crypto: arm/speck - add NEON-accelerated implementation of Speck-XTS

Add an ARM NEON-accelerated implementation of Speck-XTS.  It operates on
128-byte chunks at a time, i.e. 8 blocks for Speck128 or 16 blocks for
Speck64.  Each 128-byte chunk goes through XTS preprocessing, then is
encrypted/decrypted (doing one cipher round for all the blocks, then the
next round, etc.), then goes through XTS postprocessing.

The performance depends on the processor but can be about 3 times faster
than the generic code.  For example, on an ARMv7 processor we observe
the following performance with Speck128/256-XTS:

    xts-speck128-neon:     Encryption 107.9 MB/s, Decryption 108.1 MB/s
    xts(speck128-generic): Encryption  32.1 MB/s, Decryption  36.6 MB/s

In comparison to AES-256-XTS without the Cryptography Extensions:

    xts-aes-neonbs:        Encryption  41.2 MB/s, Decryption  36.7 MB/s
    xts(aes-asm):          Encryption  31.7 MB/s, Decryption  30.8 MB/s
    xts(aes-generic):      Encryption  21.2 MB/s, Decryption  20.9 MB/s

Speck64/128-XTS is even faster:

    xts-speck64-neon:      Encryption 138.6 MB/s, Decryption 139.1 MB/s

Note that as with the generic code, only the Speck128 and Speck64
variants are supported.  Also, for now only the XTS mode of operation is
supported, to target the disk and file encryption use cases.  The NEON
code also only handles the portion of the data that is evenly divisible
into 128-byte chunks, with any remainder handled by a C fallback.  Of
course, other modes of operation could be added later if needed, and/or
the NEON code could be updated to handle other buffer sizes.

The XTS specification is only defined for AES which has a 128-bit block
size, so for the GF(2^64) math needed for Speck64-XTS we use the
reducing polynomial 'x^64 + x^4 + x^3 + x + 1' given by the original XEX
paper.  Of course, when possible users should use Speck128-XTS, but even
that may be too slow on some processors; Speck64-XTS can be faster.

Signed-off-by: Eric Biggers <ebiggers@google.com>
Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
This commit is contained in:
Eric Biggers 2018-02-14 10:42:21 -08:00 committed by Herbert Xu
parent c8c36413ca
commit ede9622162
4 changed files with 728 additions and 0 deletions

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@ -121,4 +121,10 @@ config CRYPTO_CHACHA20_NEON
select CRYPTO_BLKCIPHER
select CRYPTO_CHACHA20
config CRYPTO_SPECK_NEON
tristate "NEON accelerated Speck cipher algorithms"
depends on KERNEL_MODE_NEON
select CRYPTO_BLKCIPHER
select CRYPTO_SPECK
endif

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@ -10,6 +10,7 @@ obj-$(CONFIG_CRYPTO_SHA1_ARM_NEON) += sha1-arm-neon.o
obj-$(CONFIG_CRYPTO_SHA256_ARM) += sha256-arm.o
obj-$(CONFIG_CRYPTO_SHA512_ARM) += sha512-arm.o
obj-$(CONFIG_CRYPTO_CHACHA20_NEON) += chacha20-neon.o
obj-$(CONFIG_CRYPTO_SPECK_NEON) += speck-neon.o
ce-obj-$(CONFIG_CRYPTO_AES_ARM_CE) += aes-arm-ce.o
ce-obj-$(CONFIG_CRYPTO_SHA1_ARM_CE) += sha1-arm-ce.o
@ -53,6 +54,7 @@ ghash-arm-ce-y := ghash-ce-core.o ghash-ce-glue.o
crct10dif-arm-ce-y := crct10dif-ce-core.o crct10dif-ce-glue.o
crc32-arm-ce-y:= crc32-ce-core.o crc32-ce-glue.o
chacha20-neon-y := chacha20-neon-core.o chacha20-neon-glue.o
speck-neon-y := speck-neon-core.o speck-neon-glue.o
quiet_cmd_perl = PERL $@
cmd_perl = $(PERL) $(<) > $(@)

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@ -0,0 +1,432 @@
// SPDX-License-Identifier: GPL-2.0
/*
* NEON-accelerated implementation of Speck128-XTS and Speck64-XTS
*
* Copyright (c) 2018 Google, Inc
*
* Author: Eric Biggers <ebiggers@google.com>
*/
#include <linux/linkage.h>
.text
.fpu neon
// arguments
ROUND_KEYS .req r0 // const {u64,u32} *round_keys
NROUNDS .req r1 // int nrounds
DST .req r2 // void *dst
SRC .req r3 // const void *src
NBYTES .req r4 // unsigned int nbytes
TWEAK .req r5 // void *tweak
// registers which hold the data being encrypted/decrypted
X0 .req q0
X0_L .req d0
X0_H .req d1
Y0 .req q1
Y0_H .req d3
X1 .req q2
X1_L .req d4
X1_H .req d5
Y1 .req q3
Y1_H .req d7
X2 .req q4
X2_L .req d8
X2_H .req d9
Y2 .req q5
Y2_H .req d11
X3 .req q6
X3_L .req d12
X3_H .req d13
Y3 .req q7
Y3_H .req d15
// the round key, duplicated in all lanes
ROUND_KEY .req q8
ROUND_KEY_L .req d16
ROUND_KEY_H .req d17
// index vector for vtbl-based 8-bit rotates
ROTATE_TABLE .req d18
// multiplication table for updating XTS tweaks
GF128MUL_TABLE .req d19
GF64MUL_TABLE .req d19
// current XTS tweak value(s)
TWEAKV .req q10
TWEAKV_L .req d20
TWEAKV_H .req d21
TMP0 .req q12
TMP0_L .req d24
TMP0_H .req d25
TMP1 .req q13
TMP2 .req q14
TMP3 .req q15
.align 4
.Lror64_8_table:
.byte 1, 2, 3, 4, 5, 6, 7, 0
.Lror32_8_table:
.byte 1, 2, 3, 0, 5, 6, 7, 4
.Lrol64_8_table:
.byte 7, 0, 1, 2, 3, 4, 5, 6
.Lrol32_8_table:
.byte 3, 0, 1, 2, 7, 4, 5, 6
.Lgf128mul_table:
.byte 0, 0x87
.fill 14
.Lgf64mul_table:
.byte 0, 0x1b, (0x1b << 1), (0x1b << 1) ^ 0x1b
.fill 12
/*
* _speck_round_128bytes() - Speck encryption round on 128 bytes at a time
*
* Do one Speck encryption round on the 128 bytes (8 blocks for Speck128, 16 for
* Speck64) stored in X0-X3 and Y0-Y3, using the round key stored in all lanes
* of ROUND_KEY. 'n' is the lane size: 64 for Speck128, or 32 for Speck64.
*
* The 8-bit rotates are implemented using vtbl instead of vshr + vsli because
* the vtbl approach is faster on some processors and the same speed on others.
*/
.macro _speck_round_128bytes n
// x = ror(x, 8)
vtbl.8 X0_L, {X0_L}, ROTATE_TABLE
vtbl.8 X0_H, {X0_H}, ROTATE_TABLE
vtbl.8 X1_L, {X1_L}, ROTATE_TABLE
vtbl.8 X1_H, {X1_H}, ROTATE_TABLE
vtbl.8 X2_L, {X2_L}, ROTATE_TABLE
vtbl.8 X2_H, {X2_H}, ROTATE_TABLE
vtbl.8 X3_L, {X3_L}, ROTATE_TABLE
vtbl.8 X3_H, {X3_H}, ROTATE_TABLE
// x += y
vadd.u\n X0, Y0
vadd.u\n X1, Y1
vadd.u\n X2, Y2
vadd.u\n X3, Y3
// x ^= k
veor X0, ROUND_KEY
veor X1, ROUND_KEY
veor X2, ROUND_KEY
veor X3, ROUND_KEY
// y = rol(y, 3)
vshl.u\n TMP0, Y0, #3
vshl.u\n TMP1, Y1, #3
vshl.u\n TMP2, Y2, #3
vshl.u\n TMP3, Y3, #3
vsri.u\n TMP0, Y0, #(\n - 3)
vsri.u\n TMP1, Y1, #(\n - 3)
vsri.u\n TMP2, Y2, #(\n - 3)
vsri.u\n TMP3, Y3, #(\n - 3)
// y ^= x
veor Y0, TMP0, X0
veor Y1, TMP1, X1
veor Y2, TMP2, X2
veor Y3, TMP3, X3
.endm
/*
* _speck_unround_128bytes() - Speck decryption round on 128 bytes at a time
*
* This is the inverse of _speck_round_128bytes().
*/
.macro _speck_unround_128bytes n
// y ^= x
veor TMP0, Y0, X0
veor TMP1, Y1, X1
veor TMP2, Y2, X2
veor TMP3, Y3, X3
// y = ror(y, 3)
vshr.u\n Y0, TMP0, #3
vshr.u\n Y1, TMP1, #3
vshr.u\n Y2, TMP2, #3
vshr.u\n Y3, TMP3, #3
vsli.u\n Y0, TMP0, #(\n - 3)
vsli.u\n Y1, TMP1, #(\n - 3)
vsli.u\n Y2, TMP2, #(\n - 3)
vsli.u\n Y3, TMP3, #(\n - 3)
// x ^= k
veor X0, ROUND_KEY
veor X1, ROUND_KEY
veor X2, ROUND_KEY
veor X3, ROUND_KEY
// x -= y
vsub.u\n X0, Y0
vsub.u\n X1, Y1
vsub.u\n X2, Y2
vsub.u\n X3, Y3
// x = rol(x, 8);
vtbl.8 X0_L, {X0_L}, ROTATE_TABLE
vtbl.8 X0_H, {X0_H}, ROTATE_TABLE
vtbl.8 X1_L, {X1_L}, ROTATE_TABLE
vtbl.8 X1_H, {X1_H}, ROTATE_TABLE
vtbl.8 X2_L, {X2_L}, ROTATE_TABLE
vtbl.8 X2_H, {X2_H}, ROTATE_TABLE
vtbl.8 X3_L, {X3_L}, ROTATE_TABLE
vtbl.8 X3_H, {X3_H}, ROTATE_TABLE
.endm
.macro _xts128_precrypt_one dst_reg, tweak_buf, tmp
// Load the next source block
vld1.8 {\dst_reg}, [SRC]!
// Save the current tweak in the tweak buffer
vst1.8 {TWEAKV}, [\tweak_buf:128]!
// XOR the next source block with the current tweak
veor \dst_reg, TWEAKV
/*
* Calculate the next tweak by multiplying the current one by x,
* modulo p(x) = x^128 + x^7 + x^2 + x + 1.
*/
vshr.u64 \tmp, TWEAKV, #63
vshl.u64 TWEAKV, #1
veor TWEAKV_H, \tmp\()_L
vtbl.8 \tmp\()_H, {GF128MUL_TABLE}, \tmp\()_H
veor TWEAKV_L, \tmp\()_H
.endm
.macro _xts64_precrypt_two dst_reg, tweak_buf, tmp
// Load the next two source blocks
vld1.8 {\dst_reg}, [SRC]!
// Save the current two tweaks in the tweak buffer
vst1.8 {TWEAKV}, [\tweak_buf:128]!
// XOR the next two source blocks with the current two tweaks
veor \dst_reg, TWEAKV
/*
* Calculate the next two tweaks by multiplying the current ones by x^2,
* modulo p(x) = x^64 + x^4 + x^3 + x + 1.
*/
vshr.u64 \tmp, TWEAKV, #62
vshl.u64 TWEAKV, #2
vtbl.8 \tmp\()_L, {GF64MUL_TABLE}, \tmp\()_L
vtbl.8 \tmp\()_H, {GF64MUL_TABLE}, \tmp\()_H
veor TWEAKV, \tmp
.endm
/*
* _speck_xts_crypt() - Speck-XTS encryption/decryption
*
* Encrypt or decrypt NBYTES bytes of data from the SRC buffer to the DST buffer
* using Speck-XTS, specifically the variant with a block size of '2n' and round
* count given by NROUNDS. The expanded round keys are given in ROUND_KEYS, and
* the current XTS tweak value is given in TWEAK. It's assumed that NBYTES is a
* nonzero multiple of 128.
*/
.macro _speck_xts_crypt n, decrypting
push {r4-r7}
mov r7, sp
/*
* The first four parameters were passed in registers r0-r3. Load the
* additional parameters, which were passed on the stack.
*/
ldr NBYTES, [sp, #16]
ldr TWEAK, [sp, #20]
/*
* If decrypting, modify the ROUND_KEYS parameter to point to the last
* round key rather than the first, since for decryption the round keys
* are used in reverse order.
*/
.if \decrypting
.if \n == 64
add ROUND_KEYS, ROUND_KEYS, NROUNDS, lsl #3
sub ROUND_KEYS, #8
.else
add ROUND_KEYS, ROUND_KEYS, NROUNDS, lsl #2
sub ROUND_KEYS, #4
.endif
.endif
// Load the index vector for vtbl-based 8-bit rotates
.if \decrypting
ldr r12, =.Lrol\n\()_8_table
.else
ldr r12, =.Lror\n\()_8_table
.endif
vld1.8 {ROTATE_TABLE}, [r12:64]
// One-time XTS preparation
/*
* Allocate stack space to store 128 bytes worth of tweaks. For
* performance, this space is aligned to a 16-byte boundary so that we
* can use the load/store instructions that declare 16-byte alignment.
*/
sub sp, #128
bic sp, #0xf
.if \n == 64
// Load first tweak
vld1.8 {TWEAKV}, [TWEAK]
// Load GF(2^128) multiplication table
ldr r12, =.Lgf128mul_table
vld1.8 {GF128MUL_TABLE}, [r12:64]
.else
// Load first tweak
vld1.8 {TWEAKV_L}, [TWEAK]
// Load GF(2^64) multiplication table
ldr r12, =.Lgf64mul_table
vld1.8 {GF64MUL_TABLE}, [r12:64]
// Calculate second tweak, packing it together with the first
vshr.u64 TMP0_L, TWEAKV_L, #63
vtbl.u8 TMP0_L, {GF64MUL_TABLE}, TMP0_L
vshl.u64 TWEAKV_H, TWEAKV_L, #1
veor TWEAKV_H, TMP0_L
.endif
.Lnext_128bytes_\@:
/*
* Load the source blocks into {X,Y}[0-3], XOR them with their XTS tweak
* values, and save the tweaks on the stack for later. Then
* de-interleave the 'x' and 'y' elements of each block, i.e. make it so
* that the X[0-3] registers contain only the second halves of blocks,
* and the Y[0-3] registers contain only the first halves of blocks.
* (Speck uses the order (y, x) rather than the more intuitive (x, y).)
*/
mov r12, sp
.if \n == 64
_xts128_precrypt_one X0, r12, TMP0
_xts128_precrypt_one Y0, r12, TMP0
_xts128_precrypt_one X1, r12, TMP0
_xts128_precrypt_one Y1, r12, TMP0
_xts128_precrypt_one X2, r12, TMP0
_xts128_precrypt_one Y2, r12, TMP0
_xts128_precrypt_one X3, r12, TMP0
_xts128_precrypt_one Y3, r12, TMP0
vswp X0_L, Y0_H
vswp X1_L, Y1_H
vswp X2_L, Y2_H
vswp X3_L, Y3_H
.else
_xts64_precrypt_two X0, r12, TMP0
_xts64_precrypt_two Y0, r12, TMP0
_xts64_precrypt_two X1, r12, TMP0
_xts64_precrypt_two Y1, r12, TMP0
_xts64_precrypt_two X2, r12, TMP0
_xts64_precrypt_two Y2, r12, TMP0
_xts64_precrypt_two X3, r12, TMP0
_xts64_precrypt_two Y3, r12, TMP0
vuzp.32 Y0, X0
vuzp.32 Y1, X1
vuzp.32 Y2, X2
vuzp.32 Y3, X3
.endif
// Do the cipher rounds
mov r12, ROUND_KEYS
mov r6, NROUNDS
.Lnext_round_\@:
.if \decrypting
.if \n == 64
vld1.64 ROUND_KEY_L, [r12]
sub r12, #8
vmov ROUND_KEY_H, ROUND_KEY_L
.else
vld1.32 {ROUND_KEY_L[],ROUND_KEY_H[]}, [r12]
sub r12, #4
.endif
_speck_unround_128bytes \n
.else
.if \n == 64
vld1.64 ROUND_KEY_L, [r12]!
vmov ROUND_KEY_H, ROUND_KEY_L
.else
vld1.32 {ROUND_KEY_L[],ROUND_KEY_H[]}, [r12]!
.endif
_speck_round_128bytes \n
.endif
subs r6, r6, #1
bne .Lnext_round_\@
// Re-interleave the 'x' and 'y' elements of each block
.if \n == 64
vswp X0_L, Y0_H
vswp X1_L, Y1_H
vswp X2_L, Y2_H
vswp X3_L, Y3_H
.else
vzip.32 Y0, X0
vzip.32 Y1, X1
vzip.32 Y2, X2
vzip.32 Y3, X3
.endif
// XOR the encrypted/decrypted blocks with the tweaks we saved earlier
mov r12, sp
vld1.8 {TMP0, TMP1}, [r12:128]!
vld1.8 {TMP2, TMP3}, [r12:128]!
veor X0, TMP0
veor Y0, TMP1
veor X1, TMP2
veor Y1, TMP3
vld1.8 {TMP0, TMP1}, [r12:128]!
vld1.8 {TMP2, TMP3}, [r12:128]!
veor X2, TMP0
veor Y2, TMP1
veor X3, TMP2
veor Y3, TMP3
// Store the ciphertext in the destination buffer
vst1.8 {X0, Y0}, [DST]!
vst1.8 {X1, Y1}, [DST]!
vst1.8 {X2, Y2}, [DST]!
vst1.8 {X3, Y3}, [DST]!
// Continue if there are more 128-byte chunks remaining, else return
subs NBYTES, #128
bne .Lnext_128bytes_\@
// Store the next tweak
.if \n == 64
vst1.8 {TWEAKV}, [TWEAK]
.else
vst1.8 {TWEAKV_L}, [TWEAK]
.endif
mov sp, r7
pop {r4-r7}
bx lr
.endm
ENTRY(speck128_xts_encrypt_neon)
_speck_xts_crypt n=64, decrypting=0
ENDPROC(speck128_xts_encrypt_neon)
ENTRY(speck128_xts_decrypt_neon)
_speck_xts_crypt n=64, decrypting=1
ENDPROC(speck128_xts_decrypt_neon)
ENTRY(speck64_xts_encrypt_neon)
_speck_xts_crypt n=32, decrypting=0
ENDPROC(speck64_xts_encrypt_neon)
ENTRY(speck64_xts_decrypt_neon)
_speck_xts_crypt n=32, decrypting=1
ENDPROC(speck64_xts_decrypt_neon)

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@ -0,0 +1,288 @@
// SPDX-License-Identifier: GPL-2.0
/*
* NEON-accelerated implementation of Speck128-XTS and Speck64-XTS
*
* Copyright (c) 2018 Google, Inc
*
* Note: the NIST recommendation for XTS only specifies a 128-bit block size,
* but a 64-bit version (needed for Speck64) is fairly straightforward; the math
* is just done in GF(2^64) instead of GF(2^128), with the reducing polynomial
* x^64 + x^4 + x^3 + x + 1 from the original XEX paper (Rogaway, 2004:
* "Efficient Instantiations of Tweakable Blockciphers and Refinements to Modes
* OCB and PMAC"), represented as 0x1B.
*/
#include <asm/hwcap.h>
#include <asm/neon.h>
#include <asm/simd.h>
#include <crypto/algapi.h>
#include <crypto/gf128mul.h>
#include <crypto/internal/skcipher.h>
#include <crypto/speck.h>
#include <crypto/xts.h>
#include <linux/kernel.h>
#include <linux/module.h>
/* The assembly functions only handle multiples of 128 bytes */
#define SPECK_NEON_CHUNK_SIZE 128
/* Speck128 */
struct speck128_xts_tfm_ctx {
struct speck128_tfm_ctx main_key;
struct speck128_tfm_ctx tweak_key;
};
asmlinkage void speck128_xts_encrypt_neon(const u64 *round_keys, int nrounds,
void *dst, const void *src,
unsigned int nbytes, void *tweak);
asmlinkage void speck128_xts_decrypt_neon(const u64 *round_keys, int nrounds,
void *dst, const void *src,
unsigned int nbytes, void *tweak);
typedef void (*speck128_crypt_one_t)(const struct speck128_tfm_ctx *,
u8 *, const u8 *);
typedef void (*speck128_xts_crypt_many_t)(const u64 *, int, void *,
const void *, unsigned int, void *);
static __always_inline int
__speck128_xts_crypt(struct skcipher_request *req,
speck128_crypt_one_t crypt_one,
speck128_xts_crypt_many_t crypt_many)
{
struct crypto_skcipher *tfm = crypto_skcipher_reqtfm(req);
const struct speck128_xts_tfm_ctx *ctx = crypto_skcipher_ctx(tfm);
struct skcipher_walk walk;
le128 tweak;
int err;
err = skcipher_walk_virt(&walk, req, true);
crypto_speck128_encrypt(&ctx->tweak_key, (u8 *)&tweak, walk.iv);
while (walk.nbytes > 0) {
unsigned int nbytes = walk.nbytes;
u8 *dst = walk.dst.virt.addr;
const u8 *src = walk.src.virt.addr;
if (nbytes >= SPECK_NEON_CHUNK_SIZE && may_use_simd()) {
unsigned int count;
count = round_down(nbytes, SPECK_NEON_CHUNK_SIZE);
kernel_neon_begin();
(*crypt_many)(ctx->main_key.round_keys,
ctx->main_key.nrounds,
dst, src, count, &tweak);
kernel_neon_end();
dst += count;
src += count;
nbytes -= count;
}
/* Handle any remainder with generic code */
while (nbytes >= sizeof(tweak)) {
le128_xor((le128 *)dst, (const le128 *)src, &tweak);
(*crypt_one)(&ctx->main_key, dst, dst);
le128_xor((le128 *)dst, (const le128 *)dst, &tweak);
gf128mul_x_ble(&tweak, &tweak);
dst += sizeof(tweak);
src += sizeof(tweak);
nbytes -= sizeof(tweak);
}
err = skcipher_walk_done(&walk, nbytes);
}
return err;
}
static int speck128_xts_encrypt(struct skcipher_request *req)
{
return __speck128_xts_crypt(req, crypto_speck128_encrypt,
speck128_xts_encrypt_neon);
}
static int speck128_xts_decrypt(struct skcipher_request *req)
{
return __speck128_xts_crypt(req, crypto_speck128_decrypt,
speck128_xts_decrypt_neon);
}
static int speck128_xts_setkey(struct crypto_skcipher *tfm, const u8 *key,
unsigned int keylen)
{
struct speck128_xts_tfm_ctx *ctx = crypto_skcipher_ctx(tfm);
int err;
err = xts_verify_key(tfm, key, keylen);
if (err)
return err;
keylen /= 2;
err = crypto_speck128_setkey(&ctx->main_key, key, keylen);
if (err)
return err;
return crypto_speck128_setkey(&ctx->tweak_key, key + keylen, keylen);
}
/* Speck64 */
struct speck64_xts_tfm_ctx {
struct speck64_tfm_ctx main_key;
struct speck64_tfm_ctx tweak_key;
};
asmlinkage void speck64_xts_encrypt_neon(const u32 *round_keys, int nrounds,
void *dst, const void *src,
unsigned int nbytes, void *tweak);
asmlinkage void speck64_xts_decrypt_neon(const u32 *round_keys, int nrounds,
void *dst, const void *src,
unsigned int nbytes, void *tweak);
typedef void (*speck64_crypt_one_t)(const struct speck64_tfm_ctx *,
u8 *, const u8 *);
typedef void (*speck64_xts_crypt_many_t)(const u32 *, int, void *,
const void *, unsigned int, void *);
static __always_inline int
__speck64_xts_crypt(struct skcipher_request *req, speck64_crypt_one_t crypt_one,
speck64_xts_crypt_many_t crypt_many)
{
struct crypto_skcipher *tfm = crypto_skcipher_reqtfm(req);
const struct speck64_xts_tfm_ctx *ctx = crypto_skcipher_ctx(tfm);
struct skcipher_walk walk;
__le64 tweak;
int err;
err = skcipher_walk_virt(&walk, req, true);
crypto_speck64_encrypt(&ctx->tweak_key, (u8 *)&tweak, walk.iv);
while (walk.nbytes > 0) {
unsigned int nbytes = walk.nbytes;
u8 *dst = walk.dst.virt.addr;
const u8 *src = walk.src.virt.addr;
if (nbytes >= SPECK_NEON_CHUNK_SIZE && may_use_simd()) {
unsigned int count;
count = round_down(nbytes, SPECK_NEON_CHUNK_SIZE);
kernel_neon_begin();
(*crypt_many)(ctx->main_key.round_keys,
ctx->main_key.nrounds,
dst, src, count, &tweak);
kernel_neon_end();
dst += count;
src += count;
nbytes -= count;
}
/* Handle any remainder with generic code */
while (nbytes >= sizeof(tweak)) {
*(__le64 *)dst = *(__le64 *)src ^ tweak;
(*crypt_one)(&ctx->main_key, dst, dst);
*(__le64 *)dst ^= tweak;
tweak = cpu_to_le64((le64_to_cpu(tweak) << 1) ^
((tweak & cpu_to_le64(1ULL << 63)) ?
0x1B : 0));
dst += sizeof(tweak);
src += sizeof(tweak);
nbytes -= sizeof(tweak);
}
err = skcipher_walk_done(&walk, nbytes);
}
return err;
}
static int speck64_xts_encrypt(struct skcipher_request *req)
{
return __speck64_xts_crypt(req, crypto_speck64_encrypt,
speck64_xts_encrypt_neon);
}
static int speck64_xts_decrypt(struct skcipher_request *req)
{
return __speck64_xts_crypt(req, crypto_speck64_decrypt,
speck64_xts_decrypt_neon);
}
static int speck64_xts_setkey(struct crypto_skcipher *tfm, const u8 *key,
unsigned int keylen)
{
struct speck64_xts_tfm_ctx *ctx = crypto_skcipher_ctx(tfm);
int err;
err = xts_verify_key(tfm, key, keylen);
if (err)
return err;
keylen /= 2;
err = crypto_speck64_setkey(&ctx->main_key, key, keylen);
if (err)
return err;
return crypto_speck64_setkey(&ctx->tweak_key, key + keylen, keylen);
}
static struct skcipher_alg speck_algs[] = {
{
.base.cra_name = "xts(speck128)",
.base.cra_driver_name = "xts-speck128-neon",
.base.cra_priority = 300,
.base.cra_blocksize = SPECK128_BLOCK_SIZE,
.base.cra_ctxsize = sizeof(struct speck128_xts_tfm_ctx),
.base.cra_alignmask = 7,
.base.cra_module = THIS_MODULE,
.min_keysize = 2 * SPECK128_128_KEY_SIZE,
.max_keysize = 2 * SPECK128_256_KEY_SIZE,
.ivsize = SPECK128_BLOCK_SIZE,
.walksize = SPECK_NEON_CHUNK_SIZE,
.setkey = speck128_xts_setkey,
.encrypt = speck128_xts_encrypt,
.decrypt = speck128_xts_decrypt,
}, {
.base.cra_name = "xts(speck64)",
.base.cra_driver_name = "xts-speck64-neon",
.base.cra_priority = 300,
.base.cra_blocksize = SPECK64_BLOCK_SIZE,
.base.cra_ctxsize = sizeof(struct speck64_xts_tfm_ctx),
.base.cra_alignmask = 7,
.base.cra_module = THIS_MODULE,
.min_keysize = 2 * SPECK64_96_KEY_SIZE,
.max_keysize = 2 * SPECK64_128_KEY_SIZE,
.ivsize = SPECK64_BLOCK_SIZE,
.walksize = SPECK_NEON_CHUNK_SIZE,
.setkey = speck64_xts_setkey,
.encrypt = speck64_xts_encrypt,
.decrypt = speck64_xts_decrypt,
}
};
static int __init speck_neon_module_init(void)
{
if (!(elf_hwcap & HWCAP_NEON))
return -ENODEV;
return crypto_register_skciphers(speck_algs, ARRAY_SIZE(speck_algs));
}
static void __exit speck_neon_module_exit(void)
{
crypto_unregister_skciphers(speck_algs, ARRAY_SIZE(speck_algs));
}
module_init(speck_neon_module_init);
module_exit(speck_neon_module_exit);
MODULE_DESCRIPTION("Speck block cipher (NEON-accelerated)");
MODULE_LICENSE("GPL");
MODULE_AUTHOR("Eric Biggers <ebiggers@google.com>");
MODULE_ALIAS_CRYPTO("xts(speck128)");
MODULE_ALIAS_CRYPTO("xts-speck128-neon");
MODULE_ALIAS_CRYPTO("xts(speck64)");
MODULE_ALIAS_CRYPTO("xts-speck64-neon");