mirror of
https://github.com/Atmosphere-NX/Atmosphere
synced 2024-11-16 01:49:32 +00:00
591 lines
26 KiB
C++
591 lines
26 KiB
C++
/*
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* Copyright (c) Atmosphère-NX
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms and conditions of the GNU General Public License,
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* version 2, as published by the Free Software Foundation.
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*
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* This program is distributed in the hope it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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* more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <vapours.hpp>
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#ifdef ATMOSPHERE_IS_STRATOSPHERE
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#include <arm_neon.h>
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namespace ams::crypto::impl {
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/* Variable management macros. */
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#define DECLARE_ROUND_KEY_VAR(n) \
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const uint8x16_t round_key_##n = vld1q_u8(keys + (BlockSize * n))
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#define AES_ENC_DEC_OUTPUT_THREE_BLOCKS() \
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[tmp0]"+w"(tmp0), [tmp1]"+w"(tmp1), [tmp2]"+w"(tmp2)
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#define AES_ENC_DEC_OUTPUT_THREE_CTRS() \
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[ctr0]"+w"(ctr0), [ctr1]"+w"(ctr1), [ctr2]"+w"(ctr2)
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#define AES_ENC_DEC_OUTPUT_ONE_BLOCK() \
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[tmp0]"+w"(tmp0)
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#define AES_ENC_DEC_OUTPUT_ONE_CTR() \
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[ctr0]"+w"(ctr0)
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#define CTR_INCREMENT_OUTPUT_HIGH_LOW() \
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[high]"=&r"(high), [low]"=&r"(low)
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#define CTR_INCREMENT_OUTPUT_HIGH_LOW_TMP() \
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[high_tmp]"=&r"(high_tmp), [low_tmp]"=&r"(low_tmp)
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#define CTR_INCREMENT_OUTPUT_HL_SINGLE_TMP() \
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[hl_tmp]"=&r"(hl_tmp)
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#define AES_ENC_DEC_INPUT_ROUND_KEY(n) \
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[round_key_##n]"w"(round_key_##n)
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/* AES Encryption macros. */
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#define AES_ENC_ROUND(n, i) \
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"aese %[tmp" #i "].16b, %[round_key_" #n "].16b\n" \
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"aesmc %[tmp" #i "].16b, %[tmp" #i "].16b\n"
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#define AES_ENC_SECOND_LAST_ROUND(n, i) \
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"aese %[tmp" #i "].16b, %[round_key_" #n "].16b\n"
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#define AES_ENC_LAST_ROUND(n, i) \
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"eor %[tmp" #i "].16b, %[tmp" #i "].16b, %[round_key_" #n "].16b\n"
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namespace {
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ALWAYS_INLINE uint8x16_t IncrementCounterOptimized(const uint8x16_t ctr) {
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uint8x16_t inc;
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uint64_t high, low;
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/* Use ASM. TODO: Better than using intrinsics? */
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__asm__ __volatile__ (
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"mov %[high], %[ctr].d[0]\n"
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"mov %[low], %[ctr].d[1]\n"
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"rev %[high], %[high]\n"
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"rev %[low], %[low]\n"
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"adds %[low], %[low], 1\n"
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"cinc %[high], %[high], cs\n"
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"rev %[high], %[high]\n"
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"rev %[low], %[low]\n"
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"mov %[inc].d[0], %[high]\n"
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"mov %[inc].d[1], %[low]\n"
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: [inc]"=w"(inc),
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CTR_INCREMENT_OUTPUT_HIGH_LOW()
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: [ctr]"w"(ctr)
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: "cc"
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);
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return inc;
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}
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}
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template<>
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void CtrModeImpl<AesEncryptor128>::ProcessBlocks(u8 *dst, const u8 *src, size_t num_blocks) {
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/* Preload all round keys + iv into neon registers. */
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const u8 *keys = m_block_cipher->GetRoundKey();
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DECLARE_ROUND_KEY_VAR(0);
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DECLARE_ROUND_KEY_VAR(1);
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DECLARE_ROUND_KEY_VAR(2);
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DECLARE_ROUND_KEY_VAR(3);
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DECLARE_ROUND_KEY_VAR(4);
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DECLARE_ROUND_KEY_VAR(5);
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DECLARE_ROUND_KEY_VAR(6);
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DECLARE_ROUND_KEY_VAR(7);
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DECLARE_ROUND_KEY_VAR(8);
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DECLARE_ROUND_KEY_VAR(9);
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DECLARE_ROUND_KEY_VAR(10);
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uint8x16_t ctr0 = vld1q_u8(m_counter);
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uint64_t high, low;
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/* Process three blocks at a time, when possible. */
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if (num_blocks >= 3) {
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/* Increment CTR twice. */
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uint8x16_t ctr1 = IncrementCounterOptimized(ctr0);
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uint8x16_t ctr2 = IncrementCounterOptimized(ctr1);
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uint64_t high_tmp, low_tmp;
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while (num_blocks >= 3) {
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/* Read blocks in. Keep them in registers for XOR later. */
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const uint8x16_t block0 = vld1q_u8(src);
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src += AesEncryptor128::BlockSize;
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const uint8x16_t block1 = vld1q_u8(src);
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src += AesEncryptor128::BlockSize;
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const uint8x16_t block2 = vld1q_u8(src);
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src += AesEncryptor128::BlockSize;
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/* We'll be encrypting the three CTRs. */
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uint8x16_t tmp0 = ctr0, tmp1 = ctr1, tmp2 = ctr2;
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/* Actually do encryption, use optimized asm. */
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/* Interleave CTR calculations with AES ones, to mask latencies. */
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__asm__ __volatile__ (
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AES_ENC_ROUND(0, 0) "mov %[high], %[ctr2].d[0]\n"
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AES_ENC_ROUND(0, 1) "mov %[low], %[ctr2].d[1]\n"
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AES_ENC_ROUND(0, 2) "rev %[high], %[high]\n"
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AES_ENC_ROUND(1, 0) "rev %[low], %[low]\n"
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AES_ENC_ROUND(1, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(1, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(2, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(2, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(2, 2) "mov %[ctr0].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(3, 0) "mov %[ctr0].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(3, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(3, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(4, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(4, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(4, 2) "mov %[ctr1].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(5, 0) "mov %[ctr1].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(5, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(5, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(6, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(6, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(6, 2) "mov %[ctr2].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(7, 0) "mov %[ctr2].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(7, 1)
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AES_ENC_ROUND(7, 2)
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AES_ENC_ROUND(8, 0) AES_ENC_ROUND(8, 1) AES_ENC_ROUND(8, 2)
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AES_ENC_SECOND_LAST_ROUND(9, 0) AES_ENC_SECOND_LAST_ROUND(9, 1) AES_ENC_SECOND_LAST_ROUND(9, 2)
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AES_ENC_LAST_ROUND(10, 0) AES_ENC_LAST_ROUND(10, 1) AES_ENC_LAST_ROUND(10, 2)
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: AES_ENC_DEC_OUTPUT_THREE_BLOCKS(),
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AES_ENC_DEC_OUTPUT_THREE_CTRS(),
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CTR_INCREMENT_OUTPUT_HIGH_LOW(),
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CTR_INCREMENT_OUTPUT_HIGH_LOW_TMP()
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: AES_ENC_DEC_INPUT_ROUND_KEY(0),
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AES_ENC_DEC_INPUT_ROUND_KEY(1),
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AES_ENC_DEC_INPUT_ROUND_KEY(2),
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AES_ENC_DEC_INPUT_ROUND_KEY(3),
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AES_ENC_DEC_INPUT_ROUND_KEY(4),
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AES_ENC_DEC_INPUT_ROUND_KEY(5),
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AES_ENC_DEC_INPUT_ROUND_KEY(6),
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AES_ENC_DEC_INPUT_ROUND_KEY(7),
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AES_ENC_DEC_INPUT_ROUND_KEY(8),
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AES_ENC_DEC_INPUT_ROUND_KEY(9),
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AES_ENC_DEC_INPUT_ROUND_KEY(10)
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: "cc"
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);
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/* XOR blocks. */
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tmp0 = veorq_u8(block0, tmp0);
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tmp1 = veorq_u8(block1, tmp1);
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tmp2 = veorq_u8(block2, tmp2);
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/* Store to output. */
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vst1q_u8(dst, tmp0);
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dst += AesEncryptor128::BlockSize;
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vst1q_u8(dst, tmp1);
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dst += AesEncryptor128::BlockSize;
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vst1q_u8(dst, tmp2);
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dst += AesEncryptor128::BlockSize;
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num_blocks -= 3;
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}
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}
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while (num_blocks >= 1) {
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/* Read block in, keep in register for XOR. */
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const uint8x16_t block0 = vld1q_u8(src);
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src += AesEncryptor128::BlockSize;
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/* We'll be encrypting the CTR. */
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uint8x16_t tmp0 = ctr0;
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/* Actually do encryption, use optimized asm. */
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/* Interleave CTR calculations with AES ones, to mask latencies. */
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__asm__ __volatile__ (
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AES_ENC_ROUND(0, 0) "mov %[high], %[ctr0].d[0]\n"
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AES_ENC_ROUND(1, 0) "mov %[low], %[ctr0].d[1]\n"
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AES_ENC_ROUND(2, 0) "rev %[high], %[high]\n"
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AES_ENC_ROUND(3, 0) "rev %[low], %[low]\n"
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AES_ENC_ROUND(4, 0) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(5, 0) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(6, 0) "rev %[high], %[high]\n"
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AES_ENC_ROUND(7, 0) "rev %[low], %[low]\n"
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AES_ENC_ROUND(8, 0) "mov %[ctr0].d[0], %[high]\n"
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AES_ENC_SECOND_LAST_ROUND(9, 0) "mov %[ctr0].d[1], %[low]\n"
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AES_ENC_LAST_ROUND(10, 0)
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: AES_ENC_DEC_OUTPUT_ONE_BLOCK(),
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AES_ENC_DEC_OUTPUT_ONE_CTR(),
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CTR_INCREMENT_OUTPUT_HIGH_LOW()
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: AES_ENC_DEC_INPUT_ROUND_KEY(0),
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AES_ENC_DEC_INPUT_ROUND_KEY(1),
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AES_ENC_DEC_INPUT_ROUND_KEY(2),
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AES_ENC_DEC_INPUT_ROUND_KEY(3),
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AES_ENC_DEC_INPUT_ROUND_KEY(4),
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AES_ENC_DEC_INPUT_ROUND_KEY(5),
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AES_ENC_DEC_INPUT_ROUND_KEY(6),
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AES_ENC_DEC_INPUT_ROUND_KEY(7),
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AES_ENC_DEC_INPUT_ROUND_KEY(8),
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AES_ENC_DEC_INPUT_ROUND_KEY(9),
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AES_ENC_DEC_INPUT_ROUND_KEY(10)
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: "cc"
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);
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/* XOR blocks. */
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tmp0 = veorq_u8(block0, tmp0);
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/* Store to output. */
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vst1q_u8(dst, tmp0);
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dst += AesEncryptor128::BlockSize;
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num_blocks--;
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}
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vst1q_u8(m_counter, ctr0);
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}
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template<>
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void CtrModeImpl<AesEncryptor192>::ProcessBlocks(u8 *dst, const u8 *src, size_t num_blocks) {
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/* Preload all round keys + iv into neon registers. */
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const u8 *keys = m_block_cipher->GetRoundKey();
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DECLARE_ROUND_KEY_VAR(0);
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DECLARE_ROUND_KEY_VAR(1);
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DECLARE_ROUND_KEY_VAR(2);
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DECLARE_ROUND_KEY_VAR(3);
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DECLARE_ROUND_KEY_VAR(4);
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DECLARE_ROUND_KEY_VAR(5);
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DECLARE_ROUND_KEY_VAR(6);
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DECLARE_ROUND_KEY_VAR(7);
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DECLARE_ROUND_KEY_VAR(8);
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DECLARE_ROUND_KEY_VAR(9);
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DECLARE_ROUND_KEY_VAR(10);
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DECLARE_ROUND_KEY_VAR(11);
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DECLARE_ROUND_KEY_VAR(12);
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uint8x16_t ctr0 = vld1q_u8(m_counter);
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uint64_t high, low;
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/* Process three blocks at a time, when possible. */
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if (num_blocks >= 3) {
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/* Increment CTR twice. */
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uint8x16_t ctr1 = IncrementCounterOptimized(ctr0);
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uint8x16_t ctr2 = IncrementCounterOptimized(ctr1);
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uint64_t high_tmp, low_tmp;
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while (num_blocks >= 3) {
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/* Read blocks in. Keep them in registers for XOR later. */
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const uint8x16_t block0 = vld1q_u8(src);
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src += AesEncryptor192::BlockSize;
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const uint8x16_t block1 = vld1q_u8(src);
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src += AesEncryptor192::BlockSize;
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const uint8x16_t block2 = vld1q_u8(src);
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src += AesEncryptor192::BlockSize;
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/* We'll be encrypting the three CTRs. */
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uint8x16_t tmp0 = ctr0, tmp1 = ctr1, tmp2 = ctr2;
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/* Actually do encryption, use optimized asm. */
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/* Interleave CTR calculations with AES ones, to mask latencies. */
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__asm__ __volatile__ (
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AES_ENC_ROUND(0, 0) "mov %[high], %[ctr2].d[0]\n"
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AES_ENC_ROUND(0, 1) "mov %[low], %[ctr2].d[1]\n"
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AES_ENC_ROUND(0, 2) "rev %[high], %[high]\n"
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AES_ENC_ROUND(1, 0) "rev %[low], %[low]\n"
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AES_ENC_ROUND(1, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(1, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(2, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(2, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(2, 2) "mov %[ctr0].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(3, 0) "mov %[ctr0].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(3, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(3, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(4, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(4, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(4, 2) "mov %[ctr1].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(5, 0) "mov %[ctr1].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(5, 1) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(5, 2) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(6, 0) "rev %[high_tmp], %[high]\n"
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AES_ENC_ROUND(6, 1) "rev %[low_tmp], %[low]\n"
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AES_ENC_ROUND(6, 2) "mov %[ctr2].d[0], %[high_tmp]\n"
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AES_ENC_ROUND(7, 0) "mov %[ctr2].d[1], %[low_tmp]\n"
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AES_ENC_ROUND(7, 1)
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AES_ENC_ROUND(7, 2)
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AES_ENC_ROUND(8, 0) AES_ENC_ROUND(8, 1) AES_ENC_ROUND(8, 2)
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AES_ENC_ROUND(9, 0) AES_ENC_ROUND(9, 1) AES_ENC_ROUND(9, 2)
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AES_ENC_ROUND(10, 0) AES_ENC_ROUND(10, 1) AES_ENC_ROUND(10, 2)
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AES_ENC_SECOND_LAST_ROUND(11, 0) AES_ENC_SECOND_LAST_ROUND(11, 1) AES_ENC_SECOND_LAST_ROUND(11, 2)
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AES_ENC_LAST_ROUND(12, 0) AES_ENC_LAST_ROUND(12, 1) AES_ENC_LAST_ROUND(12, 2)
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: AES_ENC_DEC_OUTPUT_THREE_BLOCKS(),
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AES_ENC_DEC_OUTPUT_THREE_CTRS(),
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CTR_INCREMENT_OUTPUT_HIGH_LOW(),
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CTR_INCREMENT_OUTPUT_HIGH_LOW_TMP()
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: AES_ENC_DEC_INPUT_ROUND_KEY(0),
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AES_ENC_DEC_INPUT_ROUND_KEY(1),
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AES_ENC_DEC_INPUT_ROUND_KEY(2),
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AES_ENC_DEC_INPUT_ROUND_KEY(3),
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AES_ENC_DEC_INPUT_ROUND_KEY(4),
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AES_ENC_DEC_INPUT_ROUND_KEY(5),
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AES_ENC_DEC_INPUT_ROUND_KEY(6),
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AES_ENC_DEC_INPUT_ROUND_KEY(7),
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AES_ENC_DEC_INPUT_ROUND_KEY(8),
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AES_ENC_DEC_INPUT_ROUND_KEY(9),
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AES_ENC_DEC_INPUT_ROUND_KEY(10),
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AES_ENC_DEC_INPUT_ROUND_KEY(11),
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AES_ENC_DEC_INPUT_ROUND_KEY(12)
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: "cc"
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);
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/* XOR blocks. */
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tmp0 = veorq_u8(block0, tmp0);
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tmp1 = veorq_u8(block1, tmp1);
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tmp2 = veorq_u8(block2, tmp2);
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/* Store to output. */
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vst1q_u8(dst, tmp0);
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dst += AesEncryptor192::BlockSize;
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vst1q_u8(dst, tmp1);
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dst += AesEncryptor192::BlockSize;
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vst1q_u8(dst, tmp2);
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dst += AesEncryptor192::BlockSize;
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num_blocks -= 3;
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}
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}
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while (num_blocks >= 1) {
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/* Read block in, keep in register for XOR. */
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const uint8x16_t block0 = vld1q_u8(src);
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src += AesEncryptor192::BlockSize;
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/* We'll be encrypting the CTR. */
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uint8x16_t tmp0 = ctr0;
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/* Actually do encryption, use optimized asm. */
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/* Interleave CTR calculations with AES ones, to mask latencies. */
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__asm__ __volatile__ (
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AES_ENC_ROUND(0, 0) "mov %[high], %[ctr0].d[0]\n"
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AES_ENC_ROUND(1, 0) "mov %[low], %[ctr0].d[1]\n"
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AES_ENC_ROUND(2, 0) "rev %[high], %[high]\n"
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AES_ENC_ROUND(3, 0) "rev %[low], %[low]\n"
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AES_ENC_ROUND(4, 0) "adds %[low], %[low], 1\n"
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AES_ENC_ROUND(5, 0) "cinc %[high], %[high], cs\n"
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AES_ENC_ROUND(6, 0) "rev %[high], %[high]\n"
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AES_ENC_ROUND(7, 0) "rev %[low], %[low]\n"
|
|
AES_ENC_ROUND(8, 0) "mov %[ctr0].d[0], %[high]\n"
|
|
AES_ENC_ROUND(9, 0) "mov %[ctr0].d[1], %[low]\n"
|
|
AES_ENC_ROUND(10, 0)
|
|
AES_ENC_SECOND_LAST_ROUND(11, 0)
|
|
AES_ENC_LAST_ROUND(12, 0)
|
|
: AES_ENC_DEC_OUTPUT_ONE_BLOCK(),
|
|
AES_ENC_DEC_OUTPUT_ONE_CTR(),
|
|
CTR_INCREMENT_OUTPUT_HIGH_LOW()
|
|
: AES_ENC_DEC_INPUT_ROUND_KEY(0),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(1),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(2),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(3),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(4),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(5),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(6),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(7),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(8),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(9),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(10),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(11),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(12)
|
|
: "cc"
|
|
);
|
|
|
|
/* XOR blocks. */
|
|
tmp0 = veorq_u8(block0, tmp0);
|
|
|
|
/* Store to output. */
|
|
vst1q_u8(dst, tmp0);
|
|
dst += AesEncryptor192::BlockSize;
|
|
|
|
num_blocks--;
|
|
}
|
|
|
|
vst1q_u8(m_counter, ctr0);
|
|
}
|
|
|
|
template<>
|
|
void CtrModeImpl<AesEncryptor256>::ProcessBlocks(u8 *dst, const u8 *src, size_t num_blocks) {
|
|
/* Preload all round keys + iv into neon registers. */
|
|
const u8 *keys = m_block_cipher->GetRoundKey();
|
|
DECLARE_ROUND_KEY_VAR(0);
|
|
DECLARE_ROUND_KEY_VAR(1);
|
|
DECLARE_ROUND_KEY_VAR(2);
|
|
DECLARE_ROUND_KEY_VAR(3);
|
|
DECLARE_ROUND_KEY_VAR(4);
|
|
DECLARE_ROUND_KEY_VAR(5);
|
|
DECLARE_ROUND_KEY_VAR(6);
|
|
DECLARE_ROUND_KEY_VAR(7);
|
|
DECLARE_ROUND_KEY_VAR(8);
|
|
DECLARE_ROUND_KEY_VAR(9);
|
|
DECLARE_ROUND_KEY_VAR(10);
|
|
DECLARE_ROUND_KEY_VAR(11);
|
|
DECLARE_ROUND_KEY_VAR(12);
|
|
DECLARE_ROUND_KEY_VAR(13);
|
|
DECLARE_ROUND_KEY_VAR(14);
|
|
uint8x16_t ctr0 = vld1q_u8(m_counter);
|
|
uint64_t high, low;
|
|
|
|
/* Process three blocks at a time, when possible. */
|
|
if (num_blocks >= 3) {
|
|
/* Increment CTR twice. */
|
|
uint8x16_t ctr1 = IncrementCounterOptimized(ctr0);
|
|
uint8x16_t ctr2 = IncrementCounterOptimized(ctr1);
|
|
uint64_t hl_tmp;
|
|
|
|
while (num_blocks >= 3) {
|
|
/* Read blocks in. Keep them in registers for XOR later. */
|
|
const uint8x16_t block0 = vld1q_u8(src);
|
|
src += AesEncryptor256::BlockSize;
|
|
const uint8x16_t block1 = vld1q_u8(src);
|
|
src += AesEncryptor256::BlockSize;
|
|
const uint8x16_t block2 = vld1q_u8(src);
|
|
src += AesEncryptor256::BlockSize;
|
|
|
|
/* We'll be encrypting the three CTRs. */
|
|
uint8x16_t tmp0 = ctr0, tmp1 = ctr1, tmp2 = ctr2;
|
|
|
|
/* Actually do encryption, use optimized asm. */
|
|
/* Interleave CTR calculations with AES ones, to mask latencies. */
|
|
/* Note: ASM here only uses one temporary u64 instead of two, due to 30 operand limit. */
|
|
__asm__ __volatile__ (
|
|
AES_ENC_ROUND(0, 0) "mov %[high], %[ctr2].d[0]\n"
|
|
AES_ENC_ROUND(0, 1) "mov %[low], %[ctr2].d[1]\n"
|
|
AES_ENC_ROUND(0, 2) "rev %[high], %[high]\n"
|
|
AES_ENC_ROUND(1, 0) "rev %[low], %[low]\n"
|
|
AES_ENC_ROUND(1, 1) "adds %[low], %[low], 1\n"
|
|
AES_ENC_ROUND(1, 2) "cinc %[high], %[high], cs\n"
|
|
AES_ENC_ROUND(2, 0) "rev %[hl_tmp], %[high]\n"
|
|
AES_ENC_ROUND(2, 1) "mov %[ctr0].d[0], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(2, 2) "rev %[hl_tmp], %[low]\n"
|
|
AES_ENC_ROUND(3, 0) "mov %[ctr0].d[1], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(3, 1) "adds %[low], %[low], 1\n"
|
|
AES_ENC_ROUND(3, 2) "cinc %[high], %[high], cs\n"
|
|
AES_ENC_ROUND(4, 0) "rev %[hl_tmp], %[high]\n"
|
|
AES_ENC_ROUND(4, 1) "mov %[ctr1].d[0], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(4, 2) "rev %[hl_tmp], %[low]\n"
|
|
AES_ENC_ROUND(5, 0) "mov %[ctr1].d[1], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(5, 1) "adds %[low], %[low], 1\n"
|
|
AES_ENC_ROUND(5, 2) "cinc %[high], %[high], cs\n"
|
|
AES_ENC_ROUND(6, 0) "rev %[hl_tmp], %[high]\n"
|
|
AES_ENC_ROUND(6, 1) "mov %[ctr2].d[0], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(6, 2) "rev %[hl_tmp], %[low]\n"
|
|
AES_ENC_ROUND(7, 0) "mov %[ctr2].d[1], %[hl_tmp]\n"
|
|
AES_ENC_ROUND(7, 1)
|
|
AES_ENC_ROUND(7, 2)
|
|
AES_ENC_ROUND(8, 0) AES_ENC_ROUND(8, 1) AES_ENC_ROUND(8, 2)
|
|
AES_ENC_ROUND(9, 0) AES_ENC_ROUND(9, 1) AES_ENC_ROUND(9, 2)
|
|
AES_ENC_ROUND(10, 0) AES_ENC_ROUND(10, 1) AES_ENC_ROUND(10, 2)
|
|
AES_ENC_ROUND(11, 0) AES_ENC_ROUND(11, 1) AES_ENC_ROUND(11, 2)
|
|
AES_ENC_ROUND(12, 0) AES_ENC_ROUND(12, 1) AES_ENC_ROUND(12, 2)
|
|
AES_ENC_SECOND_LAST_ROUND(13, 0) AES_ENC_SECOND_LAST_ROUND(13, 1) AES_ENC_SECOND_LAST_ROUND(13, 2)
|
|
AES_ENC_LAST_ROUND(14, 0) AES_ENC_LAST_ROUND(14, 1) AES_ENC_LAST_ROUND(14, 2)
|
|
: AES_ENC_DEC_OUTPUT_THREE_BLOCKS(),
|
|
AES_ENC_DEC_OUTPUT_THREE_CTRS(),
|
|
CTR_INCREMENT_OUTPUT_HIGH_LOW(),
|
|
CTR_INCREMENT_OUTPUT_HL_SINGLE_TMP()
|
|
: AES_ENC_DEC_INPUT_ROUND_KEY(0),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(1),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(2),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(3),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(4),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(5),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(6),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(7),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(8),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(9),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(10),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(11),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(12),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(13),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(14)
|
|
: "cc"
|
|
);
|
|
|
|
/* XOR blocks. */
|
|
tmp0 = veorq_u8(block0, tmp0);
|
|
tmp1 = veorq_u8(block1, tmp1);
|
|
tmp2 = veorq_u8(block2, tmp2);
|
|
|
|
/* Store to output. */
|
|
vst1q_u8(dst, tmp0);
|
|
dst += AesEncryptor256::BlockSize;
|
|
vst1q_u8(dst, tmp1);
|
|
dst += AesEncryptor256::BlockSize;
|
|
vst1q_u8(dst, tmp2);
|
|
dst += AesEncryptor256::BlockSize;
|
|
|
|
num_blocks -= 3;
|
|
}
|
|
}
|
|
|
|
while (num_blocks >= 1) {
|
|
/* Read block in, keep in register for XOR. */
|
|
const uint8x16_t block0 = vld1q_u8(src);
|
|
src += AesEncryptor256::BlockSize;
|
|
|
|
/* We'll be encrypting the CTR. */
|
|
uint8x16_t tmp0 = ctr0;
|
|
|
|
/* Actually do encryption, use optimized asm. */
|
|
/* Interleave CTR calculations with AES ones, to mask latencies. */
|
|
__asm__ __volatile__ (
|
|
AES_ENC_ROUND(0, 0) "mov %[high], %[ctr0].d[0]\n"
|
|
AES_ENC_ROUND(1, 0) "mov %[low], %[ctr0].d[1]\n"
|
|
AES_ENC_ROUND(2, 0) "rev %[high], %[high]\n"
|
|
AES_ENC_ROUND(3, 0) "rev %[low], %[low]\n"
|
|
AES_ENC_ROUND(4, 0) "adds %[low], %[low], 1\n"
|
|
AES_ENC_ROUND(5, 0) "cinc %[high], %[high], cs\n"
|
|
AES_ENC_ROUND(6, 0) "rev %[high], %[high]\n"
|
|
AES_ENC_ROUND(7, 0) "rev %[low], %[low]\n"
|
|
AES_ENC_ROUND(8, 0) "mov %[ctr0].d[0], %[high]\n"
|
|
AES_ENC_ROUND(9, 0) "mov %[ctr0].d[1], %[low]\n"
|
|
AES_ENC_ROUND(10, 0)
|
|
AES_ENC_ROUND(11, 0)
|
|
AES_ENC_ROUND(12, 0)
|
|
AES_ENC_SECOND_LAST_ROUND(13, 0)
|
|
AES_ENC_LAST_ROUND(14, 0)
|
|
: AES_ENC_DEC_OUTPUT_ONE_BLOCK(),
|
|
AES_ENC_DEC_OUTPUT_ONE_CTR(),
|
|
CTR_INCREMENT_OUTPUT_HIGH_LOW()
|
|
: AES_ENC_DEC_INPUT_ROUND_KEY(0),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(1),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(2),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(3),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(4),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(5),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(6),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(7),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(8),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(9),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(10),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(11),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(12),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(13),
|
|
AES_ENC_DEC_INPUT_ROUND_KEY(14)
|
|
: "cc"
|
|
);
|
|
|
|
/* XOR blocks. */
|
|
tmp0 = veorq_u8(block0, tmp0);
|
|
|
|
/* Store to output. */
|
|
vst1q_u8(dst, tmp0);
|
|
dst += AesEncryptor256::BlockSize;
|
|
|
|
num_blocks--;
|
|
}
|
|
|
|
vst1q_u8(m_counter, ctr0);
|
|
}
|
|
|
|
}
|
|
|
|
#else
|
|
|
|
/* TODO: Non-EL0 implementation. */
|
|
namespace ams::crypto::impl {
|
|
|
|
}
|
|
|
|
#endif
|