crypto/poly1305/asm/poly1305-armv8.pl

#! /usr/bin/env perl
# Copyright 2016 The OpenSSL Project Authors. All Rights Reserved.
#
# Licensed under the OpenSSL license (the "License").  You may not use
# this file except in compliance with the License.  You can obtain a copy
# in the file LICENSE in the source distribution or at
# https://www.openssl.org/source/license.html

#
# ====================================================================
# Written by Andy Polyakov <appro@openssl.org> for the OpenSSL
# project. The module is, however, dual licensed under OpenSSL and
# CRYPTOGAMS licenses depending on where you obtain it. For further
# details see http://www.openssl.org/~appro/cryptogams/.
# ====================================================================
#
# This module implements Poly1305 hash for ARMv8.
#
# June 2015
#
# Numbers are cycles per processed byte with poly1305_blocks alone.
#
#		IALU/gcc-4.9	NEON
#
# Apple A7	1.86/+5%	0.72
# Cortex-A53	2.69/+58%	1.47
# Cortex-A57	2.70/+7%	1.14
# Denver	1.64/+50%	1.18(*)
# X-Gene	2.13/+68%	2.27
#
# (*)	estimate based on resources availability is less than 1.0,
#	i.e. measured result is worse than expected, presumably binary
#	translator is not almighty;

$flavour=shift;
$output=shift;

$0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1;
( $xlate="${dir}arm-xlate.pl" and -f $xlate ) or
( $xlate="${dir}../../perlasm/arm-xlate.pl" and -f $xlate) or
die "can't locate arm-xlate.pl";

open OUT,"| \"$^X\" $xlate $flavour $output";
*STDOUT=*OUT;

my ($ctx,$inp,$len,$padbit) = map("x$_",(0..3));
my ($mac,$nonce)=($inp,$len);

my ($h0,$h1,$h2,$r0,$r1,$s1,$t0,$t1,$d0,$d1,$d2) = map("x$_",(4..14));

$code.=<<___;
#include "arm_arch.h"

.text

// forward "declarations" are required for Apple
.extern	OPENSSL_armcap_P
.globl	poly1305_blocks
.globl	poly1305_emit

.globl	poly1305_init
.type	poly1305_init,%function
.align	5
poly1305_init:
	cmp	$inp,xzr
	stp	xzr,xzr,[$ctx]		// zero hash value
	stp	xzr,xzr,[$ctx,#16]	// [along with is_base2_26]

	csel	x0,xzr,x0,eq
	b.eq	.Lno_key

#ifdef	__ILP32__
	ldrsw	$t1,.LOPENSSL_armcap_P
#else
	ldr	$t1,.LOPENSSL_armcap_P
#endif
	adr	$t0,.LOPENSSL_armcap_P

	ldp	$r0,$r1,[$inp]		// load key
	mov	$s1,#0xfffffffc0fffffff
	movk	$s1,#0x0fff,lsl#48
	ldr	w17,[$t0,$t1]
#ifdef	__ARMEB__
	rev	$r0,$r0			// flip bytes
	rev	$r1,$r1
#endif
	and	$r0,$r0,$s1		// &=0ffffffc0fffffff
	and	$s1,$s1,#-4
	and	$r1,$r1,$s1		// &=0ffffffc0ffffffc
	stp	$r0,$r1,[$ctx,#32]	// save key value

	tst	w17,#ARMV7_NEON

	adr	$d0,poly1305_blocks
	adr	$r0,poly1305_blocks_neon
	adr	$d1,poly1305_emit
	adr	$r1,poly1305_emit_neon

	csel	$d0,$d0,$r0,eq
	csel	$d1,$d1,$r1,eq

	stp	$d0,$d1,[$len]

	mov	x0,#1
.Lno_key:
	ret
.size	poly1305_init,.-poly1305_init

.type	poly1305_blocks,%function
.align	5
poly1305_blocks:
	ands	$len,$len,#-16
	b.eq	.Lno_data

	ldp	$h0,$h1,[$ctx]		// load hash value
	ldp	$r0,$r1,[$ctx,#32]	// load key value
	ldr	$h2,[$ctx,#16]
	add	$s1,$r1,$r1,lsr#2	// s1 = r1 + (r1 >> 2)
	b	.Loop

.align	5
.Loop:
	ldp	$t0,$t1,[$inp],#16	// load input
	sub	$len,$len,#16
#ifdef	__ARMEB__
	rev	$t0,$t0
	rev	$t1,$t1
#endif
	adds	$h0,$h0,$t0		// accumulate input
	adcs	$h1,$h1,$t1

	mul	$d0,$h0,$r0		// h0*r0
	adc	$h2,$h2,$padbit
	umulh	$d1,$h0,$r0

	mul	$t0,$h1,$s1		// h1*5*r1
	umulh	$t1,$h1,$s1

	adds	$d0,$d0,$t0
	mul	$t0,$h0,$r1		// h0*r1
	adc	$d1,$d1,$t1
	umulh	$d2,$h0,$r1

	adds	$d1,$d1,$t0
	mul	$t0,$h1,$r0		// h1*r0
	adc	$d2,$d2,xzr
	umulh	$t1,$h1,$r0

	adds	$d1,$d1,$t0
	mul	$t0,$h2,$s1		// h2*5*r1
	adc	$d2,$d2,$t1
	mul	$t1,$h2,$r0		// h2*r0

	adds	$d1,$d1,$t0
	adc	$d2,$d2,$t1

	and	$t0,$d2,#-4		// final reduction
	and	$h2,$d2,#3
	add	$t0,$t0,$d2,lsr#2
	adds	$h0,$d0,$t0
	adcs	$h1,$d1,xzr
	adc	$h2,$h2,xzr

	cbnz	$len,.Loop

	stp	$h0,$h1,[$ctx]		// store hash value
	str	$h2,[$ctx,#16]

.Lno_data:
	ret
.size	poly1305_blocks,.-poly1305_blocks

.type	poly1305_emit,%function
.align	5
poly1305_emit:
	ldp	$h0,$h1,[$ctx]		// load hash base 2^64
	ldr	$h2,[$ctx,#16]
	ldp	$t0,$t1,[$nonce]	// load nonce

	adds	$d0,$h0,#5		// compare to modulus
	adcs	$d1,$h1,xzr
	adc	$d2,$h2,xzr

	tst	$d2,#-4			// see if it's carried/borrowed

	csel	$h0,$h0,$d0,eq
	csel	$h1,$h1,$d1,eq

#ifdef	__ARMEB__
	ror	$t0,$t0,#32		// flip nonce words
	ror	$t1,$t1,#32
#endif
	adds	$h0,$h0,$t0		// accumulate nonce
	adc	$h1,$h1,$t1
#ifdef	__ARMEB__
	rev	$h0,$h0			// flip output bytes
	rev	$h1,$h1
#endif
	stp	$h0,$h1,[$mac]		// write result

	ret
.size	poly1305_emit,.-poly1305_emit
___
my ($R0,$R1,$S1,$R2,$S2,$R3,$S3,$R4,$S4) = map("v$_.4s",(0..8));
my ($IN01_0,$IN01_1,$IN01_2,$IN01_3,$IN01_4) = map("v$_.2s",(9..13));
my ($IN23_0,$IN23_1,$IN23_2,$IN23_3,$IN23_4) = map("v$_.2s",(14..18));
my ($ACC0,$ACC1,$ACC2,$ACC3,$ACC4) = map("v$_.2d",(19..23));
my ($H0,$H1,$H2,$H3,$H4) = map("v$_.2s",(24..28));
my ($T0,$T1,$MASK) = map("v$_",(29..31));

my ($in2,$zeros)=("x16","x17");
my $is_base2_26 = $zeros;		# borrow

$code.=<<___;
.type	poly1305_mult,%function
.align	5
poly1305_mult:
	mul	$d0,$h0,$r0		// h0*r0
	umulh	$d1,$h0,$r0

	mul	$t0,$h1,$s1		// h1*5*r1
	umulh	$t1,$h1,$s1

	adds	$d0,$d0,$t0
	mul	$t0,$h0,$r1		// h0*r1
	adc	$d1,$d1,$t1
	umulh	$d2,$h0,$r1

	adds	$d1,$d1,$t0
	mul	$t0,$h1,$r0		// h1*r0
	adc	$d2,$d2,xzr
	umulh	$t1,$h1,$r0

	adds	$d1,$d1,$t0
	mul	$t0,$h2,$s1		// h2*5*r1
	adc	$d2,$d2,$t1
	mul	$t1,$h2,$r0		// h2*r0

	adds	$d1,$d1,$t0
	adc	$d2,$d2,$t1

	and	$t0,$d2,#-4		// final reduction
	and	$h2,$d2,#3
	add	$t0,$t0,$d2,lsr#2
	adds	$h0,$d0,$t0
	adcs	$h1,$d1,xzr
	adc	$h2,$h2,xzr

	ret
.size	poly1305_mult,.-poly1305_mult

.type	poly1305_splat,%function
.align	5
poly1305_splat:
	and	x12,$h0,#0x03ffffff	// base 2^64 -> base 2^26
	ubfx	x13,$h0,#26,#26
	extr	x14,$h1,$h0,#52
	and	x14,x14,#0x03ffffff
	ubfx	x15,$h1,#14,#26
	extr	x16,$h2,$h1,#40

	str	w12,[$ctx,#16*0]	// r0
	add	w12,w13,w13,lsl#2	// r1*5
	str	w13,[$ctx,#16*1]	// r1
	add	w13,w14,w14,lsl#2	// r2*5
	str	w12,[$ctx,#16*2]	// s1
	str	w14,[$ctx,#16*3]	// r2
	add	w14,w15,w15,lsl#2	// r3*5
	str	w13,[$ctx,#16*4]	// s2
	str	w15,[$ctx,#16*5]	// r3
	add	w15,w16,w16,lsl#2	// r4*5
	str	w14,[$ctx,#16*6]	// s3
	str	w16,[$ctx,#16*7]	// r4
	str	w15,[$ctx,#16*8]	// s4

	ret
.size	poly1305_splat,.-poly1305_splat

.type	poly1305_blocks_neon,%function
.align	5
poly1305_blocks_neon:
	ldr	$is_base2_26,[$ctx,#24]
	cmp	$len,#128
	b.hs	.Lblocks_neon
	cbz	$is_base2_26,poly1305_blocks

.Lblocks_neon:
	stp	x29,x30,[sp,#-80]!
	add	x29,sp,#0

	ands	$len,$len,#-16
	b.eq	.Lno_data_neon

	cbz	$is_base2_26,.Lbase2_64_neon

	ldp	w10,w11,[$ctx]		// load hash value base 2^26
	ldp	w12,w13,[$ctx,#8]
	ldr	w14,[$ctx,#16]

	tst	$len,#31
	b.eq	.Leven_neon

	ldp	$r0,$r1,[$ctx,#32]	// load key value

	add	$h0,x10,x11,lsl#26	// base 2^26 -> base 2^64
	lsr	$h1,x12,#12
	adds	$h0,$h0,x12,lsl#52
	add	$h1,$h1,x13,lsl#14
	adc	$h1,$h1,xzr
	lsr	$h2,x14,#24
	adds	$h1,$h1,x14,lsl#40
	adc	$d2,$h2,xzr		// can be partially reduced...

	ldp	$d0,$d1,[$inp],#16	// load input
	sub	$len,$len,#16
	add	$s1,$r1,$r1,lsr#2	// s1 = r1 + (r1 >> 2)

	and	$t0,$d2,#-4		// ... so reduce
	and	$h2,$d2,#3
	add	$t0,$t0,$d2,lsr#2
	adds	$h0,$h0,$t0
	adcs	$h1,$h1,xzr
	adc	$h2,$h2,xzr

#ifdef	__ARMEB__
	rev	$d0,$d0
	rev	$d1,$d1
#endif
	adds	$h0,$h0,$d0		// accumulate input
	adcs	$h1,$h1,$d1
	adc	$h2,$h2,$padbit

	bl	poly1305_mult
	ldr	x30,[sp,#8]

	cbz	$padbit,.Lstore_base2_64_neon

	and	x10,$h0,#0x03ffffff	// base 2^64 -> base 2^26
	ubfx	x11,$h0,#26,#26
	extr	x12,$h1,$h0,#52
	and	x12,x12,#0x03ffffff
	ubfx	x13,$h1,#14,#26
	extr	x14,$h2,$h1,#40

	cbnz	$len,.Leven_neon

	stp	w10,w11,[$ctx]		// store hash value base 2^26
	stp	w12,w13,[$ctx,#8]
	str	w14,[$ctx,#16]
	b	.Lno_data_neon

.align	4
.Lstore_base2_64_neon:
	stp	$h0,$h1,[$ctx]		// store hash value base 2^64
	stp	$h2,xzr,[$ctx,#16]	// note that is_base2_26 is zeroed
	b	.Lno_data_neon

.align	4
.Lbase2_64_neon:
	ldp	$r0,$r1,[$ctx,#32]	// load key value

	ldp	$h0,$h1,[$ctx]		// load hash value base 2^64
	ldr	$h2,[$ctx,#16]

	tst	$len,#31
	b.eq	.Linit_neon

	ldp	$d0,$d1,[$inp],#16	// load input
	sub	$len,$len,#16
	add	$s1,$r1,$r1,lsr#2	// s1 = r1 + (r1 >> 2)
#ifdef	__ARMEB__
	rev	$d0,$d0
	rev	$d1,$d1
#endif
	adds	$h0,$h0,$d0		// accumulate input
	adcs	$h1,$h1,$d1
	adc	$h2,$h2,$padbit

	bl	poly1305_mult

.Linit_neon:
	and	x10,$h0,#0x03ffffff	// base 2^64 -> base 2^26
	ubfx	x11,$h0,#26,#26
	extr	x12,$h1,$h0,#52
	and	x12,x12,#0x03ffffff
	ubfx	x13,$h1,#14,#26
	extr	x14,$h2,$h1,#40

	stp	d8,d9,[sp,#16]		// meet ABI requirements
	stp	d10,d11,[sp,#32]
	stp	d12,d13,[sp,#48]
	stp	d14,d15,[sp,#64]

	fmov	${H0},x10
	fmov	${H1},x11
	fmov	${H2},x12
	fmov	${H3},x13
	fmov	${H4},x14

	////////////////////////////////// initialize r^n table
	mov	$h0,$r0			// r^1
	add	$s1,$r1,$r1,lsr#2	// s1 = r1 + (r1 >> 2)
	mov	$h1,$r1
	mov	$h2,xzr
	add	$ctx,$ctx,#48+12
	bl	poly1305_splat

	bl	poly1305_mult		// r^2
	sub	$ctx,$ctx,#4
	bl	poly1305_splat

	bl	poly1305_mult		// r^3
	sub	$ctx,$ctx,#4
	bl	poly1305_splat

	bl	poly1305_mult		// r^4
	sub	$ctx,$ctx,#4
	bl	poly1305_splat
	ldr	x30,[sp,#8]

	add	$in2,$inp,#32
	adr	$zeros,.Lzeros
	subs	$len,$len,#64
	csel	$in2,$zeros,$in2,lo

	mov	x4,#1
	str	x4,[$ctx,#-24]		// set is_base2_26
	sub	$ctx,$ctx,#48		// restore original $ctx
	b	.Ldo_neon

.align	4
.Leven_neon:
	add	$in2,$inp,#32
	adr	$zeros,.Lzeros
	subs	$len,$len,#64
	csel	$in2,$zeros,$in2,lo

	stp	d8,d9,[sp,#16]		// meet ABI requirements
	stp	d10,d11,[sp,#32]
	stp	d12,d13,[sp,#48]
	stp	d14,d15,[sp,#64]

	fmov	${H0},x10
	fmov	${H1},x11
	fmov	${H2},x12
	fmov	${H3},x13
	fmov	${H4},x14

.Ldo_neon:
	ldp	x8,x12,[$in2],#16	// inp[2:3] (or zero)
	ldp	x9,x13,[$in2],#48

	lsl	$padbit,$padbit,#24
	add	x15,$ctx,#48

#ifdef	__ARMEB__
	rev	x8,x8
	rev	x12,x12
	rev	x9,x9
	rev	x13,x13
#endif
	and	x4,x8,#0x03ffffff	// base 2^64 -> base 2^26
	and	x5,x9,#0x03ffffff
	ubfx	x6,x8,#26,#26
	ubfx	x7,x9,#26,#26
	add	x4,x4,x5,lsl#32		// bfi	x4,x5,#32,#32
	extr	x8,x12,x8,#52
	extr	x9,x13,x9,#52
	add	x6,x6,x7,lsl#32		// bfi	x6,x7,#32,#32
	fmov	$IN23_0,x4
	and	x8,x8,#0x03ffffff
	and	x9,x9,#0x03ffffff
	ubfx	x10,x12,#14,#26
	ubfx	x11,x13,#14,#26
	add	x12,$padbit,x12,lsr#40
	add	x13,$padbit,x13,lsr#40
	add	x8,x8,x9,lsl#32		// bfi	x8,x9,#32,#32
	fmov	$IN23_1,x6
	add	x10,x10,x11,lsl#32	// bfi	x10,x11,#32,#32
	add	x12,x12,x13,lsl#32	// bfi	x12,x13,#32,#32
	fmov	$IN23_2,x8
	fmov	$IN23_3,x10
	fmov	$IN23_4,x12

	ldp	x8,x12,[$inp],#16	// inp[0:1]
	ldp	x9,x13,[$inp],#48

	ld1	{$R0,$R1,$S1,$R2},[x15],#64
	ld1	{$S2,$R3,$S3,$R4},[x15],#64
	ld1	{$S4},[x15]

#ifdef	__ARMEB__
	rev	x8,x8
	rev	x12,x12
	rev	x9,x9
	rev	x13,x13
#endif
	and	x4,x8,#0x03ffffff	// base 2^64 -> base 2^26
	and	x5,x9,#0x03ffffff
	ubfx	x6,x8,#26,#26
	ubfx	x7,x9,#26,#26
	add	x4,x4,x5,lsl#32		// bfi	x4,x5,#32,#32
	extr	x8,x12,x8,#52
	extr	x9,x13,x9,#52
	add	x6,x6,x7,lsl#32		// bfi	x6,x7,#32,#32
	fmov	$IN01_0,x4
	and	x8,x8,#0x03ffffff
	and	x9,x9,#0x03ffffff
	ubfx	x10,x12,#14,#26
	ubfx	x11,x13,#14,#26
	add	x12,$padbit,x12,lsr#40
	add	x13,$padbit,x13,lsr#40
	add	x8,x8,x9,lsl#32		// bfi	x8,x9,#32,#32
	fmov	$IN01_1,x6
	add	x10,x10,x11,lsl#32	// bfi	x10,x11,#32,#32
	add	x12,x12,x13,lsl#32	// bfi	x12,x13,#32,#32
	movi	$MASK.2d,#-1
	fmov	$IN01_2,x8
	fmov	$IN01_3,x10
	fmov	$IN01_4,x12
	ushr	$MASK.2d,$MASK.2d,#38

	b.ls	.Lskip_loop

.align	4
.Loop_neon:
	////////////////////////////////////////////////////////////////
	// ((inp[0]*r^4+inp[2]*r^2+inp[4])*r^4+inp[6]*r^2
	// ((inp[1]*r^4+inp[3]*r^2+inp[5])*r^3+inp[7]*r
	//   \___________________/
	// ((inp[0]*r^4+inp[2]*r^2+inp[4])*r^4+inp[6]*r^2+inp[8])*r^2
	// ((inp[1]*r^4+inp[3]*r^2+inp[5])*r^4+inp[7]*r^2+inp[9])*r
	//   \___________________/ \____________________/
	//
	// Note that we start with inp[2:3]*r^2. This is because it
	// doesn't depend on reduction in previous iteration.
	////////////////////////////////////////////////////////////////
	// d4 = h0*r4 + h1*r3   + h2*r2   + h3*r1   + h4*r0
	// d3 = h0*r3 + h1*r2   + h2*r1   + h3*r0   + h4*5*r4
	// d2 = h0*r2 + h1*r1   + h2*r0   + h3*5*r4 + h4*5*r3
	// d1 = h0*r1 + h1*r0   + h2*5*r4 + h3*5*r3 + h4*5*r2
	// d0 = h0*r0 + h1*5*r4 + h2*5*r3 + h3*5*r2 + h4*5*r1

	subs	$len,$len,#64
	umull	$ACC4,$IN23_0,${R4}[2]
	csel	$in2,$zeros,$in2,lo
	umull	$ACC3,$IN23_0,${R3}[2]
	umull	$ACC2,$IN23_0,${R2}[2]
	 ldp	x8,x12,[$in2],#16	// inp[2:3] (or zero)
	umull	$ACC1,$IN23_0,${R1}[2]
	 ldp	x9,x13,[$in2],#48
	umull	$ACC0,$IN23_0,${R0}[2]
#ifdef	__ARMEB__
	 rev	x8,x8
	 rev	x12,x12
	 rev	x9,x9
	 rev	x13,x13
#endif

	umlal	$ACC4,$IN23_1,${R3}[2]
	 and	x4,x8,#0x03ffffff	// base 2^64 -> base 2^26
	umlal	$ACC3,$IN23_1,${R2}[2]
	 and	x5,x9,#0x03ffffff
	umlal	$ACC2,$IN23_1,${R1}[2]
	 ubfx	x6,x8,#26,#26
	umlal	$ACC1,$IN23_1,${R0}[2]
	 ubfx	x7,x9,#26,#26
	umlal	$ACC0,$IN23_1,${S4}[2]
	 add	x4,x4,x5,lsl#32		// bfi	x4,x5,#32,#32

	umlal	$ACC4,$IN23_2,${R2}[2]
	 extr	x8,x12,x8,#52
	umlal	$ACC3,$IN23_2,${R1}[2]
	 extr	x9,x13,x9,#52
	umlal	$ACC2,$IN23_2,${R0}[2]
	 add	x6,x6,x7,lsl#32		// bfi	x6,x7,#32,#32
	umlal	$ACC1,$IN23_2,${S4}[2]
	 fmov	$IN23_0,x4
	umlal	$ACC0,$IN23_2,${S3}[2]
	 and	x8,x8,#0x03ffffff

	umlal	$ACC4,$IN23_3,${R1}[2]
	 and	x9,x9,#0x03ffffff
	umlal	$ACC3,$IN23_3,${R0}[2]
	 ubfx	x10,x12,#14,#26
	umlal	$ACC2,$IN23_3,${S4}[2]
	 ubfx	x11,x13,#14,#26
	umlal	$ACC1,$IN23_3,${S3}[2]
	 add	x8,x8,x9,lsl#32		// bfi	x8,x9,#32,#32
	umlal	$ACC0,$IN23_3,${S2}[2]
	 fmov	$IN23_1,x6

	add	$IN01_2,$IN01_2,$H2
	 add	x12,$padbit,x12,lsr#40
	umlal	$ACC4,$IN23_4,${R0}[2]
	 add	x13,$padbit,x13,lsr#40
	umlal	$ACC3,$IN23_4,${S4}[2]
	 add	x10,x10,x11,lsl#32	// bfi	x10,x11,#32,#32
	umlal	$ACC2,$IN23_4,${S3}[2]
	 add	x12,x12,x13,lsl#32	// bfi	x12,x13,#32,#32
	umlal	$ACC1,$IN23_4,${S2}[2]
	 fmov	$IN23_2,x8
	umlal	$ACC0,$IN23_4,${S1}[2]
	 fmov	$IN23_3,x10

	////////////////////////////////////////////////////////////////
	// (hash+inp[0:1])*r^4 and accumulate

	add	$IN01_0,$IN01_0,$H0
	 fmov	$IN23_4,x12
	umlal	$ACC3,$IN01_2,${R1}[0]
	 ldp	x8,x12,[$inp],#16	// inp[0:1]
	umlal	$ACC0,$IN01_2,${S3}[0]
	 ldp	x9,x13,[$inp],#48
	umlal	$ACC4,$IN01_2,${R2}[0]
	umlal	$ACC1,$IN01_2,${S4}[0]
	umlal	$ACC2,$IN01_2,${R0}[0]
#ifdef	__ARMEB__
	 rev	x8,x8
	 rev	x12,x12
	 rev	x9,x9
	 rev	x13,x13
#endif

	add	$IN01_1,$IN01_1,$H1
	umlal	$ACC3,$IN01_0,${R3}[0]
	umlal	$ACC4,$IN01_0,${R4}[0]
	 and	x4,x8,#0x03ffffff	// base 2^64 -> base 2^26
	umlal	$ACC2,$IN01_0,${R2}[0]
	 and	x5,x9,#0x03ffffff
	umlal	$ACC0,$IN01_0,${R0}[0]
	 ubfx	x6,x8,#26,#26
	umlal	$ACC1,$IN01_0,${R1}[0]
	 ubfx	x7,x9,#26,#26

	add	$IN01_3,$IN01_3,$H3
	 add	x4,x4,x5,lsl#32		// bfi	x4,x5,#32,#32
	umlal	$ACC3,$IN01_1,${R2}[0]
	 extr	x8,x12,x8,#52
	umlal	$ACC4,$IN01_1,${R3}[0]
	 extr	x9,x13,x9,#52
	umlal	$ACC0,$IN01_1,${S4}[0]
	 add	x6,x6,x7,lsl#32		// bfi	x6,x7,#32,#32
	umlal	$ACC2,$IN01_1,${R1}[0]
	 fmov	$IN01_0,x4
	umlal	$ACC1,$IN01_1,${R0}[0]
	 and	x8,x8,#0x03ffffff

	add	$IN01_4,$IN01_4,$H4
	 and	x9,x9,#0x03ffffff
	umlal	$ACC3,$IN01_3,${R0}[0]
	 ubfx	x10,x12,#14,#26
	umlal	$ACC0,$IN01_3,${S2}[0]
	 ubfx	x11,x13,#14,#26
	umlal	$ACC4,$IN01_3,${R1}[0]
	 add	x8,x8,x9,lsl#32		// bfi	x8,x9,#32,#32
	umlal	$ACC1,$IN01_3,${S3}[0]
	 fmov	$IN01_1,x6
	umlal	$ACC2,$IN01_3,${S4}[0]
	 add	x12,$padbit,x12,lsr#40

	umlal	$ACC3,$IN01_4,${S4}[0]
	 add	x13,$padbit,x13,lsr#40
	umlal	$ACC0,$IN01_4,${S1}[0]
	 add	x10,x10,x11,lsl#32	// bfi	x10,x11,#32,#32
	umlal	$ACC4,$IN01_4,${R0}[0]
	 add	x12,x12,x13,lsl#32	// bfi	x12,x13,#32,#32
	umlal	$ACC1,$IN01_4,${S2}[0]
	 fmov	$IN01_2,x8
	umlal	$ACC2,$IN01_4,${S3}[0]
	 fmov	$IN01_3,x10
	 fmov	$IN01_4,x12

	/////////////////////////////////////////////////////////////////
	// lazy reduction as discussed in "NEON crypto" by D.J. Bernstein
	// and P. Schwabe
	//
	// [see discussion in poly1305-armv4 module]

	ushr	$T0.2d,$ACC3,#26
	xtn	$H3,$ACC3
	 ushr	$T1.2d,$ACC0,#26
	 and	$ACC0,$ACC0,$MASK.2d
	add	$ACC4,$ACC4,$T0.2d	// h3 -> h4
	bic	$H3,#0xfc,lsl#24	// &=0x03ffffff
	 add	$ACC1,$ACC1,$T1.2d	// h0 -> h1

	ushr	$T0.2d,$ACC4,#26
	xtn	$H4,$ACC4
	 ushr	$T1.2d,$ACC1,#26
	 xtn	$H1,$ACC1
	bic	$H4,#0xfc,lsl#24
	 add	$ACC2,$ACC2,$T1.2d	// h1 -> h2

	add	$ACC0,$ACC0,$T0.2d
	shl	$T0.2d,$T0.2d,#2
	 shrn	$T1.2s,$ACC2,#26
	 xtn	$H2,$ACC2
	add	$ACC0,$ACC0,$T0.2d	// h4 -> h0
	 bic	$H1,#0xfc,lsl#24
	 add	$H3,$H3,$T1.2s		// h2 -> h3
	 bic	$H2,#0xfc,lsl#24

	shrn	$T0.2s,$ACC0,#26
	xtn	$H0,$ACC0
	 ushr	$T1.2s,$H3,#26
	 bic	$H3,#0xfc,lsl#24
	 bic	$H0,#0xfc,lsl#24
	add	$H1,$H1,$T0.2s		// h0 -> h1
	 add	$H4,$H4,$T1.2s		// h3 -> h4

	b.hi	.Loop_neon

.Lskip_loop:
	dup	$IN23_2,${IN23_2}[0]
	add	$IN01_2,$IN01_2,$H2

	////////////////////////////////////////////////////////////////
	// multiply (inp[0:1]+hash) or inp[2:3] by r^2:r^1

	adds	$len,$len,#32
	b.ne	.Long_tail

	dup	$IN23_2,${IN01_2}[0]
	add	$IN23_0,$IN01_0,$H0
	add	$IN23_3,$IN01_3,$H3
	add	$IN23_1,$IN01_1,$H1
	add	$IN23_4,$IN01_4,$H4

.Long_tail:
	dup	$IN23_0,${IN23_0}[0]
	umull2	$ACC0,$IN23_2,${S3}
	umull2	$ACC3,$IN23_2,${R1}
	umull2	$ACC4,$IN23_2,${R2}
	umull2	$ACC2,$IN23_2,${R0}
	umull2	$ACC1,$IN23_2,${S4}

	dup	$IN23_1,${IN23_1}[0]
	umlal2	$ACC0,$IN23_0,${R0}
	umlal2	$ACC2,$IN23_0,${R2}
	umlal2	$ACC3,$IN23_0,${R3}
	umlal2	$ACC4,$IN23_0,${R4}
	umlal2	$ACC1,$IN23_0,${R1}

	dup	$IN23_3,${IN23_3}[0]
	umlal2	$ACC0,$IN23_1,${S4}
	umlal2	$ACC3,$IN23_1,${R2}
	umlal2	$ACC2,$IN23_1,${R1}
	umlal2	$ACC4,$IN23_1,${R3}
	umlal2	$ACC1,$IN23_1,${R0}

	dup	$IN23_4,${IN23_4}[0]
	umlal2	$ACC3,$IN23_3,${R0}
	umlal2	$ACC4,$IN23_3,${R1}
	umlal2	$ACC0,$IN23_3,${S2}
	umlal2	$ACC1,$IN23_3,${S3}
	umlal2	$ACC2,$IN23_3,${S4}

	umlal2	$ACC3,$IN23_4,${S4}
	umlal2	$ACC0,$IN23_4,${S1}
	umlal2	$ACC4,$IN23_4,${R0}
	umlal2	$ACC1,$IN23_4,${S2}
	umlal2	$ACC2,$IN23_4,${S3}

	b.eq	.Lshort_tail

	////////////////////////////////////////////////////////////////
	// (hash+inp[0:1])*r^4:r^3 and accumulate

	add	$IN01_0,$IN01_0,$H0
	umlal	$ACC3,$IN01_2,${R1}
	umlal	$ACC0,$IN01_2,${S3}
	umlal	$ACC4,$IN01_2,${R2}
	umlal	$ACC1,$IN01_2,${S4}
	umlal	$ACC2,$IN01_2,${R0}

	add	$IN01_1,$IN01_1,$H1
	umlal	$ACC3,$IN01_0,${R3}
	umlal	$ACC0,$IN01_0,${R0}
	umlal	$ACC4,$IN01_0,${R4}
	umlal	$ACC1,$IN01_0,${R1}
	umlal	$ACC2,$IN01_0,${R2}

	add	$IN01_3,$IN01_3,$H3
	umlal	$ACC3,$IN01_1,${R2}
	umlal	$ACC0,$IN01_1,${S4}
	umlal	$ACC4,$IN01_1,${R3}
	umlal	$ACC1,$IN01_1,${R0}
	umlal	$ACC2,$IN01_1,${R1}

	add	$IN01_4,$IN01_4,$H4
	umlal	$ACC3,$IN01_3,${R0}
	umlal	$ACC0,$IN01_3,${S2}
	umlal	$ACC4,$IN01_3,${R1}
	umlal	$ACC1,$IN01_3,${S3}
	umlal	$ACC2,$IN01_3,${S4}

	umlal	$ACC3,$IN01_4,${S4}
	umlal	$ACC0,$IN01_4,${S1}
	umlal	$ACC4,$IN01_4,${R0}
	umlal	$ACC1,$IN01_4,${S2}
	umlal	$ACC2,$IN01_4,${S3}

.Lshort_tail:
	////////////////////////////////////////////////////////////////
	// horizontal add

	addp	$ACC3,$ACC3,$ACC3
	 ldp	d8,d9,[sp,#16]		// meet ABI requirements
	addp	$ACC0,$ACC0,$ACC0
	 ldp	d10,d11,[sp,#32]
	addp	$ACC4,$ACC4,$ACC4
	 ldp	d12,d13,[sp,#48]
	addp	$ACC1,$ACC1,$ACC1
	 ldp	d14,d15,[sp,#64]
	addp	$ACC2,$ACC2,$ACC2

	////////////////////////////////////////////////////////////////
	// lazy reduction, but without narrowing

	ushr	$T0.2d,$ACC3,#26
	and	$ACC3,$ACC3,$MASK.2d
	 ushr	$T1.2d,$ACC0,#26
	 and	$ACC0,$ACC0,$MASK.2d

	add	$ACC4,$ACC4,$T0.2d	// h3 -> h4
	 add	$ACC1,$ACC1,$T1.2d	// h0 -> h1

	ushr	$T0.2d,$ACC4,#26
	and	$ACC4,$ACC4,$MASK.2d
	 ushr	$T1.2d,$ACC1,#26
	 and	$ACC1,$ACC1,$MASK.2d
	 add	$ACC2,$ACC2,$T1.2d	// h1 -> h2

	add	$ACC0,$ACC0,$T0.2d
	shl	$T0.2d,$T0.2d,#2
	 ushr	$T1.2d,$ACC2,#26
	 and	$ACC2,$ACC2,$MASK.2d
	add	$ACC0,$ACC0,$T0.2d	// h4 -> h0
	 add	$ACC3,$ACC3,$T1.2d	// h2 -> h3

	ushr	$T0.2d,$ACC0,#26
	and	$ACC0,$ACC0,$MASK.2d
	 ushr	$T1.2d,$ACC3,#26
	 and	$ACC3,$ACC3,$MASK.2d
	add	$ACC1,$ACC1,$T0.2d	// h0 -> h1
	 add	$ACC4,$ACC4,$T1.2d	// h3 -> h4

	////////////////////////////////////////////////////////////////
	// write the result, can be partially reduced

	st4	{$ACC0,$ACC1,$ACC2,$ACC3}[0],[$ctx],#16
	st1	{$ACC4}[0],[$ctx]

.Lno_data_neon:
	ldr	x29,[sp],#80
	ret
.size	poly1305_blocks_neon,.-poly1305_blocks_neon

.type	poly1305_emit_neon,%function
.align	5
poly1305_emit_neon:
	ldr	$is_base2_26,[$ctx,#24]
	cbz	$is_base2_26,poly1305_emit

	ldp	w10,w11,[$ctx]		// load hash value base 2^26
	ldp	w12,w13,[$ctx,#8]
	ldr	w14,[$ctx,#16]

	add	$h0,x10,x11,lsl#26	// base 2^26 -> base 2^64
	lsr	$h1,x12,#12
	adds	$h0,$h0,x12,lsl#52
	add	$h1,$h1,x13,lsl#14
	adc	$h1,$h1,xzr
	lsr	$h2,x14,#24
	adds	$h1,$h1,x14,lsl#40
	adc	$h2,$h2,xzr		// can be partially reduced...

	ldp	$t0,$t1,[$nonce]	// load nonce

	and	$d0,$h2,#-4		// ... so reduce
	add	$d0,$d0,$h2,lsr#2
	and	$h2,$h2,#3
	adds	$h0,$h0,$d0
	adcs	$h1,$h1,xzr
	adc	$h2,$h2,xzr

	adds	$d0,$h0,#5		// compare to modulus
	adcs	$d1,$h1,xzr
	adc	$d2,$h2,xzr

	tst	$d2,#-4			// see if it's carried/borrowed

	csel	$h0,$h0,$d0,eq
	csel	$h1,$h1,$d1,eq

#ifdef	__ARMEB__
	ror	$t0,$t0,#32		// flip nonce words
	ror	$t1,$t1,#32
#endif
	adds	$h0,$h0,$t0		// accumulate nonce
	adc	$h1,$h1,$t1
#ifdef	__ARMEB__
	rev	$h0,$h0			// flip output bytes
	rev	$h1,$h1
#endif
	stp	$h0,$h1,[$mac]		// write result

	ret
.size	poly1305_emit_neon,.-poly1305_emit_neon

.align	5
.Lzeros:
.long	0,0,0,0,0,0,0,0
.LOPENSSL_armcap_P:
#ifdef	__ILP32__
.long	OPENSSL_armcap_P-.
#else
.quad	OPENSSL_armcap_P-.
#endif
.asciz	"Poly1305 for ARMv8, CRYPTOGAMS by <appro\@openssl.org>"
.align	2
___

foreach (split("\n",$code)) {
	s/\b(shrn\s+v[0-9]+)\.[24]d/$1.2s/			or
	s/\b(fmov\s+)v([0-9]+)[^,]*,\s*x([0-9]+)/$1d$2,x$3/	or
	(m/\bdup\b/ and (s/\.[24]s/.2d/g or 1))			or
	(m/\b(eor|and)/ and (s/\.[248][sdh]/.16b/g or 1))	or
	(m/\bum(ul|la)l\b/ and (s/\.4s/.2s/g or 1))		or
	(m/\bum(ul|la)l2\b/ and (s/\.2s/.4s/g or 1))		or
	(m/\bst[1-4]\s+{[^}]+}\[/ and (s/\.[24]d/.s/g or 1));

	s/\.[124]([sd])\[/.$1\[/;

	print $_,"\n";
}
close STDOUT;