crypto: arm/blake2b - add NEON-accelerated BLAKE2b
Add a NEON-accelerated implementation of BLAKE2b. On Cortex-A7 (which these days is the most common ARM processor that doesn't have the ARMv8 Crypto Extensions), this is over twice as fast as SHA-256, and slightly faster than SHA-1. It is also almost three times as fast as the generic implementation of BLAKE2b: Algorithm Cycles per byte (on 4096-byte messages) =================== ======================================= blake2b-256-neon 14.0 sha1-neon 16.3 blake2s-256-arm 18.8 sha1-asm 20.8 blake2s-256-generic 26.0 sha256-neon 28.9 sha256-asm 32.0 blake2b-256-generic 38.9 This implementation isn't directly based on any other implementation, but it borrows some ideas from previous NEON code I've written as well as from chacha-neon-core.S. At least on Cortex-A7, it is faster than the other NEON implementations of BLAKE2b I'm aware of (the implementation in the BLAKE2 official repository using intrinsics, and Andrew Moon's implementation which can be found in SUPERCOP). It does only one block at a time, so it performs well on short messages too. NEON-accelerated BLAKE2b is useful because there is interest in using BLAKE2b-256 for dm-verity on low-end Android devices (specifically, devices that lack the ARMv8 Crypto Extensions) to replace SHA-1. On these devices, the performance cost of upgrading to SHA-256 may be unacceptable, whereas BLAKE2b-256 would actually improve performance. Although BLAKE2b is intended for 64-bit platforms (unlike BLAKE2s which is intended for 32-bit platforms), on 32-bit ARM processors with NEON, BLAKE2b is actually faster than BLAKE2s. This is because NEON supports 64-bit operations, and because BLAKE2s's block size is too small for NEON to be helpful for it. The best I've been able to do with BLAKE2s on Cortex-A7 is 18.8 cpb with an optimized scalar implementation. (I didn't try BLAKE2sp and BLAKE3, which in theory would be faster, but they're more complex as they require running multiple hashes at once. Note that BLAKE2b already uses all the NEON bandwidth on the Cortex-A7, so I expect that any speedup from BLAKE2sp or BLAKE3 would come only from the smaller number of rounds, not from the extra parallelism.) For now this BLAKE2b implementation is only wired up to the shash API, since there is no library API for BLAKE2b yet. However, I've tried to keep things consistent with BLAKE2s, e.g. by defining blake2b_compress_arch() which is analogous to blake2s_compress_arch() and could be exported for use by the library API later if needed. Acked-by: Ard Biesheuvel <ardb@kernel.org> Signed-off-by: Eric Biggers <ebiggers@google.com> Tested-by: Ard Biesheuvel <ardb@kernel.org> Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
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@ -71,6 +71,16 @@ config CRYPTO_BLAKE2S_ARM
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slower than the NEON implementation of BLAKE2b. (There is no NEON
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implementation of BLAKE2s, since NEON doesn't really help with it.)
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config CRYPTO_BLAKE2B_NEON
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tristate "BLAKE2b digest algorithm (ARM NEON)"
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depends on KERNEL_MODE_NEON
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select CRYPTO_BLAKE2B
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help
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BLAKE2b digest algorithm optimized with ARM NEON instructions.
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On ARM processors that have NEON support but not the ARMv8
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Crypto Extensions, typically this BLAKE2b implementation is
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much faster than SHA-2 and slightly faster than SHA-1.
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config CRYPTO_AES_ARM
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tristate "Scalar AES cipher for ARM"
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select CRYPTO_ALGAPI
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@ -10,6 +10,7 @@ obj-$(CONFIG_CRYPTO_SHA1_ARM_NEON) += sha1-arm-neon.o
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obj-$(CONFIG_CRYPTO_SHA256_ARM) += sha256-arm.o
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obj-$(CONFIG_CRYPTO_SHA512_ARM) += sha512-arm.o
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obj-$(CONFIG_CRYPTO_BLAKE2S_ARM) += blake2s-arm.o
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obj-$(CONFIG_CRYPTO_BLAKE2B_NEON) += blake2b-neon.o
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obj-$(CONFIG_CRYPTO_CHACHA20_NEON) += chacha-neon.o
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obj-$(CONFIG_CRYPTO_POLY1305_ARM) += poly1305-arm.o
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obj-$(CONFIG_CRYPTO_NHPOLY1305_NEON) += nhpoly1305-neon.o
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@ -31,6 +32,7 @@ sha256-arm-y := sha256-core.o sha256_glue.o $(sha256-arm-neon-y)
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sha512-arm-neon-$(CONFIG_KERNEL_MODE_NEON) := sha512-neon-glue.o
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sha512-arm-y := sha512-core.o sha512-glue.o $(sha512-arm-neon-y)
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blake2s-arm-y := blake2s-core.o blake2s-glue.o
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blake2b-neon-y := blake2b-neon-core.o blake2b-neon-glue.o
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sha1-arm-ce-y := sha1-ce-core.o sha1-ce-glue.o
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sha2-arm-ce-y := sha2-ce-core.o sha2-ce-glue.o
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aes-arm-ce-y := aes-ce-core.o aes-ce-glue.o
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@ -0,0 +1,347 @@
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/* SPDX-License-Identifier: GPL-2.0-or-later */
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/*
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* BLAKE2b digest algorithm, NEON accelerated
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*
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* Copyright 2020 Google LLC
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*
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* Author: Eric Biggers <ebiggers@google.com>
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*/
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#include <linux/linkage.h>
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.text
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.fpu neon
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// The arguments to blake2b_compress_neon()
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STATE .req r0
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BLOCK .req r1
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NBLOCKS .req r2
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INC .req r3
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// Pointers to the rotation tables
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ROR24_TABLE .req r4
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ROR16_TABLE .req r5
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// The original stack pointer
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ORIG_SP .req r6
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// NEON registers which contain the message words of the current block.
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// M_0-M_3 are occasionally used for other purposes too.
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M_0 .req d16
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M_1 .req d17
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M_2 .req d18
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M_3 .req d19
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M_4 .req d20
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M_5 .req d21
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M_6 .req d22
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M_7 .req d23
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M_8 .req d24
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M_9 .req d25
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M_10 .req d26
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M_11 .req d27
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M_12 .req d28
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M_13 .req d29
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M_14 .req d30
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M_15 .req d31
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.align 4
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// Tables for computing ror64(x, 24) and ror64(x, 16) using the vtbl.8
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// instruction. This is the most efficient way to implement these
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// rotation amounts with NEON. (On Cortex-A53 it's the same speed as
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// vshr.u64 + vsli.u64, while on Cortex-A7 it's faster.)
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.Lror24_table:
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.byte 3, 4, 5, 6, 7, 0, 1, 2
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.Lror16_table:
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.byte 2, 3, 4, 5, 6, 7, 0, 1
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// The BLAKE2b initialization vector
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.Lblake2b_IV:
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.quad 0x6a09e667f3bcc908, 0xbb67ae8584caa73b
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.quad 0x3c6ef372fe94f82b, 0xa54ff53a5f1d36f1
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.quad 0x510e527fade682d1, 0x9b05688c2b3e6c1f
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.quad 0x1f83d9abfb41bd6b, 0x5be0cd19137e2179
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// Execute one round of BLAKE2b by updating the state matrix v[0..15] in the
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// NEON registers q0-q7. The message block is in q8..q15 (M_0-M_15). The stack
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// pointer points to a 32-byte aligned buffer containing a copy of q8 and q9
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// (M_0-M_3), so that they can be reloaded if they are used as temporary
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// registers. The macro arguments s0-s15 give the order in which the message
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// words are used in this round. 'final' is 1 if this is the final round.
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.macro _blake2b_round s0, s1, s2, s3, s4, s5, s6, s7, \
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s8, s9, s10, s11, s12, s13, s14, s15, final=0
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// Mix the columns:
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// (v[0], v[4], v[8], v[12]), (v[1], v[5], v[9], v[13]),
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// (v[2], v[6], v[10], v[14]), and (v[3], v[7], v[11], v[15]).
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// a += b + m[blake2b_sigma[r][2*i + 0]];
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vadd.u64 q0, q0, q2
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vadd.u64 q1, q1, q3
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vadd.u64 d0, d0, M_\s0
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vadd.u64 d1, d1, M_\s2
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vadd.u64 d2, d2, M_\s4
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vadd.u64 d3, d3, M_\s6
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// d = ror64(d ^ a, 32);
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veor q6, q6, q0
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veor q7, q7, q1
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vrev64.32 q6, q6
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vrev64.32 q7, q7
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// c += d;
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vadd.u64 q4, q4, q6
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vadd.u64 q5, q5, q7
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// b = ror64(b ^ c, 24);
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vld1.8 {M_0}, [ROR24_TABLE, :64]
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veor q2, q2, q4
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veor q3, q3, q5
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vtbl.8 d4, {d4}, M_0
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vtbl.8 d5, {d5}, M_0
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vtbl.8 d6, {d6}, M_0
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vtbl.8 d7, {d7}, M_0
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// a += b + m[blake2b_sigma[r][2*i + 1]];
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//
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// M_0 got clobbered above, so we have to reload it if any of the four
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// message words this step needs happens to be M_0. Otherwise we don't
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// need to reload it here, as it will just get clobbered again below.
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.if \s1 == 0 || \s3 == 0 || \s5 == 0 || \s7 == 0
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vld1.8 {M_0}, [sp, :64]
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.endif
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vadd.u64 q0, q0, q2
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vadd.u64 q1, q1, q3
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vadd.u64 d0, d0, M_\s1
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vadd.u64 d1, d1, M_\s3
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vadd.u64 d2, d2, M_\s5
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vadd.u64 d3, d3, M_\s7
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// d = ror64(d ^ a, 16);
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vld1.8 {M_0}, [ROR16_TABLE, :64]
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veor q6, q6, q0
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veor q7, q7, q1
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vtbl.8 d12, {d12}, M_0
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vtbl.8 d13, {d13}, M_0
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vtbl.8 d14, {d14}, M_0
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vtbl.8 d15, {d15}, M_0
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// c += d;
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vadd.u64 q4, q4, q6
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vadd.u64 q5, q5, q7
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// b = ror64(b ^ c, 63);
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//
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// This rotation amount isn't a multiple of 8, so it has to be
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// implemented using a pair of shifts, which requires temporary
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// registers. Use q8-q9 (M_0-M_3) for this, and reload them afterwards.
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veor q8, q2, q4
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veor q9, q3, q5
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vshr.u64 q2, q8, #63
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vshr.u64 q3, q9, #63
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vsli.u64 q2, q8, #1
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vsli.u64 q3, q9, #1
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vld1.8 {q8-q9}, [sp, :256]
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// Mix the diagonals:
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// (v[0], v[5], v[10], v[15]), (v[1], v[6], v[11], v[12]),
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// (v[2], v[7], v[8], v[13]), and (v[3], v[4], v[9], v[14]).
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//
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// There are two possible ways to do this: use 'vext' instructions to
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// shift the rows of the matrix so that the diagonals become columns,
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// and undo it afterwards; or just use 64-bit operations on 'd'
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// registers instead of 128-bit operations on 'q' registers. We use the
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// latter approach, as it performs much better on Cortex-A7.
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// a += b + m[blake2b_sigma[r][2*i + 0]];
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vadd.u64 d0, d0, d5
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vadd.u64 d1, d1, d6
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vadd.u64 d2, d2, d7
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vadd.u64 d3, d3, d4
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vadd.u64 d0, d0, M_\s8
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vadd.u64 d1, d1, M_\s10
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vadd.u64 d2, d2, M_\s12
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vadd.u64 d3, d3, M_\s14
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// d = ror64(d ^ a, 32);
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veor d15, d15, d0
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veor d12, d12, d1
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veor d13, d13, d2
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veor d14, d14, d3
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vrev64.32 d15, d15
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vrev64.32 d12, d12
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vrev64.32 d13, d13
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vrev64.32 d14, d14
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// c += d;
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vadd.u64 d10, d10, d15
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vadd.u64 d11, d11, d12
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vadd.u64 d8, d8, d13
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vadd.u64 d9, d9, d14
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// b = ror64(b ^ c, 24);
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vld1.8 {M_0}, [ROR24_TABLE, :64]
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veor d5, d5, d10
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veor d6, d6, d11
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veor d7, d7, d8
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veor d4, d4, d9
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vtbl.8 d5, {d5}, M_0
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vtbl.8 d6, {d6}, M_0
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vtbl.8 d7, {d7}, M_0
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vtbl.8 d4, {d4}, M_0
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// a += b + m[blake2b_sigma[r][2*i + 1]];
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.if \s9 == 0 || \s11 == 0 || \s13 == 0 || \s15 == 0
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vld1.8 {M_0}, [sp, :64]
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.endif
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vadd.u64 d0, d0, d5
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vadd.u64 d1, d1, d6
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vadd.u64 d2, d2, d7
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vadd.u64 d3, d3, d4
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vadd.u64 d0, d0, M_\s9
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vadd.u64 d1, d1, M_\s11
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vadd.u64 d2, d2, M_\s13
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vadd.u64 d3, d3, M_\s15
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// d = ror64(d ^ a, 16);
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vld1.8 {M_0}, [ROR16_TABLE, :64]
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veor d15, d15, d0
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veor d12, d12, d1
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veor d13, d13, d2
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veor d14, d14, d3
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vtbl.8 d12, {d12}, M_0
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vtbl.8 d13, {d13}, M_0
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vtbl.8 d14, {d14}, M_0
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vtbl.8 d15, {d15}, M_0
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// c += d;
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vadd.u64 d10, d10, d15
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vadd.u64 d11, d11, d12
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vadd.u64 d8, d8, d13
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vadd.u64 d9, d9, d14
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// b = ror64(b ^ c, 63);
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veor d16, d4, d9
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veor d17, d5, d10
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veor d18, d6, d11
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veor d19, d7, d8
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vshr.u64 q2, q8, #63
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vshr.u64 q3, q9, #63
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vsli.u64 q2, q8, #1
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vsli.u64 q3, q9, #1
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// Reloading q8-q9 can be skipped on the final round.
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.if ! \final
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vld1.8 {q8-q9}, [sp, :256]
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.endif
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.endm
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//
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// void blake2b_compress_neon(struct blake2b_state *state,
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// const u8 *block, size_t nblocks, u32 inc);
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//
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// Only the first three fields of struct blake2b_state are used:
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// u64 h[8]; (inout)
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// u64 t[2]; (inout)
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// u64 f[2]; (in)
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//
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.align 5
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ENTRY(blake2b_compress_neon)
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push {r4-r10}
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// Allocate a 32-byte stack buffer that is 32-byte aligned.
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mov ORIG_SP, sp
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sub ip, sp, #32
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bic ip, ip, #31
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mov sp, ip
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adr ROR24_TABLE, .Lror24_table
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adr ROR16_TABLE, .Lror16_table
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mov ip, STATE
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vld1.64 {q0-q1}, [ip]! // Load h[0..3]
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vld1.64 {q2-q3}, [ip]! // Load h[4..7]
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.Lnext_block:
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adr r10, .Lblake2b_IV
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vld1.64 {q14-q15}, [ip] // Load t[0..1] and f[0..1]
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vld1.64 {q4-q5}, [r10]! // Load IV[0..3]
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vmov r7, r8, d28 // Copy t[0] to (r7, r8)
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vld1.64 {q6-q7}, [r10] // Load IV[4..7]
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adds r7, r7, INC // Increment counter
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bcs .Lslow_inc_ctr
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vmov.i32 d28[0], r7
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vst1.64 {d28}, [ip] // Update t[0]
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.Linc_ctr_done:
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// Load the next message block and finish initializing the state matrix
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// 'v'. Fortunately, there are exactly enough NEON registers to fit the
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// entire state matrix in q0-q7 and the entire message block in q8-15.
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//
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// However, _blake2b_round also needs some extra registers for rotates,
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// so we have to spill some registers. It's better to spill the message
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// registers than the state registers, as the message doesn't change.
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// Therefore we store a copy of the first 32 bytes of the message block
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// (q8-q9) in an aligned buffer on the stack so that they can be
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// reloaded when needed. (We could just reload directly from the
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// message buffer, but it's faster to use aligned loads.)
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vld1.8 {q8-q9}, [BLOCK]!
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veor q6, q6, q14 // v[12..13] = IV[4..5] ^ t[0..1]
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vld1.8 {q10-q11}, [BLOCK]!
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veor q7, q7, q15 // v[14..15] = IV[6..7] ^ f[0..1]
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vld1.8 {q12-q13}, [BLOCK]!
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vst1.8 {q8-q9}, [sp, :256]
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mov ip, STATE
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vld1.8 {q14-q15}, [BLOCK]!
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// Execute the rounds. Each round is provided the order in which it
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// needs to use the message words.
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_blake2b_round 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15
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_blake2b_round 14, 10, 4, 8, 9, 15, 13, 6, 1, 12, 0, 2, 11, 7, 5, 3
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_blake2b_round 11, 8, 12, 0, 5, 2, 15, 13, 10, 14, 3, 6, 7, 1, 9, 4
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_blake2b_round 7, 9, 3, 1, 13, 12, 11, 14, 2, 6, 5, 10, 4, 0, 15, 8
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_blake2b_round 9, 0, 5, 7, 2, 4, 10, 15, 14, 1, 11, 12, 6, 8, 3, 13
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_blake2b_round 2, 12, 6, 10, 0, 11, 8, 3, 4, 13, 7, 5, 15, 14, 1, 9
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_blake2b_round 12, 5, 1, 15, 14, 13, 4, 10, 0, 7, 6, 3, 9, 2, 8, 11
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_blake2b_round 13, 11, 7, 14, 12, 1, 3, 9, 5, 0, 15, 4, 8, 6, 2, 10
|
||||
_blake2b_round 6, 15, 14, 9, 11, 3, 0, 8, 12, 2, 13, 7, 1, 4, 10, 5
|
||||
_blake2b_round 10, 2, 8, 4, 7, 6, 1, 5, 15, 11, 9, 14, 3, 12, 13, 0
|
||||
_blake2b_round 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15
|
||||
_blake2b_round 14, 10, 4, 8, 9, 15, 13, 6, 1, 12, 0, 2, 11, 7, 5, 3 \
|
||||
final=1
|
||||
|
||||
// Fold the final state matrix into the hash chaining value:
|
||||
//
|
||||
// for (i = 0; i < 8; i++)
|
||||
// h[i] ^= v[i] ^ v[i + 8];
|
||||
//
|
||||
vld1.64 {q8-q9}, [ip]! // Load old h[0..3]
|
||||
veor q0, q0, q4 // v[0..1] ^= v[8..9]
|
||||
veor q1, q1, q5 // v[2..3] ^= v[10..11]
|
||||
vld1.64 {q10-q11}, [ip] // Load old h[4..7]
|
||||
veor q2, q2, q6 // v[4..5] ^= v[12..13]
|
||||
veor q3, q3, q7 // v[6..7] ^= v[14..15]
|
||||
veor q0, q0, q8 // v[0..1] ^= h[0..1]
|
||||
veor q1, q1, q9 // v[2..3] ^= h[2..3]
|
||||
mov ip, STATE
|
||||
subs NBLOCKS, NBLOCKS, #1 // nblocks--
|
||||
vst1.64 {q0-q1}, [ip]! // Store new h[0..3]
|
||||
veor q2, q2, q10 // v[4..5] ^= h[4..5]
|
||||
veor q3, q3, q11 // v[6..7] ^= h[6..7]
|
||||
vst1.64 {q2-q3}, [ip]! // Store new h[4..7]
|
||||
|
||||
// Advance to the next block, if there is one.
|
||||
bne .Lnext_block // nblocks != 0?
|
||||
|
||||
mov sp, ORIG_SP
|
||||
pop {r4-r10}
|
||||
mov pc, lr
|
||||
|
||||
.Lslow_inc_ctr:
|
||||
// Handle the case where the counter overflowed its low 32 bits, by
|
||||
// carrying the overflow bit into the full 128-bit counter.
|
||||
vmov r9, r10, d29
|
||||
adcs r8, r8, #0
|
||||
adcs r9, r9, #0
|
||||
adc r10, r10, #0
|
||||
vmov d28, r7, r8
|
||||
vmov d29, r9, r10
|
||||
vst1.64 {q14}, [ip] // Update t[0] and t[1]
|
||||
b .Linc_ctr_done
|
||||
ENDPROC(blake2b_compress_neon)
|
|
@ -0,0 +1,105 @@
|
|||
// SPDX-License-Identifier: GPL-2.0-or-later
|
||||
/*
|
||||
* BLAKE2b digest algorithm, NEON accelerated
|
||||
*
|
||||
* Copyright 2020 Google LLC
|
||||
*/
|
||||
|
||||
#include <crypto/internal/blake2b.h>
|
||||
#include <crypto/internal/hash.h>
|
||||
#include <crypto/internal/simd.h>
|
||||
|
||||
#include <linux/module.h>
|
||||
#include <linux/sizes.h>
|
||||
|
||||
#include <asm/neon.h>
|
||||
#include <asm/simd.h>
|
||||
|
||||
asmlinkage void blake2b_compress_neon(struct blake2b_state *state,
|
||||
const u8 *block, size_t nblocks, u32 inc);
|
||||
|
||||
static void blake2b_compress_arch(struct blake2b_state *state,
|
||||
const u8 *block, size_t nblocks, u32 inc)
|
||||
{
|
||||
if (!crypto_simd_usable()) {
|
||||
blake2b_compress_generic(state, block, nblocks, inc);
|
||||
return;
|
||||
}
|
||||
|
||||
do {
|
||||
const size_t blocks = min_t(size_t, nblocks,
|
||||
SZ_4K / BLAKE2B_BLOCK_SIZE);
|
||||
|
||||
kernel_neon_begin();
|
||||
blake2b_compress_neon(state, block, blocks, inc);
|
||||
kernel_neon_end();
|
||||
|
||||
nblocks -= blocks;
|
||||
block += blocks * BLAKE2B_BLOCK_SIZE;
|
||||
} while (nblocks);
|
||||
}
|
||||
|
||||
static int crypto_blake2b_update_neon(struct shash_desc *desc,
|
||||
const u8 *in, unsigned int inlen)
|
||||
{
|
||||
return crypto_blake2b_update(desc, in, inlen, blake2b_compress_arch);
|
||||
}
|
||||
|
||||
static int crypto_blake2b_final_neon(struct shash_desc *desc, u8 *out)
|
||||
{
|
||||
return crypto_blake2b_final(desc, out, blake2b_compress_arch);
|
||||
}
|
||||
|
||||
#define BLAKE2B_ALG(name, driver_name, digest_size) \
|
||||
{ \
|
||||
.base.cra_name = name, \
|
||||
.base.cra_driver_name = driver_name, \
|
||||
.base.cra_priority = 200, \
|
||||
.base.cra_flags = CRYPTO_ALG_OPTIONAL_KEY, \
|
||||
.base.cra_blocksize = BLAKE2B_BLOCK_SIZE, \
|
||||
.base.cra_ctxsize = sizeof(struct blake2b_tfm_ctx), \
|
||||
.base.cra_module = THIS_MODULE, \
|
||||
.digestsize = digest_size, \
|
||||
.setkey = crypto_blake2b_setkey, \
|
||||
.init = crypto_blake2b_init, \
|
||||
.update = crypto_blake2b_update_neon, \
|
||||
.final = crypto_blake2b_final_neon, \
|
||||
.descsize = sizeof(struct blake2b_state), \
|
||||
}
|
||||
|
||||
static struct shash_alg blake2b_neon_algs[] = {
|
||||
BLAKE2B_ALG("blake2b-160", "blake2b-160-neon", BLAKE2B_160_HASH_SIZE),
|
||||
BLAKE2B_ALG("blake2b-256", "blake2b-256-neon", BLAKE2B_256_HASH_SIZE),
|
||||
BLAKE2B_ALG("blake2b-384", "blake2b-384-neon", BLAKE2B_384_HASH_SIZE),
|
||||
BLAKE2B_ALG("blake2b-512", "blake2b-512-neon", BLAKE2B_512_HASH_SIZE),
|
||||
};
|
||||
|
||||
static int __init blake2b_neon_mod_init(void)
|
||||
{
|
||||
if (!(elf_hwcap & HWCAP_NEON))
|
||||
return -ENODEV;
|
||||
|
||||
return crypto_register_shashes(blake2b_neon_algs,
|
||||
ARRAY_SIZE(blake2b_neon_algs));
|
||||
}
|
||||
|
||||
static void __exit blake2b_neon_mod_exit(void)
|
||||
{
|
||||
return crypto_unregister_shashes(blake2b_neon_algs,
|
||||
ARRAY_SIZE(blake2b_neon_algs));
|
||||
}
|
||||
|
||||
module_init(blake2b_neon_mod_init);
|
||||
module_exit(blake2b_neon_mod_exit);
|
||||
|
||||
MODULE_DESCRIPTION("BLAKE2b digest algorithm, NEON accelerated");
|
||||
MODULE_LICENSE("GPL");
|
||||
MODULE_AUTHOR("Eric Biggers <ebiggers@google.com>");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-160");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-160-neon");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-256");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-256-neon");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-384");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-384-neon");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-512");
|
||||
MODULE_ALIAS_CRYPTO("blake2b-512-neon");
|
Loading…
Reference in New Issue