arch/arm/crypto/ghash-ce-core.S - pub/scm/linux/kernel/git/jack/linux-fs - Git at Google

 /*
  * Accelerated GHASH implementation with NEON/ARMv8 vmull.p8/64 instructions.
  *
  * Copyright (C) 2015 - 2017 Linaro Ltd. <ard.biesheuvel@linaro.org>
  *
  * This program is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 as published
  * by the Free Software Foundation.
  */

 #include <linux/linkage.h>
 #include <asm/assembler.h>

 	SHASH		.req	q0
 	T1		.req	q1
 	XL		.req	q2
 	XM		.req	q3
 	XH		.req	q4
 	IN1		.req	q4

 	SHASH_L		.req	d0
 	SHASH_H		.req	d1
 	T1_L		.req	d2
 	T1_H		.req	d3
 	XL_L		.req	d4
 	XL_H		.req	d5
 	XM_L		.req	d6
 	XM_H		.req	d7
 	XH_L		.req	d8

 	t0l		.req	d10
 	t0h		.req	d11
 	t1l		.req	d12
 	t1h		.req	d13
 	t2l		.req	d14
 	t2h		.req	d15
 	t3l		.req	d16
 	t3h		.req	d17
 	t4l		.req	d18
 	t4h		.req	d19

 	t0q		.req	q5
 	t1q		.req	q6
 	t2q		.req	q7
 	t3q		.req	q8
 	t4q		.req	q9
 	T2		.req	q9

 	s1l		.req	d20
 	s1h		.req	d21
 	s2l		.req	d22
 	s2h		.req	d23
 	s3l		.req	d24
 	s3h		.req	d25
 	s4l		.req	d26
 	s4h		.req	d27

 	MASK		.req	d28
 	SHASH2_p8	.req	d28

 	k16		.req	d29
 	k32		.req	d30
 	k48		.req	d31
 	SHASH2_p64	.req	d31

 	HH		.req	q10
 	HH3		.req	q11
 	HH4		.req	q12
 	HH34		.req	q13

 	HH_L		.req	d20
 	HH_H		.req	d21
 	HH3_L		.req	d22
 	HH3_H		.req	d23
 	HH4_L		.req	d24
 	HH4_H		.req	d25
 	HH34_L		.req	d26
 	HH34_H		.req	d27
 	SHASH2_H	.req	d29

 	XL2		.req	q5
 	XM2		.req	q6
 	XH2		.req	q7
 	T3		.req	q8

 	XL2_L		.req	d10
 	XL2_H		.req	d11
 	XM2_L		.req	d12
 	XM2_H		.req	d13
 	T3_L		.req	d16
 	T3_H		.req	d17

 	.text
 	.fpu		crypto-neon-fp-armv8

 	.macro		__pmull_p64, rd, rn, rm, b1, b2, b3, b4
 	vmull.p64	\rd, \rn, \rm
 	.endm

 	/*
 	 * This implementation of 64x64 -> 128 bit polynomial multiplication
 	 * using vmull.p8 instructions (8x8 -> 16) is taken from the paper
 	 * "Fast Software Polynomial Multiplication on ARM Processors Using
 	 * the NEON Engine" by Danilo Camara, Conrado Gouvea, Julio Lopez and
 	 * Ricardo Dahab (https://hal.inria.fr/hal-01506572)
 	 *
 	 * It has been slightly tweaked for in-order performance, and to allow
 	 * 'rq' to overlap with 'ad' or 'bd'.
 	 */
 	.macro		__pmull_p8, rq, ad, bd, b1=t4l, b2=t3l, b3=t4l, b4=t3l
 	vext.8		t0l, \ad, \ad, #1	@ A1
 	.ifc		\b1, t4l
 	vext.8		t4l, \bd, \bd, #1	@ B1
 	.endif
 	vmull.p8	t0q, t0l, \bd		@ F = A1*B
 	vext.8		t1l, \ad, \ad, #2	@ A2
 	vmull.p8	t4q, \ad, \b1		@ E = A*B1
 	.ifc		\b2, t3l
 	vext.8		t3l, \bd, \bd, #2	@ B2
 	.endif
 	vmull.p8	t1q, t1l, \bd		@ H = A2*B
 	vext.8		t2l, \ad, \ad, #3	@ A3
 	vmull.p8	t3q, \ad, \b2		@ G = A*B2
 	veor		t0q, t0q, t4q		@ L = E + F
 	.ifc		\b3, t4l
 	vext.8		t4l, \bd, \bd, #3	@ B3
 	.endif
 	vmull.p8	t2q, t2l, \bd		@ J = A3*B
 	veor		t0l, t0l, t0h		@ t0 = (L) (P0 + P1) << 8
 	veor		t1q, t1q, t3q		@ M = G + H
 	.ifc		\b4, t3l
 	vext.8		t3l, \bd, \bd, #4	@ B4
 	.endif
 	vmull.p8	t4q, \ad, \b3		@ I = A*B3
 	veor		t1l, t1l, t1h		@ t1 = (M) (P2 + P3) << 16
 	vmull.p8	t3q, \ad, \b4		@ K = A*B4
 	vand		t0h, t0h, k48
 	vand		t1h, t1h, k32
 	veor		t2q, t2q, t4q		@ N = I + J
 	veor		t0l, t0l, t0h
 	veor		t1l, t1l, t1h
 	veor		t2l, t2l, t2h		@ t2 = (N) (P4 + P5) << 24
 	vand		t2h, t2h, k16
 	veor		t3l, t3l, t3h		@ t3 = (K) (P6 + P7) << 32
 	vmov.i64	t3h, #0
 	vext.8		t0q, t0q, t0q, #15
 	veor		t2l, t2l, t2h
 	vext.8		t1q, t1q, t1q, #14
 	vmull.p8	\rq, \ad, \bd		@ D = A*B
 	vext.8		t2q, t2q, t2q, #13
 	vext.8		t3q, t3q, t3q, #12
 	veor		t0q, t0q, t1q
 	veor		t2q, t2q, t3q
 	veor		\rq, \rq, t0q
 	veor		\rq, \rq, t2q
 	.endm

 	//
 	// PMULL (64x64->128) based reduction for CPUs that can do
 	// it in a single instruction.
 	//
 	.macro		__pmull_reduce_p64
 	vmull.p64	T1, XL_L, MASK

 	veor		XH_L, XH_L, XM_H
 	vext.8		T1, T1, T1, #8
 	veor		XL_H, XL_H, XM_L
 	veor		T1, T1, XL

 	vmull.p64	XL, T1_H, MASK
 	.endm

 	//
 	// Alternative reduction for CPUs that lack support for the
 	// 64x64->128 PMULL instruction
 	//
 	.macro		__pmull_reduce_p8
 	veor		XL_H, XL_H, XM_L
 	veor		XH_L, XH_L, XM_H

 	vshl.i64	T1, XL, #57
 	vshl.i64	T2, XL, #62
 	veor		T1, T1, T2
 	vshl.i64	T2, XL, #63
 	veor		T1, T1, T2
 	veor		XL_H, XL_H, T1_L
 	veor		XH_L, XH_L, T1_H

 	vshr.u64	T1, XL, #1
 	veor		XH, XH, XL
 	veor		XL, XL, T1
 	vshr.u64	T1, T1, #6
 	vshr.u64	XL, XL, #1
 	.endm

 	.macro		ghash_update, pn
 	vld1.64		{XL}, [r1]

 	/* do the head block first, if supplied */
 	ldr		ip, [sp]
 	teq		ip, #0
 	beq		0f
 	vld1.64		{T1}, [ip]
 	teq		r0, #0
 	b		3f

 0:	.ifc		\pn, p64
 	tst		r0, #3			// skip until #blocks is a
 	bne		2f			// round multiple of 4

 	vld1.8		{XL2-XM2}, [r2]!
 1:	vld1.8		{T3-T2}, [r2]!
 	vrev64.8	XL2, XL2
 	vrev64.8	XM2, XM2

 	subs		r0, r0, #4

 	vext.8		T1, XL2, XL2, #8
 	veor		XL2_H, XL2_H, XL_L
 	veor		XL, XL, T1

 	vrev64.8	T3, T3
 	vrev64.8	T1, T2

 	vmull.p64	XH, HH4_H, XL_H			// a1 * b1
 	veor		XL2_H, XL2_H, XL_H
 	vmull.p64	XL, HH4_L, XL_L			// a0 * b0
 	vmull.p64	XM, HH34_H, XL2_H		// (a1 + a0)(b1 + b0)

 	vmull.p64	XH2, HH3_H, XM2_L		// a1 * b1
 	veor		XM2_L, XM2_L, XM2_H
 	vmull.p64	XL2, HH3_L, XM2_H		// a0 * b0
 	vmull.p64	XM2, HH34_L, XM2_L		// (a1 + a0)(b1 + b0)

 	veor		XH, XH, XH2
 	veor		XL, XL, XL2
 	veor		XM, XM, XM2

 	vmull.p64	XH2, HH_H, T3_L			// a1 * b1
 	veor		T3_L, T3_L, T3_H
 	vmull.p64	XL2, HH_L, T3_H			// a0 * b0
 	vmull.p64	XM2, SHASH2_H, T3_L		// (a1 + a0)(b1 + b0)

 	veor		XH, XH, XH2
 	veor		XL, XL, XL2
 	veor		XM, XM, XM2

 	vmull.p64	XH2, SHASH_H, T1_L		// a1 * b1
 	veor		T1_L, T1_L, T1_H
 	vmull.p64	XL2, SHASH_L, T1_H		// a0 * b0
 	vmull.p64	XM2, SHASH2_p64, T1_L		// (a1 + a0)(b1 + b0)

 	veor		XH, XH, XH2
 	veor		XL, XL, XL2
 	veor		XM, XM, XM2

 	beq		4f

 	vld1.8		{XL2-XM2}, [r2]!

 	veor		T1, XL, XH
 	veor		XM, XM, T1

 	__pmull_reduce_p64

 	veor		T1, T1, XH
 	veor		XL, XL, T1

 	b		1b
 	.endif

 2:	vld1.64		{T1}, [r2]!
 	subs		r0, r0, #1

 3:	/* multiply XL by SHASH in GF(2^128) */
 #ifndef CONFIG_CPU_BIG_ENDIAN
 	vrev64.8	T1, T1
 #endif
 	vext.8		IN1, T1, T1, #8
 	veor		T1_L, T1_L, XL_H
 	veor		XL, XL, IN1

 	__pmull_\pn	XH, XL_H, SHASH_H, s1h, s2h, s3h, s4h	@ a1 * b1
 	veor		T1, T1, XL
 	__pmull_\pn	XL, XL_L, SHASH_L, s1l, s2l, s3l, s4l	@ a0 * b0
 	__pmull_\pn	XM, T1_L, SHASH2_\pn			@ (a1+a0)(b1+b0)

 4:	veor		T1, XL, XH
 	veor		XM, XM, T1

 	__pmull_reduce_\pn

 	veor		T1, T1, XH
 	veor		XL, XL, T1

 	bne		0b

 	vst1.64		{XL}, [r1]
 	bx		lr
 	.endm

 	/*
 	 * void pmull_ghash_update(int blocks, u64 dg[], const char *src,
 	 *			   struct ghash_key const *k, const char *head)
 	 */
 ENTRY(pmull_ghash_update_p64)
 	vld1.64		{SHASH}, [r3]!
 	vld1.64		{HH}, [r3]!
 	vld1.64		{HH3-HH4}, [r3]

 	veor		SHASH2_p64, SHASH_L, SHASH_H
 	veor		SHASH2_H, HH_L, HH_H
 	veor		HH34_L, HH3_L, HH3_H
 	veor		HH34_H, HH4_L, HH4_H

 	vmov.i8		MASK, #0xe1
 	vshl.u64	MASK, MASK, #57

 	ghash_update	p64
 ENDPROC(pmull_ghash_update_p64)

 ENTRY(pmull_ghash_update_p8)
 	vld1.64		{SHASH}, [r3]
 	veor		SHASH2_p8, SHASH_L, SHASH_H

 	vext.8		s1l, SHASH_L, SHASH_L, #1
 	vext.8		s2l, SHASH_L, SHASH_L, #2
 	vext.8		s3l, SHASH_L, SHASH_L, #3
 	vext.8		s4l, SHASH_L, SHASH_L, #4
 	vext.8		s1h, SHASH_H, SHASH_H, #1
 	vext.8		s2h, SHASH_H, SHASH_H, #2
 	vext.8		s3h, SHASH_H, SHASH_H, #3
 	vext.8		s4h, SHASH_H, SHASH_H, #4

 	vmov.i64	k16, #0xffff
 	vmov.i64	k32, #0xffffffff
 	vmov.i64	k48, #0xffffffffffff

 	ghash_update	p8
 ENDPROC(pmull_ghash_update_p8)
	/*
	* Accelerated GHASH implementation with NEON/ARMv8 vmull.p8/64 instructions.
	*
	* Copyright (C) 2015 - 2017 Linaro Ltd. <ard.biesheuvel@linaro.org>
	*
	* This program is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 as published
	* by the Free Software Foundation.
	*/

	#include <linux/linkage.h>
	#include <asm/assembler.h>

	SHASH .req q0
	T1 .req q1
	XL .req q2
	XM .req q3
	XH .req q4
	IN1 .req q4

	SHASH_L .req d0
	SHASH_H .req d1
	T1_L .req d2
	T1_H .req d3
	XL_L .req d4
	XL_H .req d5
	XM_L .req d6
	XM_H .req d7
	XH_L .req d8

	t0l .req d10
	t0h .req d11
	t1l .req d12
	t1h .req d13
	t2l .req d14
	t2h .req d15
	t3l .req d16
	t3h .req d17
	t4l .req d18
	t4h .req d19

	t0q .req q5
	t1q .req q6
	t2q .req q7
	t3q .req q8
	t4q .req q9
	T2 .req q9

	s1l .req d20
	s1h .req d21
	s2l .req d22
	s2h .req d23
	s3l .req d24
	s3h .req d25
	s4l .req d26
	s4h .req d27

	MASK .req d28
	SHASH2_p8 .req d28

	k16 .req d29
	k32 .req d30
	k48 .req d31
	SHASH2_p64 .req d31

	HH .req q10
	HH3 .req q11
	HH4 .req q12
	HH34 .req q13

	HH_L .req d20
	HH_H .req d21
	HH3_L .req d22
	HH3_H .req d23
	HH4_L .req d24
	HH4_H .req d25
	HH34_L .req d26
	HH34_H .req d27
	SHASH2_H .req d29

	XL2 .req q5
	XM2 .req q6
	XH2 .req q7
	T3 .req q8

	XL2_L .req d10
	XL2_H .req d11
	XM2_L .req d12
	XM2_H .req d13
	T3_L .req d16
	T3_H .req d17

	.text
	.fpu crypto-neon-fp-armv8

	.macro __pmull_p64, rd, rn, rm, b1, b2, b3, b4
	vmull.p64 \rd, \rn, \rm
	.endm

	/*
	* This implementation of 64x64 -> 128 bit polynomial multiplication
	* using vmull.p8 instructions (8x8 -> 16) is taken from the paper
	* "Fast Software Polynomial Multiplication on ARM Processors Using
	* the NEON Engine" by Danilo Camara, Conrado Gouvea, Julio Lopez and
	* Ricardo Dahab (https://hal.inria.fr/hal-01506572)
	*
	* It has been slightly tweaked for in-order performance, and to allow
	* 'rq' to overlap with 'ad' or 'bd'.
	*/
	.macro __pmull_p8, rq, ad, bd, b1=t4l, b2=t3l, b3=t4l, b4=t3l
	vext.8 t0l, \ad, \ad, #1 @ A1
	.ifc \b1, t4l
	vext.8 t4l, \bd, \bd, #1 @ B1
	.endif
	vmull.p8 t0q, t0l, \bd @ F = A1*B
	vext.8 t1l, \ad, \ad, #2 @ A2
	vmull.p8 t4q, \ad, \b1 @ E = A*B1
	.ifc \b2, t3l
	vext.8 t3l, \bd, \bd, #2 @ B2
	.endif
	vmull.p8 t1q, t1l, \bd @ H = A2*B
	vext.8 t2l, \ad, \ad, #3 @ A3
	vmull.p8 t3q, \ad, \b2 @ G = A*B2
	veor t0q, t0q, t4q @ L = E + F
	.ifc \b3, t4l
	vext.8 t4l, \bd, \bd, #3 @ B3
	.endif
	vmull.p8 t2q, t2l, \bd @ J = A3*B
	veor t0l, t0l, t0h @ t0 = (L) (P0 + P1) << 8
	veor t1q, t1q, t3q @ M = G + H
	.ifc \b4, t3l
	vext.8 t3l, \bd, \bd, #4 @ B4
	.endif
	vmull.p8 t4q, \ad, \b3 @ I = A*B3
	veor t1l, t1l, t1h @ t1 = (M) (P2 + P3) << 16
	vmull.p8 t3q, \ad, \b4 @ K = A*B4
	vand t0h, t0h, k48
	vand t1h, t1h, k32
	veor t2q, t2q, t4q @ N = I + J
	veor t0l, t0l, t0h
	veor t1l, t1l, t1h
	veor t2l, t2l, t2h @ t2 = (N) (P4 + P5) << 24
	vand t2h, t2h, k16
	veor t3l, t3l, t3h @ t3 = (K) (P6 + P7) << 32
	vmov.i64 t3h, #0
	vext.8 t0q, t0q, t0q, #15
	veor t2l, t2l, t2h
	vext.8 t1q, t1q, t1q, #14
	vmull.p8 \rq, \ad, \bd @ D = A*B
	vext.8 t2q, t2q, t2q, #13
	vext.8 t3q, t3q, t3q, #12
	veor t0q, t0q, t1q
	veor t2q, t2q, t3q
	veor \rq, \rq, t0q
	veor \rq, \rq, t2q
	.endm

	//
	// PMULL (64x64->128) based reduction for CPUs that can do
	// it in a single instruction.
	//
	.macro __pmull_reduce_p64
	vmull.p64 T1, XL_L, MASK

	veor XH_L, XH_L, XM_H
	vext.8 T1, T1, T1, #8
	veor XL_H, XL_H, XM_L
	veor T1, T1, XL

	vmull.p64 XL, T1_H, MASK
	.endm

	//
	// Alternative reduction for CPUs that lack support for the
	// 64x64->128 PMULL instruction
	//
	.macro __pmull_reduce_p8
	veor XL_H, XL_H, XM_L
	veor XH_L, XH_L, XM_H

	vshl.i64 T1, XL, #57
	vshl.i64 T2, XL, #62
	veor T1, T1, T2
	vshl.i64 T2, XL, #63
	veor T1, T1, T2
	veor XL_H, XL_H, T1_L
	veor XH_L, XH_L, T1_H

	vshr.u64 T1, XL, #1
	veor XH, XH, XL
	veor XL, XL, T1
	vshr.u64 T1, T1, #6
	vshr.u64 XL, XL, #1
	.endm

	.macro ghash_update, pn
	vld1.64 {XL}, [r1]

	/* do the head block first, if supplied */
	ldr ip, [sp]
	teq ip, #0
	beq 0f
	vld1.64 {T1}, [ip]
	teq r0, #0
	b 3f

	0: .ifc \pn, p64
	tst r0, #3 // skip until #blocks is a
	bne 2f // round multiple of 4

	vld1.8 {XL2-XM2}, [r2]!
	1: vld1.8 {T3-T2}, [r2]!
	vrev64.8 XL2, XL2
	vrev64.8 XM2, XM2

	subs r0, r0, #4

	vext.8 T1, XL2, XL2, #8
	veor XL2_H, XL2_H, XL_L
	veor XL, XL, T1

	vrev64.8 T3, T3
	vrev64.8 T1, T2

	vmull.p64 XH, HH4_H, XL_H // a1 * b1
	veor XL2_H, XL2_H, XL_H
	vmull.p64 XL, HH4_L, XL_L // a0 * b0
	vmull.p64 XM, HH34_H, XL2_H // (a1 + a0)(b1 + b0)

	vmull.p64 XH2, HH3_H, XM2_L // a1 * b1
	veor XM2_L, XM2_L, XM2_H
	vmull.p64 XL2, HH3_L, XM2_H // a0 * b0
	vmull.p64 XM2, HH34_L, XM2_L // (a1 + a0)(b1 + b0)

	veor XH, XH, XH2
	veor XL, XL, XL2
	veor XM, XM, XM2

	vmull.p64 XH2, HH_H, T3_L // a1 * b1
	veor T3_L, T3_L, T3_H
	vmull.p64 XL2, HH_L, T3_H // a0 * b0
	vmull.p64 XM2, SHASH2_H, T3_L // (a1 + a0)(b1 + b0)

	veor XH, XH, XH2
	veor XL, XL, XL2
	veor XM, XM, XM2

	vmull.p64 XH2, SHASH_H, T1_L // a1 * b1
	veor T1_L, T1_L, T1_H
	vmull.p64 XL2, SHASH_L, T1_H // a0 * b0
	vmull.p64 XM2, SHASH2_p64, T1_L // (a1 + a0)(b1 + b0)

	veor XH, XH, XH2
	veor XL, XL, XL2
	veor XM, XM, XM2

	beq 4f

	vld1.8 {XL2-XM2}, [r2]!

	veor T1, XL, XH
	veor XM, XM, T1

	__pmull_reduce_p64

	veor T1, T1, XH
	veor XL, XL, T1

	b 1b
	.endif

	2: vld1.64 {T1}, [r2]!
	subs r0, r0, #1

	3: /* multiply XL by SHASH in GF(2^128) */
	#ifndef CONFIG_CPU_BIG_ENDIAN
	vrev64.8 T1, T1
	#endif
	vext.8 IN1, T1, T1, #8
	veor T1_L, T1_L, XL_H
	veor XL, XL, IN1

	__pmull_\pn XH, XL_H, SHASH_H, s1h, s2h, s3h, s4h @ a1 * b1
	veor T1, T1, XL
	__pmull_\pn XL, XL_L, SHASH_L, s1l, s2l, s3l, s4l @ a0 * b0
	__pmull_\pn XM, T1_L, SHASH2_\pn @ (a1+a0)(b1+b0)

	4: veor T1, XL, XH
	veor XM, XM, T1

	__pmull_reduce_\pn

	veor T1, T1, XH
	veor XL, XL, T1

	bne 0b

	vst1.64 {XL}, [r1]
	bx lr
	.endm

	/*
	* void pmull_ghash_update(int blocks, u64 dg[], const char *src,
	* struct ghash_key const k, const char head)
	*/
	ENTRY(pmull_ghash_update_p64)
	vld1.64 {SHASH}, [r3]!
	vld1.64 {HH}, [r3]!
	vld1.64 {HH3-HH4}, [r3]

	veor SHASH2_p64, SHASH_L, SHASH_H
	veor SHASH2_H, HH_L, HH_H
	veor HH34_L, HH3_L, HH3_H
	veor HH34_H, HH4_L, HH4_H

	vmov.i8 MASK, #0xe1
	vshl.u64 MASK, MASK, #57

	ghash_update p64
	ENDPROC(pmull_ghash_update_p64)

	ENTRY(pmull_ghash_update_p8)
	vld1.64 {SHASH}, [r3]
	veor SHASH2_p8, SHASH_L, SHASH_H

	vext.8 s1l, SHASH_L, SHASH_L, #1
	vext.8 s2l, SHASH_L, SHASH_L, #2
	vext.8 s3l, SHASH_L, SHASH_L, #3
	vext.8 s4l, SHASH_L, SHASH_L, #4
	vext.8 s1h, SHASH_H, SHASH_H, #1
	vext.8 s2h, SHASH_H, SHASH_H, #2
	vext.8 s3h, SHASH_H, SHASH_H, #3
	vext.8 s4h, SHASH_H, SHASH_H, #4

	vmov.i64 k16, #0xffff
	vmov.i64 k32, #0xffffffff
	vmov.i64 k48, #0xffffffffffff

	ghash_update p8
	ENDPROC(pmull_ghash_update_p8)