crypto: arm64/sm3 - add NEON assembly implementation

This patch adds the NEON acceleration implementation of the SM3 hash
algorithm. The main algorithm is based on SM3 NEON accelerated work of
the libgcrypt project.

Benchmark on T-Head Yitian-710 2.75 GHz, the data comes from the 326 mode
of tcrypt, and compares the performance data of sm3-generic and sm3-ce.
The abscissas are blocks of different lengths. The data is tabulated and
the unit is Mb/s:

update-size    |      16      64     256    1024    2048    4096    8192
---------------+--------------------------------------------------------
sm3-generic    |  185.24  221.28  301.26  307.43  300.83  308.82  308.91
sm3-neon       |  171.81  220.20  322.94  339.28  334.09  343.61  343.87
sm3-ce         |  227.48  333.48  502.62  527.87  520.45  534.91  535.40

Signed-off-by: Tianjia Zhang <tianjia.zhang@linux.alibaba.com>
Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
This commit is contained in:
Tianjia Zhang 2022-10-27 14:54:54 +08:00 committed by Herbert Xu
parent e1fa51aa2b
commit a41b212946
4 changed files with 717 additions and 0 deletions

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@ -96,6 +96,17 @@ config CRYPTO_SHA3_ARM64
Architecture: arm64 using:
- ARMv8.2 Crypto Extensions
config CRYPTO_SM3_NEON
tristate "Hash functions: SM3 (NEON)"
depends on KERNEL_MODE_NEON
select CRYPTO_HASH
select CRYPTO_SM3
help
SM3 (ShangMi 3) secure hash function (OSCCA GM/T 0004-2012)
Architecture: arm64 using:
- NEON (Advanced SIMD) extensions
config CRYPTO_SM3_ARM64_CE
tristate "Hash functions: SM3 (ARMv8.2 Crypto Extensions)"
depends on KERNEL_MODE_NEON

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@ -17,6 +17,9 @@ sha512-ce-y := sha512-ce-glue.o sha512-ce-core.o
obj-$(CONFIG_CRYPTO_SHA3_ARM64) += sha3-ce.o
sha3-ce-y := sha3-ce-glue.o sha3-ce-core.o
obj-$(CONFIG_CRYPTO_SM3_NEON) += sm3-neon.o
sm3-neon-y := sm3-neon-glue.o sm3-neon-core.o
obj-$(CONFIG_CRYPTO_SM3_ARM64_CE) += sm3-ce.o
sm3-ce-y := sm3-ce-glue.o sm3-ce-core.o

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@ -0,0 +1,600 @@
// SPDX-License-Identifier: GPL-2.0-or-later
/*
* sm3-neon-core.S - SM3 secure hash using NEON instructions
*
* Linux/arm64 port of the libgcrypt SM3 implementation for AArch64
*
* Copyright (C) 2021 Jussi Kivilinna <jussi.kivilinna@iki.fi>
* Copyright (c) 2022 Tianjia Zhang <tianjia.zhang@linux.alibaba.com>
*/
#include <linux/linkage.h>
#include <asm/assembler.h>
/* Context structure */
#define state_h0 0
#define state_h1 4
#define state_h2 8
#define state_h3 12
#define state_h4 16
#define state_h5 20
#define state_h6 24
#define state_h7 28
/* Stack structure */
#define STACK_W_SIZE (32 * 2 * 3)
#define STACK_W (0)
#define STACK_SIZE (STACK_W + STACK_W_SIZE)
/* Register macros */
#define RSTATE x0
#define RDATA x1
#define RNBLKS x2
#define RKPTR x28
#define RFRAME x29
#define ra w3
#define rb w4
#define rc w5
#define rd w6
#define re w7
#define rf w8
#define rg w9
#define rh w10
#define t0 w11
#define t1 w12
#define t2 w13
#define t3 w14
#define t4 w15
#define t5 w16
#define t6 w17
#define k_even w19
#define k_odd w20
#define addr0 x21
#define addr1 x22
#define s0 w23
#define s1 w24
#define s2 w25
#define s3 w26
#define W0 v0
#define W1 v1
#define W2 v2
#define W3 v3
#define W4 v4
#define W5 v5
#define XTMP0 v6
#define XTMP1 v7
#define XTMP2 v16
#define XTMP3 v17
#define XTMP4 v18
#define XTMP5 v19
#define XTMP6 v20
/* Helper macros. */
#define _(...) /*_*/
#define clear_vec(x) \
movi x.8h, #0;
#define rolw(o, a, n) \
ror o, a, #(32 - n);
/* Round function macros. */
#define GG1_1(x, y, z, o, t) \
eor o, x, y;
#define GG1_2(x, y, z, o, t) \
eor o, o, z;
#define GG1_3(x, y, z, o, t)
#define FF1_1(x, y, z, o, t) GG1_1(x, y, z, o, t)
#define FF1_2(x, y, z, o, t)
#define FF1_3(x, y, z, o, t) GG1_2(x, y, z, o, t)
#define GG2_1(x, y, z, o, t) \
bic o, z, x;
#define GG2_2(x, y, z, o, t) \
and t, y, x;
#define GG2_3(x, y, z, o, t) \
eor o, o, t;
#define FF2_1(x, y, z, o, t) \
eor o, x, y;
#define FF2_2(x, y, z, o, t) \
and t, x, y; \
and o, o, z;
#define FF2_3(x, y, z, o, t) \
eor o, o, t;
#define R(i, a, b, c, d, e, f, g, h, k, K_LOAD, round, widx, wtype, IOP, iop_param) \
K_LOAD(round); \
ldr t5, [sp, #(wtype##_W1_ADDR(round, widx))]; \
rolw(t0, a, 12); /* rol(a, 12) => t0 */ \
IOP(1, iop_param); \
FF##i##_1(a, b, c, t1, t2); \
ldr t6, [sp, #(wtype##_W1W2_ADDR(round, widx))]; \
add k, k, e; \
IOP(2, iop_param); \
GG##i##_1(e, f, g, t3, t4); \
FF##i##_2(a, b, c, t1, t2); \
IOP(3, iop_param); \
add k, k, t0; \
add h, h, t5; \
add d, d, t6; /* w1w2 + d => d */ \
IOP(4, iop_param); \
rolw(k, k, 7); /* rol (t0 + e + t), 7) => k */ \
GG##i##_2(e, f, g, t3, t4); \
add h, h, k; /* h + w1 + k => h */ \
IOP(5, iop_param); \
FF##i##_3(a, b, c, t1, t2); \
eor t0, t0, k; /* k ^ t0 => t0 */ \
GG##i##_3(e, f, g, t3, t4); \
add d, d, t1; /* FF(a,b,c) + d => d */ \
IOP(6, iop_param); \
add t3, t3, h; /* GG(e,f,g) + h => t3 */ \
rolw(b, b, 9); /* rol(b, 9) => b */ \
eor h, t3, t3, ror #(32-9); \
IOP(7, iop_param); \
add d, d, t0; /* t0 + d => d */ \
rolw(f, f, 19); /* rol(f, 19) => f */ \
IOP(8, iop_param); \
eor h, h, t3, ror #(32-17); /* P0(t3) => h */
#define R1(a, b, c, d, e, f, g, h, k, K_LOAD, round, widx, wtype, IOP, iop_param) \
R(1, ##a, ##b, ##c, ##d, ##e, ##f, ##g, ##h, ##k, K_LOAD, round, widx, wtype, IOP, iop_param)
#define R2(a, b, c, d, e, f, g, h, k, K_LOAD, round, widx, wtype, IOP, iop_param) \
R(2, ##a, ##b, ##c, ##d, ##e, ##f, ##g, ##h, ##k, K_LOAD, round, widx, wtype, IOP, iop_param)
#define KL(round) \
ldp k_even, k_odd, [RKPTR, #(4*(round))];
/* Input expansion macros. */
/* Byte-swapped input address. */
#define IW_W_ADDR(round, widx, offs) \
(STACK_W + ((round) / 4) * 64 + (offs) + ((widx) * 4))
/* Expanded input address. */
#define XW_W_ADDR(round, widx, offs) \
(STACK_W + ((((round) / 3) - 4) % 2) * 64 + (offs) + ((widx) * 4))
/* Rounds 1-12, byte-swapped input block addresses. */
#define IW_W1_ADDR(round, widx) IW_W_ADDR(round, widx, 32)
#define IW_W1W2_ADDR(round, widx) IW_W_ADDR(round, widx, 48)
/* Rounds 1-12, expanded input block addresses. */
#define XW_W1_ADDR(round, widx) XW_W_ADDR(round, widx, 0)
#define XW_W1W2_ADDR(round, widx) XW_W_ADDR(round, widx, 16)
/* Input block loading.
* Interleaving within round function needed for in-order CPUs. */
#define LOAD_W_VEC_1_1() \
add addr0, sp, #IW_W1_ADDR(0, 0);
#define LOAD_W_VEC_1_2() \
add addr1, sp, #IW_W1_ADDR(4, 0);
#define LOAD_W_VEC_1_3() \
ld1 {W0.16b}, [RDATA], #16;
#define LOAD_W_VEC_1_4() \
ld1 {W1.16b}, [RDATA], #16;
#define LOAD_W_VEC_1_5() \
ld1 {W2.16b}, [RDATA], #16;
#define LOAD_W_VEC_1_6() \
ld1 {W3.16b}, [RDATA], #16;
#define LOAD_W_VEC_1_7() \
rev32 XTMP0.16b, W0.16b;
#define LOAD_W_VEC_1_8() \
rev32 XTMP1.16b, W1.16b;
#define LOAD_W_VEC_2_1() \
rev32 XTMP2.16b, W2.16b;
#define LOAD_W_VEC_2_2() \
rev32 XTMP3.16b, W3.16b;
#define LOAD_W_VEC_2_3() \
eor XTMP4.16b, XTMP1.16b, XTMP0.16b;
#define LOAD_W_VEC_2_4() \
eor XTMP5.16b, XTMP2.16b, XTMP1.16b;
#define LOAD_W_VEC_2_5() \
st1 {XTMP0.16b}, [addr0], #16;
#define LOAD_W_VEC_2_6() \
st1 {XTMP4.16b}, [addr0]; \
add addr0, sp, #IW_W1_ADDR(8, 0);
#define LOAD_W_VEC_2_7() \
eor XTMP6.16b, XTMP3.16b, XTMP2.16b;
#define LOAD_W_VEC_2_8() \
ext W0.16b, XTMP0.16b, XTMP0.16b, #8; /* W0: xx, w0, xx, xx */
#define LOAD_W_VEC_3_1() \
mov W2.16b, XTMP1.16b; /* W2: xx, w6, w5, w4 */
#define LOAD_W_VEC_3_2() \
st1 {XTMP1.16b}, [addr1], #16;
#define LOAD_W_VEC_3_3() \
st1 {XTMP5.16b}, [addr1]; \
ext W1.16b, XTMP0.16b, XTMP0.16b, #4; /* W1: xx, w3, w2, w1 */
#define LOAD_W_VEC_3_4() \
ext W3.16b, XTMP1.16b, XTMP2.16b, #12; /* W3: xx, w9, w8, w7 */
#define LOAD_W_VEC_3_5() \
ext W4.16b, XTMP2.16b, XTMP3.16b, #8; /* W4: xx, w12, w11, w10 */
#define LOAD_W_VEC_3_6() \
st1 {XTMP2.16b}, [addr0], #16;
#define LOAD_W_VEC_3_7() \
st1 {XTMP6.16b}, [addr0];
#define LOAD_W_VEC_3_8() \
ext W5.16b, XTMP3.16b, XTMP3.16b, #4; /* W5: xx, w15, w14, w13 */
#define LOAD_W_VEC_1(iop_num, ...) \
LOAD_W_VEC_1_##iop_num()
#define LOAD_W_VEC_2(iop_num, ...) \
LOAD_W_VEC_2_##iop_num()
#define LOAD_W_VEC_3(iop_num, ...) \
LOAD_W_VEC_3_##iop_num()
/* Message scheduling. Note: 3 words per vector register.
* Interleaving within round function needed for in-order CPUs. */
#define SCHED_W_1_1(round, w0, w1, w2, w3, w4, w5) \
/* Load (w[i - 16]) => XTMP0 */ \
/* Load (w[i - 13]) => XTMP5 */ \
ext XTMP0.16b, w0.16b, w0.16b, #12; /* XTMP0: w0, xx, xx, xx */
#define SCHED_W_1_2(round, w0, w1, w2, w3, w4, w5) \
ext XTMP5.16b, w1.16b, w1.16b, #12;
#define SCHED_W_1_3(round, w0, w1, w2, w3, w4, w5) \
ext XTMP0.16b, XTMP0.16b, w1.16b, #12; /* XTMP0: xx, w2, w1, w0 */
#define SCHED_W_1_4(round, w0, w1, w2, w3, w4, w5) \
ext XTMP5.16b, XTMP5.16b, w2.16b, #12;
#define SCHED_W_1_5(round, w0, w1, w2, w3, w4, w5) \
/* w[i - 9] == w3 */ \
/* W3 ^ XTMP0 => XTMP0 */ \
eor XTMP0.16b, XTMP0.16b, w3.16b;
#define SCHED_W_1_6(round, w0, w1, w2, w3, w4, w5) \
/* w[i - 3] == w5 */ \
/* rol(XMM5, 15) ^ XTMP0 => XTMP0 */ \
/* rol(XTMP5, 7) => XTMP1 */ \
add addr0, sp, #XW_W1_ADDR((round), 0); \
shl XTMP2.4s, w5.4s, #15;
#define SCHED_W_1_7(round, w0, w1, w2, w3, w4, w5) \
shl XTMP1.4s, XTMP5.4s, #7;
#define SCHED_W_1_8(round, w0, w1, w2, w3, w4, w5) \
sri XTMP2.4s, w5.4s, #(32-15);
#define SCHED_W_2_1(round, w0, w1, w2, w3, w4, w5) \
sri XTMP1.4s, XTMP5.4s, #(32-7);
#define SCHED_W_2_2(round, w0, w1, w2, w3, w4, w5) \
eor XTMP0.16b, XTMP0.16b, XTMP2.16b;
#define SCHED_W_2_3(round, w0, w1, w2, w3, w4, w5) \
/* w[i - 6] == W4 */ \
/* W4 ^ XTMP1 => XTMP1 */ \
eor XTMP1.16b, XTMP1.16b, w4.16b;
#define SCHED_W_2_4(round, w0, w1, w2, w3, w4, w5) \
/* P1(XTMP0) ^ XTMP1 => W0 */ \
shl XTMP3.4s, XTMP0.4s, #15;
#define SCHED_W_2_5(round, w0, w1, w2, w3, w4, w5) \
shl XTMP4.4s, XTMP0.4s, #23;
#define SCHED_W_2_6(round, w0, w1, w2, w3, w4, w5) \
eor w0.16b, XTMP1.16b, XTMP0.16b;
#define SCHED_W_2_7(round, w0, w1, w2, w3, w4, w5) \
sri XTMP3.4s, XTMP0.4s, #(32-15);
#define SCHED_W_2_8(round, w0, w1, w2, w3, w4, w5) \
sri XTMP4.4s, XTMP0.4s, #(32-23);
#define SCHED_W_3_1(round, w0, w1, w2, w3, w4, w5) \
eor w0.16b, w0.16b, XTMP3.16b;
#define SCHED_W_3_2(round, w0, w1, w2, w3, w4, w5) \
/* Load (w[i - 3]) => XTMP2 */ \
ext XTMP2.16b, w4.16b, w4.16b, #12;
#define SCHED_W_3_3(round, w0, w1, w2, w3, w4, w5) \
eor w0.16b, w0.16b, XTMP4.16b;
#define SCHED_W_3_4(round, w0, w1, w2, w3, w4, w5) \
ext XTMP2.16b, XTMP2.16b, w5.16b, #12;
#define SCHED_W_3_5(round, w0, w1, w2, w3, w4, w5) \
/* W1 ^ W2 => XTMP3 */ \
eor XTMP3.16b, XTMP2.16b, w0.16b;
#define SCHED_W_3_6(round, w0, w1, w2, w3, w4, w5)
#define SCHED_W_3_7(round, w0, w1, w2, w3, w4, w5) \
st1 {XTMP2.16b-XTMP3.16b}, [addr0];
#define SCHED_W_3_8(round, w0, w1, w2, w3, w4, w5)
#define SCHED_W_W0W1W2W3W4W5_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W0, W1, W2, W3, W4, W5)
#define SCHED_W_W0W1W2W3W4W5_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W0, W1, W2, W3, W4, W5)
#define SCHED_W_W0W1W2W3W4W5_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W0, W1, W2, W3, W4, W5)
#define SCHED_W_W1W2W3W4W5W0_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W1, W2, W3, W4, W5, W0)
#define SCHED_W_W1W2W3W4W5W0_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W1, W2, W3, W4, W5, W0)
#define SCHED_W_W1W2W3W4W5W0_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W1, W2, W3, W4, W5, W0)
#define SCHED_W_W2W3W4W5W0W1_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W2, W3, W4, W5, W0, W1)
#define SCHED_W_W2W3W4W5W0W1_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W2, W3, W4, W5, W0, W1)
#define SCHED_W_W2W3W4W5W0W1_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W2, W3, W4, W5, W0, W1)
#define SCHED_W_W3W4W5W0W1W2_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W3, W4, W5, W0, W1, W2)
#define SCHED_W_W3W4W5W0W1W2_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W3, W4, W5, W0, W1, W2)
#define SCHED_W_W3W4W5W0W1W2_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W3, W4, W5, W0, W1, W2)
#define SCHED_W_W4W5W0W1W2W3_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W4, W5, W0, W1, W2, W3)
#define SCHED_W_W4W5W0W1W2W3_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W4, W5, W0, W1, W2, W3)
#define SCHED_W_W4W5W0W1W2W3_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W4, W5, W0, W1, W2, W3)
#define SCHED_W_W5W0W1W2W3W4_1(iop_num, round) \
SCHED_W_1_##iop_num(round, W5, W0, W1, W2, W3, W4)
#define SCHED_W_W5W0W1W2W3W4_2(iop_num, round) \
SCHED_W_2_##iop_num(round, W5, W0, W1, W2, W3, W4)
#define SCHED_W_W5W0W1W2W3W4_3(iop_num, round) \
SCHED_W_3_##iop_num(round, W5, W0, W1, W2, W3, W4)
/*
* Transform blocks*64 bytes (blocks*16 32-bit words) at 'src'.
*
* void sm3_neon_transform(struct sm3_state *sst, u8 const *src,
* int blocks)
*/
.text
.align 3
SYM_FUNC_START(sm3_neon_transform)
ldp ra, rb, [RSTATE, #0]
ldp rc, rd, [RSTATE, #8]
ldp re, rf, [RSTATE, #16]
ldp rg, rh, [RSTATE, #24]
stp x28, x29, [sp, #-16]!
stp x19, x20, [sp, #-16]!
stp x21, x22, [sp, #-16]!
stp x23, x24, [sp, #-16]!
stp x25, x26, [sp, #-16]!
mov RFRAME, sp
sub addr0, sp, #STACK_SIZE
adr_l RKPTR, .LKtable
and sp, addr0, #(~63)
/* Preload first block. */
LOAD_W_VEC_1(1, 0)
LOAD_W_VEC_1(2, 0)
LOAD_W_VEC_1(3, 0)
LOAD_W_VEC_1(4, 0)
LOAD_W_VEC_1(5, 0)
LOAD_W_VEC_1(6, 0)
LOAD_W_VEC_1(7, 0)
LOAD_W_VEC_1(8, 0)
LOAD_W_VEC_2(1, 0)
LOAD_W_VEC_2(2, 0)
LOAD_W_VEC_2(3, 0)
LOAD_W_VEC_2(4, 0)
LOAD_W_VEC_2(5, 0)
LOAD_W_VEC_2(6, 0)
LOAD_W_VEC_2(7, 0)
LOAD_W_VEC_2(8, 0)
LOAD_W_VEC_3(1, 0)
LOAD_W_VEC_3(2, 0)
LOAD_W_VEC_3(3, 0)
LOAD_W_VEC_3(4, 0)
LOAD_W_VEC_3(5, 0)
LOAD_W_VEC_3(6, 0)
LOAD_W_VEC_3(7, 0)
LOAD_W_VEC_3(8, 0)
.balign 16
.Loop:
/* Transform 0-3 */
R1(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 0, 0, IW, _, 0)
R1(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 1, 1, IW, _, 0)
R1(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 2, 2, IW, _, 0)
R1(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 3, 3, IW, _, 0)
/* Transform 4-7 + Precalc 12-14 */
R1(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 4, 0, IW, _, 0)
R1(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 5, 1, IW, _, 0)
R1(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 6, 2, IW, SCHED_W_W0W1W2W3W4W5_1, 12)
R1(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 7, 3, IW, SCHED_W_W0W1W2W3W4W5_2, 12)
/* Transform 8-11 + Precalc 12-17 */
R1(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 8, 0, IW, SCHED_W_W0W1W2W3W4W5_3, 12)
R1(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 9, 1, IW, SCHED_W_W1W2W3W4W5W0_1, 15)
R1(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 10, 2, IW, SCHED_W_W1W2W3W4W5W0_2, 15)
R1(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 11, 3, IW, SCHED_W_W1W2W3W4W5W0_3, 15)
/* Transform 12-14 + Precalc 18-20 */
R1(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 12, 0, XW, SCHED_W_W2W3W4W5W0W1_1, 18)
R1(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 13, 1, XW, SCHED_W_W2W3W4W5W0W1_2, 18)
R1(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 14, 2, XW, SCHED_W_W2W3W4W5W0W1_3, 18)
/* Transform 15-17 + Precalc 21-23 */
R1(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 15, 0, XW, SCHED_W_W3W4W5W0W1W2_1, 21)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 16, 1, XW, SCHED_W_W3W4W5W0W1W2_2, 21)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 17, 2, XW, SCHED_W_W3W4W5W0W1W2_3, 21)
/* Transform 18-20 + Precalc 24-26 */
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 18, 0, XW, SCHED_W_W4W5W0W1W2W3_1, 24)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 19, 1, XW, SCHED_W_W4W5W0W1W2W3_2, 24)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 20, 2, XW, SCHED_W_W4W5W0W1W2W3_3, 24)
/* Transform 21-23 + Precalc 27-29 */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 21, 0, XW, SCHED_W_W5W0W1W2W3W4_1, 27)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 22, 1, XW, SCHED_W_W5W0W1W2W3W4_2, 27)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 23, 2, XW, SCHED_W_W5W0W1W2W3W4_3, 27)
/* Transform 24-26 + Precalc 30-32 */
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 24, 0, XW, SCHED_W_W0W1W2W3W4W5_1, 30)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 25, 1, XW, SCHED_W_W0W1W2W3W4W5_2, 30)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 26, 2, XW, SCHED_W_W0W1W2W3W4W5_3, 30)
/* Transform 27-29 + Precalc 33-35 */
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 27, 0, XW, SCHED_W_W1W2W3W4W5W0_1, 33)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 28, 1, XW, SCHED_W_W1W2W3W4W5W0_2, 33)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 29, 2, XW, SCHED_W_W1W2W3W4W5W0_3, 33)
/* Transform 30-32 + Precalc 36-38 */
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 30, 0, XW, SCHED_W_W2W3W4W5W0W1_1, 36)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 31, 1, XW, SCHED_W_W2W3W4W5W0W1_2, 36)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 32, 2, XW, SCHED_W_W2W3W4W5W0W1_3, 36)
/* Transform 33-35 + Precalc 39-41 */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 33, 0, XW, SCHED_W_W3W4W5W0W1W2_1, 39)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 34, 1, XW, SCHED_W_W3W4W5W0W1W2_2, 39)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 35, 2, XW, SCHED_W_W3W4W5W0W1W2_3, 39)
/* Transform 36-38 + Precalc 42-44 */
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 36, 0, XW, SCHED_W_W4W5W0W1W2W3_1, 42)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 37, 1, XW, SCHED_W_W4W5W0W1W2W3_2, 42)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 38, 2, XW, SCHED_W_W4W5W0W1W2W3_3, 42)
/* Transform 39-41 + Precalc 45-47 */
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 39, 0, XW, SCHED_W_W5W0W1W2W3W4_1, 45)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 40, 1, XW, SCHED_W_W5W0W1W2W3W4_2, 45)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 41, 2, XW, SCHED_W_W5W0W1W2W3W4_3, 45)
/* Transform 42-44 + Precalc 48-50 */
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 42, 0, XW, SCHED_W_W0W1W2W3W4W5_1, 48)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 43, 1, XW, SCHED_W_W0W1W2W3W4W5_2, 48)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 44, 2, XW, SCHED_W_W0W1W2W3W4W5_3, 48)
/* Transform 45-47 + Precalc 51-53 */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 45, 0, XW, SCHED_W_W1W2W3W4W5W0_1, 51)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 46, 1, XW, SCHED_W_W1W2W3W4W5W0_2, 51)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 47, 2, XW, SCHED_W_W1W2W3W4W5W0_3, 51)
/* Transform 48-50 + Precalc 54-56 */
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 48, 0, XW, SCHED_W_W2W3W4W5W0W1_1, 54)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 49, 1, XW, SCHED_W_W2W3W4W5W0W1_2, 54)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 50, 2, XW, SCHED_W_W2W3W4W5W0W1_3, 54)
/* Transform 51-53 + Precalc 57-59 */
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 51, 0, XW, SCHED_W_W3W4W5W0W1W2_1, 57)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 52, 1, XW, SCHED_W_W3W4W5W0W1W2_2, 57)
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 53, 2, XW, SCHED_W_W3W4W5W0W1W2_3, 57)
/* Transform 54-56 + Precalc 60-62 */
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 54, 0, XW, SCHED_W_W4W5W0W1W2W3_1, 60)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 55, 1, XW, SCHED_W_W4W5W0W1W2W3_2, 60)
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 56, 2, XW, SCHED_W_W4W5W0W1W2W3_3, 60)
/* Transform 57-59 + Precalc 63 */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 57, 0, XW, SCHED_W_W5W0W1W2W3W4_1, 63)
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 58, 1, XW, SCHED_W_W5W0W1W2W3W4_2, 63)
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 59, 2, XW, SCHED_W_W5W0W1W2W3W4_3, 63)
/* Transform 60 */
R2(ra, rb, rc, rd, re, rf, rg, rh, k_even, KL, 60, 0, XW, _, _)
subs RNBLKS, RNBLKS, #1
b.eq .Lend
/* Transform 61-63 + Preload next block */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 61, 1, XW, LOAD_W_VEC_1, _)
ldp s0, s1, [RSTATE, #0]
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 62, 2, XW, LOAD_W_VEC_2, _)
ldp s2, s3, [RSTATE, #8]
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 63, 0, XW, LOAD_W_VEC_3, _)
/* Update the chaining variables. */
eor ra, ra, s0
eor rb, rb, s1
ldp s0, s1, [RSTATE, #16]
eor rc, rc, s2
ldp k_even, k_odd, [RSTATE, #24]
eor rd, rd, s3
eor re, re, s0
stp ra, rb, [RSTATE, #0]
eor rf, rf, s1
stp rc, rd, [RSTATE, #8]
eor rg, rg, k_even
stp re, rf, [RSTATE, #16]
eor rh, rh, k_odd
stp rg, rh, [RSTATE, #24]
b .Loop
.Lend:
/* Transform 61-63 */
R2(rd, ra, rb, rc, rh, re, rf, rg, k_odd, _, 61, 1, XW, _, _)
ldp s0, s1, [RSTATE, #0]
R2(rc, rd, ra, rb, rg, rh, re, rf, k_even, KL, 62, 2, XW, _, _)
ldp s2, s3, [RSTATE, #8]
R2(rb, rc, rd, ra, rf, rg, rh, re, k_odd, _, 63, 0, XW, _, _)
/* Update the chaining variables. */
eor ra, ra, s0
clear_vec(W0)
eor rb, rb, s1
clear_vec(W1)
ldp s0, s1, [RSTATE, #16]
clear_vec(W2)
eor rc, rc, s2
clear_vec(W3)
ldp k_even, k_odd, [RSTATE, #24]
clear_vec(W4)
eor rd, rd, s3
clear_vec(W5)
eor re, re, s0
clear_vec(XTMP0)
stp ra, rb, [RSTATE, #0]
clear_vec(XTMP1)
eor rf, rf, s1
clear_vec(XTMP2)
stp rc, rd, [RSTATE, #8]
clear_vec(XTMP3)
eor rg, rg, k_even
clear_vec(XTMP4)
stp re, rf, [RSTATE, #16]
clear_vec(XTMP5)
eor rh, rh, k_odd
clear_vec(XTMP6)
stp rg, rh, [RSTATE, #24]
/* Clear message expansion area */
add addr0, sp, #STACK_W
st1 {W0.16b-W3.16b}, [addr0], #64
st1 {W0.16b-W3.16b}, [addr0], #64
st1 {W0.16b-W3.16b}, [addr0]
mov sp, RFRAME
ldp x25, x26, [sp], #16
ldp x23, x24, [sp], #16
ldp x21, x22, [sp], #16
ldp x19, x20, [sp], #16
ldp x28, x29, [sp], #16
ret
SYM_FUNC_END(sm3_neon_transform)
.section ".rodata", "a"
.align 4
.LKtable:
.long 0x79cc4519, 0xf3988a32, 0xe7311465, 0xce6228cb
.long 0x9cc45197, 0x3988a32f, 0x7311465e, 0xe6228cbc
.long 0xcc451979, 0x988a32f3, 0x311465e7, 0x6228cbce
.long 0xc451979c, 0x88a32f39, 0x11465e73, 0x228cbce6
.long 0x9d8a7a87, 0x3b14f50f, 0x7629ea1e, 0xec53d43c
.long 0xd8a7a879, 0xb14f50f3, 0x629ea1e7, 0xc53d43ce
.long 0x8a7a879d, 0x14f50f3b, 0x29ea1e76, 0x53d43cec
.long 0xa7a879d8, 0x4f50f3b1, 0x9ea1e762, 0x3d43cec5
.long 0x7a879d8a, 0xf50f3b14, 0xea1e7629, 0xd43cec53
.long 0xa879d8a7, 0x50f3b14f, 0xa1e7629e, 0x43cec53d
.long 0x879d8a7a, 0x0f3b14f5, 0x1e7629ea, 0x3cec53d4
.long 0x79d8a7a8, 0xf3b14f50, 0xe7629ea1, 0xcec53d43
.long 0x9d8a7a87, 0x3b14f50f, 0x7629ea1e, 0xec53d43c
.long 0xd8a7a879, 0xb14f50f3, 0x629ea1e7, 0xc53d43ce
.long 0x8a7a879d, 0x14f50f3b, 0x29ea1e76, 0x53d43cec
.long 0xa7a879d8, 0x4f50f3b1, 0x9ea1e762, 0x3d43cec5

View File

@ -0,0 +1,103 @@
// SPDX-License-Identifier: GPL-2.0-or-later
/*
* sm3-neon-glue.c - SM3 secure hash using NEON instructions
*
* Copyright (C) 2022 Tianjia Zhang <tianjia.zhang@linux.alibaba.com>
*/
#include <asm/neon.h>
#include <asm/simd.h>
#include <asm/unaligned.h>
#include <crypto/internal/hash.h>
#include <crypto/internal/simd.h>
#include <crypto/sm3.h>
#include <crypto/sm3_base.h>
#include <linux/cpufeature.h>
#include <linux/crypto.h>
#include <linux/module.h>
asmlinkage void sm3_neon_transform(struct sm3_state *sst, u8 const *src,
int blocks);
static int sm3_neon_update(struct shash_desc *desc, const u8 *data,
unsigned int len)
{
if (!crypto_simd_usable()) {
sm3_update(shash_desc_ctx(desc), data, len);
return 0;
}
kernel_neon_begin();
sm3_base_do_update(desc, data, len, sm3_neon_transform);
kernel_neon_end();
return 0;
}
static int sm3_neon_final(struct shash_desc *desc, u8 *out)
{
if (!crypto_simd_usable()) {
sm3_final(shash_desc_ctx(desc), out);
return 0;
}
kernel_neon_begin();
sm3_base_do_finalize(desc, sm3_neon_transform);
kernel_neon_end();
return sm3_base_finish(desc, out);
}
static int sm3_neon_finup(struct shash_desc *desc, const u8 *data,
unsigned int len, u8 *out)
{
if (!crypto_simd_usable()) {
struct sm3_state *sctx = shash_desc_ctx(desc);
if (len)
sm3_update(sctx, data, len);
sm3_final(sctx, out);
return 0;
}
kernel_neon_begin();
if (len)
sm3_base_do_update(desc, data, len, sm3_neon_transform);
sm3_base_do_finalize(desc, sm3_neon_transform);
kernel_neon_end();
return sm3_base_finish(desc, out);
}
static struct shash_alg sm3_alg = {
.digestsize = SM3_DIGEST_SIZE,
.init = sm3_base_init,
.update = sm3_neon_update,
.final = sm3_neon_final,
.finup = sm3_neon_finup,
.descsize = sizeof(struct sm3_state),
.base.cra_name = "sm3",
.base.cra_driver_name = "sm3-neon",
.base.cra_blocksize = SM3_BLOCK_SIZE,
.base.cra_module = THIS_MODULE,
.base.cra_priority = 200,
};
static int __init sm3_neon_init(void)
{
return crypto_register_shash(&sm3_alg);
}
static void __exit sm3_neon_fini(void)
{
crypto_unregister_shash(&sm3_alg);
}
module_init(sm3_neon_init);
module_exit(sm3_neon_fini);
MODULE_DESCRIPTION("SM3 secure hash using NEON instructions");
MODULE_AUTHOR("Jussi Kivilinna <jussi.kivilinna@iki.fi>");
MODULE_AUTHOR("Tianjia Zhang <tianjia.zhang@linux.alibaba.com>");
MODULE_LICENSE("GPL v2");