)
 LABEL_DEF(umodhi3)
 	bsr	LABEL(udivhi3)
 	mov	A3,A0
 	rts

 ; A0=A0/A1 unsigned
 ; A3=A0%A1 unsigned
 ; A2H trashed
 ; D high 8 bits of denom
 ; d low 8 bits of denom
 ; N high 8 bits of num
 ; n low 8 bits of num
 ; M high 8 bits of mod
 ; m low 8 bits of mod
 ; Q high 8 bits of quot
 ; q low 8 bits of quot
 ; P preserve

 ; The H8/300 only has a 16/8 bit divide, so we look at the incoming and
 ; see how to partition up the expression.

 	.global	LABEL(udivhi3)
 LABEL_DEF(udivhi3)
 				; A0 A1 A2 A3
 				; Nn Dd       P
 	sub.w	A3,A3		; Nn Dd xP 00
 	or	A1H,A1H
 	bne	divlongway
 	or	A0H,A0H
 	beq	_lab6

 ; we know that D == 0 and N is != 0
 	mov.b	A0H,A3L		; Nn Dd xP 0N
 	divxu	A1L,A3		;          MQ
 	mov.b	A3L,A0H	 	; Q
 ; dealt with N, do n
 _lab6:	mov.b	A0L,A3L		;           n
 	divxu	A1L,A3		;          mq
 	mov.b	A3L,A0L		; Qq
 	mov.b	A3H,A3L         ;           m
 	mov.b	#0x0,A3H	; Qq       0m
 	rts

 ; D != 0 - which means the denominator is
 ;          loop around to get the result.

 divlongway:
 	mov.b	A0H,A3L		; Nn Dd xP 0N
 	mov.b	#0x0,A0H	; high byte of answer has to be zero
 	mov.b	#0x8,A2H	;       8
 div8:	add.b	A0L,A0L		; n*=2
 	rotxl	A3L		; Make remainder bigger
 	rotxl	A3H
 	sub.w	A1,A3		; Q-=N
 	bhs	setbit		; set a bit ?
 	add.w	A1,A3		;  no : too far , Q+=N

 	dec	A2H
 	bne	div8		; next bit
 	rts

 setbit:	inc	A0L		; do insert bit
 	dec	A2H
 	bne	div8		; next bit
 	rts

 #endif /* __H8300__ */
 #endif /* L_divhi3 */

 #ifdef L_divsi3

 ;; 4 byte integer divides for the H8/300.
 ;;
 ;; We have one routine which does all the work and lots of
 ;; little ones which prepare the args and massage the sign.
 ;; We bunch all of this into one object file since there are several
 ;; "supporting routines".

 	.section .text
 	.align 2

 ; Put abs SIs into r0/r1 and r2/r3, and leave a 1 in r6l with sign of rest.
 ; This function is here to keep branch displacements small.

 #ifdef __H8300__

 divnorm:
 	mov.b	A0H,A0H		; is the numerator -ve
 	stc	ccr,S2L		; keep the sign in bit 3 of S2L
 	bge	postive

 	; negate arg
 	not	A0H
 	not	A1H
 	not	A0L
 	not	A1L

 	add	#1,A1L
 	addx	#0,A1H
 	addx	#0,A0L
 	addx	#0,A0H
 postive:
 	mov.b	A2H,A2H		; is the denominator -ve
 	bge	postive2
 	not	A2L
 	not	A2H
 	not	A3L
 	not	A3H
 	add.b	#1,A3L
 	addx	#0,A3H
 	addx	#0,A2L
 	addx	#0,A2H
 	xor.b	#0x08,S2L	; toggle the result sign
 postive2:
 	rts

 ;; Basically the same, except that the sign of the divisor determines
 ;; the sign.
 modnorm:
 	mov.b	A0H,A0H		; is the numerator -ve
 	stc	ccr,S2L		; keep the sign in bit 3 of S2L
 	bge	mpostive

 	; negate arg
 	not	A0H
 	not	A1H
 	not	A0L
 	not	A1L

 	add	#1,A1L
 	addx	#0,A1H
 	addx	#0,A0L
 	addx	#0,A0H
 mpostive:
 	mov.b	A2H,A2H		; is the denominator -ve
 	bge	mpostive2
 	not	A2L
 	not	A2H
 	not	A3L
 	not	A3H
 	add.b	#1,A3L
 	addx	#0,A3H
 	addx	#0,A2L
 	addx	#0,A2H
 mpostive2:
 	rts

 #else /* __H8300H__ */

 divnorm:
 	mov.l	A0P,A0P		; is the numerator -ve
 	stc	ccr,S2L		; keep the sign in bit 3 of S2L
 	bge	postive

 	neg.l	A0P		; negate arg

 postive:
 	mov.l	A1P,A1P		; is the denominator -ve
 	bge	postive2

 	neg.l	A1P		; negate arg
 	xor.b	#0x08,S2L	; toggle the result sign

 postive2:
 	rts

 ;; Basically the same, except that the sign of the divisor determines
 ;; the sign.
 modnorm:
 	mov.l	A0P,A0P		; is the numerator -ve
 	stc	ccr,S2L		; keep the sign in bit 3 of S2L
 	bge	mpostive

 	neg.l	A0P		; negate arg

 mpostive:
 	mov.l	A1P,A1P		; is the denominator -ve
 	bge	mpostive2

 	neg.l	A1P		; negate arg

 mpostive2:
 	rts

 #endif

 ; numerator in A0/A1
 ; denominator in A2/A3
 	.global	LABEL(modsi3)
 LABEL_DEF(modsi3)
 #ifdef __H8300__
 	PUSHP	S2P
 	PUSHP	S0P
 	PUSHP	S1P
 	bsr	modnorm
 	bsr	divmodsi4
 	mov	S0,A0
 	mov	S1,A1
 	bra	exitdiv
 #else
 	PUSHP	S2P
 	bsr	modnorm
 	bsr	LABEL(divsi3)
 	mov.l	er3,er0
 	bra	exitdiv
 #endif

 	;; H8/300H and H8S version of ___udivsi3 is defined later in
 	;; the file.
 #ifdef __H8300__
 	.global	LABEL(udivsi3)
 LABEL_DEF(udivsi3)
 	PUSHP	S2P
 	PUSHP	S0P
 	PUSHP	S1P
 	bsr	divmodsi4
 	bra	reti
 #endif

 	.global	LABEL(umodsi3)
 LABEL_DEF(umodsi3)
 #ifdef __H8300__
 	PUSHP	S2P
 	PUSHP	S0P
 	PUSHP	S1P
 	bsr	divmodsi4
 	mov	S0,A0
 	mov	S1,A1
 	bra	reti
 #else
 	bsr	LABEL(udivsi3)
 	mov.l	er3,er0
 	rts
 #endif

 	.global	LABEL(divsi3)
 LABEL_DEF(divsi3)
 #ifdef __H8300__
 	PUSHP	S2P
 	PUSHP	S0P
 	PUSHP	S1P
 	jsr	divnorm
 	jsr	divmodsi4
 #else
 	PUSHP	S2P
 	jsr	divnorm
 	bsr	LABEL(udivsi3)
 #endif

 	; examine what the sign should be
 exitdiv:
 	btst	#3,S2L
 	beq	reti

 	; should be -ve
 #ifdef __H8300__
 	not	A0H
 	not	A1H
 	not	A0L
 	not	A1L

 	add	#1,A1L
 	addx	#0,A1H
 	addx	#0,A0L
 	addx	#0,A0H
 #else /* __H8300H__ */
 	neg.l	A0P
 #endif

 reti:
 #ifdef __H8300__
 	POPP	S1P
 	POPP	S0P
 #endif
 	POPP	S2P
 	rts

 	; takes A0/A1 numerator (A0P for H8/300H)
 	; A2/A3 denominator (A1P for H8/300H)
 	; returns A0/A1 quotient (A0P for H8/300H)
 	; S0/S1 remainder (S0P for H8/300H)
 	; trashes S2H

 #ifdef __H8300__

 divmodsi4:
         sub.w	S0,S0		; zero play area
         mov.w	S0,S1
         mov.b	A2H,S2H
         or	A2L,S2H
         or	A3H,S2H
         bne	DenHighNonZero
         mov.b	A0H,A0H
         bne	NumByte0Zero
         mov.b	A0L,A0L
         bne	NumByte1Zero
         mov.b	A1H,A1H
         bne	NumByte2Zero
         bra	NumByte3Zero
 NumByte0Zero:
 	mov.b	A0H,S1L
         divxu	A3L,S1
         mov.b	S1L,A0H
 NumByte1Zero:
 	mov.b	A0L,S1L
         divxu	A3L,S1
         mov.b	S1L,A0L
 NumByte2Zero:
 	mov.b	A1H,S1L
         divxu	A3L,S1
         mov.b	S1L,A1H
 NumByte3Zero:
 	mov.b	A1L,S1L
         divxu	A3L,S1
         mov.b	S1L,A1L

         mov.b	S1H,S1L
         mov.b	#0x0,S1H
         rts

 ; have to do the divide by shift and test
 DenHighNonZero:
 	mov.b	A0H,S1L
         mov.b	A0L,A0H
         mov.b	A1H,A0L
         mov.b	A1L,A1H

         mov.b	#0,A1L
         mov.b	#24,S2H	; only do 24 iterations

 nextbit:
 	add.w	A1,A1	; double the answer guess
         rotxl	A0L
         rotxl	A0H

         rotxl	S1L	; double remainder
         rotxl	S1H
         rotxl	S0L
         rotxl	S0H
         sub.w	A3,S1	; does it all fit
         subx	A2L,S0L
         subx	A2H,S0H
         bhs	setone

         add.w	A3,S1	; no, restore mistake
         addx	A2L,S0L
         addx	A2H,S0H

         dec	S2H
         bne	nextbit
         rts

 setone:
 	inc	A1L
         dec	S2H
         bne	nextbit
         rts

 #else /* __H8300H__ */

 	;; This function also computes the remainder and stores it in er3.
 	.global	LABEL(udivsi3)
 LABEL_DEF(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 __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

 #endif
 #endif /* L_divsi3 */

 #ifdef L_mulhi3

 ;; HImode multiply.
 ; The H8/300 only has an 8*8->16 multiply.
 ; The answer is the same as:
 ;
 ; product = (srca.l * srcb.l) + ((srca.h * srcb.l) + (srcb.h * srca.l)) * 256
 ; (we can ignore A1.h * A0.h cause that will all off the top)
 ; A0 in
 ; A1 in
 ; A0 answer

 #ifdef __H8300__
 	.section .text
 	.align 2
 	.global	LABEL(mulhi3)
 LABEL_DEF(mulhi3)
 	mov.b	A1L,A2L		; A2l gets srcb.l
 	mulxu	A0L,A2		; A2 gets first sub product

 	mov.b	A0H,A3L		; prepare for
 	mulxu	A1L,A3		; second sub product

 	add.b	A3L,A2H		; sum first two terms

 	mov.b	A1H,A3L		; third sub product
 	mulxu	A0L,A3

 	add.b	A3L,A2H		; almost there
 	mov.w	A2,A0		; that is
 	rts

 #endif
 #endif /* L_mulhi3 */

 #ifdef L_mulsi3

 ;; SImode multiply.
 ;;
 ;; I think that shift and add may be sufficient for this.  Using the
 ;; supplied 8x8->16 would need 10 ops of 14 cycles each + overhead.  This way
 ;; the inner loop uses maybe 20 cycles + overhead, but terminates
 ;; quickly on small args.
 ;;
 ;; A0/A1 src_a
 ;; A2/A3 src_b
 ;;
 ;;  while (a)
 ;;    {
 ;;      if (a & 1)
 ;;        r += b;
 ;;      a >>= 1;
 ;;      b <<= 1;
 ;;    }

 	.section .text
 	.align 2

 #ifdef __H8300__

 	.global	LABEL(mulsi3)
 LABEL_DEF(mulsi3)
 	PUSHP	S0P
 	PUSHP	S1P

 	sub.w	S0,S0
 	sub.w	S1,S1

 	; while (a)
 _top:	mov.w	A0,A0
 	bne	_more
 	mov.w	A1,A1
 	beq	_done
 _more:	; if (a & 1)
 	bld	#0,A1L
 	bcc	_nobit
 	; r += b
 	add.w	A3,S1
 	addx	A2L,S0L
 	addx	A2H,S0H
 _nobit:
 	; a >>= 1
 	shlr	A0H
 	rotxr	A0L
 	rotxr	A1H
 	rotxr	A1L

 	; b <<= 1
 	add.w	A3,A3
 	addx	A2L,A2L
 	addx	A2H,A2H
 	bra 	_top

 _done:
 	mov.w	S0,A0
 	mov.w	S1,A1
 	POPP	S1P
 	POPP	S0P
 	rts

 #else /* __H8300H__ */

 ;
 ; mulsi3 for H8/300H - based on Renesas SH implementation
 ;
 ; by Toshiyasu Morita
 ;
 ; Old code:
 ;
 ; 16b * 16b = 372 states (worst case)
 ; 32b * 32b = 724 states (worst case)
 ;
 ; New code:
 ;
 ; 16b * 16b =  48 states
 ; 16b * 32b =  72 states
 ; 32b * 32b =  92 states
 ;

 	.global LABEL(mulsi3)
 LABEL_DEF(mulsi3)
 	mov.w	r1,r2   ; ( 2 states) b * d
 	mulxu	r0,er2  ; (22 states)

 	mov.w	e0,r3   ; ( 2 states) a * d
 	beq	L_skip1 ; ( 4 states)
 	mulxu	r1,er3  ; (22 states)
 	add.w	r3,e2   ; ( 2 states)

 L_skip1:
 	mov.w	e1,r3   ; ( 2 states) c * b
 	beq	L_skip2 ; ( 4 states)
 	mulxu	r0,er3  ; (22 states)
 	add.w	r3,e2   ; ( 2 states)

 L_skip2:
 	mov.l	er2,er0	; ( 2 states)
 	rts		; (10 states)

 #endif
 #endif /* L_mulsi3 */
 #ifdef L_fixunssfsi_asm
 /* For the h8300 we use asm to save some bytes, to
    allow more programs to fit into the tiny address
    space.  For the H8/300H and H8S, the C version is good enough.  */
 #ifdef __H8300__
 /* We still treat NANs different than libgcc2.c, but then, the
    behavior is undefined anyways.  */
 	.global LABEL(fixunssfsi)
 LABEL_DEF(fixunssfsi)
 	cmp.b #0x4f,r0h
 	bge Large_num
 	jmp     @LABEL(fixsfsi)
 Large_num:
 	bhi L_huge_num
 	xor.b #0x80,A0L
 	bmi L_shift8
 L_huge_num:
 	mov.w #65535,A0
 	mov.w A0,A1
 	rts
 L_shift8:
 	mov.b A0L,A0H
 	mov.b A1H,A0L
 	mov.b A1L,A1H
 	mov.b #0,A1L
 	rts
 #endif
 #endif /* L_fixunssfsi_asm */
	;; libgcc routines for the Renesas H8/300 CPU.
	;; Contributed by Steve Chamberlain <sac@cygnus.com>
	;; Optimizations by Toshiyasu Morita <toshiyasu.morita@renesas.com>

	/* Copyright (C) 1994-2021 Free Software Foundation, Inc.

	This file is free software; you can redistribute it and/or modify it
	under the terms of the GNU General Public License as published by the
	Free Software Foundation; either version 3, or (at your option) any
	later version.

	This file is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	General Public License for more details.

	Under Section 7 of GPL version 3, you are granted additional
	permissions described in the GCC Runtime Library Exception, version
	3.1, as published by the Free Software Foundation.

	You should have received a copy of the GNU General Public License and
	a copy of the GCC Runtime Library Exception along with this program;
	see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
	<http://www.gnu.org/licenses/>. */

	/* Assembler register definitions. */

	#define A0 r0
	#define A0L r0l
	#define A0H r0h

	#define A1 r1
	#define A1L r1l
	#define A1H r1h

	#define A2 r2
	#define A2L r2l
	#define A2H r2h

	#define A3 r3
	#define A3L r3l
	#define A3H r3h

	#define S0 r4
	#define S0L r4l
	#define S0H r4h

	#define S1 r5
	#define S1L r5l
	#define S1H r5h

	#define S2 r6
	#define S2L r6l
	#define S2H r6h

	#ifdef __H8300__
	#define PUSHP push
	#define POPP pop

	#define A0P r0
	#define A1P r1
	#define A2P r2
	#define A3P r3
	#define S0P r4
	#define S1P r5
	#define S2P r6
	#endif

	#if defined (__H8300H__) \|\| defined (__H8300S__) \|\| defined (__H8300SX__)
	#define PUSHP push.l
	#define POPP pop.l

	#define A0P er0
	#define A1P er1
	#define A2P er2
	#define A3P er3
	#define S0P er4
	#define S1P er5
	#define S2P er6

	#define A0E e0
	#define A1E e1
	#define A2E e2
	#define A3E e3
	#endif

	#define CONCAT(A,B) A##B
	#define LABEL0(U,X) CONCAT(U,__##X)
	#define LABEL0_DEF(U,X) CONCAT(U,__##X##:)
	#define LABEL_DEF(X) LABEL0_DEF(__USER_LABEL_PREFIX__,X)
	#define LABEL(X) LABEL0(__USER_LABEL_PREFIX__,X)

	#ifdef __H8300H__
	#ifdef __NORMAL_MODE__
	.h8300hn
	#else
	.h8300h
	#endif
	#endif

	#ifdef __H8300S__
	#ifdef __NORMAL_MODE__
	.h8300sn
	#else
	.h8300s
	#endif
	#endif
	#ifdef __H8300SX__
	#ifdef __NORMAL_MODE__
	.h8300sxn
	#else
	.h8300sx
	#endif
	#endif

	#ifdef L_cmpsi2
	#ifdef __H8300__
	.section .text
	.align 2
	.global LABEL(cmpsi2)
	LABEL_DEF(cmpsi2)
	cmp.w A0,A2
	bne .L2
	cmp.w A1,A3
	bne .L4
	mov.w #1,A0
	rts
	.L2:
	bgt .L5
	.L3:
	mov.w #2,A0
	rts
	.L4:
	bls .L3
	.L5:
	sub.w A0,A0
	rts
	.end
	#endif
	#endif /* L_cmpsi2 */

	#ifdef L_ucmpsi2
	#ifdef __H8300__
	.section .text
	.align 2
	.global LABEL(ucmpsi2)
	LABEL_DEF(ucmpsi2)
	cmp.w A0,A2
	bne .L2
	cmp.w A1,A3
	bne .L4
	mov.w #1,A0
	rts
	.L2:
	bhi .L5
	.L3:
	mov.w #2,A0
	rts
	.L4:
	bls .L3
	.L5:
	sub.w A0,A0
	rts
	.end
	#endif
	#endif /* L_ucmpsi2 */

	#ifdef L_divhi3

	;; HImode divides for the H8/300.
	;; We bunch all of this into one object file since there are several
	;; "supporting routines".

	; general purpose normalize routine
	;
	; divisor in A0
	; dividend in A1
	; turns both into +ve numbers, and leaves what the answer sign
	; should be in A2L

	#ifdef __H8300__
	.section .text
	.align 2
	divnorm:
	or A0H,A0H ; is divisor > 0
	stc ccr,A2L
	bge _lab1
	not A0H ; no - then make it +ve
	not A0L
	adds #1,A0
	_lab1: or A1H,A1H ; look at dividend
	bge _lab2
	not A1H ; it is -ve, make it positive
	not A1L
	adds #1,A1
	xor #0x8,A2L; and toggle sign of result
	_lab2: rts
	;; Basically the same, except that the sign of the divisor determines
	;; the sign.
	modnorm:
	or A0H,A0H ; is divisor > 0
	stc ccr,A2L
	bge _lab7
	not A0H ; no - then make it +ve
	not A0L
	adds #1,A0
	_lab7: or A1H,A1H ; look at dividend
	bge _lab8
	not A1H ; it is -ve, make it positive
	not A1L
	adds #1,A1
	_lab8: rts

	; A0=A0/A1 signed

	.global LABEL(divhi3)
	LABEL_DEF(divhi3)
	bsr divnorm
	bsr LABEL(udivhi3)
	negans: btst #3,A2L ; should answer be negative ?
	beq _lab4
	not A0H ; yes, so make it so
	not A0L
	adds #1,A0
	_lab4: rts

	; A0=A0%A1 signed

	.global LABEL(modhi3)
	LABEL_DEF(modhi3)
	bsr modnorm
	bsr LABEL(udivhi3)
	mov A3,A0
	bra negans

	; A0=A0%A1 unsigned

	.global LABEL(umodhi3)
	LABEL_DEF(umodhi3)
	bsr LABEL(udivhi3)
	mov A3,A0
	rts

	; A0=A0/A1 unsigned
	; A3=A0%A1 unsigned
	; A2H trashed
	; D high 8 bits of denom
	; d low 8 bits of denom
	; N high 8 bits of num
	; n low 8 bits of num
	; M high 8 bits of mod
	; m low 8 bits of mod
	; Q high 8 bits of quot
	; q low 8 bits of quot
	; P preserve

	; The H8/300 only has a 16/8 bit divide, so we look at the incoming and
	; see how to partition up the expression.

	.global LABEL(udivhi3)
	LABEL_DEF(udivhi3)
	; A0 A1 A2 A3
	; Nn Dd P
	sub.w A3,A3 ; Nn Dd xP 00
	or A1H,A1H
	bne divlongway
	or A0H,A0H
	beq _lab6

	; we know that D == 0 and N is != 0
	mov.b A0H,A3L ; Nn Dd xP 0N
	divxu A1L,A3 ; MQ
	mov.b A3L,A0H ; Q
	; dealt with N, do n
	_lab6: mov.b A0L,A3L ; n
	divxu A1L,A3 ; mq
	mov.b A3L,A0L ; Qq
	mov.b A3H,A3L ; m
	mov.b #0x0,A3H ; Qq 0m
	rts

	; D != 0 - which means the denominator is
	; loop around to get the result.

	divlongway:
	mov.b A0H,A3L ; Nn Dd xP 0N
	mov.b #0x0,A0H ; high byte of answer has to be zero
	mov.b #0x8,A2H ; 8
	div8: add.b A0L,A0L ; n*=2
	rotxl A3L ; Make remainder bigger
	rotxl A3H
	sub.w A1,A3 ; Q-=N
	bhs setbit ; set a bit ?
	add.w A1,A3 ; no : too far , Q+=N

	dec A2H
	bne div8 ; next bit
	rts

	setbit: inc A0L ; do insert bit
	dec A2H
	bne div8 ; next bit
	rts

	#endif /* __H8300__ */
	#endif /* L_divhi3 */

	#ifdef L_divsi3

	;; 4 byte integer divides for the H8/300.
	;;
	;; We have one routine which does all the work and lots of
	;; little ones which prepare the args and massage the sign.
	;; We bunch all of this into one object file since there are several
	;; "supporting routines".

	.section .text
	.align 2

	; Put abs SIs into r0/r1 and r2/r3, and leave a 1 in r6l with sign of rest.
	; This function is here to keep branch displacements small.

	#ifdef __H8300__

	divnorm:
	mov.b A0H,A0H ; is the numerator -ve
	stc ccr,S2L ; keep the sign in bit 3 of S2L
	bge postive

	; negate arg
	not A0H
	not A1H
	not A0L
	not A1L

	add #1,A1L
	addx #0,A1H
	addx #0,A0L
	addx #0,A0H
	postive:
	mov.b A2H,A2H ; is the denominator -ve
	bge postive2
	not A2L
	not A2H
	not A3L
	not A3H
	add.b #1,A3L
	addx #0,A3H
	addx #0,A2L
	addx #0,A2H
	xor.b #0x08,S2L ; toggle the result sign
	postive2:
	rts

	;; Basically the same, except that the sign of the divisor determines
	;; the sign.
	modnorm:
	mov.b A0H,A0H ; is the numerator -ve
	stc ccr,S2L ; keep the sign in bit 3 of S2L
	bge mpostive

	; negate arg
	not A0H
	not A1H
	not A0L
	not A1L

	add #1,A1L
	addx #0,A1H
	addx #0,A0L
	addx #0,A0H
	mpostive:
	mov.b A2H,A2H ; is the denominator -ve
	bge mpostive2
	not A2L
	not A2H
	not A3L
	not A3H
	add.b #1,A3L
	addx #0,A3H
	addx #0,A2L
	addx #0,A2H
	mpostive2:
	rts

	#else /* __H8300H__ */

	divnorm:
	mov.l A0P,A0P ; is the numerator -ve
	stc ccr,S2L ; keep the sign in bit 3 of S2L
	bge postive

	neg.l A0P ; negate arg

	postive:
	mov.l A1P,A1P ; is the denominator -ve
	bge postive2

	neg.l A1P ; negate arg
	xor.b #0x08,S2L ; toggle the result sign

	postive2:
	rts

	;; Basically the same, except that the sign of the divisor determines
	;; the sign.
	modnorm:
	mov.l A0P,A0P ; is the numerator -ve
	stc ccr,S2L ; keep the sign in bit 3 of S2L
	bge mpostive

	neg.l A0P ; negate arg

	mpostive:
	mov.l A1P,A1P ; is the denominator -ve
	bge mpostive2

	neg.l A1P ; negate arg

	mpostive2:
	rts

	#endif

	; numerator in A0/A1
	; denominator in A2/A3
	.global LABEL(modsi3)
	LABEL_DEF(modsi3)
	#ifdef __H8300__
	PUSHP S2P
	PUSHP S0P
	PUSHP S1P
	bsr modnorm
	bsr divmodsi4
	mov S0,A0
	mov S1,A1
	bra exitdiv
	#else
	PUSHP S2P
	bsr modnorm
	bsr LABEL(divsi3)
	mov.l er3,er0
	bra exitdiv
	#endif

	;; H8/300H and H8S version of ___udivsi3 is defined later in
	;; the file.
	#ifdef __H8300__
	.global LABEL(udivsi3)
	LABEL_DEF(udivsi3)
	PUSHP S2P
	PUSHP S0P
	PUSHP S1P
	bsr divmodsi4
	bra reti
	#endif

	.global LABEL(umodsi3)
	LABEL_DEF(umodsi3)
	#ifdef __H8300__
	PUSHP S2P
	PUSHP S0P
	PUSHP S1P
	bsr divmodsi4
	mov S0,A0
	mov S1,A1
	bra reti
	#else
	bsr LABEL(udivsi3)
	mov.l er3,er0
	rts
	#endif

	.global LABEL(divsi3)
	LABEL_DEF(divsi3)
	#ifdef __H8300__
	PUSHP S2P
	PUSHP S0P
	PUSHP S1P
	jsr divnorm
	jsr divmodsi4
	#else
	PUSHP S2P
	jsr divnorm
	bsr LABEL(udivsi3)
	#endif

	; examine what the sign should be
	exitdiv:
	btst #3,S2L
	beq reti

	; should be -ve
	#ifdef __H8300__
	not A0H
	not A1H
	not A0L
	not A1L

	add #1,A1L
	addx #0,A1H
	addx #0,A0L
	addx #0,A0H
	#else /* __H8300H__ */
	neg.l A0P
	#endif

	reti:
	#ifdef __H8300__
	POPP S1P
	POPP S0P
	#endif
	POPP S2P
	rts

	; takes A0/A1 numerator (A0P for H8/300H)
	; A2/A3 denominator (A1P for H8/300H)
	; returns A0/A1 quotient (A0P for H8/300H)
	; S0/S1 remainder (S0P for H8/300H)
	; trashes S2H

	#ifdef __H8300__

	divmodsi4:
	sub.w S0,S0 ; zero play area
	mov.w S0,S1
	mov.b A2H,S2H
	or A2L,S2H
	or A3H,S2H
	bne DenHighNonZero
	mov.b A0H,A0H
	bne NumByte0Zero
	mov.b A0L,A0L
	bne NumByte1Zero
	mov.b A1H,A1H
	bne NumByte2Zero
	bra NumByte3Zero
	NumByte0Zero:
	mov.b A0H,S1L
	divxu A3L,S1
	mov.b S1L,A0H
	NumByte1Zero:
	mov.b A0L,S1L
	divxu A3L,S1
	mov.b S1L,A0L
	NumByte2Zero:
	mov.b A1H,S1L
	divxu A3L,S1
	mov.b S1L,A1H
	NumByte3Zero:
	mov.b A1L,S1L
	divxu A3L,S1
	mov.b S1L,A1L

	mov.b S1H,S1L
	mov.b #0x0,S1H
	rts

	; have to do the divide by shift and test
	DenHighNonZero:
	mov.b A0H,S1L
	mov.b A0L,A0H
	mov.b A1H,A0L
	mov.b A1L,A1H

	mov.b #0,A1L
	mov.b #24,S2H ; only do 24 iterations

	nextbit:
	add.w A1,A1 ; double the answer guess
	rotxl A0L
	rotxl A0H

	rotxl S1L ; double remainder
	rotxl S1H
	rotxl S0L
	rotxl S0H
	sub.w A3,S1 ; does it all fit
	subx A2L,S0L
	subx A2H,S0H
	bhs setone

	add.w A3,S1 ; no, restore mistake
	addx A2L,S0L
	addx A2H,S0H

	dec S2H
	bne nextbit
	rts

	setone:
	inc A1L
	dec S2H
	bne nextbit
	rts

	#else /* __H8300H__ */

	;; This function also computes the remainder and stores it in er3.
	.global LABEL(udivsi3)
	LABEL_DEF(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 __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

	#endif
	#endif /* L_divsi3 */

	#ifdef L_mulhi3

	;; HImode multiply.
	; The H8/300 only has an 8*8->16 multiply.
	; The answer is the same as:
	;
	; product = (srca.l * srcb.l) + ((srca.h * srcb.l) + (srcb.h * srca.l)) * 256
	; (we can ignore A1.h * A0.h cause that will all off the top)
	; A0 in
	; A1 in
	; A0 answer

	#ifdef __H8300__
	.section .text
	.align 2
	.global LABEL(mulhi3)
	LABEL_DEF(mulhi3)
	mov.b A1L,A2L ; A2l gets srcb.l
	mulxu A0L,A2 ; A2 gets first sub product

	mov.b A0H,A3L ; prepare for
	mulxu A1L,A3 ; second sub product

	add.b A3L,A2H ; sum first two terms

	mov.b A1H,A3L ; third sub product
	mulxu A0L,A3

	add.b A3L,A2H ; almost there
	mov.w A2,A0 ; that is
	rts

	#endif
	#endif /* L_mulhi3 */

	#ifdef L_mulsi3

	;; SImode multiply.
	;;
	;; I think that shift and add may be sufficient for this. Using the
	;; supplied 8x8->16 would need 10 ops of 14 cycles each + overhead. This way
	;; the inner loop uses maybe 20 cycles + overhead, but terminates
	;; quickly on small args.
	;;
	;; A0/A1 src_a
	;; A2/A3 src_b
	;;
	;; while (a)
	;; {
	;; if (a & 1)
	;; r += b;
	;; a >>= 1;
	;; b <<= 1;
	;; }

	.section .text
	.align 2

	#ifdef __H8300__

	.global LABEL(mulsi3)
	LABEL_DEF(mulsi3)
	PUSHP S0P
	PUSHP S1P

	sub.w S0,S0
	sub.w S1,S1

	; while (a)
	_top: mov.w A0,A0
	bne _more
	mov.w A1,A1
	beq _done
	_more: ; if (a & 1)
	bld #0,A1L
	bcc _nobit
	; r += b
	add.w A3,S1
	addx A2L,S0L
	addx A2H,S0H
	_nobit:
	; a >>= 1
	shlr A0H
	rotxr A0L
	rotxr A1H
	rotxr A1L

	; b <<= 1
	add.w A3,A3
	addx A2L,A2L
	addx A2H,A2H
	bra _top

	_done:
	mov.w S0,A0
	mov.w S1,A1
	POPP S1P
	POPP S0P
	rts

	#else /* __H8300H__ */

	;
	; mulsi3 for H8/300H - based on Renesas SH implementation
	;
	; by Toshiyasu Morita
	;
	; Old code:
	;
	; 16b * 16b = 372 states (worst case)
	; 32b * 32b = 724 states (worst case)
	;
	; New code:
	;
	; 16b * 16b = 48 states
	; 16b * 32b = 72 states
	; 32b * 32b = 92 states
	;

	.global LABEL(mulsi3)
	LABEL_DEF(mulsi3)
	mov.w r1,r2 ; ( 2 states) b * d
	mulxu r0,er2 ; (22 states)

	mov.w e0,r3 ; ( 2 states) a * d
	beq L_skip1 ; ( 4 states)
	mulxu r1,er3 ; (22 states)
	add.w r3,e2 ; ( 2 states)

	L_skip1:
	mov.w e1,r3 ; ( 2 states) c * b
	beq L_skip2 ; ( 4 states)
	mulxu r0,er3 ; (22 states)
	add.w r3,e2 ; ( 2 states)

	L_skip2:
	mov.l er2,er0 ; ( 2 states)
	rts ; (10 states)

	#endif
	#endif /* L_mulsi3 */
	#ifdef L_fixunssfsi_asm
	/* For the h8300 we use asm to save some bytes, to
	allow more programs to fit into the tiny address
	space. For the H8/300H and H8S, the C version is good enough. */
	#ifdef __H8300__
	/* We still treat NANs different than libgcc2.c, but then, the
	behavior is undefined anyways. */
	.global LABEL(fixunssfsi)
	LABEL_DEF(fixunssfsi)
	cmp.b #0x4f,r0h
	bge Large_num
	jmp @LABEL(fixsfsi)
	Large_num:
	bhi L_huge_num
	xor.b #0x80,A0L
	bmi L_shift8
	L_huge_num:
	mov.w #65535,A0
	mov.w A0,A1
	rts
	L_shift8:
	mov.b A0L,A0H
	mov.b A1H,A0L
	mov.b A1L,A1H
	mov.b #0,A1L
	rts
	#endif
	#endif /* L_fixunssfsi_asm */