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diff --git a/arch/arm64/crypto/speck-neon-core.S b/arch/arm64/crypto/speck-neon-core.S
new file mode 100644
index 000000000000..b14463438b09
--- /dev/null
+++ b/arch/arm64/crypto/speck-neon-core.S
@@ -0,0 +1,352 @@
+// SPDX-License-Identifier: GPL-2.0
+/*
+ * ARM64 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
+
+	// arguments
+	ROUND_KEYS	.req	x0	// const {u64,u32} *round_keys
+	NROUNDS		.req	w1	// int nrounds
+	NROUNDS_X	.req	x1
+	DST		.req	x2	// void *dst
+	SRC		.req	x3	// const void *src
+	NBYTES		.req	w4	// unsigned int nbytes
+	TWEAK		.req	x5	// void *tweak
+
+	// registers which hold the data being encrypted/decrypted
+	// (underscores avoid a naming collision with ARM64 registers x0-x3)
+	X_0		.req	v0
+	Y_0		.req	v1
+	X_1		.req	v2
+	Y_1		.req	v3
+	X_2		.req	v4
+	Y_2		.req	v5
+	X_3		.req	v6
+	Y_3		.req	v7
+
+	// the round key, duplicated in all lanes
+	ROUND_KEY	.req	v8
+
+	// index vector for tbl-based 8-bit rotates
+	ROTATE_TABLE	.req	v9
+	ROTATE_TABLE_Q	.req	q9
+
+	// temporary registers
+	TMP0		.req	v10
+	TMP1		.req	v11
+	TMP2		.req	v12
+	TMP3		.req	v13
+
+	// multiplication table for updating XTS tweaks
+	GFMUL_TABLE	.req	v14
+	GFMUL_TABLE_Q	.req	q14
+
+	// next XTS tweak value(s)
+	TWEAKV_NEXT	.req	v15
+
+	// XTS tweaks for the blocks currently being encrypted/decrypted
+	TWEAKV0		.req	v16
+	TWEAKV1		.req	v17
+	TWEAKV2		.req	v18
+	TWEAKV3		.req	v19
+	TWEAKV4		.req	v20
+	TWEAKV5		.req	v21
+	TWEAKV6		.req	v22
+	TWEAKV7		.req	v23
+
+	.align		4
+.Lror64_8_table:
+	.octa		0x080f0e0d0c0b0a090007060504030201
+.Lror32_8_table:
+	.octa		0x0c0f0e0d080b0a090407060500030201
+.Lrol64_8_table:
+	.octa		0x0e0d0c0b0a09080f0605040302010007
+.Lrol32_8_table:
+	.octa		0x0e0d0c0f0a09080b0605040702010003
+.Lgf128mul_table:
+	.octa		0x00000000000000870000000000000001
+.Lgf64mul_table:
+	.octa		0x0000000000000000000000002d361b00
+
+/*
+ * _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.
+ * 'lanes' is the lane specifier: "2d" for Speck128 or "4s" for Speck64.
+ */
+.macro _speck_round_128bytes	n, lanes
+
+	// x = ror(x, 8)
+	tbl		X_0.16b, {X_0.16b}, ROTATE_TABLE.16b
+	tbl		X_1.16b, {X_1.16b}, ROTATE_TABLE.16b
+	tbl		X_2.16b, {X_2.16b}, ROTATE_TABLE.16b
+	tbl		X_3.16b, {X_3.16b}, ROTATE_TABLE.16b
+
+	// x += y
+	add		X_0.\lanes, X_0.\lanes, Y_0.\lanes
+	add		X_1.\lanes, X_1.\lanes, Y_1.\lanes
+	add		X_2.\lanes, X_2.\lanes, Y_2.\lanes
+	add		X_3.\lanes, X_3.\lanes, Y_3.\lanes
+
+	// x ^= k
+	eor		X_0.16b, X_0.16b, ROUND_KEY.16b
+	eor		X_1.16b, X_1.16b, ROUND_KEY.16b
+	eor		X_2.16b, X_2.16b, ROUND_KEY.16b
+	eor		X_3.16b, X_3.16b, ROUND_KEY.16b
+
+	// y = rol(y, 3)
+	shl		TMP0.\lanes, Y_0.\lanes, #3
+	shl		TMP1.\lanes, Y_1.\lanes, #3
+	shl		TMP2.\lanes, Y_2.\lanes, #3
+	shl		TMP3.\lanes, Y_3.\lanes, #3
+	sri		TMP0.\lanes, Y_0.\lanes, #(\n - 3)
+	sri		TMP1.\lanes, Y_1.\lanes, #(\n - 3)
+	sri		TMP2.\lanes, Y_2.\lanes, #(\n - 3)
+	sri		TMP3.\lanes, Y_3.\lanes, #(\n - 3)
+
+	// y ^= x
+	eor		Y_0.16b, TMP0.16b, X_0.16b
+	eor		Y_1.16b, TMP1.16b, X_1.16b
+	eor		Y_2.16b, TMP2.16b, X_2.16b
+	eor		Y_3.16b, TMP3.16b, X_3.16b
+.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, lanes
+
+	// y ^= x
+	eor		TMP0.16b, Y_0.16b, X_0.16b
+	eor		TMP1.16b, Y_1.16b, X_1.16b
+	eor		TMP2.16b, Y_2.16b, X_2.16b
+	eor		TMP3.16b, Y_3.16b, X_3.16b
+
+	// y = ror(y, 3)
+	ushr		Y_0.\lanes, TMP0.\lanes, #3
+	ushr		Y_1.\lanes, TMP1.\lanes, #3
+	ushr		Y_2.\lanes, TMP2.\lanes, #3
+	ushr		Y_3.\lanes, TMP3.\lanes, #3
+	sli		Y_0.\lanes, TMP0.\lanes, #(\n - 3)
+	sli		Y_1.\lanes, TMP1.\lanes, #(\n - 3)
+	sli		Y_2.\lanes, TMP2.\lanes, #(\n - 3)
+	sli		Y_3.\lanes, TMP3.\lanes, #(\n - 3)
+
+	// x ^= k
+	eor		X_0.16b, X_0.16b, ROUND_KEY.16b
+	eor		X_1.16b, X_1.16b, ROUND_KEY.16b
+	eor		X_2.16b, X_2.16b, ROUND_KEY.16b
+	eor		X_3.16b, X_3.16b, ROUND_KEY.16b
+
+	// x -= y
+	sub		X_0.\lanes, X_0.\lanes, Y_0.\lanes
+	sub		X_1.\lanes, X_1.\lanes, Y_1.\lanes
+	sub		X_2.\lanes, X_2.\lanes, Y_2.\lanes
+	sub		X_3.\lanes, X_3.\lanes, Y_3.\lanes
+
+	// x = rol(x, 8)
+	tbl		X_0.16b, {X_0.16b}, ROTATE_TABLE.16b
+	tbl		X_1.16b, {X_1.16b}, ROTATE_TABLE.16b
+	tbl		X_2.16b, {X_2.16b}, ROTATE_TABLE.16b
+	tbl		X_3.16b, {X_3.16b}, ROTATE_TABLE.16b
+.endm
+
+.macro _next_xts_tweak	next, cur, tmp, n
+.if \n == 64
+	/*
+	 * Calculate the next tweak by multiplying the current one by x,
+	 * modulo p(x) = x^128 + x^7 + x^2 + x + 1.
+	 */
+	sshr		\tmp\().2d, \cur\().2d, #63
+	and		\tmp\().16b, \tmp\().16b, GFMUL_TABLE.16b
+	shl		\next\().2d, \cur\().2d, #1
+	ext		\tmp\().16b, \tmp\().16b, \tmp\().16b, #8
+	eor		\next\().16b, \next\().16b, \tmp\().16b
+.else
+	/*
+	 * Calculate the next two tweaks by multiplying the current ones by x^2,
+	 * modulo p(x) = x^64 + x^4 + x^3 + x + 1.
+	 */
+	ushr		\tmp\().2d, \cur\().2d, #62
+	shl		\next\().2d, \cur\().2d, #2
+	tbl		\tmp\().16b, {GFMUL_TABLE.16b}, \tmp\().16b
+	eor		\next\().16b, \next\().16b, \tmp\().16b
+.endif
+.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, lanes, decrypting
+
+	/*
+	 * 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
+	mov		NROUNDS, NROUNDS	/* zero the high 32 bits */
+.if \n == 64
+	add		ROUND_KEYS, ROUND_KEYS, NROUNDS_X, lsl #3
+	sub		ROUND_KEYS, ROUND_KEYS, #8
+.else
+	add		ROUND_KEYS, ROUND_KEYS, NROUNDS_X, lsl #2
+	sub		ROUND_KEYS, ROUND_KEYS, #4
+.endif
+.endif
+
+	// Load the index vector for tbl-based 8-bit rotates
+.if \decrypting
+	ldr		ROTATE_TABLE_Q, .Lrol\n\()_8_table
+.else
+	ldr		ROTATE_TABLE_Q, .Lror\n\()_8_table
+.endif
+
+	// One-time XTS preparation
+.if \n == 64
+	// Load first tweak
+	ld1		{TWEAKV0.16b}, [TWEAK]
+
+	// Load GF(2^128) multiplication table
+	ldr		GFMUL_TABLE_Q, .Lgf128mul_table
+.else
+	// Load first tweak
+	ld1		{TWEAKV0.8b}, [TWEAK]
+
+	// Load GF(2^64) multiplication table
+	ldr		GFMUL_TABLE_Q, .Lgf64mul_table
+
+	// Calculate second tweak, packing it together with the first
+	ushr		TMP0.2d, TWEAKV0.2d, #63
+	shl		TMP1.2d, TWEAKV0.2d, #1
+	tbl		TMP0.8b, {GFMUL_TABLE.16b}, TMP0.8b
+	eor		TMP0.8b, TMP0.8b, TMP1.8b
+	mov		TWEAKV0.d[1], TMP0.d[0]
+.endif
+
+.Lnext_128bytes_\@:
+
+	// Calculate XTS tweaks for next 128 bytes
+	_next_xts_tweak	TWEAKV1, TWEAKV0, TMP0, \n
+	_next_xts_tweak	TWEAKV2, TWEAKV1, TMP0, \n
+	_next_xts_tweak	TWEAKV3, TWEAKV2, TMP0, \n
+	_next_xts_tweak	TWEAKV4, TWEAKV3, TMP0, \n
+	_next_xts_tweak	TWEAKV5, TWEAKV4, TMP0, \n
+	_next_xts_tweak	TWEAKV6, TWEAKV5, TMP0, \n
+	_next_xts_tweak	TWEAKV7, TWEAKV6, TMP0, \n
+	_next_xts_tweak	TWEAKV_NEXT, TWEAKV7, TMP0, \n
+
+	// Load the next source blocks into {X,Y}[0-3]
+	ld1		{X_0.16b-Y_1.16b}, [SRC], #64
+	ld1		{X_2.16b-Y_3.16b}, [SRC], #64
+
+	// XOR the source blocks with their XTS tweaks
+	eor		TMP0.16b, X_0.16b, TWEAKV0.16b
+	eor		Y_0.16b,  Y_0.16b, TWEAKV1.16b
+	eor		TMP1.16b, X_1.16b, TWEAKV2.16b
+	eor		Y_1.16b,  Y_1.16b, TWEAKV3.16b
+	eor		TMP2.16b, X_2.16b, TWEAKV4.16b
+	eor		Y_2.16b,  Y_2.16b, TWEAKV5.16b
+	eor		TMP3.16b, X_3.16b, TWEAKV6.16b
+	eor		Y_3.16b,  Y_3.16b, TWEAKV7.16b
+
+	/*
+	 * 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).)
+	 */
+	uzp2		X_0.\lanes, TMP0.\lanes, Y_0.\lanes
+	uzp1		Y_0.\lanes, TMP0.\lanes, Y_0.\lanes
+	uzp2		X_1.\lanes, TMP1.\lanes, Y_1.\lanes
+	uzp1		Y_1.\lanes, TMP1.\lanes, Y_1.\lanes
+	uzp2		X_2.\lanes, TMP2.\lanes, Y_2.\lanes
+	uzp1		Y_2.\lanes, TMP2.\lanes, Y_2.\lanes
+	uzp2		X_3.\lanes, TMP3.\lanes, Y_3.\lanes
+	uzp1		Y_3.\lanes, TMP3.\lanes, Y_3.\lanes
+
+	// Do the cipher rounds
+	mov		x6, ROUND_KEYS
+	mov		w7, NROUNDS
+.Lnext_round_\@:
+.if \decrypting
+	ld1r		{ROUND_KEY.\lanes}, [x6]
+	sub		x6, x6, #( \n / 8 )
+	_speck_unround_128bytes	\n, \lanes
+.else
+	ld1r		{ROUND_KEY.\lanes}, [x6], #( \n / 8 )
+	_speck_round_128bytes	\n, \lanes
+.endif
+	subs		w7, w7, #1
+	bne		.Lnext_round_\@
+
+	// Re-interleave the 'x' and 'y' elements of each block
+	zip1		TMP0.\lanes, Y_0.\lanes, X_0.\lanes
+	zip2		Y_0.\lanes,  Y_0.\lanes, X_0.\lanes
+	zip1		TMP1.\lanes, Y_1.\lanes, X_1.\lanes
+	zip2		Y_1.\lanes,  Y_1.\lanes, X_1.\lanes
+	zip1		TMP2.\lanes, Y_2.\lanes, X_2.\lanes
+	zip2		Y_2.\lanes,  Y_2.\lanes, X_2.\lanes
+	zip1		TMP3.\lanes, Y_3.\lanes, X_3.\lanes
+	zip2		Y_3.\lanes,  Y_3.\lanes, X_3.\lanes
+
+	// XOR the encrypted/decrypted blocks with the tweaks calculated earlier
+	eor		X_0.16b, TMP0.16b, TWEAKV0.16b
+	eor		Y_0.16b, Y_0.16b,  TWEAKV1.16b
+	eor		X_1.16b, TMP1.16b, TWEAKV2.16b
+	eor		Y_1.16b, Y_1.16b,  TWEAKV3.16b
+	eor		X_2.16b, TMP2.16b, TWEAKV4.16b
+	eor		Y_2.16b, Y_2.16b,  TWEAKV5.16b
+	eor		X_3.16b, TMP3.16b, TWEAKV6.16b
+	eor		Y_3.16b, Y_3.16b,  TWEAKV7.16b
+	mov		TWEAKV0.16b, TWEAKV_NEXT.16b
+
+	// Store the ciphertext in the destination buffer
+	st1		{X_0.16b-Y_1.16b}, [DST], #64
+	st1		{X_2.16b-Y_3.16b}, [DST], #64
+
+	// Continue if there are more 128-byte chunks remaining
+	subs		NBYTES, NBYTES, #128
+	bne		.Lnext_128bytes_\@
+
+	// Store the next tweak and return
+.if \n == 64
+	st1		{TWEAKV_NEXT.16b}, [TWEAK]
+.else
+	st1		{TWEAKV_NEXT.8b}, [TWEAK]
+.endif
+	ret
+.endm
+
+ENTRY(speck128_xts_encrypt_neon)
+	_speck_xts_crypt	n=64, lanes=2d, decrypting=0
+ENDPROC(speck128_xts_encrypt_neon)
+
+ENTRY(speck128_xts_decrypt_neon)
+	_speck_xts_crypt	n=64, lanes=2d, decrypting=1
+ENDPROC(speck128_xts_decrypt_neon)
+
+ENTRY(speck64_xts_encrypt_neon)
+	_speck_xts_crypt	n=32, lanes=4s, decrypting=0
+ENDPROC(speck64_xts_encrypt_neon)
+
+ENTRY(speck64_xts_decrypt_neon)
+	_speck_xts_crypt	n=32, lanes=4s, decrypting=1
+ENDPROC(speck64_xts_decrypt_neon)