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-// 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.
- * For Thumb2 compatibility, don't do the 'bic' directly on 'sp'.
- */
- sub r12, sp, #128
- bic r12, #0xf
- mov sp, r12
-
-.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)