path: root/gcc-4.9/libgcc/config/sh/lib1funcs.S

/* Copyright (C) 1994-2014 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/>.  */


!! libgcc routines for the Renesas / SuperH SH CPUs.
!! Contributed by Steve Chamberlain.
!! sac@cygnus.com

!! ashiftrt_r4_x, ___ashrsi3, ___ashlsi3, ___lshrsi3 routines
!! recoded in assembly by Toshiyasu Morita
!! tm@netcom.com

#if defined(__ELF__) && defined(__linux__)
.section .note.GNU-stack,"",%progbits
.previous
#endif

/* SH2 optimizations for ___ashrsi3, ___ashlsi3, ___lshrsi3 and
   ELF local label prefixes by J"orn Rennecke
   amylaar@cygnus.com  */

#include "lib1funcs.h"

/* t-vxworks needs to build both PIC and non-PIC versions of libgcc,
   so it is more convenient to define NO_FPSCR_VALUES here than to
   define it on the command line.  */
#if defined __vxworks && defined __PIC__
#define NO_FPSCR_VALUES
#endif
	
#if ! __SH5__
#ifdef L_ashiftrt
	.global	GLOBAL(ashiftrt_r4_0)
	.global	GLOBAL(ashiftrt_r4_1)
	.global	GLOBAL(ashiftrt_r4_2)
	.global	GLOBAL(ashiftrt_r4_3)
	.global	GLOBAL(ashiftrt_r4_4)
	.global	GLOBAL(ashiftrt_r4_5)
	.global	GLOBAL(ashiftrt_r4_6)
	.global	GLOBAL(ashiftrt_r4_7)
	.global	GLOBAL(ashiftrt_r4_8)
	.global	GLOBAL(ashiftrt_r4_9)
	.global	GLOBAL(ashiftrt_r4_10)
	.global	GLOBAL(ashiftrt_r4_11)
	.global	GLOBAL(ashiftrt_r4_12)
	.global	GLOBAL(ashiftrt_r4_13)
	.global	GLOBAL(ashiftrt_r4_14)
	.global	GLOBAL(ashiftrt_r4_15)
	.global	GLOBAL(ashiftrt_r4_16)
	.global	GLOBAL(ashiftrt_r4_17)
	.global	GLOBAL(ashiftrt_r4_18)
	.global	GLOBAL(ashiftrt_r4_19)
	.global	GLOBAL(ashiftrt_r4_20)
	.global	GLOBAL(ashiftrt_r4_21)
	.global	GLOBAL(ashiftrt_r4_22)
	.global	GLOBAL(ashiftrt_r4_23)
	.global	GLOBAL(ashiftrt_r4_24)
	.global	GLOBAL(ashiftrt_r4_25)
	.global	GLOBAL(ashiftrt_r4_26)
	.global	GLOBAL(ashiftrt_r4_27)
	.global	GLOBAL(ashiftrt_r4_28)
	.global	GLOBAL(ashiftrt_r4_29)
	.global	GLOBAL(ashiftrt_r4_30)
	.global	GLOBAL(ashiftrt_r4_31)
	.global	GLOBAL(ashiftrt_r4_32)

	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_0))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_1))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_2))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_3))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_4))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_5))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_6))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_7))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_8))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_9))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_10))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_11))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_12))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_13))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_14))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_15))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_16))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_17))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_18))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_19))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_20))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_21))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_22))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_23))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_24))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_25))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_26))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_27))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_28))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_29))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_30))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_31))
	HIDDEN_FUNC(GLOBAL(ashiftrt_r4_32))

	.align	1
GLOBAL(ashiftrt_r4_32):
GLOBAL(ashiftrt_r4_31):
	rotcl	r4
	rts
	subc	r4,r4

GLOBAL(ashiftrt_r4_30):
	shar	r4
GLOBAL(ashiftrt_r4_29):
	shar	r4
GLOBAL(ashiftrt_r4_28):
	shar	r4
GLOBAL(ashiftrt_r4_27):
	shar	r4
GLOBAL(ashiftrt_r4_26):
	shar	r4
GLOBAL(ashiftrt_r4_25):
	shar	r4
GLOBAL(ashiftrt_r4_24):
	shlr16	r4
	shlr8	r4
	rts
	exts.b	r4,r4

GLOBAL(ashiftrt_r4_23):
	shar	r4
GLOBAL(ashiftrt_r4_22):
	shar	r4
GLOBAL(ashiftrt_r4_21):
	shar	r4
GLOBAL(ashiftrt_r4_20):
	shar	r4
GLOBAL(ashiftrt_r4_19):
	shar	r4
GLOBAL(ashiftrt_r4_18):
	shar	r4
GLOBAL(ashiftrt_r4_17):
	shar	r4
GLOBAL(ashiftrt_r4_16):
	shlr16	r4
	rts
	exts.w	r4,r4

GLOBAL(ashiftrt_r4_15):
	shar	r4
GLOBAL(ashiftrt_r4_14):
	shar	r4
GLOBAL(ashiftrt_r4_13):
	shar	r4
GLOBAL(ashiftrt_r4_12):
	shar	r4
GLOBAL(ashiftrt_r4_11):
	shar	r4
GLOBAL(ashiftrt_r4_10):
	shar	r4
GLOBAL(ashiftrt_r4_9):
	shar	r4
GLOBAL(ashiftrt_r4_8):
	shar	r4
GLOBAL(ashiftrt_r4_7):
	shar	r4
GLOBAL(ashiftrt_r4_6):
	shar	r4
GLOBAL(ashiftrt_r4_5):
	shar	r4
GLOBAL(ashiftrt_r4_4):
	shar	r4
GLOBAL(ashiftrt_r4_3):
	shar	r4
GLOBAL(ashiftrt_r4_2):
	shar	r4
GLOBAL(ashiftrt_r4_1):
	rts
	shar	r4

GLOBAL(ashiftrt_r4_0):
	rts
	nop

	ENDFUNC(GLOBAL(ashiftrt_r4_0))
	ENDFUNC(GLOBAL(ashiftrt_r4_1))
	ENDFUNC(GLOBAL(ashiftrt_r4_2))
	ENDFUNC(GLOBAL(ashiftrt_r4_3))
	ENDFUNC(GLOBAL(ashiftrt_r4_4))
	ENDFUNC(GLOBAL(ashiftrt_r4_5))
	ENDFUNC(GLOBAL(ashiftrt_r4_6))
	ENDFUNC(GLOBAL(ashiftrt_r4_7))
	ENDFUNC(GLOBAL(ashiftrt_r4_8))
	ENDFUNC(GLOBAL(ashiftrt_r4_9))
	ENDFUNC(GLOBAL(ashiftrt_r4_10))
	ENDFUNC(GLOBAL(ashiftrt_r4_11))
	ENDFUNC(GLOBAL(ashiftrt_r4_12))
	ENDFUNC(GLOBAL(ashiftrt_r4_13))
	ENDFUNC(GLOBAL(ashiftrt_r4_14))
	ENDFUNC(GLOBAL(ashiftrt_r4_15))
	ENDFUNC(GLOBAL(ashiftrt_r4_16))
	ENDFUNC(GLOBAL(ashiftrt_r4_17))
	ENDFUNC(GLOBAL(ashiftrt_r4_18))
	ENDFUNC(GLOBAL(ashiftrt_r4_19))
	ENDFUNC(GLOBAL(ashiftrt_r4_20))
	ENDFUNC(GLOBAL(ashiftrt_r4_21))
	ENDFUNC(GLOBAL(ashiftrt_r4_22))
	ENDFUNC(GLOBAL(ashiftrt_r4_23))
	ENDFUNC(GLOBAL(ashiftrt_r4_24))
	ENDFUNC(GLOBAL(ashiftrt_r4_25))
	ENDFUNC(GLOBAL(ashiftrt_r4_26))
	ENDFUNC(GLOBAL(ashiftrt_r4_27))
	ENDFUNC(GLOBAL(ashiftrt_r4_28))
	ENDFUNC(GLOBAL(ashiftrt_r4_29))
	ENDFUNC(GLOBAL(ashiftrt_r4_30))
	ENDFUNC(GLOBAL(ashiftrt_r4_31))
	ENDFUNC(GLOBAL(ashiftrt_r4_32))
#endif

#ifdef L_ashiftrt_n

!
! GLOBAL(ashrsi3)
!
! Entry:
!
! r4: Value to shift
! r5: Shift count
!
! Exit:
!
! r0: Result
!
! Destroys:
!
! T bit, r5
!

	.global	GLOBAL(ashrsi3)
	HIDDEN_FUNC(GLOBAL(ashrsi3))
	.align	2
GLOBAL(ashrsi3):
	mov	#31,r0
	and	r0,r5
	mova	LOCAL(ashrsi3_table),r0
	mov.b	@(r0,r5),r5
#ifdef __sh1__
	add	r5,r0
	jmp	@r0
#else
	braf	r5
#endif
	mov	r4,r0

	.align	2
LOCAL(ashrsi3_table):
	.byte		LOCAL(ashrsi3_0)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_1)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_2)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_3)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_4)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_5)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_6)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_7)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_8)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_9)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_10)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_11)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_12)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_13)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_14)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_15)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_16)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_17)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_18)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_19)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_20)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_21)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_22)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_23)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_24)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_25)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_26)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_27)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_28)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_29)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_30)-LOCAL(ashrsi3_table)
	.byte		LOCAL(ashrsi3_31)-LOCAL(ashrsi3_table)

LOCAL(ashrsi3_31):
	rotcl	r0
	rts
	subc	r0,r0

LOCAL(ashrsi3_30):
	shar	r0
LOCAL(ashrsi3_29):
	shar	r0
LOCAL(ashrsi3_28):
	shar	r0
LOCAL(ashrsi3_27):
	shar	r0
LOCAL(ashrsi3_26):
	shar	r0
LOCAL(ashrsi3_25):
	shar	r0
LOCAL(ashrsi3_24):
	shlr16	r0
	shlr8	r0
	rts
	exts.b	r0,r0

LOCAL(ashrsi3_23):
	shar	r0
LOCAL(ashrsi3_22):
	shar	r0
LOCAL(ashrsi3_21):
	shar	r0
LOCAL(ashrsi3_20):
	shar	r0
LOCAL(ashrsi3_19):
	shar	r0
LOCAL(ashrsi3_18):
	shar	r0
LOCAL(ashrsi3_17):
	shar	r0
LOCAL(ashrsi3_16):
	shlr16	r0
	rts
	exts.w	r0,r0

LOCAL(ashrsi3_15):
	shar	r0
LOCAL(ashrsi3_14):
	shar	r0
LOCAL(ashrsi3_13):
	shar	r0
LOCAL(ashrsi3_12):
	shar	r0
LOCAL(ashrsi3_11):
	shar	r0
LOCAL(ashrsi3_10):
	shar	r0
LOCAL(ashrsi3_9):
	shar	r0
LOCAL(ashrsi3_8):
	shar	r0
LOCAL(ashrsi3_7):
	shar	r0
LOCAL(ashrsi3_6):
	shar	r0
LOCAL(ashrsi3_5):
	shar	r0
LOCAL(ashrsi3_4):
	shar	r0
LOCAL(ashrsi3_3):
	shar	r0
LOCAL(ashrsi3_2):
	shar	r0
LOCAL(ashrsi3_1):
	rts
	shar	r0

LOCAL(ashrsi3_0):
	rts
	nop

	ENDFUNC(GLOBAL(ashrsi3))
#endif

#ifdef L_ashiftlt

!
! GLOBAL(ashlsi3)
! (For compatibility with older binaries, not used by compiler)
!
! Entry:
!	r4: Value to shift
!	r5: Shift count
!
! Exit:
!	r0: Result
!
! Destroys:
!	T bit
!
!
! GLOBAL(ashlsi3_r0)
!
! Entry:
!	r4: Value to shift
!	r0: Shift count
!
! Exit:
!	r0: Result
!
! Destroys:
!	T bit

	.global	GLOBAL(ashlsi3)
	.global GLOBAL(ashlsi3_r0)
	HIDDEN_FUNC(GLOBAL(ashlsi3))
	HIDDEN_FUNC(GLOBAL(ashlsi3_r0))
GLOBAL(ashlsi3):
	mov	r5,r0
	.align	2
GLOBAL(ashlsi3_r0):

#ifdef __sh1__
	and	#31,r0
	shll2	r0
	mov.l	r4,@-r15
	mov	r0,r4
	mova	LOCAL(ashlsi3_table),r0
	add	r4,r0
	mov.l	@r15+,r4
	jmp	@r0
	mov	r4,r0
	.align 2
#else
	and	#31,r0
	shll2	r0
	braf	r0
	mov	r4,r0
#endif

LOCAL(ashlsi3_table):
	rts				// << 0
	nop
LOCAL(ashlsi_1):
	rts				// << 1
	shll	r0
LOCAL(ashlsi_2):			// << 2
	rts
	shll2	r0
	bra	LOCAL(ashlsi_1)		// << 3
	shll2	r0
	bra	LOCAL(ashlsi_2)		// << 4
	shll2	r0
	bra	LOCAL(ashlsi_5)		// << 5
	shll	r0
	bra	LOCAL(ashlsi_6)		// << 6
	shll2	r0
	bra	LOCAL(ashlsi_7)		// << 7
	shll	r0
LOCAL(ashlsi_8):			// << 8
	rts
	shll8	r0
	bra	LOCAL(ashlsi_8)		// << 9
	shll	r0
	bra	LOCAL(ashlsi_8)		// << 10
	shll2	r0
	bra	LOCAL(ashlsi_11)	// << 11
	shll	r0
	bra	LOCAL(ashlsi_12)	// << 12
	shll2	r0
	bra	LOCAL(ashlsi_13)	// << 13
	shll	r0
	bra	LOCAL(ashlsi_14)	// << 14
	shll8	r0
	bra	LOCAL(ashlsi_15)	// << 15
	shll8	r0
LOCAL(ashlsi_16):			// << 16
	rts
	shll16	r0
	bra	LOCAL(ashlsi_16)	// << 17
	shll	r0
	bra	LOCAL(ashlsi_16)	// << 18
	shll2	r0
	bra	LOCAL(ashlsi_19)	// << 19
	shll	r0
	bra	LOCAL(ashlsi_20)	// << 20
	shll2	r0
	bra	LOCAL(ashlsi_21)	// << 21
	shll	r0
	bra	LOCAL(ashlsi_22)	// << 22
	shll16	r0
	bra	LOCAL(ashlsi_23)	// << 23
	shll16	r0
	bra	LOCAL(ashlsi_16)	// << 24
	shll8	r0
	bra	LOCAL(ashlsi_25)	// << 25
	shll	r0
	bra	LOCAL(ashlsi_26)	// << 26
	shll2	r0
	bra	LOCAL(ashlsi_27)	// << 27
	shll	r0
	bra	LOCAL(ashlsi_28)	// << 28
	shll2	r0
	bra	LOCAL(ashlsi_29)	// << 29
	shll16	r0
	bra	LOCAL(ashlsi_30)	// << 30
	shll16	r0
	and	#1,r0			// << 31
	rts
	rotr	r0

LOCAL(ashlsi_7):
	shll2	r0
LOCAL(ashlsi_5):
LOCAL(ashlsi_6):
	shll2	r0
	rts
LOCAL(ashlsi_13):
	shll2	r0
LOCAL(ashlsi_12):
LOCAL(ashlsi_11):
	shll8	r0
	rts
LOCAL(ashlsi_21):
	shll2	r0
LOCAL(ashlsi_20):
LOCAL(ashlsi_19):
	shll16	r0
	rts
LOCAL(ashlsi_28):
LOCAL(ashlsi_27):
	shll2	r0
LOCAL(ashlsi_26):
LOCAL(ashlsi_25):
	shll16	r0
	rts
	shll8	r0

LOCAL(ashlsi_22):
LOCAL(ashlsi_14):
	shlr2	r0
	rts
	shll8	r0

LOCAL(ashlsi_23):
LOCAL(ashlsi_15):
	shlr	r0
	rts
	shll8	r0

LOCAL(ashlsi_29):
	shlr	r0
LOCAL(ashlsi_30):
	shlr2	r0
	rts
	shll16	r0	

	ENDFUNC(GLOBAL(ashlsi3))
	ENDFUNC(GLOBAL(ashlsi3_r0))
#endif

#ifdef L_lshiftrt

!
! GLOBAL(lshrsi3)
! (For compatibility with older binaries, not used by compiler)
!
! Entry:
!	r4: Value to shift
!	r5: Shift count
!
! Exit:
!	r0: Result
!
! Destroys:
!	T bit
!
!
! GLOBAL(lshrsi3_r0)
!
! Entry:
!	r4: Value to shift
!	r0: Shift count
!
! Exit:
!	r0: Result
!
! Destroys:
!	T bit

	.global	GLOBAL(lshrsi3)
	.global	GLOBAL(lshrsi3_r0)
	HIDDEN_FUNC(GLOBAL(lshrsi3))
	HIDDEN_FUNC(GLOBAL(lshrsi3_r0))
GLOBAL(lshrsi3):
	mov	r5,r0
	.align	2
GLOBAL(lshrsi3_r0):

#ifdef __sh1__
	and	#31,r0
	shll2	r0
	mov.l	r4,@-r15
	mov	r0,r4
	mova	LOCAL(lshrsi3_table),r0
	add	r4,r0
	mov.l	@r15+,r4
	jmp	@r0
	mov	r4,r0
	.align 2
#else
	and	#31,r0
	shll2	r0
	braf	r0
	mov	r4,r0
#endif
LOCAL(lshrsi3_table):
	rts				// >> 0
	nop
LOCAL(lshrsi_1):			// >> 1
	rts
	shlr	r0
LOCAL(lshrsi_2):			// >> 2
	rts
	shlr2	r0
	bra	LOCAL(lshrsi_1)		// >> 3
	shlr2	r0
	bra	LOCAL(lshrsi_2)		// >> 4
	shlr2	r0
	bra	LOCAL(lshrsi_5)		// >> 5
	shlr	r0
	bra	LOCAL(lshrsi_6)		// >> 6
	shlr2	r0
	bra	LOCAL(lshrsi_7)		// >> 7
	shlr	r0
LOCAL(lshrsi_8):			// >> 8
	rts
	shlr8	r0
	bra	LOCAL(lshrsi_8)		// >> 9
	shlr	r0
	bra	LOCAL(lshrsi_8)		// >> 10
	shlr2	r0
	bra	LOCAL(lshrsi_11)	// >> 11
	shlr	r0
	bra	LOCAL(lshrsi_12)	// >> 12
	shlr2	r0
	bra	LOCAL(lshrsi_13)	// >> 13
	shlr	r0
	bra	LOCAL(lshrsi_14)	// >> 14
	shlr8	r0
	bra	LOCAL(lshrsi_15)	// >> 15
	shlr8	r0
LOCAL(lshrsi_16):			// >> 16
	rts
	shlr16	r0
	bra	LOCAL(lshrsi_16)	// >> 17
	shlr	r0
	bra	LOCAL(lshrsi_16)	// >> 18
	shlr2	r0
	bra	LOCAL(lshrsi_19)	// >> 19
	shlr	r0
	bra	LOCAL(lshrsi_20)	// >> 20
	shlr2	r0
	bra	LOCAL(lshrsi_21)	// >> 21
	shlr	r0
	bra	LOCAL(lshrsi_22)	// >> 22
	shlr16	r0
	bra	LOCAL(lshrsi_23)	// >> 23
	shlr16	r0
	bra	LOCAL(lshrsi_16)	// >> 24
	shlr8	r0
	bra	LOCAL(lshrsi_25)	// >> 25
	shlr	r0
	bra	LOCAL(lshrsi_26)	// >> 26
	shlr2	r0
	bra	LOCAL(lshrsi_27)	// >> 27
	shlr	r0
	bra	LOCAL(lshrsi_28)	// >> 28
	shlr2	r0
	bra	LOCAL(lshrsi_29)	// >> 29
	shlr16	r0
	bra	LOCAL(lshrsi_30)	// >> 30
	shlr16	r0
	shll	r0			// >> 31
	rts
	movt	r0

LOCAL(lshrsi_7):
	shlr2	r0
LOCAL(lshrsi_5):
LOCAL(lshrsi_6):
	shlr2	r0
	rts
LOCAL(lshrsi_13):
	shlr2	r0
LOCAL(lshrsi_12):
LOCAL(lshrsi_11):
	shlr8	r0
	rts
LOCAL(lshrsi_21):
	shlr2	r0
LOCAL(lshrsi_20):
LOCAL(lshrsi_19):
	shlr16	r0
	rts
LOCAL(lshrsi_28):
LOCAL(lshrsi_27):
	shlr2	r0
LOCAL(lshrsi_26):
LOCAL(lshrsi_25):
	shlr16	r0
	rts
	shlr8	r0

LOCAL(lshrsi_22):
LOCAL(lshrsi_14):
	shll2	r0
	rts
	shlr8	r0

LOCAL(lshrsi_23):
LOCAL(lshrsi_15):
	shll	r0
	rts
	shlr8	r0

LOCAL(lshrsi_29):
	shll	r0
LOCAL(lshrsi_30):
	shll2	r0
	rts
	shlr16	r0	

	ENDFUNC(GLOBAL(lshrsi3))
	ENDFUNC(GLOBAL(lshrsi3_r0))
#endif

#ifdef L_movmem
	.text
	.balign	4
	.global	GLOBAL(movmem)
	HIDDEN_FUNC(GLOBAL(movmem))
	HIDDEN_ALIAS(movstr,movmem)
	/* This would be a lot simpler if r6 contained the byte count
	   minus 64, and we wouldn't be called here for a byte count of 64.  */
GLOBAL(movmem):
	sts.l	pr,@-r15
	shll2	r6
	bsr	GLOBAL(movmemSI52+2)
	mov.l	@(48,r5),r0
	.balign	4
LOCAL(movmem_loop): /* Reached with rts */
	mov.l	@(60,r5),r0
	add	#-64,r6
	mov.l	r0,@(60,r4)
	tst	r6,r6
	mov.l	@(56,r5),r0
	bt	LOCAL(movmem_done)
	mov.l	r0,@(56,r4)
	cmp/pl	r6
	mov.l	@(52,r5),r0
	add	#64,r5
	mov.l	r0,@(52,r4)
	add	#64,r4
	bt	GLOBAL(movmemSI52)
! done all the large groups, do the remainder
! jump to movmem+
	mova	GLOBAL(movmemSI4)+4,r0
	add	r6,r0
	jmp	@r0
LOCAL(movmem_done): ! share slot insn, works out aligned.
	lds.l	@r15+,pr
	mov.l	r0,@(56,r4)
	mov.l	@(52,r5),r0
	rts
	mov.l	r0,@(52,r4)
	.balign	4
! ??? We need aliases movstr* for movmem* for the older libraries.  These
! aliases will be removed at the some point in the future.
	.global	GLOBAL(movmemSI64)
	HIDDEN_FUNC(GLOBAL(movmemSI64))
	HIDDEN_ALIAS(movstrSI64,movmemSI64)
GLOBAL(movmemSI64):
	mov.l	@(60,r5),r0
	mov.l	r0,@(60,r4)
	.global	GLOBAL(movmemSI60)
	HIDDEN_FUNC(GLOBAL(movmemSI60))
	HIDDEN_ALIAS(movstrSI60,movmemSI60)
GLOBAL(movmemSI60):
	mov.l	@(56,r5),r0
	mov.l	r0,@(56,r4)
	.global	GLOBAL(movmemSI56)
	HIDDEN_FUNC(GLOBAL(movmemSI56))
	HIDDEN_ALIAS(movstrSI56,movmemSI56)
GLOBAL(movmemSI56):
	mov.l	@(52,r5),r0
	mov.l	r0,@(52,r4)
	.global	GLOBAL(movmemSI52)
	HIDDEN_FUNC(GLOBAL(movmemSI52))
	HIDDEN_ALIAS(movstrSI52,movmemSI52)
GLOBAL(movmemSI52):
	mov.l	@(48,r5),r0
	mov.l	r0,@(48,r4)
	.global	GLOBAL(movmemSI48)
	HIDDEN_FUNC(GLOBAL(movmemSI48))
	HIDDEN_ALIAS(movstrSI48,movmemSI48)
GLOBAL(movmemSI48):
	mov.l	@(44,r5),r0
	mov.l	r0,@(44,r4)
	.global	GLOBAL(movmemSI44)
	HIDDEN_FUNC(GLOBAL(movmemSI44))
	HIDDEN_ALIAS(movstrSI44,movmemSI44)
GLOBAL(movmemSI44):
	mov.l	@(40,r5),r0
	mov.l	r0,@(40,r4)
	.global	GLOBAL(movmemSI40)
	HIDDEN_FUNC(GLOBAL(movmemSI40))
	HIDDEN_ALIAS(movstrSI40,movmemSI40)
GLOBAL(movmemSI40):
	mov.l	@(36,r5),r0
	mov.l	r0,@(36,r4)
	.global	GLOBAL(movmemSI36)
	HIDDEN_FUNC(GLOBAL(movmemSI36))
	HIDDEN_ALIAS(movstrSI36,movmemSI36)
GLOBAL(movmemSI36):
	mov.l	@(32,r5),r0
	mov.l	r0,@(32,r4)
	.global	GLOBAL(movmemSI32)
	HIDDEN_FUNC(GLOBAL(movmemSI32))
	HIDDEN_ALIAS(movstrSI32,movmemSI32)
GLOBAL(movmemSI32):
	mov.l	@(28,r5),r0
	mov.l	r0,@(28,r4)
	.global	GLOBAL(movmemSI28)
	HIDDEN_FUNC(GLOBAL(movmemSI28))
	HIDDEN_ALIAS(movstrSI28,movmemSI28)
GLOBAL(movmemSI28):
	mov.l	@(24,r5),r0
	mov.l	r0,@(24,r4)
	.global	GLOBAL(movmemSI24)
	HIDDEN_FUNC(GLOBAL(movmemSI24))
	HIDDEN_ALIAS(movstrSI24,movmemSI24)
GLOBAL(movmemSI24):
	mov.l	@(20,r5),r0
	mov.l	r0,@(20,r4)
	.global	GLOBAL(movmemSI20)
	HIDDEN_FUNC(GLOBAL(movmemSI20))
	HIDDEN_ALIAS(movstrSI20,movmemSI20)
GLOBAL(movmemSI20):
	mov.l	@(16,r5),r0
	mov.l	r0,@(16,r4)
	.global	GLOBAL(movmemSI16)
	HIDDEN_FUNC(GLOBAL(movmemSI16))
	HIDDEN_ALIAS(movstrSI16,movmemSI16)
GLOBAL(movmemSI16):
	mov.l	@(12,r5),r0
	mov.l	r0,@(12,r4)
	.global	GLOBAL(movmemSI12)
	HIDDEN_FUNC(GLOBAL(movmemSI12))
	HIDDEN_ALIAS(movstrSI12,movmemSI12)
GLOBAL(movmemSI12):
	mov.l	@(8,r5),r0
	mov.l	r0,@(8,r4)
	.global	GLOBAL(movmemSI8)
	HIDDEN_FUNC(GLOBAL(movmemSI8))
	HIDDEN_ALIAS(movstrSI8,movmemSI8)
GLOBAL(movmemSI8):
	mov.l	@(4,r5),r0
	mov.l	r0,@(4,r4)
	.global	GLOBAL(movmemSI4)
	HIDDEN_FUNC(GLOBAL(movmemSI4))
	HIDDEN_ALIAS(movstrSI4,movmemSI4)
GLOBAL(movmemSI4):
	mov.l	@(0,r5),r0
	rts
	mov.l	r0,@(0,r4)

	ENDFUNC(GLOBAL(movmemSI64))
	ENDFUNC(GLOBAL(movmemSI60))
	ENDFUNC(GLOBAL(movmemSI56))
	ENDFUNC(GLOBAL(movmemSI52))
	ENDFUNC(GLOBAL(movmemSI48))
	ENDFUNC(GLOBAL(movmemSI44))
	ENDFUNC(GLOBAL(movmemSI40))
	ENDFUNC(GLOBAL(movmemSI36))
	ENDFUNC(GLOBAL(movmemSI32))
	ENDFUNC(GLOBAL(movmemSI28))
	ENDFUNC(GLOBAL(movmemSI24))
	ENDFUNC(GLOBAL(movmemSI20))
	ENDFUNC(GLOBAL(movmemSI16))
	ENDFUNC(GLOBAL(movmemSI12))
	ENDFUNC(GLOBAL(movmemSI8))
	ENDFUNC(GLOBAL(movmemSI4))
	ENDFUNC(GLOBAL(movmem))
#endif

#ifdef L_movmem_i4
	.text
	.global	GLOBAL(movmem_i4_even)
	.global	GLOBAL(movmem_i4_odd)
	.global	GLOBAL(movmemSI12_i4)

	HIDDEN_FUNC(GLOBAL(movmem_i4_even))
	HIDDEN_FUNC(GLOBAL(movmem_i4_odd))
	HIDDEN_FUNC(GLOBAL(movmemSI12_i4))

	HIDDEN_ALIAS(movstr_i4_even,movmem_i4_even)
	HIDDEN_ALIAS(movstr_i4_odd,movmem_i4_odd)
	HIDDEN_ALIAS(movstrSI12_i4,movmemSI12_i4)

	.p2align	5
L_movmem_2mod4_end:
	mov.l	r0,@(16,r4)
	rts
	mov.l	r1,@(20,r4)

	.p2align	2

GLOBAL(movmem_i4_even):
	mov.l	@r5+,r0
	bra	L_movmem_start_even
	mov.l	@r5+,r1

GLOBAL(movmem_i4_odd):
	mov.l	@r5+,r1
	add	#-4,r4
	mov.l	@r5+,r2
	mov.l	@r5+,r3
	mov.l	r1,@(4,r4)
	mov.l	r2,@(8,r4)

L_movmem_loop:
	mov.l	r3,@(12,r4)
	dt	r6
	mov.l	@r5+,r0
	bt/s	L_movmem_2mod4_end
	mov.l	@r5+,r1
	add	#16,r4
L_movmem_start_even:
	mov.l	@r5+,r2
	mov.l	@r5+,r3
	mov.l	r0,@r4
	dt	r6
	mov.l	r1,@(4,r4)
	bf/s	L_movmem_loop
	mov.l	r2,@(8,r4)
	rts
	mov.l	r3,@(12,r4)

	ENDFUNC(GLOBAL(movmem_i4_even))
	ENDFUNC(GLOBAL(movmem_i4_odd))

	.p2align	4
GLOBAL(movmemSI12_i4):
	mov.l	@r5,r0
	mov.l	@(4,r5),r1
	mov.l	@(8,r5),r2
	mov.l	r0,@r4
	mov.l	r1,@(4,r4)
	rts
	mov.l	r2,@(8,r4)

	ENDFUNC(GLOBAL(movmemSI12_i4))
#endif

#ifdef L_mulsi3


	.global	GLOBAL(mulsi3)
	HIDDEN_FUNC(GLOBAL(mulsi3))

! r4 =       aabb
! r5 =       ccdd
! r0 = aabb*ccdd  via partial products
!
! if aa == 0 and cc = 0
! r0 = bb*dd
!
! else
! aa = bb*dd + (aa*dd*65536) + (cc*bb*65536)
!

GLOBAL(mulsi3):
	mulu.w  r4,r5		! multiply the lsws  macl=bb*dd
	mov     r5,r3		! r3 = ccdd
	swap.w  r4,r2		! r2 = bbaa
	xtrct   r2,r3		! r3 = aacc
	tst  	r3,r3		! msws zero ?
	bf      hiset
	rts			! yes - then we have the answer
	sts     macl,r0

hiset:	sts	macl,r0		! r0 = bb*dd
	mulu.w	r2,r5		! brewing macl = aa*dd
	sts	macl,r1
	mulu.w	r3,r4		! brewing macl = cc*bb
	sts	macl,r2
	add	r1,r2
	shll16	r2
	rts
	add	r2,r0

	ENDFUNC(GLOBAL(mulsi3))
#endif
#endif /* ! __SH5__ */

/*------------------------------------------------------------------------------
  32 bit signed integer division that uses FPU double precision division.  */

#ifdef L_sdivsi3_i4
	.title "SH DIVIDE"

#if defined (__SH4__) || defined (__SH2A__)
/* This variant is used when FPSCR.PR = 1 (double precision) is the default
   setting.
   Args in r4 and r5, result in fpul, clobber dr0, dr2.  */

	.global	GLOBAL(sdivsi3_i4)
	HIDDEN_FUNC(GLOBAL(sdivsi3_i4))
GLOBAL(sdivsi3_i4):
	lds r4,fpul
	float fpul,dr0
	lds r5,fpul
	float fpul,dr2
	fdiv dr2,dr0
	rts
	ftrc dr0,fpul

	ENDFUNC(GLOBAL(sdivsi3_i4))

#elif defined (__SH2A_SINGLE__) || defined (__SH2A_SINGLE_ONLY__) || defined(__SH4_SINGLE__) || defined(__SH4_SINGLE_ONLY__) || (defined (__SH5__) && ! defined __SH4_NOFPU__)
/* This variant is used when FPSCR.PR = 0 (sigle precision) is the default
   setting.
   Args in r4 and r5, result in fpul, clobber r2, dr0, dr2.
   For this to work, we must temporarily switch the FPU do double precision,
   but we better do not touch FPSCR.FR.  See PR 6526.  */

#if ! __SH5__ || __SH5__ == 32
#if __SH5__
	.mode	SHcompact
#endif
	.global	GLOBAL(sdivsi3_i4)
	HIDDEN_FUNC(GLOBAL(sdivsi3_i4))
GLOBAL(sdivsi3_i4):

#ifndef __SH4A__
	mov.l	r3,@-r15
	sts	fpscr,r2
	mov	#8,r3
	swap.w	r3,r3		// r3 = 1 << 19 (FPSCR.PR bit)
	or	r2,r3
	lds	r3,fpscr	// Set FPSCR.PR = 1.
	lds	r4,fpul
	float	fpul,dr0
	lds	r5,fpul
	float	fpul,dr2
	fdiv	dr2,dr0
	ftrc	dr0,fpul
	lds	r2,fpscr
	rts
	mov.l	@r15+,r3
#else
/* On SH4A we can use the fpchg instruction to flip the FPSCR.PR bit.  */
	fpchg
	lds	r4,fpul
	float	fpul,dr0
	lds	r5,fpul
	float	fpul,dr2
	fdiv	dr2,dr0
	ftrc	dr0,fpul
	rts
	fpchg	

#endif /* __SH4A__  */

	ENDFUNC(GLOBAL(sdivsi3_i4))
#endif /* ! __SH5__ || __SH5__ == 32 */
#endif /* ! __SH4__ || __SH2A__  */
#endif /* L_sdivsi3_i4  */

//------------------------------------------------------------------------------
#ifdef L_sdivsi3
/* __SH4_SINGLE_ONLY__ keeps this part for link compatibility with
   sh2e/sh3e code.  */
!!
!! Steve Chamberlain
!! sac@cygnus.com
!!
!!

!! args in r4 and r5, result in r0 clobber r1, r2, r3, and t bit

	.global	GLOBAL(sdivsi3)
#if __SHMEDIA__
#if __SH5__ == 32
	.section	.text..SHmedia32,"ax"
#else
	.text
#endif
	.align	2
#if 0
/* The assembly code that follows is a hand-optimized version of the C
   code that follows.  Note that the registers that are modified are
   exactly those listed as clobbered in the patterns divsi3_i1 and
   divsi3_i1_media.
	
int __sdivsi3 (i, j)
     int i, j;
{
  register unsigned long long r18 asm ("r18");
  register unsigned long long r19 asm ("r19");
  register unsigned long long r0 asm ("r0") = 0;
  register unsigned long long r1 asm ("r1") = 1;
  register int r2 asm ("r2") = i >> 31;
  register int r3 asm ("r3") = j >> 31;

  r2 = r2 ? r2 : r1;
  r3 = r3 ? r3 : r1;
  r18 = i * r2;
  r19 = j * r3;
  r2 *= r3;
  
  r19 <<= 31;
  r1 <<= 31;
  do
    if (r18 >= r19)
      r0 |= r1, r18 -= r19;
  while (r19 >>= 1, r1 >>= 1);

  return r2 * (int)r0;
}
*/
GLOBAL(sdivsi3):
	pt/l	LOCAL(sdivsi3_dontadd), tr2
	pt/l	LOCAL(sdivsi3_loop), tr1
	ptabs/l	r18, tr0
	movi	0, r0
	movi	1, r1
	shari.l	r4, 31, r2
	shari.l	r5, 31, r3
	cmveq	r2, r1, r2
	cmveq	r3, r1, r3
	muls.l	r4, r2, r18
	muls.l	r5, r3, r19
	muls.l	r2, r3, r2
	shlli	r19, 31, r19
	shlli	r1, 31, r1
LOCAL(sdivsi3_loop):
	bgtu	r19, r18, tr2
	or	r0, r1, r0
	sub	r18, r19, r18
LOCAL(sdivsi3_dontadd):
	shlri	r1, 1, r1
	shlri	r19, 1, r19
	bnei	r1, 0, tr1
	muls.l	r0, r2, r0
	add.l	r0, r63, r0
	blink	tr0, r63
#elif 0 /* ! 0 */
 // inputs: r4,r5
 // clobbered: r1,r2,r3,r18,r19,r20,r21,r25,tr0
 // result in r0
GLOBAL(sdivsi3):
 // can create absolute value without extra latency,
 // but dependent on proper sign extension of inputs:
 // shari.l r5,31,r2
 // xor r5,r2,r20
 // sub r20,r2,r20 // r20 is now absolute value of r5, zero-extended.
 shari.l r5,31,r2
 ori r2,1,r2
 muls.l r5,r2,r20 // r20 is now absolute value of r5, zero-extended.
 movi 0xffffffffffffbb0c,r19 // shift count eqiv 76
 shari.l r4,31,r3
 nsb r20,r0
 shlld r20,r0,r25
 shlri r25,48,r25
 sub r19,r25,r1
 mmulfx.w r1,r1,r2
 mshflo.w r1,r63,r1
 // If r4 was to be used in-place instead of r21, could use this sequence
 // to compute absolute:
 // sub r63,r4,r19 // compute absolute value of r4
 // shlri r4,32,r3 // into lower 32 bit of r4, keeping
 // mcmv r19,r3,r4 // the sign in the upper 32 bits intact.
 ori r3,1,r3
 mmulfx.w r25,r2,r2
 sub r19,r0,r0
 muls.l r4,r3,r21
 msub.w r1,r2,r2
 addi r2,-2,r1
 mulu.l r21,r1,r19
 mmulfx.w r2,r2,r2
 shlli r1,15,r1
 shlrd r19,r0,r19
 mulu.l r19,r20,r3
 mmacnfx.wl r25,r2,r1
 ptabs r18,tr0
 sub r21,r3,r25

 mulu.l r25,r1,r2
 addi r0,14,r0
 xor r4,r5,r18
 shlrd r2,r0,r2
 mulu.l r2,r20,r3
 add r19,r2,r19
 shari.l r18,31,r18
 sub r25,r3,r25

 mulu.l r25,r1,r2
 sub r25,r20,r25
 add r19,r18,r19
 shlrd r2,r0,r2
 mulu.l r2,r20,r3
 addi r25,1,r25
 add r19,r2,r19

 cmpgt r25,r3,r25
 add.l r19,r25,r0
 xor r0,r18,r0
 blink tr0,r63
#else /* ! 0 && ! 0 */

 // inputs: r4,r5
 // clobbered: r1,r18,r19,r20,r21,r25,tr0
 // result in r0
	HIDDEN_FUNC(GLOBAL(sdivsi3_2))
#ifndef __pic__
	FUNC(GLOBAL(sdivsi3))
GLOBAL(sdivsi3): /* this is the shcompact entry point */
 // The special SHmedia entry point sdivsi3_1 prevents accidental linking
 // with the SHcompact implementation, which clobbers tr1 / tr2.
 .global GLOBAL(sdivsi3_1)
GLOBAL(sdivsi3_1):
 .global GLOBAL(div_table_internal)
 movi (GLOBAL(div_table_internal) >> 16) & 65535, r20
 shori GLOBAL(div_table_internal) & 65535, r20
#endif
 .global GLOBAL(sdivsi3_2)
 // div_table in r20
 // clobbered: r1,r18,r19,r21,r25,tr0
GLOBAL(sdivsi3_2):
 nsb r5, r1
 shlld r5, r1, r25    // normalize; [-2 ..1, 1..2) in s2.62
 shari r25, 58, r21   // extract 5(6) bit index (s2.4 with hole -1..1)
 ldx.ub r20, r21, r19 // u0.8
 shari r25, 32, r25   // normalize to s2.30
 shlli r21, 1, r21
 muls.l r25, r19, r19 // s2.38
 ldx.w r20, r21, r21  // s2.14
  ptabs r18, tr0
 shari r19, 24, r19   // truncate to s2.14
 sub r21, r19, r19    // some 11 bit inverse in s1.14
 muls.l r19, r19, r21 // u0.28
  sub r63, r1, r1
  addi r1, 92, r1
 muls.l r25, r21, r18 // s2.58
 shlli r19, 45, r19   // multiply by two and convert to s2.58
  /* bubble */
 sub r19, r18, r18
 shari r18, 28, r18   // some 22 bit inverse in s1.30
 muls.l r18, r25, r0  // s2.60
  muls.l r18, r4, r25 // s32.30
  /* bubble */
 shari r0, 16, r19   // s-16.44
 muls.l r19, r18, r19 // s-16.74
  shari r25, 63, r0
  shari r4, 14, r18   // s19.-14
 shari r19, 30, r19   // s-16.44
 muls.l r19, r18, r19 // s15.30
  xor r21, r0, r21    // You could also use the constant 1 << 27.
  add r21, r25, r21
 sub r21, r19, r21
 shard r21, r1, r21
 sub r21, r0, r0
 blink tr0, r63
#ifndef __pic__
	ENDFUNC(GLOBAL(sdivsi3))
#endif
	ENDFUNC(GLOBAL(sdivsi3_2))
#endif
#elif __SHMEDIA__
/* m5compact-nofpu */
 // clobbered: r18,r19,r20,r21,r25,tr0,tr1,tr2
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	FUNC(GLOBAL(sdivsi3))
GLOBAL(sdivsi3):
	pt/l LOCAL(sdivsi3_dontsub), tr0
	pt/l LOCAL(sdivsi3_loop), tr1
	ptabs/l r18,tr2
	shari.l r4,31,r18
	shari.l r5,31,r19
	xor r4,r18,r20
	xor r5,r19,r21
	sub.l r20,r18,r20
	sub.l r21,r19,r21
	xor r18,r19,r19
	shlli r21,32,r25
	addi r25,-1,r21
	addz.l r20,r63,r20
LOCAL(sdivsi3_loop):
	shlli r20,1,r20
	bgeu/u r21,r20,tr0
	sub r20,r21,r20
LOCAL(sdivsi3_dontsub):
	addi.l r25,-1,r25
	bnei r25,-32,tr1
	xor r20,r19,r20
	sub.l r20,r19,r0
	blink tr2,r63
	ENDFUNC(GLOBAL(sdivsi3))
#else /* ! __SHMEDIA__ */
	FUNC(GLOBAL(sdivsi3))
GLOBAL(sdivsi3):
	mov	r4,r1
	mov	r5,r0

	tst	r0,r0
	bt	div0
	mov	#0,r2
	div0s	r2,r1
	subc	r3,r3
	subc	r2,r1
	div0s	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	div1	r0,r3
	rotcl	r1
	addc	r2,r1
	rts
	mov	r1,r0


div0:	rts
	mov	#0,r0

	ENDFUNC(GLOBAL(sdivsi3))
#endif /* ! __SHMEDIA__  */
#endif /* L_sdivsi3  */

/*------------------------------------------------------------------------------
  32 bit unsigned integer division that uses FPU double precision division.  */

#ifdef L_udivsi3_i4
	.title "SH DIVIDE"

#if defined (__SH4__) || defined (__SH2A__)
/* This variant is used when FPSCR.PR = 1 (double precision) is the default
   setting.
   Args in r4 and r5, result in fpul,
   clobber r0, r1, r4, r5, dr0, dr2, dr4, and t bit  */

	.global	GLOBAL(udivsi3_i4)
	HIDDEN_FUNC(GLOBAL(udivsi3_i4))
GLOBAL(udivsi3_i4):
	mov	#1,r1
	cmp/hi	r1,r5
	bf/s	trivial
	rotr	r1
	xor	r1,r4
	lds	r4,fpul
	mova	L1,r0
#ifdef FMOVD_WORKS
	fmov.d	@r0+,dr4
#else
	fmov.s	@r0+,DR40
	fmov.s	@r0,DR41
#endif
	float	fpul,dr0
	xor	r1,r5
	lds	r5,fpul
	float	fpul,dr2
	fadd	dr4,dr0
	fadd	dr4,dr2
	fdiv	dr2,dr0
	rts
	ftrc	dr0,fpul

trivial:
	rts
	lds	r4,fpul

	.align 2
#ifdef FMOVD_WORKS
	.align 3	// Make the double below 8 byte aligned.
#endif
L1:
	.double 2147483648

	ENDFUNC(GLOBAL(udivsi3_i4))

#elif defined (__SH5__) && ! defined (__SH4_NOFPU__) && ! defined (__SH2A_NOFPU__)
#if ! __SH5__ || __SH5__ == 32
!! args in r4 and r5, result in fpul, clobber r20, r21, dr0, fr33
	.mode	SHmedia
	.global	GLOBAL(udivsi3_i4)
	HIDDEN_FUNC(GLOBAL(udivsi3_i4))
GLOBAL(udivsi3_i4):
	addz.l	r4,r63,r20
	addz.l	r5,r63,r21
	fmov.qd	r20,dr0
	fmov.qd	r21,dr32
	ptabs	r18,tr0
	float.qd dr0,dr0
	float.qd dr32,dr32
	fdiv.d	dr0,dr32,dr0
	ftrc.dq dr0,dr32
	fmov.s fr33,fr32
	blink tr0,r63

	ENDFUNC(GLOBAL(udivsi3_i4))
#endif /* ! __SH5__ || __SH5__ == 32 */

#elif defined (__SH2A_SINGLE__) || defined (__SH2A_SINGLE_ONLY__) || defined(__SH4_SINGLE__) || defined(__SH4_SINGLE_ONLY__)
/* This variant is used when FPSCR.PR = 0 (sigle precision) is the default
   setting.
   Args in r4 and r5, result in fpul,
   clobber r0, r1, r4, r5, dr0, dr2, dr4.
   For this to work, we must temporarily switch the FPU do double precision,
   but we better do not touch FPSCR.FR.  See PR 6526.  */

	.global	GLOBAL(udivsi3_i4)
	HIDDEN_FUNC(GLOBAL(udivsi3_i4))
GLOBAL(udivsi3_i4):

#ifndef __SH4A__
	mov	#1,r1
	cmp/hi	r1,r5
	bf/s	trivial
	rotr	r1		// r1 = 1 << 31
	sts.l	fpscr,@-r15
	xor	r1,r4
	mov.l	@(0,r15),r0
	xor	r1,r5
	mov.l	L2,r1
	lds	r4,fpul
	or	r0,r1
	mova	L1,r0
	lds	r1,fpscr
#ifdef FMOVD_WORKS
	fmov.d	@r0+,dr4
#else
	fmov.s	@r0+,DR40
	fmov.s	@r0,DR41
#endif
	float	fpul,dr0
	lds	r5,fpul
	float	fpul,dr2
	fadd	dr4,dr0
	fadd	dr4,dr2
	fdiv	dr2,dr0
	ftrc	dr0,fpul
	rts
	lds.l	@r15+,fpscr

#ifdef FMOVD_WORKS
	.align 3	// Make the double below 8 byte aligned.
#endif
trivial:
	rts
	lds	r4,fpul

	.align 2
L2:
#ifdef FMOVD_WORKS
	.long 0x180000	// FPSCR.PR = 1, FPSCR.SZ = 1
#else
	.long 0x80000	// FPSCR.PR = 1
#endif
L1:
	.double 2147483648

#else
/* On SH4A we can use the fpchg instruction to flip the FPSCR.PR bit.
   Although on SH4A fmovd usually works, it would require either additional
   two fschg instructions or an FPSCR push + pop.  It's not worth the effort
   for loading only one double constant.  */
	mov	#1,r1
	cmp/hi	r1,r5
	bf/s	trivial
	rotr	r1		// r1 = 1 << 31
	fpchg
	mova	L1,r0
	xor	r1,r4
	fmov.s	@r0+,DR40
	lds	r4,fpul
	fmov.s	@r0,DR41
	xor	r1,r5
	float	fpul,dr0
	lds	r5,fpul
	float	fpul,dr2
	fadd	dr4,dr0
	fadd	dr4,dr2
	fdiv	dr2,dr0
	ftrc	dr0,fpul
	rts
	fpchg

trivial:
	rts
	lds	r4,fpul

	.align 2
L1:
	.double 2147483648

#endif /* __SH4A__  */


	ENDFUNC(GLOBAL(udivsi3_i4))
#endif /* ! __SH4__ */
#endif /* L_udivsi3_i4  */

#ifdef L_udivsi3
/* __SH4_SINGLE_ONLY__ keeps this part for link compatibility with
   sh2e/sh3e code.  */

!! args in r4 and r5, result in r0, clobbers r4, pr, and t bit
	.global	GLOBAL(udivsi3)
	HIDDEN_FUNC(GLOBAL(udivsi3))

#if __SHMEDIA__
#if __SH5__ == 32
	.section	.text..SHmedia32,"ax"
#else
	.text
#endif
	.align	2
#if 0
/* The assembly code that follows is a hand-optimized version of the C
   code that follows.  Note that the registers that are modified are
   exactly those listed as clobbered in the patterns udivsi3_i1 and
   udivsi3_i1_media.
	
unsigned 
__udivsi3 (i, j)
    unsigned i, j; 
{
  register unsigned long long r0 asm ("r0") = 0;
  register unsigned long long r18 asm ("r18") = 1;
  register unsigned long long r4 asm ("r4") = i;
  register unsigned long long r19 asm ("r19") = j;

  r19 <<= 31;
  r18 <<= 31;
  do
    if (r4 >= r19)
      r0 |= r18, r4 -= r19;
  while (r19 >>= 1, r18 >>= 1);

  return r0;
}
*/
GLOBAL(udivsi3):
	pt/l	LOCAL(udivsi3_dontadd), tr2
	pt/l	LOCAL(udivsi3_loop), tr1
	ptabs/l	r18, tr0
	movi	0, r0
	movi	1, r18
	addz.l	r5, r63, r19
	addz.l	r4, r63, r4
	shlli	r19, 31, r19
	shlli	r18, 31, r18
LOCAL(udivsi3_loop):
	bgtu	r19, r4, tr2
	or	r0, r18, r0
	sub	r4, r19, r4
LOCAL(udivsi3_dontadd):
	shlri	r18, 1, r18
	shlri	r19, 1, r19
	bnei	r18, 0, tr1
	blink	tr0, r63
#else
GLOBAL(udivsi3):
 // inputs: r4,r5
 // clobbered: r18,r19,r20,r21,r22,r25,tr0
 // result in r0.
 addz.l r5,r63,r22
 nsb r22,r0
 shlld r22,r0,r25
 shlri r25,48,r25
 movi 0xffffffffffffbb0c,r20 // shift count eqiv 76
 sub r20,r25,r21
 mmulfx.w r21,r21,r19
 mshflo.w r21,r63,r21
 ptabs r18,tr0
 mmulfx.w r25,r19,r19
 sub r20,r0,r0
 /* bubble */
 msub.w r21,r19,r19
 addi r19,-2,r21 /* It would be nice for scheduling to do this add to r21
		    before the msub.w, but we need a different value for
		    r19 to keep errors under control.  */
 mulu.l r4,r21,r18
 mmulfx.w r19,r19,r19
 shlli r21,15,r21
 shlrd r18,r0,r18
 mulu.l r18,r22,r20
 mmacnfx.wl r25,r19,r21
 /* bubble */
 sub r4,r20,r25

 mulu.l r25,r21,r19
 addi r0,14,r0
 /* bubble */
 shlrd r19,r0,r19
 mulu.l r19,r22,r20
 add r18,r19,r18
 /* bubble */
 sub.l r25,r20,r25

 mulu.l r25,r21,r19
 addz.l r25,r63,r25
 sub r25,r22,r25
 shlrd r19,r0,r19
 mulu.l r19,r22,r20
 addi r25,1,r25
 add r18,r19,r18

 cmpgt r25,r20,r25
 add.l r18,r25,r0
 blink tr0,r63
#endif
#elif __SHMEDIA__
/* m5compact-nofpu - more emphasis on code size than on speed, but don't
   ignore speed altogether - div1 needs 9 cycles, subc 7 and rotcl 4.
   So use a short shmedia loop.  */
 // clobbered: r20,r21,r25,tr0,tr1,tr2
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
GLOBAL(udivsi3):
 pt/l LOCAL(udivsi3_dontsub), tr0
 pt/l LOCAL(udivsi3_loop), tr1
 ptabs/l r18,tr2
 shlli r5,32,r25
 addi r25,-1,r21
 addz.l r4,r63,r20
LOCAL(udivsi3_loop):
 shlli r20,1,r20
 bgeu/u r21,r20,tr0
 sub r20,r21,r20
LOCAL(udivsi3_dontsub):
 addi.l r25,-1,r25
 bnei r25,-32,tr1
 add.l r20,r63,r0
 blink tr2,r63
#else /* ! __SHMEDIA__ */
LOCAL(div8):
 div1 r5,r4
LOCAL(div7):
 div1 r5,r4; div1 r5,r4; div1 r5,r4
 div1 r5,r4; div1 r5,r4; div1 r5,r4; rts; div1 r5,r4

LOCAL(divx4):
 div1 r5,r4; rotcl r0
 div1 r5,r4; rotcl r0
 div1 r5,r4; rotcl r0
 rts; div1 r5,r4

GLOBAL(udivsi3):
 sts.l pr,@-r15
 extu.w r5,r0
 cmp/eq r5,r0
#ifdef __sh1__
 bf LOCAL(large_divisor)
#else
 bf/s LOCAL(large_divisor)
#endif
 div0u
 swap.w r4,r0
 shlr16 r4
 bsr LOCAL(div8)
 shll16 r5
 bsr LOCAL(div7)
 div1 r5,r4
 xtrct r4,r0
 xtrct r0,r4
 bsr LOCAL(div8)
 swap.w r4,r4
 bsr LOCAL(div7)
 div1 r5,r4
 lds.l @r15+,pr
 xtrct r4,r0
 swap.w r0,r0
 rotcl r0
 rts
 shlr16 r5

LOCAL(large_divisor):
#ifdef __sh1__
 div0u
#endif
 mov #0,r0
 xtrct r4,r0
 xtrct r0,r4
 bsr LOCAL(divx4)
 rotcl r0
 bsr LOCAL(divx4)
 rotcl r0
 bsr LOCAL(divx4)
 rotcl r0
 bsr LOCAL(divx4)
 rotcl r0
 lds.l @r15+,pr
 rts
 rotcl r0

	ENDFUNC(GLOBAL(udivsi3))
#endif /* ! __SHMEDIA__ */
#endif /* L_udivsi3 */

#ifdef L_udivdi3
#if __SHMEDIA__
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	.global	GLOBAL(udivdi3)
	FUNC(GLOBAL(udivdi3))
GLOBAL(udivdi3):
	HIDDEN_ALIAS(udivdi3_internal,udivdi3)
	shlri r3,1,r4
	nsb r4,r22
	shlld r3,r22,r6
	shlri r6,49,r5
	movi 0xffffffffffffbaf1,r21 /* .l shift count 17.  */
	sub r21,r5,r1
	mmulfx.w r1,r1,r4
	mshflo.w r1,r63,r1
	sub r63,r22,r20 // r63 == 64 % 64
	mmulfx.w r5,r4,r4
	pta LOCAL(large_divisor),tr0
	addi r20,32,r9
	msub.w r1,r4,r1
	madd.w r1,r1,r1
	mmulfx.w r1,r1,r4
	shlri r6,32,r7
	bgt/u r9,r63,tr0 // large_divisor
	mmulfx.w r5,r4,r4
	shlri r2,32+14,r19
	addi r22,-31,r0
	msub.w r1,r4,r1

	mulu.l r1,r7,r4
	addi r1,-3,r5
	mulu.l r5,r19,r5
	sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
	shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
	                 the case may be, %0000000000000000 000.11111111111, still */
	muls.l r1,r4,r4 /* leaving at least one sign bit.  */
	mulu.l r5,r3,r8
	mshalds.l r1,r21,r1
	shari r4,26,r4
	shlld r8,r0,r8
	add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
	sub r2,r8,r2
	/* Can do second step of 64 : 32 div now, using r1 and the rest in r2.  */

	shlri r2,22,r21
	mulu.l r21,r1,r21
	shlld r5,r0,r8
	addi r20,30-22,r0
	shlrd r21,r0,r21
	mulu.l r21,r3,r5
	add r8,r21,r8
	mcmpgt.l r21,r63,r21 // See Note 1
	addi r20,30,r0
	mshfhi.l r63,r21,r21
	sub r2,r5,r2
	andc r2,r21,r2

	/* small divisor: need a third divide step */
	mulu.l r2,r1,r7
	ptabs r18,tr0
	addi r2,1,r2
	shlrd r7,r0,r7
	mulu.l r7,r3,r5
	add r8,r7,r8
	sub r2,r3,r2
	cmpgt r2,r5,r5
	add r8,r5,r2
	/* could test r3 here to check for divide by zero.  */
	blink tr0,r63

LOCAL(large_divisor):
	mmulfx.w r5,r4,r4
	shlrd r2,r9,r25
	shlri r25,32,r8
	msub.w r1,r4,r1

	mulu.l r1,r7,r4
	addi r1,-3,r5
	mulu.l r5,r8,r5
	sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
	shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
	                 the case may be, %0000000000000000 000.11111111111, still */
	muls.l r1,r4,r4 /* leaving at least one sign bit.  */
	shlri r5,14-1,r8
	mulu.l r8,r7,r5
	mshalds.l r1,r21,r1
	shari r4,26,r4
	add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
	sub r25,r5,r25
	/* Can do second step of 64 : 32 div now, using r1 and the rest in r25.  */

	shlri r25,22,r21
	mulu.l r21,r1,r21
	pta LOCAL(no_lo_adj),tr0
	addi r22,32,r0
	shlri r21,40,r21
	mulu.l r21,r7,r5
	add r8,r21,r8
	shlld r2,r0,r2
	sub r25,r5,r25
	bgtu/u r7,r25,tr0 // no_lo_adj
	addi r8,1,r8
	sub r25,r7,r25
LOCAL(no_lo_adj):
	mextr4 r2,r25,r2

	/* large_divisor: only needs a few adjustments.  */
	mulu.l r8,r6,r5
	ptabs r18,tr0
	/* bubble */
	cmpgtu r5,r2,r5
	sub r8,r5,r2
	blink tr0,r63
	ENDFUNC(GLOBAL(udivdi3))
/* Note 1: To shift the result of the second divide stage so that the result
   always fits into 32 bits, yet we still reduce the rest sufficiently
   would require a lot of instructions to do the shifts just right.  Using
   the full 64 bit shift result to multiply with the divisor would require
   four extra instructions for the upper 32 bits (shift / mulu / shift / sub).
   Fortunately, if the upper 32 bits of the shift result are nonzero, we
   know that the rest after taking this partial result into account will
   fit into 32 bits.  So we just clear the upper 32 bits of the rest if the
   upper 32 bits of the partial result are nonzero.  */
#endif /* __SHMEDIA__ */
#endif /* L_udivdi3 */

#ifdef L_divdi3
#if __SHMEDIA__
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	.global	GLOBAL(divdi3)
	FUNC(GLOBAL(divdi3))
GLOBAL(divdi3):
	pta GLOBAL(udivdi3_internal),tr0
	shari r2,63,r22
	shari r3,63,r23
	xor r2,r22,r2
	xor r3,r23,r3
	sub r2,r22,r2
	sub r3,r23,r3
	beq/u r22,r23,tr0
	ptabs r18,tr1
	blink tr0,r18
	sub r63,r2,r2
	blink tr1,r63
	ENDFUNC(GLOBAL(divdi3))
#endif /* __SHMEDIA__ */
#endif /* L_divdi3 */

#ifdef L_umoddi3
#if __SHMEDIA__
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	.global	GLOBAL(umoddi3)
	FUNC(GLOBAL(umoddi3))
GLOBAL(umoddi3):
	HIDDEN_ALIAS(umoddi3_internal,umoddi3)
	shlri r3,1,r4
	nsb r4,r22
	shlld r3,r22,r6
	shlri r6,49,r5
	movi 0xffffffffffffbaf1,r21 /* .l shift count 17.  */
	sub r21,r5,r1
	mmulfx.w r1,r1,r4
	mshflo.w r1,r63,r1
	sub r63,r22,r20 // r63 == 64 % 64
	mmulfx.w r5,r4,r4
	pta LOCAL(large_divisor),tr0
	addi r20,32,r9
	msub.w r1,r4,r1
	madd.w r1,r1,r1
	mmulfx.w r1,r1,r4
	shlri r6,32,r7
	bgt/u r9,r63,tr0 // large_divisor
	mmulfx.w r5,r4,r4
	shlri r2,32+14,r19
	addi r22,-31,r0
	msub.w r1,r4,r1

	mulu.l r1,r7,r4
	addi r1,-3,r5
	mulu.l r5,r19,r5
	sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
	shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
	                 the case may be, %0000000000000000 000.11111111111, still */
	muls.l r1,r4,r4 /* leaving at least one sign bit.  */
	mulu.l r5,r3,r5
	mshalds.l r1,r21,r1
	shari r4,26,r4
	shlld r5,r0,r5
	add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
	sub r2,r5,r2
	/* Can do second step of 64 : 32 div now, using r1 and the rest in r2.  */

	shlri r2,22,r21
	mulu.l r21,r1,r21
	addi r20,30-22,r0
	/* bubble */ /* could test r3 here to check for divide by zero.  */
	shlrd r21,r0,r21
	mulu.l r21,r3,r5
	mcmpgt.l r21,r63,r21 // See Note 1
	addi r20,30,r0
	mshfhi.l r63,r21,r21
	sub r2,r5,r2
	andc r2,r21,r2

	/* small divisor: need a third divide step */
	mulu.l r2,r1,r7
	ptabs r18,tr0
	sub r2,r3,r8 /* re-use r8 here for rest - r3 */
	shlrd r7,r0,r7
	mulu.l r7,r3,r5
	/* bubble */
	addi r8,1,r7
	cmpgt r7,r5,r7
	cmvne r7,r8,r2
	sub r2,r5,r2
	blink tr0,r63

LOCAL(large_divisor):
	mmulfx.w r5,r4,r4
	shlrd r2,r9,r25
	shlri r25,32,r8
	msub.w r1,r4,r1

	mulu.l r1,r7,r4
	addi r1,-3,r5
	mulu.l r5,r8,r5
	sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
	shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
	                 the case may be, %0000000000000000 000.11111111111, still */
	muls.l r1,r4,r4 /* leaving at least one sign bit.  */
	shlri r5,14-1,r8
	mulu.l r8,r7,r5
	mshalds.l r1,r21,r1
	shari r4,26,r4
	add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
	sub r25,r5,r25
	/* Can do second step of 64 : 32 div now, using r1 and the rest in r25.  */

	shlri r25,22,r21
	mulu.l r21,r1,r21
	pta LOCAL(no_lo_adj),tr0
	addi r22,32,r0
	shlri r21,40,r21
	mulu.l r21,r7,r5
	add r8,r21,r8
	shlld r2,r0,r2
	sub r25,r5,r25
	bgtu/u r7,r25,tr0 // no_lo_adj
	addi r8,1,r8
	sub r25,r7,r25
LOCAL(no_lo_adj):
	mextr4 r2,r25,r2

	/* large_divisor: only needs a few adjustments.  */
	mulu.l r8,r6,r5
	ptabs r18,tr0
	add r2,r6,r7
	cmpgtu r5,r2,r8
	cmvne r8,r7,r2
	sub r2,r5,r2
	shlrd r2,r22,r2
	blink tr0,r63
	ENDFUNC(GLOBAL(umoddi3))
/* Note 1: To shift the result of the second divide stage so that the result
   always fits into 32 bits, yet we still reduce the rest sufficiently
   would require a lot of instructions to do the shifts just right.  Using
   the full 64 bit shift result to multiply with the divisor would require
   four extra instructions for the upper 32 bits (shift / mulu / shift / sub).
   Fortunately, if the upper 32 bits of the shift result are nonzero, we
   know that the rest after taking this partial result into account will
   fit into 32 bits.  So we just clear the upper 32 bits of the rest if the
   upper 32 bits of the partial result are nonzero.  */
#endif /* __SHMEDIA__ */
#endif /* L_umoddi3 */

#ifdef L_moddi3
#if __SHMEDIA__
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	.global	GLOBAL(moddi3)
	FUNC(GLOBAL(moddi3))
GLOBAL(moddi3):
	pta GLOBAL(umoddi3_internal),tr0
	shari r2,63,r22
	shari r3,63,r23
	xor r2,r22,r2
	xor r3,r23,r3
	sub r2,r22,r2
	sub r3,r23,r3
	beq/u r22,r63,tr0
	ptabs r18,tr1
	blink tr0,r18
	sub r63,r2,r2
	blink tr1,r63
	ENDFUNC(GLOBAL(moddi3))
#endif /* __SHMEDIA__ */
#endif /* L_moddi3 */

#ifdef L_set_fpscr
#if !defined (__SH2A_NOFPU__)
#if defined (__SH2E__) || defined (__SH2A__) || defined (__SH3E__) || defined(__SH4_SINGLE__) || defined(__SH4__) || defined(__SH4_SINGLE_ONLY__) || __SH5__ == 32
#ifdef __SH5__
	.mode	SHcompact
#endif
	.global GLOBAL(set_fpscr)
	HIDDEN_FUNC(GLOBAL(set_fpscr))
GLOBAL(set_fpscr):
	lds r4,fpscr
#ifdef __PIC__
	mov.l	r12,@-r15
#ifdef __vxworks
	mov.l	LOCAL(set_fpscr_L0_base),r12
	mov.l	LOCAL(set_fpscr_L0_index),r0
	mov.l	@r12,r12
	mov.l	@(r0,r12),r12
#else
	mova	LOCAL(set_fpscr_L0),r0
	mov.l	LOCAL(set_fpscr_L0),r12
	add	r0,r12
#endif
	mov.l	LOCAL(set_fpscr_L1),r0
	mov.l	@(r0,r12),r1
	mov.l	@r15+,r12
#else
	mov.l LOCAL(set_fpscr_L1),r1
#endif
	swap.w r4,r0
	or #24,r0
#ifndef FMOVD_WORKS
	xor #16,r0
#endif
#if defined(__SH4__) || defined (__SH2A_DOUBLE__)
	swap.w r0,r3
	mov.l r3,@(4,r1)
#else /* defined (__SH2E__) || defined(__SH3E__) || defined(__SH4_SINGLE*__) */
	swap.w r0,r2
	mov.l r2,@r1
#endif
#ifndef FMOVD_WORKS
	xor #8,r0
#else
	xor #24,r0
#endif
#if defined(__SH4__) || defined (__SH2A_DOUBLE__)
	swap.w r0,r2
	rts
	mov.l r2,@r1
#else /* defined(__SH2E__) || defined(__SH3E__) || defined(__SH4_SINGLE*__) */
	swap.w r0,r3
	rts
	mov.l r3,@(4,r1)
#endif
	.align 2
#ifdef __PIC__
#ifdef __vxworks
LOCAL(set_fpscr_L0_base):
	.long ___GOTT_BASE__
LOCAL(set_fpscr_L0_index):
	.long ___GOTT_INDEX__
#else
LOCAL(set_fpscr_L0):
	.long _GLOBAL_OFFSET_TABLE_
#endif
LOCAL(set_fpscr_L1):
	.long GLOBAL(fpscr_values@GOT)
#else
LOCAL(set_fpscr_L1):
	.long GLOBAL(fpscr_values)
#endif

	ENDFUNC(GLOBAL(set_fpscr))
#ifndef NO_FPSCR_VALUES
#ifdef __ELF__
        .comm   GLOBAL(fpscr_values),8,4
#else
        .comm   GLOBAL(fpscr_values),8
#endif /* ELF */
#endif /* NO_FPSCR_VALUES */
#endif /* SH2E / SH3E / SH4 */
#endif /* __SH2A_NOFPU__ */
#endif /* L_set_fpscr */
#ifdef L_ic_invalidate
#if __SH5__ == 32
	.mode	SHmedia
	.section	.text..SHmedia32,"ax"
	.align	2
	.global	GLOBAL(init_trampoline)
	HIDDEN_FUNC(GLOBAL(init_trampoline))
GLOBAL(init_trampoline):
	st.l	r0,8,r2
#ifdef __LITTLE_ENDIAN__
	movi	9,r20
	shori	0x402b,r20
	shori	0xd101,r20
	shori	0xd002,r20
#else
	movi	0xffffffffffffd002,r20
	shori	0xd101,r20
	shori	0x402b,r20
	shori	9,r20
#endif
	st.q	r0,0,r20
	st.l	r0,12,r3
	ENDFUNC(GLOBAL(init_trampoline))
	.global	GLOBAL(ic_invalidate)
	HIDDEN_FUNC(GLOBAL(ic_invalidate))
GLOBAL(ic_invalidate):
	ocbwb	r0,0
	synco
	icbi	r0, 0
	ptabs	r18, tr0
	synci
	blink	tr0, r63
	ENDFUNC(GLOBAL(ic_invalidate))
#elif defined(__SH4A__)
	.global GLOBAL(ic_invalidate)
	HIDDEN_FUNC(GLOBAL(ic_invalidate))
GLOBAL(ic_invalidate):
	ocbwb	@r4
	synco
	icbi	@r4
	rts
	  nop
	ENDFUNC(GLOBAL(ic_invalidate))
#elif defined(__SH4_SINGLE__) || defined(__SH4__) || defined(__SH4_SINGLE_ONLY__) || (defined(__SH4_NOFPU__) && !defined(__SH5__))
	/* For system code, we use ic_invalidate_line_i, but user code
	   needs a different mechanism.  A kernel call is generally not
	   available, and it would also be slow.  Different SH4 variants use
	   different sizes and associativities of the Icache.  We use a small
	   bit of dispatch code that can be put hidden in every shared object,
	   which calls the actual processor-specific invalidation code in a
	   separate module.
	   Or if you have operating system support, the OS could mmap the
	   procesor-specific code from a single page, since it is highly
	   repetitive.  */
	.global GLOBAL(ic_invalidate)
	HIDDEN_FUNC(GLOBAL(ic_invalidate))
GLOBAL(ic_invalidate):
#ifdef __pic__
#ifdef __vxworks
	mov.l	1f,r1
	mov.l	2f,r0
	mov.l	@r1,r1
	mov.l	0f,r2
	mov.l	@(r0,r1),r0
#else
	mov.l	1f,r1
	mova	1f,r0
	mov.l	0f,r2
	add	r1,r0
#endif
	mov.l	@(r0,r2),r1
#else
	mov.l	0f,r1
#endif
	ocbwb	@r4
	mov.l	@(8,r1),r0
	sub	r1,r4
	and	r4,r0
	add	r1,r0
	jmp	@r0
	mov.l	@(4,r1),r0
	.align	2
#ifndef __pic__
0:	.long   GLOBAL(ic_invalidate_array)
#else /* __pic__ */
	.global GLOBAL(ic_invalidate_array)
0:	.long   GLOBAL(ic_invalidate_array)@GOT
#ifdef __vxworks
1:	.long	___GOTT_BASE__
2:	.long	___GOTT_INDEX__
#else
1:	.long   _GLOBAL_OFFSET_TABLE_
#endif
	ENDFUNC(GLOBAL(ic_invalidate))
#endif /* __pic__ */
#endif /* SH4 */
#endif /* L_ic_invalidate */

#ifdef L_ic_invalidate_array
#if defined(__SH4A__) || (defined (__FORCE_SH4A__) && (defined(__SH4_SINGLE__) || defined(__SH4__) || defined(__SH4_SINGLE_ONLY__) || (defined(__SH4_NOFPU__) && !defined(__SH5__))))
	.global GLOBAL(ic_invalidate_array)
	/* This is needed when an SH4 dso with trampolines is used on SH4A.  */
	.global GLOBAL(ic_invalidate_array)
	FUNC(GLOBAL(ic_invalidate_array))
GLOBAL(ic_invalidate_array):
	add	r1,r4
	synco
	icbi	@r4
	rts
	  nop
	.align 2
	.long	0
	ENDFUNC(GLOBAL(ic_invalidate_array))
#elif defined(__SH4_SINGLE__) || defined(__SH4__) || defined(__SH4_SINGLE_ONLY__) || (defined(__SH4_NOFPU__) && !defined(__SH5__))
	.global GLOBAL(ic_invalidate_array)
	.p2align 5
	FUNC(GLOBAL(ic_invalidate_array))
/* This must be aligned to the beginning of a cache line.  */
GLOBAL(ic_invalidate_array):
#ifndef WAYS
#define WAYS 4
#define WAY_SIZE 0x4000
#endif
#if WAYS == 1
	.rept	WAY_SIZE * WAYS / 32
	rts
	nop
	.rept	7
	.long	WAY_SIZE - 32
	.endr
	.endr
#elif WAYS <= 6
	.rept	WAY_SIZE * WAYS / 32
	braf	r0
	add	#-8,r0
	.long	WAY_SIZE + 8
	.long	WAY_SIZE - 32
	.rept	WAYS-2
	braf	r0
	nop
	.endr
	.rept	7 - WAYS
	rts
	nop
	.endr
	.endr
#else /* WAYS > 6 */
	/* This variant needs two different pages for mmap-ing.  */
 	.rept	WAYS-1
	.rept	WAY_SIZE / 32
	braf	r0
	nop
	.long	WAY_SIZE
	.rept 6
	.long	WAY_SIZE - 32
	.endr
	.endr
	.endr
	.rept	WAY_SIZE / 32
	rts
	.rept	15
	nop
	.endr
	.endr
#endif /* WAYS */
	ENDFUNC(GLOBAL(ic_invalidate_array))
#endif /* SH4 */
#endif /* L_ic_invalidate_array */

#if defined (__SH5__) && __SH5__ == 32
#ifdef L_shcompact_call_trampoline
	.section	.rodata
	.align	1
LOCAL(ct_main_table):
.word	LOCAL(ct_r2_fp) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r2_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r2_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r3_fp) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r3_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r3_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r4_fp) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r4_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r4_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r5_fp) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r5_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r5_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r6_fph) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r6_fpl) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r6_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r6_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r7_fph) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r7_fpl) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r7_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r7_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r8_fph) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r8_fpl) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r8_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r8_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r9_fph) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r9_fpl) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r9_ld) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r9_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_pop_seq) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_pop_seq) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_r9_pop) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_ret_wide) - datalabel LOCAL(ct_main_label)
.word	LOCAL(ct_call_func) - datalabel LOCAL(ct_main_label)
	.mode	SHmedia
	.section	.text..SHmedia32, "ax"
	.align	2
	
     /* This function loads 64-bit general-purpose registers from the
	stack, from a memory address contained in them or from an FP
	register, according to a cookie passed in r1.  Its execution
	time is linear on the number of registers that actually have
	to be copied.  See sh.h for details on the actual bit pattern.

	The function to be called is passed in r0.  If a 32-bit return
	value is expected, the actual function will be tail-called,
	otherwise the return address will be stored in r10 (that the
	caller should expect to be clobbered) and the return value
	will be expanded into r2/r3 upon return.  */
	
	.global	GLOBAL(GCC_shcompact_call_trampoline)
	FUNC(GLOBAL(GCC_shcompact_call_trampoline))
GLOBAL(GCC_shcompact_call_trampoline):
	ptabs/l	r0, tr0	/* Prepare to call the actual function.  */
	movi	((datalabel LOCAL(ct_main_table) - 31 * 2) >> 16) & 65535, r0
	pt/l	LOCAL(ct_loop), tr1
	addz.l	r1, r63, r1
	shori	((datalabel LOCAL(ct_main_table) - 31 * 2)) & 65535, r0
LOCAL(ct_loop):
	nsb	r1, r28
	shlli	r28, 1, r29
	ldx.w	r0, r29, r30
LOCAL(ct_main_label):
	ptrel/l	r30, tr2
	blink	tr2, r63
LOCAL(ct_r2_fp):	/* Copy r2 from an FP register.  */
	/* It must be dr0, so just do it.  */
	fmov.dq	dr0, r2
	movi	7, r30
	shlli	r30, 29, r31
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r3_fp):	/* Copy r3 from an FP register.  */
	/* It is either dr0 or dr2.  */
	movi	7, r30
	shlri	r1, 26, r32
	shlli	r30, 26, r31
	andc	r1, r31, r1
	fmov.dq	dr0, r3
	beqi/l	r32, 4, tr1
	fmov.dq	dr2, r3
	blink	tr1, r63
LOCAL(ct_r4_fp):	/* Copy r4 from an FP register.  */
	shlri	r1, 23 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r4_fp_copy) - datalabel LOCAL(ct_r4_fp_base), r32
LOCAL(ct_r4_fp_base):
	ptrel/l	r32, tr2
	movi	7, r30
	shlli	r30, 23, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r4_fp_copy):
	fmov.dq	dr0, r4
	blink	tr1, r63
	fmov.dq	dr2, r4
	blink	tr1, r63
	fmov.dq	dr4, r4
	blink	tr1, r63
LOCAL(ct_r5_fp):	/* Copy r5 from an FP register.  */
	shlri	r1, 20 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r5_fp_copy) - datalabel LOCAL(ct_r5_fp_base), r32
LOCAL(ct_r5_fp_base):
	ptrel/l	r32, tr2
	movi	7, r30
	shlli	r30, 20, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r5_fp_copy):
	fmov.dq	dr0, r5
	blink	tr1, r63
	fmov.dq	dr2, r5
	blink	tr1, r63
	fmov.dq	dr4, r5
	blink	tr1, r63
	fmov.dq	dr6, r5
	blink	tr1, r63
LOCAL(ct_r6_fph):	/* Copy r6 from a high FP register.  */
	/* It must be dr8.  */
	fmov.dq	dr8, r6
	movi	15, r30
	shlli	r30, 16, r31
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r6_fpl):	/* Copy r6 from a low FP register.  */
	shlri	r1, 16 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r6_fp_copy) - datalabel LOCAL(ct_r6_fp_base), r32
LOCAL(ct_r6_fp_base):
	ptrel/l	r32, tr2
	movi	7, r30
	shlli	r30, 16, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r6_fp_copy):
	fmov.dq	dr0, r6
	blink	tr1, r63
	fmov.dq	dr2, r6
	blink	tr1, r63
	fmov.dq	dr4, r6
	blink	tr1, r63
	fmov.dq	dr6, r6
	blink	tr1, r63
LOCAL(ct_r7_fph):	/* Copy r7 from a high FP register.  */
	/* It is either dr8 or dr10.  */
	movi	15 << 12, r31
	shlri	r1, 12, r32
	andc	r1, r31, r1
	fmov.dq	dr8, r7
	beqi/l	r32, 8, tr1
	fmov.dq	dr10, r7
	blink	tr1, r63
LOCAL(ct_r7_fpl):	/* Copy r7 from a low FP register.  */
	shlri	r1, 12 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r7_fp_copy) - datalabel LOCAL(ct_r7_fp_base), r32
LOCAL(ct_r7_fp_base):
	ptrel/l	r32, tr2
	movi	7 << 12, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r7_fp_copy):
	fmov.dq	dr0, r7
	blink	tr1, r63
	fmov.dq	dr2, r7
	blink	tr1, r63
	fmov.dq	dr4, r7
	blink	tr1, r63
	fmov.dq	dr6, r7
	blink	tr1, r63
LOCAL(ct_r8_fph):	/* Copy r8 from a high FP register.  */
	/* It is either dr8 or dr10.  */
	movi	15 << 8, r31
	andi	r1, 1 << 8, r32
	andc	r1, r31, r1
	fmov.dq	dr8, r8
	beq/l	r32, r63, tr1
	fmov.dq	dr10, r8
	blink	tr1, r63
LOCAL(ct_r8_fpl):	/* Copy r8 from a low FP register.  */
	shlri	r1, 8 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r8_fp_copy) - datalabel LOCAL(ct_r8_fp_base), r32
LOCAL(ct_r8_fp_base):
	ptrel/l	r32, tr2
	movi	7 << 8, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r8_fp_copy):
	fmov.dq	dr0, r8
	blink	tr1, r63
	fmov.dq	dr2, r8
	blink	tr1, r63
	fmov.dq	dr4, r8
	blink	tr1, r63
	fmov.dq	dr6, r8
	blink	tr1, r63
LOCAL(ct_r9_fph):	/* Copy r9 from a high FP register.  */
	/* It is either dr8 or dr10.  */
	movi	15 << 4, r31
	andi	r1, 1 << 4, r32
	andc	r1, r31, r1
	fmov.dq	dr8, r9
	beq/l	r32, r63, tr1
	fmov.dq	dr10, r9
	blink	tr1, r63
LOCAL(ct_r9_fpl):	/* Copy r9 from a low FP register.  */
	shlri	r1, 4 - 3, r34
	andi	r34, 3 << 3, r33
	addi	r33, LOCAL(ct_r9_fp_copy) - datalabel LOCAL(ct_r9_fp_base), r32
LOCAL(ct_r9_fp_base):
	ptrel/l	r32, tr2
	movi	7 << 4, r31
	andc	r1, r31, r1
	blink	tr2, r63
LOCAL(ct_r9_fp_copy):
	fmov.dq	dr0, r9
	blink	tr1, r63
	fmov.dq	dr2, r9
	blink	tr1, r63
	fmov.dq	dr4, r9
	blink	tr1, r63
	fmov.dq	dr6, r9
	blink	tr1, r63
LOCAL(ct_r2_ld):	/* Copy r2 from a memory address.  */
	pt/l	LOCAL(ct_r2_load), tr2
	movi	3, r30
	shlli	r30, 29, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r2, 8, r3
	ldx.q	r2, r63, r2
	/* Fall through.  */
LOCAL(ct_r3_ld):	/* Copy r3 from a memory address.  */
	pt/l	LOCAL(ct_r3_load), tr2
	movi	3, r30
	shlli	r30, 26, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r3, 8, r4
	ldx.q	r3, r63, r3
LOCAL(ct_r4_ld):	/* Copy r4 from a memory address.  */
	pt/l	LOCAL(ct_r4_load), tr2
	movi	3, r30
	shlli	r30, 23, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r4, 8, r5
	ldx.q	r4, r63, r4
LOCAL(ct_r5_ld):	/* Copy r5 from a memory address.  */
	pt/l	LOCAL(ct_r5_load), tr2
	movi	3, r30
	shlli	r30, 20, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r5, 8, r6
	ldx.q	r5, r63, r5
LOCAL(ct_r6_ld):	/* Copy r6 from a memory address.  */
	pt/l	LOCAL(ct_r6_load), tr2
	movi	3 << 16, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r6, 8, r7
	ldx.q	r6, r63, r6
LOCAL(ct_r7_ld):	/* Copy r7 from a memory address.  */
	pt/l	LOCAL(ct_r7_load), tr2
	movi	3 << 12, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r7, 8, r8
	ldx.q	r7, r63, r7
LOCAL(ct_r8_ld):	/* Copy r8 from a memory address.  */
	pt/l	LOCAL(ct_r8_load), tr2
	movi	3 << 8, r31
	and	r1, r31, r32
	andc	r1, r31, r1
	beq/l	r31, r32, tr2
	addi.l	r8, 8, r9
	ldx.q	r8, r63, r8
LOCAL(ct_r9_ld):	/* Copy r9 from a memory address.  */
	pt/l	LOCAL(ct_check_tramp), tr2
	ldx.q	r9, r63, r9
	blink	tr2, r63
LOCAL(ct_r2_load):
	ldx.q	r2, r63, r2
	blink	tr1, r63
LOCAL(ct_r3_load):
	ldx.q	r3, r63, r3
	blink	tr1, r63
LOCAL(ct_r4_load):
	ldx.q	r4, r63, r4
	blink	tr1, r63
LOCAL(ct_r5_load):
	ldx.q	r5, r63, r5
	blink	tr1, r63
LOCAL(ct_r6_load):
	ldx.q	r6, r63, r6
	blink	tr1, r63
LOCAL(ct_r7_load):
	ldx.q	r7, r63, r7
	blink	tr1, r63
LOCAL(ct_r8_load):
	ldx.q	r8, r63, r8
	blink	tr1, r63
LOCAL(ct_r2_pop):	/* Pop r2 from the stack.  */
	movi	1, r30
	ldx.q	r15, r63, r2
	shlli	r30, 29, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r3_pop):	/* Pop r3 from the stack.  */
	movi	1, r30
	ldx.q	r15, r63, r3
	shlli	r30, 26, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r4_pop):	/* Pop r4 from the stack.  */
	movi	1, r30
	ldx.q	r15, r63, r4
	shlli	r30, 23, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r5_pop):	/* Pop r5 from the stack.  */
	movi	1, r30
	ldx.q	r15, r63, r5
	shlli	r30, 20, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r6_pop):	/* Pop r6 from the stack.  */
	movi	1, r30
	ldx.q	r15, r63, r6
	shlli	r30, 16, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r7_pop):	/* Pop r7 from the stack.  */
	ldx.q	r15, r63, r7
	movi	1 << 12, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_r8_pop):	/* Pop r8 from the stack.  */
	ldx.q	r15, r63, r8
	movi	1 << 8, r31
	addi.l	r15, 8, r15
	andc	r1, r31, r1
	blink	tr1, r63
LOCAL(ct_pop_seq):	/* Pop a sequence of registers off the stack.  */
	andi	r1, 7 << 1, r30
	movi	(LOCAL(ct_end_of_pop_seq) >> 16) & 65535, r32
	shlli	r30, 2, r31
	shori	LOCAL(ct_end_of_pop_seq) & 65535, r32
	sub.l	r32, r31, r33
	ptabs/l	r33, tr2
	blink	tr2, r63
LOCAL(ct_start_of_pop_seq):	/* Beginning of pop sequence.  */
	ldx.q	r15, r63, r3
	addi.l	r15, 8, r15
	ldx.q	r15, r63, r4
	addi.l	r15, 8, r15
	ldx.q	r15, r63, r5
	addi.l	r15, 8, r15
	ldx.q	r15, r63, r6
	addi.l	r15, 8, r15
	ldx.q	r15, r63, r7
	addi.l	r15, 8, r15
	ldx.q	r15, r63, r8
	addi.l	r15, 8, r15
LOCAL(ct_r9_pop):	/* Pop r9 from the stack.  */
	ldx.q	r15, r63, r9
	addi.l	r15, 8, r15
LOCAL(ct_end_of_pop_seq): /* Label used to compute first pop instruction.  */
LOCAL(ct_check_tramp):	/* Check whether we need a trampoline.  */
	pt/u	LOCAL(ct_ret_wide), tr2
	andi	r1, 1, r1
	bne/u	r1, r63, tr2
LOCAL(ct_call_func):	/* Just branch to the function.  */
	blink	tr0, r63
LOCAL(ct_ret_wide):	/* Call the function, so that we can unpack its 
			   64-bit return value.  */
	add.l	r18, r63, r10
	blink	tr0, r18
	ptabs	r10, tr0
#if __LITTLE_ENDIAN__
	shari	r2, 32, r3
	add.l	r2, r63, r2
#else
	add.l	r2, r63, r3
	shari	r2, 32, r2
#endif
	blink	tr0, r63

	ENDFUNC(GLOBAL(GCC_shcompact_call_trampoline))
#endif /* L_shcompact_call_trampoline */

#ifdef L_shcompact_return_trampoline
     /* This function does the converse of the code in `ret_wide'
	above.  It is tail-called by SHcompact functions returning
	64-bit non-floating-point values, to pack the 32-bit values in
	r2 and r3 into r2.  */

	.mode	SHmedia
	.section	.text..SHmedia32, "ax"
	.align	2
	.global	GLOBAL(GCC_shcompact_return_trampoline)
	HIDDEN_FUNC(GLOBAL(GCC_shcompact_return_trampoline))
GLOBAL(GCC_shcompact_return_trampoline):
	ptabs/l	r18, tr0
#if __LITTLE_ENDIAN__
	addz.l	r2, r63, r2
	shlli	r3, 32, r3
#else
	addz.l	r3, r63, r3
	shlli	r2, 32, r2
#endif
	or	r3, r2, r2
	blink	tr0, r63

	ENDFUNC(GLOBAL(GCC_shcompact_return_trampoline))
#endif /* L_shcompact_return_trampoline */

#ifdef L_shcompact_incoming_args
	.section	.rodata
	.align	1
LOCAL(ia_main_table):
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r2_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r2_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r3_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r3_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r4_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r4_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r5_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r5_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r6_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r6_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r7_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r7_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r8_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r8_push) - datalabel LOCAL(ia_main_label)
.word	1 /* Invalid, just loop */
.word	1 /* Invalid, just loop */
.word	LOCAL(ia_r9_ld) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r9_push) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_push_seq) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_push_seq) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_r9_push) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_return) - datalabel LOCAL(ia_main_label)
.word	LOCAL(ia_return) - datalabel LOCAL(ia_main_label)
	.mode	SHmedia
	.section	.text..SHmedia32, "ax"
	.align	2
	
     /* This function stores 64-bit general-purpose registers back in
	the stack, and loads the address in which each register
	was stored into itself.  The lower 32 bits of r17 hold the address
	to begin storing, and the upper 32 bits of r17 hold the cookie.
	Its execution time is linear on the
	number of registers that actually have to be copied, and it is
	optimized for structures larger than 64 bits, as opposed to
	individual `long long' arguments.  See sh.h for details on the
	actual bit pattern.  */
	
	.global	GLOBAL(GCC_shcompact_incoming_args)
 	FUNC(GLOBAL(GCC_shcompact_incoming_args))
GLOBAL(GCC_shcompact_incoming_args):
	ptabs/l	r18, tr0	/* Prepare to return.  */
	shlri	r17, 32, r0	/* Load the cookie.  */
	movi	((datalabel LOCAL(ia_main_table) - 31 * 2) >> 16) & 65535, r43
	pt/l	LOCAL(ia_loop), tr1
	add.l	r17, r63, r17
	shori	((datalabel LOCAL(ia_main_table) - 31 * 2)) & 65535, r43
LOCAL(ia_loop):
	nsb	r0, r36
	shlli	r36, 1, r37
	ldx.w	r43, r37, r38
LOCAL(ia_main_label):
	ptrel/l	r38, tr2
	blink	tr2, r63
LOCAL(ia_r2_ld):	/* Store r2 and load its address.  */
	movi	3, r38
	shlli	r38, 29, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r2
	add.l	r17, r63, r2
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r3_ld):	/* Store r3 and load its address.  */
	movi	3, r38
	shlli	r38, 26, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r3
	add.l	r17, r63, r3
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r4_ld):	/* Store r4 and load its address.  */
	movi	3, r38
	shlli	r38, 23, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r4
	add.l	r17, r63, r4
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r5_ld):	/* Store r5 and load its address.  */
	movi	3, r38
	shlli	r38, 20, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r5
	add.l	r17, r63, r5
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r6_ld):	/* Store r6 and load its address.  */
	movi	3, r38
	shlli	r38, 16, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r6
	add.l	r17, r63, r6
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r7_ld):	/* Store r7 and load its address.  */
	movi	3 << 12, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r7
	add.l	r17, r63, r7
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r8_ld):	/* Store r8 and load its address.  */
	movi	3 << 8, r39
	and	r0, r39, r40
	andc	r0, r39, r0
	stx.q	r17, r63, r8
	add.l	r17, r63, r8
	addi.l	r17, 8, r17
	beq/u	r39, r40, tr1
LOCAL(ia_r9_ld):	/* Store r9 and load its address.  */
	stx.q	r17, r63, r9
	add.l	r17, r63, r9
	blink	tr0, r63
LOCAL(ia_r2_push):	/* Push r2 onto the stack.  */
	movi	1, r38
	shlli	r38, 29, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r2
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r3_push):	/* Push r3 onto the stack.  */
	movi	1, r38
	shlli	r38, 26, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r3
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r4_push):	/* Push r4 onto the stack.  */
	movi	1, r38
	shlli	r38, 23, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r4
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r5_push):	/* Push r5 onto the stack.  */
	movi	1, r38
	shlli	r38, 20, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r5
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r6_push):	/* Push r6 onto the stack.  */
	movi	1, r38
	shlli	r38, 16, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r6
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r7_push):	/* Push r7 onto the stack.  */
	movi	1 << 12, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r7
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_r8_push):	/* Push r8 onto the stack.  */
	movi	1 << 8, r39
	andc	r0, r39, r0
	stx.q	r17, r63, r8
	addi.l	r17, 8, r17
	blink	tr1, r63
LOCAL(ia_push_seq):	/* Push a sequence of registers onto the stack.  */
	andi	r0, 7 << 1, r38
	movi	(LOCAL(ia_end_of_push_seq) >> 16) & 65535, r40
	shlli	r38, 2, r39
	shori	LOCAL(ia_end_of_push_seq) & 65535, r40
	sub.l	r40, r39, r41
	ptabs/l	r41, tr2
	blink	tr2, r63
LOCAL(ia_stack_of_push_seq):	 /* Beginning of push sequence.  */
	stx.q	r17, r63, r3
	addi.l	r17, 8, r17
	stx.q	r17, r63, r4
	addi.l	r17, 8, r17
	stx.q	r17, r63, r5
	addi.l	r17, 8, r17
	stx.q	r17, r63, r6
	addi.l	r17, 8, r17
	stx.q	r17, r63, r7
	addi.l	r17, 8, r17
	stx.q	r17, r63, r8
	addi.l	r17, 8, r17
LOCAL(ia_r9_push):	/* Push r9 onto the stack.  */
	stx.q	r17, r63, r9
LOCAL(ia_return):	/* Return.  */
	blink	tr0, r63
LOCAL(ia_end_of_push_seq): /* Label used to compute the first push instruction.  */
	ENDFUNC(GLOBAL(GCC_shcompact_incoming_args))
#endif /* L_shcompact_incoming_args */
#endif
#if __SH5__
#ifdef L_nested_trampoline
#if __SH5__ == 32
	.section	.text..SHmedia32,"ax"
#else
	.text
#endif
	.align	3 /* It is copied in units of 8 bytes in SHmedia mode.  */
	.global	GLOBAL(GCC_nested_trampoline)
	HIDDEN_FUNC(GLOBAL(GCC_nested_trampoline))
GLOBAL(GCC_nested_trampoline):
	.mode	SHmedia
	ptrel/u	r63, tr0
	gettr	tr0, r0
#if __SH5__ == 64
	ld.q	r0, 24, r1
#else
	ld.l	r0, 24, r1
#endif
	ptabs/l	r1, tr1
#if __SH5__ == 64
	ld.q	r0, 32, r1
#else
	ld.l	r0, 28, r1
#endif
	blink	tr1, r63

	ENDFUNC(GLOBAL(GCC_nested_trampoline))
#endif /* L_nested_trampoline */
#endif /* __SH5__ */
#if __SH5__ == 32
#ifdef L_push_pop_shmedia_regs
	.section	.text..SHmedia32,"ax"
	.mode	SHmedia
	.align	2
#ifndef __SH4_NOFPU__	
	.global	GLOBAL(GCC_push_shmedia_regs)
	FUNC(GLOBAL(GCC_push_shmedia_regs))
GLOBAL(GCC_push_shmedia_regs):
	addi.l	r15, -14*8, r15
	fst.d	r15, 13*8, dr62
	fst.d	r15, 12*8, dr60
	fst.d	r15, 11*8, dr58
	fst.d	r15, 10*8, dr56
	fst.d	r15,  9*8, dr54
	fst.d	r15,  8*8, dr52
	fst.d	r15,  7*8, dr50
	fst.d	r15,  6*8, dr48
	fst.d	r15,  5*8, dr46
	fst.d	r15,  4*8, dr44
	fst.d	r15,  3*8, dr42
	fst.d	r15,  2*8, dr40
	fst.d	r15,  1*8, dr38
	fst.d	r15,  0*8, dr36
#else /* ! __SH4_NOFPU__ */
	.global	GLOBAL(GCC_push_shmedia_regs_nofpu)
	FUNC(GLOBAL(GCC_push_shmedia_regs_nofpu))
GLOBAL(GCC_push_shmedia_regs_nofpu):
#endif /* ! __SH4_NOFPU__ */
	ptabs/l	r18, tr0
	addi.l	r15, -27*8, r15
	gettr	tr7, r62
	gettr	tr6, r61
	gettr	tr5, r60
	st.q	r15, 26*8, r62
	st.q	r15, 25*8, r61
	st.q	r15, 24*8, r60
	st.q	r15, 23*8, r59
	st.q	r15, 22*8, r58
	st.q	r15, 21*8, r57
	st.q	r15, 20*8, r56
	st.q	r15, 19*8, r55
	st.q	r15, 18*8, r54
	st.q	r15, 17*8, r53
	st.q	r15, 16*8, r52
	st.q	r15, 15*8, r51
	st.q	r15, 14*8, r50
	st.q	r15, 13*8, r49
	st.q	r15, 12*8, r48
	st.q	r15, 11*8, r47
	st.q	r15, 10*8, r46
	st.q	r15,  9*8, r45
	st.q	r15,  8*8, r44
	st.q	r15,  7*8, r35
	st.q	r15,  6*8, r34
	st.q	r15,  5*8, r33
	st.q	r15,  4*8, r32
	st.q	r15,  3*8, r31
	st.q	r15,  2*8, r30
	st.q	r15,  1*8, r29
	st.q	r15,  0*8, r28
	blink	tr0, r63
#ifndef __SH4_NOFPU__	
	ENDFUNC(GLOBAL(GCC_push_shmedia_regs))
#else
	ENDFUNC(GLOBAL(GCC_push_shmedia_regs_nofpu))
#endif
#ifndef __SH4_NOFPU__	
	.global	GLOBAL(GCC_pop_shmedia_regs)
	FUNC(GLOBAL(GCC_pop_shmedia_regs))
GLOBAL(GCC_pop_shmedia_regs):
	pt	.L0, tr1
	movi	41*8, r0
	fld.d	r15, 40*8, dr62
	fld.d	r15, 39*8, dr60
	fld.d	r15, 38*8, dr58
	fld.d	r15, 37*8, dr56
	fld.d	r15, 36*8, dr54
	fld.d	r15, 35*8, dr52
	fld.d	r15, 34*8, dr50
	fld.d	r15, 33*8, dr48
	fld.d	r15, 32*8, dr46
	fld.d	r15, 31*8, dr44
	fld.d	r15, 30*8, dr42
	fld.d	r15, 29*8, dr40
	fld.d	r15, 28*8, dr38
	fld.d	r15, 27*8, dr36
	blink	tr1, r63
#else /* ! __SH4_NOFPU__	*/
	.global	GLOBAL(GCC_pop_shmedia_regs_nofpu)
	FUNC(GLOBAL(GCC_pop_shmedia_regs_nofpu))
GLOBAL(GCC_pop_shmedia_regs_nofpu):
#endif /* ! __SH4_NOFPU__	*/
	movi	27*8, r0
.L0:
	ptabs	r18, tr0
	ld.q	r15, 26*8, r62
	ld.q	r15, 25*8, r61
	ld.q	r15, 24*8, r60
	ptabs	r62, tr7
	ptabs	r61, tr6
	ptabs	r60, tr5
	ld.q	r15, 23*8, r59
	ld.q	r15, 22*8, r58
	ld.q	r15, 21*8, r57
	ld.q	r15, 20*8, r56
	ld.q	r15, 19*8, r55
	ld.q	r15, 18*8, r54
	ld.q	r15, 17*8, r53
	ld.q	r15, 16*8, r52
	ld.q	r15, 15*8, r51
	ld.q	r15, 14*8, r50
	ld.q	r15, 13*8, r49
	ld.q	r15, 12*8, r48
	ld.q	r15, 11*8, r47
	ld.q	r15, 10*8, r46
	ld.q	r15,  9*8, r45
	ld.q	r15,  8*8, r44
	ld.q	r15,  7*8, r35
	ld.q	r15,  6*8, r34
	ld.q	r15,  5*8, r33
	ld.q	r15,  4*8, r32
	ld.q	r15,  3*8, r31
	ld.q	r15,  2*8, r30
	ld.q	r15,  1*8, r29
	ld.q	r15,  0*8, r28
	add.l	r15, r0, r15
	blink	tr0, r63

#ifndef __SH4_NOFPU__
	ENDFUNC(GLOBAL(GCC_pop_shmedia_regs))
#else
	ENDFUNC(GLOBAL(GCC_pop_shmedia_regs_nofpu))
#endif
#endif /* __SH5__ == 32 */
#endif /* L_push_pop_shmedia_regs */

#ifdef L_div_table
#if __SH5__
#if defined(__pic__) && __SHMEDIA__
	.global	GLOBAL(sdivsi3)
	FUNC(GLOBAL(sdivsi3))
#if __SH5__ == 32
	.section	.text..SHmedia32,"ax"
#else
	.text
#endif
#if 0
/* ??? FIXME: Presumably due to a linker bug, exporting data symbols
   in a text section does not work (at least for shared libraries):
   the linker sets the LSB of the address as if this was SHmedia code.  */
#define TEXT_DATA_BUG
#endif
	.align	2
 // inputs: r4,r5
 // clobbered: r1,r18,r19,r20,r21,r25,tr0
 // result in r0
 .global GLOBAL(sdivsi3)
GLOBAL(sdivsi3):
#ifdef TEXT_DATA_BUG
 ptb datalabel Local_div_table,tr0
#else
 ptb GLOBAL(div_table_internal),tr0
#endif
 nsb r5, r1
 shlld r5, r1, r25    // normalize; [-2 ..1, 1..2) in s2.62
 shari r25, 58, r21   // extract 5(6) bit index (s2.4 with hole -1..1)
 /* bubble */
 gettr tr0,r20
 ldx.ub r20, r21, r19 // u0.8
 shari r25, 32, r25   // normalize to s2.30
 shlli r21, 1, r21
 muls.l r25, r19, r19 // s2.38
 ldx.w r20, r21, r21  // s2.14
  ptabs r18, tr0
 shari r19, 24, r19   // truncate to s2.14
 sub r21, r19, r19    // some 11 bit inverse in s1.14
 muls.l r19, r19, r21 // u0.28
  sub r63, r1, r1
  addi r1, 92, r1
 muls.l r25, r21, r18 // s2.58
 shlli r19, 45, r19   // multiply by two and convert to s2.58
  /* bubble */
 sub r19, r18, r18
 shari r18, 28, r18   // some 22 bit inverse in s1.30
 muls.l r18, r25, r0  // s2.60
  muls.l r18, r4, r25 // s32.30
  /* bubble */
 shari r0, 16, r19   // s-16.44
 muls.l r19, r18, r19 // s-16.74
  shari r25, 63, r0
  shari r4, 14, r18   // s19.-14
 shari r19, 30, r19   // s-16.44
 muls.l r19, r18, r19 // s15.30
  xor r21, r0, r21    // You could also use the constant 1 << 27.
  add r21, r25, r21
 sub r21, r19, r21
 shard r21, r1, r21
 sub r21, r0, r0
 blink tr0, r63
	ENDFUNC(GLOBAL(sdivsi3))
/* This table has been generated by divtab.c .
Defects for bias -330:
   Max defect: 6.081536e-07 at -1.000000e+00
   Min defect: 2.849516e-08 at 1.030651e+00
   Max 2nd step defect: 9.606539e-12 at -1.000000e+00
   Min 2nd step defect: 0.000000e+00 at 0.000000e+00
   Defect at 1: 1.238659e-07
   Defect at -2: 1.061708e-07 */
#else /* ! __pic__ || ! __SHMEDIA__ */
	.section	.rodata
#endif /* __pic__ */
#if defined(TEXT_DATA_BUG) && defined(__pic__) && __SHMEDIA__
	.balign 2
	.type	Local_div_table,@object
	.size	Local_div_table,128
/* negative division constants */
	.word	-16638
	.word	-17135
	.word	-17737
	.word	-18433
	.word	-19103
	.word	-19751
	.word	-20583
	.word	-21383
	.word	-22343
	.word	-23353
	.word	-24407
	.word	-25582
	.word	-26863
	.word	-28382
	.word	-29965
	.word	-31800
/* negative division factors */
	.byte	66
	.byte	70
	.byte	75
	.byte	81
	.byte	87
	.byte	93
	.byte	101
	.byte	109
	.byte	119
	.byte	130
	.byte	142
	.byte	156
	.byte	172
	.byte	192
	.byte	214
	.byte	241
	.skip 16
Local_div_table:
	.skip 16
/* positive division factors */
	.byte	241
	.byte	214
	.byte	192
	.byte	172
	.byte	156
	.byte	142
	.byte	130
	.byte	119
	.byte	109
	.byte	101
	.byte	93
	.byte	87
	.byte	81
	.byte	75
	.byte	70
	.byte	66
/* positive division constants */
	.word	31801
	.word	29966
	.word	28383
	.word	26864
	.word	25583
	.word	24408
	.word	23354
	.word	22344
	.word	21384
	.word	20584
	.word	19752
	.word	19104
	.word	18434
	.word	17738
	.word	17136
	.word	16639
	.section	.rodata
#endif /* TEXT_DATA_BUG */
	.balign 2
	.type	GLOBAL(div_table),@object
	.size	GLOBAL(div_table),128
/* negative division constants */
	.word	-16638
	.word	-17135
	.word	-17737
	.word	-18433
	.word	-19103
	.word	-19751
	.word	-20583
	.word	-21383
	.word	-22343
	.word	-23353
	.word	-24407
	.word	-25582
	.word	-26863
	.word	-28382
	.word	-29965
	.word	-31800
/* negative division factors */
	.byte	66
	.byte	70
	.byte	75
	.byte	81
	.byte	87
	.byte	93
	.byte	101
	.byte	109
	.byte	119
	.byte	130
	.byte	142
	.byte	156
	.byte	172
	.byte	192
	.byte	214
	.byte	241
	.skip 16
	.global	GLOBAL(div_table)
GLOBAL(div_table):
	HIDDEN_ALIAS(div_table_internal,div_table)
	.skip 16
/* positive division factors */
	.byte	241
	.byte	214
	.byte	192
	.byte	172
	.byte	156
	.byte	142
	.byte	130
	.byte	119
	.byte	109
	.byte	101
	.byte	93
	.byte	87
	.byte	81
	.byte	75
	.byte	70
	.byte	66
/* positive division constants */
	.word	31801
	.word	29966
	.word	28383
	.word	26864
	.word	25583
	.word	24408
	.word	23354
	.word	22344
	.word	21384
	.word	20584
	.word	19752
	.word	19104
	.word	18434
	.word	17738
	.word	17136
	.word	16639

#elif defined (__SH2A__) || defined (__SH3__) || defined (__SH3E__) || defined (__SH4__) || defined (__SH4_SINGLE__) || defined (__SH4_SINGLE_ONLY__) || defined (__SH4_NOFPU__)
/* This code uses shld, thus is not suitable for SH1 / SH2.  */

/* Signed / unsigned division without use of FPU, optimized for SH4.
   Uses a lookup table for divisors in the range -128 .. +128, and
   div1 with case distinction for larger divisors in three more ranges.
   The code is lumped together with the table to allow the use of mova.  */
#ifdef __LITTLE_ENDIAN__
#define L_LSB 0
#define L_LSWMSB 1
#define L_MSWLSB 2
#else
#define L_LSB 3
#define L_LSWMSB 2
#define L_MSWLSB 1
#endif

	.balign 4
	.global	GLOBAL(udivsi3_i4i)
	FUNC(GLOBAL(udivsi3_i4i))
GLOBAL(udivsi3_i4i):
	mov.w LOCAL(c128_w), r1
	div0u
	mov r4,r0
	shlr8 r0
	cmp/hi r1,r5
	extu.w r5,r1
	bf LOCAL(udiv_le128)
	cmp/eq r5,r1
	bf LOCAL(udiv_ge64k)
	shlr r0
	mov r5,r1
	shll16 r5
	mov.l r4,@-r15
	div1 r5,r0
	mov.l r1,@-r15
	div1 r5,r0
	div1 r5,r0
	bra LOCAL(udiv_25)
	div1 r5,r0

LOCAL(div_le128):
	mova LOCAL(div_table_ix),r0
	bra LOCAL(div_le128_2)
	mov.b @(r0,r5),r1
LOCAL(udiv_le128):
	mov.l r4,@-r15
	mova LOCAL(div_table_ix),r0
	mov.b @(r0,r5),r1
	mov.l r5,@-r15
LOCAL(div_le128_2):
	mova LOCAL(div_table_inv),r0
	mov.l @(r0,r1),r1
	mov r5,r0
	tst #0xfe,r0
	mova LOCAL(div_table_clz),r0
	dmulu.l r1,r4
	mov.b @(r0,r5),r1
	bt/s LOCAL(div_by_1)
	mov r4,r0
	mov.l @r15+,r5
	sts mach,r0
	/* clrt */
	addc r4,r0
	mov.l @r15+,r4
	rotcr r0
	rts
	shld r1,r0

LOCAL(div_by_1_neg):
	neg r4,r0
LOCAL(div_by_1):
	mov.l @r15+,r5
	rts
	mov.l @r15+,r4

LOCAL(div_ge64k):
	bt/s LOCAL(div_r8)
	div0u
	shll8 r5
	bra LOCAL(div_ge64k_2)
	div1 r5,r0
LOCAL(udiv_ge64k):
	cmp/hi r0,r5
	mov r5,r1
	bt LOCAL(udiv_r8)
	shll8 r5
	mov.l r4,@-r15
	div1 r5,r0
	mov.l r1,@-r15
LOCAL(div_ge64k_2):
	div1 r5,r0
	mov.l LOCAL(zero_l),r1
	.rept 4
	div1 r5,r0
	.endr
	mov.l r1,@-r15
	div1 r5,r0
	mov.w LOCAL(m256_w),r1
	div1 r5,r0
	mov.b r0,@(L_LSWMSB,r15)
	xor r4,r0
	and r1,r0
	bra LOCAL(div_ge64k_end)
	xor r4,r0
	
LOCAL(div_r8):
	shll16 r4
	bra LOCAL(div_r8_2)
	shll8 r4
LOCAL(udiv_r8):
	mov.l r4,@-r15
	shll16 r4
	clrt
	shll8 r4
	mov.l r5,@-r15
LOCAL(div_r8_2):
	rotcl r4
	mov r0,r1
	div1 r5,r1
	mov r4,r0
	rotcl r0
	mov r5,r4
	div1 r5,r1
	.rept 5
	rotcl r0; div1 r5,r1
	.endr
	rotcl r0
	mov.l @r15+,r5
	div1 r4,r1
	mov.l @r15+,r4
	rts
	rotcl r0

	ENDFUNC(GLOBAL(udivsi3_i4i))

	.global	GLOBAL(sdivsi3_i4i)
	FUNC(GLOBAL(sdivsi3_i4i))
	/* This is link-compatible with a GLOBAL(sdivsi3) call,
	   but we effectively clobber only r1.  */
GLOBAL(sdivsi3_i4i):
	mov.l r4,@-r15
	cmp/pz r5
	mov.w LOCAL(c128_w), r1
	bt/s LOCAL(pos_divisor)
	cmp/pz r4
	mov.l r5,@-r15
	neg r5,r5
	bt/s LOCAL(neg_result)
	cmp/hi r1,r5
	neg r4,r4
LOCAL(pos_result):
	extu.w r5,r0
	bf LOCAL(div_le128)
	cmp/eq r5,r0
	mov r4,r0
	shlr8 r0
	bf/s LOCAL(div_ge64k)
	cmp/hi r0,r5
	div0u
	shll16 r5
	div1 r5,r0
	div1 r5,r0
	div1 r5,r0
LOCAL(udiv_25):
	mov.l LOCAL(zero_l),r1
	div1 r5,r0
	div1 r5,r0
	mov.l r1,@-r15
	.rept 3
	div1 r5,r0
	.endr
	mov.b r0,@(L_MSWLSB,r15)
	xtrct r4,r0
	swap.w r0,r0
	.rept 8
	div1 r5,r0
	.endr
	mov.b r0,@(L_LSWMSB,r15)
LOCAL(div_ge64k_end):
	.rept 8
	div1 r5,r0
	.endr
	mov.l @r15+,r4 ! zero-extension and swap using LS unit.
	extu.b r0,r0
	mov.l @r15+,r5
	or r4,r0
	mov.l @r15+,r4
	rts
	rotcl r0

LOCAL(div_le128_neg):
	tst #0xfe,r0
	mova LOCAL(div_table_ix),r0
	mov.b @(r0,r5),r1
	mova LOCAL(div_table_inv),r0
	bt/s LOCAL(div_by_1_neg)
	mov.l @(r0,r1),r1
	mova LOCAL(div_table_clz),r0
	dmulu.l r1,r4
	mov.b @(r0,r5),r1
	mov.l @r15+,r5
	sts mach,r0
	/* clrt */
	addc r4,r0
	mov.l @r15+,r4
	rotcr r0
	shld r1,r0
	rts
	neg r0,r0

LOCAL(pos_divisor):
	mov.l r5,@-r15
	bt/s LOCAL(pos_result)
	cmp/hi r1,r5
	neg r4,r4
LOCAL(neg_result):
	extu.w r5,r0
	bf LOCAL(div_le128_neg)
	cmp/eq r5,r0
	mov r4,r0
	shlr8 r0
	bf/s LOCAL(div_ge64k_neg)
	cmp/hi r0,r5
	div0u
	mov.l LOCAL(zero_l),r1
	shll16 r5
	div1 r5,r0
	mov.l r1,@-r15
	.rept 7
	div1 r5,r0
	.endr
	mov.b r0,@(L_MSWLSB,r15)
	xtrct r4,r0
	swap.w r0,r0
	.rept 8
	div1 r5,r0
	.endr
	mov.b r0,@(L_LSWMSB,r15)
LOCAL(div_ge64k_neg_end):
	.rept 8
	div1 r5,r0
	.endr
	mov.l @r15+,r4 ! zero-extension and swap using LS unit.
	extu.b r0,r1
	mov.l @r15+,r5
	or r4,r1
LOCAL(div_r8_neg_end):
	mov.l @r15+,r4
	rotcl r1
	rts
	neg r1,r0

LOCAL(div_ge64k_neg):
	bt/s LOCAL(div_r8_neg)
	div0u
	shll8 r5
	mov.l LOCAL(zero_l),r1
	.rept 6
	div1 r5,r0
	.endr
	mov.l r1,@-r15
	div1 r5,r0
	mov.w LOCAL(m256_w),r1
	div1 r5,r0
	mov.b r0,@(L_LSWMSB,r15)
	xor r4,r0
	and r1,r0
	bra LOCAL(div_ge64k_neg_end)
	xor r4,r0

LOCAL(c128_w):
	.word 128

LOCAL(div_r8_neg):
	clrt
	shll16 r4
	mov r4,r1
	shll8 r1
	mov r5,r4
	.rept 7
	rotcl r1; div1 r5,r0
	.endr
	mov.l @r15+,r5
	rotcl r1
	bra LOCAL(div_r8_neg_end)
	div1 r4,r0

LOCAL(m256_w):
	.word 0xff00
/* This table has been generated by divtab-sh4.c.  */
	.balign 4
LOCAL(div_table_clz):
	.byte	0
	.byte	1
	.byte	0
	.byte	-1
	.byte	-1
	.byte	-2
	.byte	-2
	.byte	-2
	.byte	-2
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-3
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-4
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-5
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
	.byte	-6
/* Lookup table translating positive divisor to index into table of
   normalized inverse.  N.B. the '0' entry is also the last entry of the
 previous table, and causes an unaligned access for division by zero.  */
LOCAL(div_table_ix):
	.byte	-6
	.byte	-128
	.byte	-128
	.byte	0
	.byte	-128
	.byte	-64
	.byte	0
	.byte	64
	.byte	-128
	.byte	-96
	.byte	-64
	.byte	-32
	.byte	0
	.byte	32
	.byte	64
	.byte	96
	.byte	-128
	.byte	-112
	.byte	-96
	.byte	-80
	.byte	-64
	.byte	-48
	.byte	-32
	.byte	-16
	.byte	0
	.byte	16
	.byte	32
	.byte	48
	.byte	64
	.byte	80
	.byte	96
	.byte	112
	.byte	-128
	.byte	-120
	.byte	-112
	.byte	-104
	.byte	-96
	.byte	-88
	.byte	-80
	.byte	-72
	.byte	-64
	.byte	-56
	.byte	-48
	.byte	-40
	.byte	-32
	.byte	-24
	.byte	-16
	.byte	-8
	.byte	0
	.byte	8
	.byte	16
	.byte	24
	.byte	32
	.byte	40
	.byte	48
	.byte	56
	.byte	64
	.byte	72
	.byte	80
	.byte	88
	.byte	96
	.byte	104
	.byte	112
	.byte	120
	.byte	-128
	.byte	-124
	.byte	-120
	.byte	-116
	.byte	-112
	.byte	-108
	.byte	-104
	.byte	-100
	.byte	-96
	.byte	-92
	.byte	-88
	.byte	-84
	.byte	-80
	.byte	-76
	.byte	-72
	.byte	-68
	.byte	-64
	.byte	-60
	.byte	-56
	.byte	-52
	.byte	-48
	.byte	-44
	.byte	-40
	.byte	-36
	.byte	-32
	.byte	-28
	.byte	-24
	.byte	-20
	.byte	-16
	.byte	-12
	.byte	-8
	.byte	-4
	.byte	0
	.byte	4
	.byte	8
	.byte	12
	.byte	16
	.byte	20
	.byte	24
	.byte	28
	.byte	32
	.byte	36
	.byte	40
	.byte	44
	.byte	48
	.byte	52
	.byte	56
	.byte	60
	.byte	64
	.byte	68
	.byte	72
	.byte	76
	.byte	80
	.byte	84
	.byte	88
	.byte	92
	.byte	96
	.byte	100
	.byte	104
	.byte	108
	.byte	112
	.byte	116
	.byte	120
	.byte	124
	.byte	-128
/* 1/64 .. 1/127, normalized.  There is an implicit leading 1 in bit 32.  */
	.balign 4
LOCAL(zero_l):
	.long	0x0
	.long	0xF81F81F9
	.long	0xF07C1F08
	.long	0xE9131AC0
	.long	0xE1E1E1E2
	.long	0xDAE6076C
	.long	0xD41D41D5
	.long	0xCD856891
	.long	0xC71C71C8
	.long	0xC0E07039
	.long	0xBACF914D
	.long	0xB4E81B4F
	.long	0xAF286BCB
	.long	0xA98EF607
	.long	0xA41A41A5
	.long	0x9EC8E952
	.long	0x9999999A
	.long	0x948B0FCE
	.long	0x8F9C18FA
	.long	0x8ACB90F7
	.long	0x86186187
	.long	0x81818182
	.long	0x7D05F418
	.long	0x78A4C818
	.long	0x745D1746
	.long	0x702E05C1
	.long	0x6C16C16D
	.long	0x68168169
	.long	0x642C8591
	.long	0x60581606
	.long	0x5C9882BA
	.long	0x58ED2309
LOCAL(div_table_inv):
	.long	0x55555556
	.long	0x51D07EAF
	.long	0x4E5E0A73
	.long	0x4AFD6A06
	.long	0x47AE147B
	.long	0x446F8657
	.long	0x41414142
	.long	0x3E22CBCF
	.long	0x3B13B13C
	.long	0x38138139
	.long	0x3521CFB3
	.long	0x323E34A3
	.long	0x2F684BDB
	.long	0x2C9FB4D9
	.long	0x29E4129F
	.long	0x27350B89
	.long	0x24924925
	.long	0x21FB7813
	.long	0x1F7047DD
	.long	0x1CF06ADB
	.long	0x1A7B9612
	.long	0x18118119
	.long	0x15B1E5F8
	.long	0x135C8114
	.long	0x11111112
	.long	0xECF56BF
	.long	0xC9714FC
	.long	0xA6810A7
	.long	0x8421085
	.long	0x624DD30
	.long	0x4104105
	.long	0x2040811
	/* maximum error: 0.987342 scaled: 0.921875*/

	ENDFUNC(GLOBAL(sdivsi3_i4i))
#endif /* SH3 / SH4 */

#endif /* L_div_table */

#ifdef L_udiv_qrnnd_16
#if !__SHMEDIA__
	HIDDEN_FUNC(GLOBAL(udiv_qrnnd_16))
	/* r0: rn r1: qn */ /* r0: n1 r4: n0 r5: d r6: d1 */ /* r2: __m */
	/* n1 < d, but n1 might be larger than d1.  */
	.global GLOBAL(udiv_qrnnd_16)
	.balign 8
GLOBAL(udiv_qrnnd_16):
	div0u
	cmp/hi r6,r0
	bt .Lots
	.rept 16
	div1 r6,r0 
	.endr
	extu.w r0,r1
	bt 0f
	add r6,r0
0:	rotcl r1
	mulu.w r1,r5
	xtrct r4,r0
	swap.w r0,r0
	sts macl,r2
	cmp/hs r2,r0
	sub r2,r0
	bt 0f
	addc r5,r0
	add #-1,r1
	bt 0f
1:	add #-1,r1
	rts
	add r5,r0
	.balign 8
.Lots:
	sub r5,r0
	swap.w r4,r1
	xtrct r0,r1
	clrt
	mov r1,r0
	addc r5,r0
	mov #-1,r1
	SL1(bf, 1b,
	shlr16 r1)
0:	rts
	nop
	ENDFUNC(GLOBAL(udiv_qrnnd_16))
#endif /* !__SHMEDIA__ */
#endif /* L_udiv_qrnnd_16 */