arch/c6x/lib/divu.S - linux - Git at Google

 ;; SPDX-License-Identifier: GPL-2.0-or-later
 ;;  Copyright 2010  Free Software Foundation, Inc.
 ;;  Contributed by Bernd Schmidt <bernds@codesourcery.com>.
 ;;

 #include <linux/linkage.h>

 	;; ABI considerations for the divide functions
 	;; The following registers are call-used:
 	;; __c6xabi_divi A0,A1,A2,A4,A6,B0,B1,B2,B4,B5
 	;; __c6xabi_divu A0,A1,A2,A4,A6,B0,B1,B2,B4
 	;; __c6xabi_remi A1,A2,A4,A5,A6,B0,B1,B2,B4
 	;; __c6xabi_remu A1,A4,A5,A7,B0,B1,B2,B4
 	;;
 	;; In our implementation, divu and remu are leaf functions,
 	;; while both divi and remi call into divu.
 	;; A0 is not clobbered by any of the functions.
 	;; divu does not clobber B2 either, which is taken advantage of
 	;; in remi.
 	;; divi uses B5 to hold the original return address during
 	;; the call to divu.
 	;; remi uses B2 and A5 to hold the input values during the
 	;; call to divu.  It stores B3 in on the stack.

 	.text
 ENTRY(__c6xabi_divu)
 	;; We use a series of up to 31 subc instructions.  First, we find
 	;; out how many leading zero bits there are in the divisor.  This
 	;; gives us both a shift count for aligning (shifting) the divisor
 	;; to the, and the number of times we have to execute subc.

 	;; At the end, we have both the remainder and most of the quotient
 	;; in A4.  The top bit of the quotient is computed first and is
 	;; placed in A2.

 	;; Return immediately if the dividend is zero.
 	 mv	.s2x	A4, B1
    [B1]	 lmbd	.l2	1, B4, B1
 || [!B1] b	.s2	B3	; RETURN A
 || [!B1] mvk	.d2	1, B4
 	 mv	.l1x	B1, A6
 ||	 shl	.s2	B4, B1, B4

 	;; The loop performs a maximum of 28 steps, so we do the
 	;; first 3 here.
 	 cmpltu	.l1x	A4, B4, A2
    [!A2] sub	.l1x	A4, B4, A4
 ||	 shru	.s2	B4, 1, B4
 ||	 xor	.s1	1, A2, A2

 	 shl	.s1	A2, 31, A2
 || [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1

 	;; RETURN A may happen here (note: must happen before the next branch)
 _divu_loop:
 	 cmpgt	.l2	B1, 7, B0
 || [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
 || [B0]  b	.s1	_divu_loop
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
    [B1]	 subc	.l1x	A4,B4,A4
 || [B1]	 add	.s2	-1, B1, B1
 	;; loop backwards branch happens here

 	 ret	.s2	B3
 ||	 mvk	.s1	32, A1
 	 sub	.l1	A1, A6, A6
 	 shl	.s1	A4, A6, A4
 	 shru	.s1	A4, 1, A4
 ||	 sub	.l1	A6, 1, A6
 	 or	.l1	A2, A4, A4
 	 shru	.s1	A4, A6, A4
 	 nop
 ENDPROC(__c6xabi_divu)
	;; SPDX-License-Identifier: GPL-2.0-or-later
	;; Copyright 2010 Free Software Foundation, Inc.
	;; Contributed by Bernd Schmidt <bernds@codesourcery.com>.
	;;

	#include <linux/linkage.h>

	;; ABI considerations for the divide functions
	;; The following registers are call-used:
	;; __c6xabi_divi A0,A1,A2,A4,A6,B0,B1,B2,B4,B5
	;; __c6xabi_divu A0,A1,A2,A4,A6,B0,B1,B2,B4
	;; __c6xabi_remi A1,A2,A4,A5,A6,B0,B1,B2,B4
	;; __c6xabi_remu A1,A4,A5,A7,B0,B1,B2,B4
	;;
	;; In our implementation, divu and remu are leaf functions,
	;; while both divi and remi call into divu.
	;; A0 is not clobbered by any of the functions.
	;; divu does not clobber B2 either, which is taken advantage of
	;; in remi.
	;; divi uses B5 to hold the original return address during
	;; the call to divu.
	;; remi uses B2 and A5 to hold the input values during the
	;; call to divu. It stores B3 in on the stack.

	.text
	ENTRY(__c6xabi_divu)
	;; We use a series of up to 31 subc instructions. First, we find
	;; out how many leading zero bits there are in the divisor. This
	;; gives us both a shift count for aligning (shifting) the divisor
	;; to the, and the number of times we have to execute subc.

	;; At the end, we have both the remainder and most of the quotient
	;; in A4. The top bit of the quotient is computed first and is
	;; placed in A2.

	;; Return immediately if the dividend is zero.
	mv .s2x A4, B1
	[B1] lmbd .l2 1, B4, B1
	\|\| [!B1] b .s2 B3 ; RETURN A
	\|\| [!B1] mvk .d2 1, B4
	mv .l1x B1, A6
	\|\| shl .s2 B4, B1, B4

	;; The loop performs a maximum of 28 steps, so we do the
	;; first 3 here.
	cmpltu .l1x A4, B4, A2
	[!A2] sub .l1x A4, B4, A4
	\|\| shru .s2 B4, 1, B4
	\|\| xor .s1 1, A2, A2

	shl .s1 A2, 31, A2
	\|\| [B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1

	;; RETURN A may happen here (note: must happen before the next branch)
	_divu_loop:
	cmpgt .l2 B1, 7, B0
	\|\| [B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	\|\| [B0] b .s1 _divu_loop
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	[B1] subc .l1x A4,B4,A4
	\|\| [B1] add .s2 -1, B1, B1
	;; loop backwards branch happens here

	ret .s2 B3
	\|\| mvk .s1 32, A1
	sub .l1 A1, A6, A6
	shl .s1 A4, A6, A4
	shru .s1 A4, 1, A4
	\|\| sub .l1 A6, 1, A6
	or .l1 A2, A4, A4
	shru .s1 A4, A6, A4
	nop
	ENDPROC(__c6xabi_divu)