| /* Copyright (c) 2019, Google Inc. |
| * |
| * Permission to use, copy, modify, and/or distribute this software for any |
| * purpose with or without fee is hereby granted, provided that the above |
| * copyright notice and this permission notice appear in all copies. |
| * |
| * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES |
| * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF |
| * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY |
| * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES |
| * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION |
| * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN |
| * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ |
| |
| #include <openssl/aes.h> |
| |
| #include <assert.h> |
| #include <string.h> |
| |
| #include "../../internal.h" |
| #include "internal.h" |
| |
| #if defined(OPENSSL_SSE2) |
| #include <emmintrin.h> |
| #endif |
| |
| |
| // This file contains a constant-time implementation of AES, bitsliced with |
| // 32-bit, 64-bit, or 128-bit words, operating on two-, four-, and eight-block |
| // batches, respectively. The 128-bit implementation requires SSE2 intrinsics. |
| // |
| // This implementation is based on the algorithms described in the following |
| // references: |
| // - https://bearssl.org/constanttime.html#aes |
| // - https://eprint.iacr.org/2009/129.pdf |
| // - https://eprint.iacr.org/2009/191.pdf |
| |
| |
| // Word operations. |
| // |
| // An aes_word_t is the word used for this AES implementation. Throughout this |
| // file, bits and bytes are ordered little-endian, though "left" and "right" |
| // shifts match the operations themselves, which makes them reversed in a |
| // little-endian, left-to-right reading. |
| // |
| // Eight |aes_word_t|s contain |AES_NOHW_BATCH_SIZE| blocks. The bits in an |
| // |aes_word_t| are divided into 16 consecutive groups of |AES_NOHW_BATCH_SIZE| |
| // bits each, each corresponding to a byte in an AES block in column-major |
| // order (AES's byte order). We refer to these as "logical bytes". Note, in the |
| // 32-bit and 64-bit implementations, they are smaller than a byte. (The |
| // contents of a logical byte will be described later.) |
| // |
| // MSVC does not support C bit operators on |__m128i|, so the wrapper functions |
| // |aes_nohw_and|, etc., should be used instead. Note |aes_nohw_shift_left| and |
| // |aes_nohw_shift_right| measure the shift in logical bytes. That is, the shift |
| // value ranges from 0 to 15 independent of |aes_word_t| and |
| // |AES_NOHW_BATCH_SIZE|. |
| // |
| // This ordering is different from https://eprint.iacr.org/2009/129.pdf, which |
| // uses row-major order. Matching the AES order was easier to reason about, and |
| // we do not have PSHUFB available to arbitrarily permute bytes. |
| |
| #if defined(OPENSSL_SSE2) |
| typedef __m128i aes_word_t; |
| // AES_NOHW_WORD_SIZE is sizeof(aes_word_t). alignas(sizeof(T)) does not work in |
| // MSVC, so we define a constant. |
| #define AES_NOHW_WORD_SIZE 16 |
| #define AES_NOHW_BATCH_SIZE 8 |
| #define AES_NOHW_ROW0_MASK \ |
| _mm_set_epi32(0x000000ff, 0x000000ff, 0x000000ff, 0x000000ff) |
| #define AES_NOHW_ROW1_MASK \ |
| _mm_set_epi32(0x0000ff00, 0x0000ff00, 0x0000ff00, 0x0000ff00) |
| #define AES_NOHW_ROW2_MASK \ |
| _mm_set_epi32(0x00ff0000, 0x00ff0000, 0x00ff0000, 0x00ff0000) |
| #define AES_NOHW_ROW3_MASK \ |
| _mm_set_epi32(0xff000000, 0xff000000, 0xff000000, 0xff000000) |
| #define AES_NOHW_COL01_MASK \ |
| _mm_set_epi32(0x00000000, 0x00000000, 0xffffffff, 0xffffffff) |
| #define AES_NOHW_COL2_MASK \ |
| _mm_set_epi32(0x00000000, 0xffffffff, 0x00000000, 0x00000000) |
| #define AES_NOHW_COL3_MASK \ |
| _mm_set_epi32(0xffffffff, 0x00000000, 0x00000000, 0x00000000) |
| |
| static inline aes_word_t aes_nohw_and(aes_word_t a, aes_word_t b) { |
| return _mm_and_si128(a, b); |
| } |
| |
| static inline aes_word_t aes_nohw_or(aes_word_t a, aes_word_t b) { |
| return _mm_or_si128(a, b); |
| } |
| |
| static inline aes_word_t aes_nohw_xor(aes_word_t a, aes_word_t b) { |
| return _mm_xor_si128(a, b); |
| } |
| |
| static inline aes_word_t aes_nohw_not(aes_word_t a) { |
| return _mm_xor_si128( |
| a, _mm_set_epi32(0xffffffff, 0xffffffff, 0xffffffff, 0xffffffff)); |
| } |
| |
| // These are macros because parameters to |_mm_slli_si128| and |_mm_srli_si128| |
| // must be constants. |
| #define aes_nohw_shift_left(/* aes_word_t */ a, /* const */ i) \ |
| _mm_slli_si128((a), (i)) |
| #define aes_nohw_shift_right(/* aes_word_t */ a, /* const */ i) \ |
| _mm_srli_si128((a), (i)) |
| #else // !OPENSSL_SSE2 |
| #if defined(OPENSSL_64_BIT) |
| typedef uint64_t aes_word_t; |
| #define AES_NOHW_WORD_SIZE 8 |
| #define AES_NOHW_BATCH_SIZE 4 |
| #define AES_NOHW_ROW0_MASK UINT64_C(0x000f000f000f000f) |
| #define AES_NOHW_ROW1_MASK UINT64_C(0x00f000f000f000f0) |
| #define AES_NOHW_ROW2_MASK UINT64_C(0x0f000f000f000f00) |
| #define AES_NOHW_ROW3_MASK UINT64_C(0xf000f000f000f000) |
| #define AES_NOHW_COL01_MASK UINT64_C(0x00000000ffffffff) |
| #define AES_NOHW_COL2_MASK UINT64_C(0x0000ffff00000000) |
| #define AES_NOHW_COL3_MASK UINT64_C(0xffff000000000000) |
| #else // !OPENSSL_64_BIT |
| typedef uint32_t aes_word_t; |
| #define AES_NOHW_WORD_SIZE 4 |
| #define AES_NOHW_BATCH_SIZE 2 |
| #define AES_NOHW_ROW0_MASK 0x03030303 |
| #define AES_NOHW_ROW1_MASK 0x0c0c0c0c |
| #define AES_NOHW_ROW2_MASK 0x30303030 |
| #define AES_NOHW_ROW3_MASK 0xc0c0c0c0 |
| #define AES_NOHW_COL01_MASK 0x0000ffff |
| #define AES_NOHW_COL2_MASK 0x00ff0000 |
| #define AES_NOHW_COL3_MASK 0xff000000 |
| #endif // OPENSSL_64_BIT |
| |
| static inline aes_word_t aes_nohw_and(aes_word_t a, aes_word_t b) { |
| return a & b; |
| } |
| |
| static inline aes_word_t aes_nohw_or(aes_word_t a, aes_word_t b) { |
| return a | b; |
| } |
| |
| static inline aes_word_t aes_nohw_xor(aes_word_t a, aes_word_t b) { |
| return a ^ b; |
| } |
| |
| static inline aes_word_t aes_nohw_not(aes_word_t a) { return ~a; } |
| |
| static inline aes_word_t aes_nohw_shift_left(aes_word_t a, aes_word_t i) { |
| return a << (i * AES_NOHW_BATCH_SIZE); |
| } |
| |
| static inline aes_word_t aes_nohw_shift_right(aes_word_t a, aes_word_t i) { |
| return a >> (i * AES_NOHW_BATCH_SIZE); |
| } |
| #endif // OPENSSL_SSE2 |
| |
| static_assert(AES_NOHW_BATCH_SIZE * 128 == 8 * 8 * sizeof(aes_word_t), |
| "batch size does not match word size"); |
| static_assert(AES_NOHW_WORD_SIZE == sizeof(aes_word_t), |
| "AES_NOHW_WORD_SIZE is incorrect"); |
| |
| |
| // Block representations. |
| // |
| // This implementation uses three representations for AES blocks. First, the |
| // public API represents blocks as uint8_t[16] in the usual way. Second, most |
| // AES steps are evaluated in bitsliced form, stored in an |AES_NOHW_BATCH|. |
| // This stores |AES_NOHW_BATCH_SIZE| blocks in bitsliced order. For 64-bit words |
| // containing bitsliced blocks a, b, c, d, this would be as follows (vertical |
| // bars divide logical bytes): |
| // |
| // batch.w[0] = a0 b0 c0 d0 | a8 b8 c8 d8 | a16 b16 c16 d16 ... |
| // batch.w[1] = a1 b1 c1 d1 | a9 b9 c9 d9 | a17 b17 c17 d17 ... |
| // batch.w[2] = a2 b2 c2 d2 | a10 b10 c10 d10 | a18 b18 c18 d18 ... |
| // batch.w[3] = a3 b3 c3 d3 | a11 b11 c11 d11 | a19 b19 c19 d19 ... |
| // ... |
| // |
| // Finally, an individual block may be stored as an intermediate form in an |
| // aes_word_t[AES_NOHW_BLOCK_WORDS]. In this form, we permute the bits in each |
| // block, so that block[0]'s ith logical byte contains least-significant |
| // |AES_NOHW_BATCH_SIZE| bits of byte i, block[1] contains the next group of |
| // |AES_NOHW_BATCH_SIZE| bits, and so on. We refer to this transformation as |
| // "compacting" the block. Note this is no-op with 128-bit words because then |
| // |AES_NOHW_BLOCK_WORDS| is one and |AES_NOHW_BATCH_SIZE| is eight. For 64-bit |
| // words, one block would be stored in two words: |
| // |
| // block[0] = a0 a1 a2 a3 | a8 a9 a10 a11 | a16 a17 a18 a19 ... |
| // block[1] = a4 a5 a6 a7 | a12 a13 a14 a15 | a20 a21 a22 a23 ... |
| // |
| // Observe that the distances between corresponding bits in bitsliced and |
| // compact bit orders match. If we line up corresponding words of each block, |
| // the bitsliced and compact representations may be converted by tranposing bits |
| // in corresponding logical bytes. Continuing the 64-bit example: |
| // |
| // block_a[0] = a0 a1 a2 a3 | a8 a9 a10 a11 | a16 a17 a18 a19 ... |
| // block_b[0] = b0 b1 b2 b3 | b8 b9 b10 b11 | b16 b17 b18 b19 ... |
| // block_c[0] = c0 c1 c2 c3 | c8 c9 c10 c11 | c16 c17 c18 c19 ... |
| // block_d[0] = d0 d1 d2 d3 | d8 d9 d10 d11 | d16 d17 d18 d19 ... |
| // |
| // batch.w[0] = a0 b0 c0 d0 | a8 b8 c8 d8 | a16 b16 c16 d16 ... |
| // batch.w[1] = a1 b1 c1 d1 | a9 b9 c9 d9 | a17 b17 c17 d17 ... |
| // batch.w[2] = a2 b2 c2 d2 | a10 b10 c10 d10 | a18 b18 c18 d18 ... |
| // batch.w[3] = a3 b3 c3 d3 | a11 b11 c11 d11 | a19 b19 c19 d19 ... |
| // |
| // Note also that bitwise operations and (logical) byte permutations on an |
| // |aes_word_t| work equally for the bitsliced and compact words. |
| // |
| // We use the compact form in the |AES_KEY| representation to save work |
| // inflating round keys into |AES_NOHW_BATCH|. The compact form also exists |
| // temporarily while moving blocks in or out of an |AES_NOHW_BATCH|, immediately |
| // before or after |aes_nohw_transpose|. |
| |
| #define AES_NOHW_BLOCK_WORDS (16 / sizeof(aes_word_t)) |
| |
| // An AES_NOHW_BATCH stores |AES_NOHW_BATCH_SIZE| blocks. Unless otherwise |
| // specified, it is in bitsliced form. |
| typedef struct { |
| aes_word_t w[8]; |
| } AES_NOHW_BATCH; |
| |
| // An AES_NOHW_SCHEDULE is an expanded bitsliced AES key schedule. It is |
| // suitable for encryption or decryption. It is as large as |AES_NOHW_BATCH| |
| // |AES_KEY|s so it should not be used as a long-term key representation. |
| typedef struct { |
| // keys is an array of batches, one for each round key. Each batch stores |
| // |AES_NOHW_BATCH_SIZE| copies of the round key in bitsliced form. |
| AES_NOHW_BATCH keys[AES_MAXNR + 1]; |
| } AES_NOHW_SCHEDULE; |
| |
| // aes_nohw_batch_set sets the |i|th block of |batch| to |in|. |batch| is in |
| // compact form. |
| static inline void aes_nohw_batch_set(AES_NOHW_BATCH *batch, |
| const aes_word_t in[AES_NOHW_BLOCK_WORDS], |
| size_t i) { |
| // Note the words are interleaved. The order comes from |aes_nohw_transpose|. |
| // If |i| is zero and this is the 64-bit implementation, in[0] contains bits |
| // 0-3 and in[1] contains bits 4-7. We place in[0] at w[0] and in[1] at |
| // w[4] so that bits 0 and 4 are in the correct position. (In general, bits |
| // along diagonals of |AES_NOHW_BATCH_SIZE| by |AES_NOHW_BATCH_SIZE| squares |
| // will be correctly placed.) |
| assert(i < AES_NOHW_BATCH_SIZE); |
| #if defined(OPENSSL_SSE2) |
| batch->w[i] = in[0]; |
| #elif defined(OPENSSL_64_BIT) |
| batch->w[i] = in[0]; |
| batch->w[i + 4] = in[1]; |
| #else |
| batch->w[i] = in[0]; |
| batch->w[i + 2] = in[1]; |
| batch->w[i + 4] = in[2]; |
| batch->w[i + 6] = in[3]; |
| #endif |
| } |
| |
| // aes_nohw_batch_get writes the |i|th block of |batch| to |out|. |batch| is in |
| // compact form. |
| static inline void aes_nohw_batch_get(const AES_NOHW_BATCH *batch, |
| aes_word_t out[AES_NOHW_BLOCK_WORDS], |
| size_t i) { |
| assert(i < AES_NOHW_BATCH_SIZE); |
| #if defined(OPENSSL_SSE2) |
| out[0] = batch->w[i]; |
| #elif defined(OPENSSL_64_BIT) |
| out[0] = batch->w[i]; |
| out[1] = batch->w[i + 4]; |
| #else |
| out[0] = batch->w[i]; |
| out[1] = batch->w[i + 2]; |
| out[2] = batch->w[i + 4]; |
| out[3] = batch->w[i + 6]; |
| #endif |
| } |
| |
| #if !defined(OPENSSL_SSE2) |
| // aes_nohw_delta_swap returns |a| with bits |a & mask| and |
| // |a & (mask << shift)| swapped. |mask| and |mask << shift| may not overlap. |
| static inline aes_word_t aes_nohw_delta_swap(aes_word_t a, aes_word_t mask, |
| aes_word_t shift) { |
| // See |
| // https://reflectionsonsecurity.wordpress.com/2014/05/11/efficient-bit-permutation-using-delta-swaps/ |
| aes_word_t b = (a ^ (a >> shift)) & mask; |
| return a ^ b ^ (b << shift); |
| } |
| |
| // In the 32-bit and 64-bit implementations, a block spans multiple words. |
| // |aes_nohw_compact_block| must permute bits across different words. First we |
| // implement |aes_nohw_compact_word| which performs a smaller version of the |
| // transformation which stays within a single word. |
| // |
| // These transformations are generalizations of the output of |
| // http://programming.sirrida.de/calcperm.php on smaller inputs. |
| #if defined(OPENSSL_64_BIT) |
| static inline uint64_t aes_nohw_compact_word(uint64_t a) { |
| // Numbering the 64/2 = 16 4-bit chunks, least to most significant, we swap |
| // quartets of those chunks: |
| // 0 1 2 3 | 4 5 6 7 | 8 9 10 11 | 12 13 14 15 => |
| // 0 2 1 3 | 4 6 5 7 | 8 10 9 11 | 12 14 13 15 |
| a = aes_nohw_delta_swap(a, UINT64_C(0x00f000f000f000f0), 4); |
| // Swap quartets of 8-bit chunks (still numbering by 4-bit chunks): |
| // 0 2 1 3 | 4 6 5 7 | 8 10 9 11 | 12 14 13 15 => |
| // 0 2 4 6 | 1 3 5 7 | 8 10 12 14 | 9 11 13 15 |
| a = aes_nohw_delta_swap(a, UINT64_C(0x0000ff000000ff00), 8); |
| // Swap quartets of 16-bit chunks (still numbering by 4-bit chunks): |
| // 0 2 4 6 | 1 3 5 7 | 8 10 12 14 | 9 11 13 15 => |
| // 0 2 4 6 | 8 10 12 14 | 1 3 5 7 | 9 11 13 15 |
| a = aes_nohw_delta_swap(a, UINT64_C(0x00000000ffff0000), 16); |
| return a; |
| } |
| |
| static inline uint64_t aes_nohw_uncompact_word(uint64_t a) { |
| // Reverse the steps of |aes_nohw_uncompact_word|. |
| a = aes_nohw_delta_swap(a, UINT64_C(0x00000000ffff0000), 16); |
| a = aes_nohw_delta_swap(a, UINT64_C(0x0000ff000000ff00), 8); |
| a = aes_nohw_delta_swap(a, UINT64_C(0x00f000f000f000f0), 4); |
| return a; |
| } |
| #else // !OPENSSL_64_BIT |
| static inline uint32_t aes_nohw_compact_word(uint32_t a) { |
| // Numbering the 32/2 = 16 pairs of bits, least to most significant, we swap: |
| // 0 1 2 3 | 4 5 6 7 | 8 9 10 11 | 12 13 14 15 => |
| // 0 4 2 6 | 1 5 3 7 | 8 12 10 14 | 9 13 11 15 |
| // Note: 0x00cc = 0b0000_0000_1100_1100 |
| // 0x00cc << 6 = 0b0011_0011_0000_0000 |
| a = aes_nohw_delta_swap(a, 0x00cc00cc, 6); |
| // Now we swap groups of four bits (still numbering by pairs): |
| // 0 4 2 6 | 1 5 3 7 | 8 12 10 14 | 9 13 11 15 => |
| // 0 4 8 12 | 1 5 9 13 | 2 6 10 14 | 3 7 11 15 |
| // Note: 0x0000_f0f0 << 12 = 0x0f0f_0000 |
| a = aes_nohw_delta_swap(a, 0x0000f0f0, 12); |
| return a; |
| } |
| |
| static inline uint32_t aes_nohw_uncompact_word(uint32_t a) { |
| // Reverse the steps of |aes_nohw_uncompact_word|. |
| a = aes_nohw_delta_swap(a, 0x0000f0f0, 12); |
| a = aes_nohw_delta_swap(a, 0x00cc00cc, 6); |
| return a; |
| } |
| |
| static inline uint32_t aes_nohw_word_from_bytes(uint8_t a0, uint8_t a1, |
| uint8_t a2, uint8_t a3) { |
| return (uint32_t)a0 | ((uint32_t)a1 << 8) | ((uint32_t)a2 << 16) | |
| ((uint32_t)a3 << 24); |
| } |
| #endif // OPENSSL_64_BIT |
| #endif // !OPENSSL_SSE2 |
| |
| static inline void aes_nohw_compact_block(aes_word_t out[AES_NOHW_BLOCK_WORDS], |
| const uint8_t in[16]) { |
| memcpy(out, in, 16); |
| #if defined(OPENSSL_SSE2) |
| // No conversions needed. |
| #elif defined(OPENSSL_64_BIT) |
| uint64_t a0 = aes_nohw_compact_word(out[0]); |
| uint64_t a1 = aes_nohw_compact_word(out[1]); |
| out[0] = (a0 & UINT64_C(0x00000000ffffffff)) | (a1 << 32); |
| out[1] = (a1 & UINT64_C(0xffffffff00000000)) | (a0 >> 32); |
| #else |
| uint32_t a0 = aes_nohw_compact_word(out[0]); |
| uint32_t a1 = aes_nohw_compact_word(out[1]); |
| uint32_t a2 = aes_nohw_compact_word(out[2]); |
| uint32_t a3 = aes_nohw_compact_word(out[3]); |
| // Note clang, when building for ARM Thumb2, will sometimes miscompile |
| // expressions such as (a0 & 0x0000ff00) << 8, particularly when building |
| // without optimizations. This bug was introduced in |
| // https://reviews.llvm.org/rL340261 and fixed in |
| // https://reviews.llvm.org/rL351310. The following is written to avoid this. |
| out[0] = aes_nohw_word_from_bytes(a0, a1, a2, a3); |
| out[1] = aes_nohw_word_from_bytes(a0 >> 8, a1 >> 8, a2 >> 8, a3 >> 8); |
| out[2] = aes_nohw_word_from_bytes(a0 >> 16, a1 >> 16, a2 >> 16, a3 >> 16); |
| out[3] = aes_nohw_word_from_bytes(a0 >> 24, a1 >> 24, a2 >> 24, a3 >> 24); |
| #endif |
| } |
| |
| static inline void aes_nohw_uncompact_block( |
| uint8_t out[16], const aes_word_t in[AES_NOHW_BLOCK_WORDS]) { |
| #if defined(OPENSSL_SSE2) |
| memcpy(out, in, 16); // No conversions needed. |
| #elif defined(OPENSSL_64_BIT) |
| uint64_t a0 = in[0]; |
| uint64_t a1 = in[1]; |
| uint64_t b0 = |
| aes_nohw_uncompact_word((a0 & UINT64_C(0x00000000ffffffff)) | (a1 << 32)); |
| uint64_t b1 = |
| aes_nohw_uncompact_word((a1 & UINT64_C(0xffffffff00000000)) | (a0 >> 32)); |
| memcpy(out, &b0, 8); |
| memcpy(out + 8, &b1, 8); |
| #else |
| uint32_t a0 = in[0]; |
| uint32_t a1 = in[1]; |
| uint32_t a2 = in[2]; |
| uint32_t a3 = in[3]; |
| // Note clang, when building for ARM Thumb2, will sometimes miscompile |
| // expressions such as (a0 & 0x0000ff00) << 8, particularly when building |
| // without optimizations. This bug was introduced in |
| // https://reviews.llvm.org/rL340261 and fixed in |
| // https://reviews.llvm.org/rL351310. The following is written to avoid this. |
| uint32_t b0 = aes_nohw_word_from_bytes(a0, a1, a2, a3); |
| uint32_t b1 = aes_nohw_word_from_bytes(a0 >> 8, a1 >> 8, a2 >> 8, a3 >> 8); |
| uint32_t b2 = |
| aes_nohw_word_from_bytes(a0 >> 16, a1 >> 16, a2 >> 16, a3 >> 16); |
| uint32_t b3 = |
| aes_nohw_word_from_bytes(a0 >> 24, a1 >> 24, a2 >> 24, a3 >> 24); |
| b0 = aes_nohw_uncompact_word(b0); |
| b1 = aes_nohw_uncompact_word(b1); |
| b2 = aes_nohw_uncompact_word(b2); |
| b3 = aes_nohw_uncompact_word(b3); |
| memcpy(out, &b0, 4); |
| memcpy(out + 4, &b1, 4); |
| memcpy(out + 8, &b2, 4); |
| memcpy(out + 12, &b3, 4); |
| #endif |
| } |
| |
| // aes_nohw_swap_bits is a variation on a delta swap. It swaps the bits in |
| // |*a & (mask << shift)| with the bits in |*b & mask|. |mask| and |
| // |mask << shift| must not overlap. |mask| is specified as a |uint32_t|, but it |
| // is repeated to the full width of |aes_word_t|. |
| #if defined(OPENSSL_SSE2) |
| // This must be a macro because |_mm_srli_epi32| and |_mm_slli_epi32| require |
| // constant shift values. |
| #define aes_nohw_swap_bits(/*__m128i* */ a, /*__m128i* */ b, \ |
| /* uint32_t */ mask, /* const */ shift) \ |
| do { \ |
| __m128i swap = \ |
| _mm_and_si128(_mm_xor_si128(_mm_srli_epi32(*(a), (shift)), *(b)), \ |
| _mm_set_epi32((mask), (mask), (mask), (mask))); \ |
| *(a) = _mm_xor_si128(*(a), _mm_slli_epi32(swap, (shift))); \ |
| *(b) = _mm_xor_si128(*(b), swap); \ |
| \ |
| } while (0) |
| #else |
| static inline void aes_nohw_swap_bits(aes_word_t *a, aes_word_t *b, |
| uint32_t mask, aes_word_t shift) { |
| #if defined(OPENSSL_64_BIT) |
| aes_word_t mask_w = (((uint64_t)mask) << 32) | mask; |
| #else |
| aes_word_t mask_w = mask; |
| #endif |
| // This is a variation on a delta swap. |
| aes_word_t swap = ((*a >> shift) ^ *b) & mask_w; |
| *a ^= swap << shift; |
| *b ^= swap; |
| } |
| #endif // OPENSSL_SSE2 |
| |
| // aes_nohw_transpose converts |batch| to and from bitsliced form. It divides |
| // the 8 × word_size bits into AES_NOHW_BATCH_SIZE × AES_NOHW_BATCH_SIZE squares |
| // and transposes each square. |
| static void aes_nohw_transpose(AES_NOHW_BATCH *batch) { |
| // Swap bits with index 0 and 1 mod 2 (0x55 = 0b01010101). |
| aes_nohw_swap_bits(&batch->w[0], &batch->w[1], 0x55555555, 1); |
| aes_nohw_swap_bits(&batch->w[2], &batch->w[3], 0x55555555, 1); |
| aes_nohw_swap_bits(&batch->w[4], &batch->w[5], 0x55555555, 1); |
| aes_nohw_swap_bits(&batch->w[6], &batch->w[7], 0x55555555, 1); |
| |
| #if AES_NOHW_BATCH_SIZE >= 4 |
| // Swap bits with index 0-1 and 2-3 mod 4 (0x33 = 0b00110011). |
| aes_nohw_swap_bits(&batch->w[0], &batch->w[2], 0x33333333, 2); |
| aes_nohw_swap_bits(&batch->w[1], &batch->w[3], 0x33333333, 2); |
| aes_nohw_swap_bits(&batch->w[4], &batch->w[6], 0x33333333, 2); |
| aes_nohw_swap_bits(&batch->w[5], &batch->w[7], 0x33333333, 2); |
| #endif |
| |
| #if AES_NOHW_BATCH_SIZE >= 8 |
| // Swap bits with index 0-3 and 4-7 mod 8 (0x0f = 0b00001111). |
| aes_nohw_swap_bits(&batch->w[0], &batch->w[4], 0x0f0f0f0f, 4); |
| aes_nohw_swap_bits(&batch->w[1], &batch->w[5], 0x0f0f0f0f, 4); |
| aes_nohw_swap_bits(&batch->w[2], &batch->w[6], 0x0f0f0f0f, 4); |
| aes_nohw_swap_bits(&batch->w[3], &batch->w[7], 0x0f0f0f0f, 4); |
| #endif |
| } |
| |
| // aes_nohw_to_batch initializes |out| with the |num_blocks| blocks from |in|. |
| // |num_blocks| must be at most |AES_NOHW_BATCH|. |
| static void aes_nohw_to_batch(AES_NOHW_BATCH *out, const uint8_t *in, |
| size_t num_blocks) { |
| // Don't leave unused blocks uninitialized. |
| memset(out, 0, sizeof(AES_NOHW_BATCH)); |
| assert(num_blocks <= AES_NOHW_BATCH_SIZE); |
| for (size_t i = 0; i < num_blocks; i++) { |
| aes_word_t block[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_compact_block(block, in + 16 * i); |
| aes_nohw_batch_set(out, block, i); |
| } |
| |
| aes_nohw_transpose(out); |
| } |
| |
| // aes_nohw_to_batch writes the first |num_blocks| blocks in |batch| to |out|. |
| // |num_blocks| must be at most |AES_NOHW_BATCH|. |
| static void aes_nohw_from_batch(uint8_t *out, size_t num_blocks, |
| const AES_NOHW_BATCH *batch) { |
| AES_NOHW_BATCH copy = *batch; |
| aes_nohw_transpose(©); |
| |
| assert(num_blocks <= AES_NOHW_BATCH_SIZE); |
| for (size_t i = 0; i < num_blocks; i++) { |
| aes_word_t block[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_batch_get(©, block, i); |
| aes_nohw_uncompact_block(out + 16 * i, block); |
| } |
| } |
| |
| |
| // AES round steps. |
| |
| static void aes_nohw_add_round_key(AES_NOHW_BATCH *batch, |
| const AES_NOHW_BATCH *key) { |
| for (size_t i = 0; i < 8; i++) { |
| batch->w[i] = aes_nohw_xor(batch->w[i], key->w[i]); |
| } |
| } |
| |
| static void aes_nohw_sub_bytes(AES_NOHW_BATCH *batch) { |
| // See https://eprint.iacr.org/2009/191.pdf, Appendix C. |
| aes_word_t x0 = batch->w[7]; |
| aes_word_t x1 = batch->w[6]; |
| aes_word_t x2 = batch->w[5]; |
| aes_word_t x3 = batch->w[4]; |
| aes_word_t x4 = batch->w[3]; |
| aes_word_t x5 = batch->w[2]; |
| aes_word_t x6 = batch->w[1]; |
| aes_word_t x7 = batch->w[0]; |
| |
| // Figure 2, the top linear transformation. |
| aes_word_t y14 = aes_nohw_xor(x3, x5); |
| aes_word_t y13 = aes_nohw_xor(x0, x6); |
| aes_word_t y9 = aes_nohw_xor(x0, x3); |
| aes_word_t y8 = aes_nohw_xor(x0, x5); |
| aes_word_t t0 = aes_nohw_xor(x1, x2); |
| aes_word_t y1 = aes_nohw_xor(t0, x7); |
| aes_word_t y4 = aes_nohw_xor(y1, x3); |
| aes_word_t y12 = aes_nohw_xor(y13, y14); |
| aes_word_t y2 = aes_nohw_xor(y1, x0); |
| aes_word_t y5 = aes_nohw_xor(y1, x6); |
| aes_word_t y3 = aes_nohw_xor(y5, y8); |
| aes_word_t t1 = aes_nohw_xor(x4, y12); |
| aes_word_t y15 = aes_nohw_xor(t1, x5); |
| aes_word_t y20 = aes_nohw_xor(t1, x1); |
| aes_word_t y6 = aes_nohw_xor(y15, x7); |
| aes_word_t y10 = aes_nohw_xor(y15, t0); |
| aes_word_t y11 = aes_nohw_xor(y20, y9); |
| aes_word_t y7 = aes_nohw_xor(x7, y11); |
| aes_word_t y17 = aes_nohw_xor(y10, y11); |
| aes_word_t y19 = aes_nohw_xor(y10, y8); |
| aes_word_t y16 = aes_nohw_xor(t0, y11); |
| aes_word_t y21 = aes_nohw_xor(y13, y16); |
| aes_word_t y18 = aes_nohw_xor(x0, y16); |
| |
| // Figure 3, the middle non-linear section. |
| aes_word_t t2 = aes_nohw_and(y12, y15); |
| aes_word_t t3 = aes_nohw_and(y3, y6); |
| aes_word_t t4 = aes_nohw_xor(t3, t2); |
| aes_word_t t5 = aes_nohw_and(y4, x7); |
| aes_word_t t6 = aes_nohw_xor(t5, t2); |
| aes_word_t t7 = aes_nohw_and(y13, y16); |
| aes_word_t t8 = aes_nohw_and(y5, y1); |
| aes_word_t t9 = aes_nohw_xor(t8, t7); |
| aes_word_t t10 = aes_nohw_and(y2, y7); |
| aes_word_t t11 = aes_nohw_xor(t10, t7); |
| aes_word_t t12 = aes_nohw_and(y9, y11); |
| aes_word_t t13 = aes_nohw_and(y14, y17); |
| aes_word_t t14 = aes_nohw_xor(t13, t12); |
| aes_word_t t15 = aes_nohw_and(y8, y10); |
| aes_word_t t16 = aes_nohw_xor(t15, t12); |
| aes_word_t t17 = aes_nohw_xor(t4, t14); |
| aes_word_t t18 = aes_nohw_xor(t6, t16); |
| aes_word_t t19 = aes_nohw_xor(t9, t14); |
| aes_word_t t20 = aes_nohw_xor(t11, t16); |
| aes_word_t t21 = aes_nohw_xor(t17, y20); |
| aes_word_t t22 = aes_nohw_xor(t18, y19); |
| aes_word_t t23 = aes_nohw_xor(t19, y21); |
| aes_word_t t24 = aes_nohw_xor(t20, y18); |
| aes_word_t t25 = aes_nohw_xor(t21, t22); |
| aes_word_t t26 = aes_nohw_and(t21, t23); |
| aes_word_t t27 = aes_nohw_xor(t24, t26); |
| aes_word_t t28 = aes_nohw_and(t25, t27); |
| aes_word_t t29 = aes_nohw_xor(t28, t22); |
| aes_word_t t30 = aes_nohw_xor(t23, t24); |
| aes_word_t t31 = aes_nohw_xor(t22, t26); |
| aes_word_t t32 = aes_nohw_and(t31, t30); |
| aes_word_t t33 = aes_nohw_xor(t32, t24); |
| aes_word_t t34 = aes_nohw_xor(t23, t33); |
| aes_word_t t35 = aes_nohw_xor(t27, t33); |
| aes_word_t t36 = aes_nohw_and(t24, t35); |
| aes_word_t t37 = aes_nohw_xor(t36, t34); |
| aes_word_t t38 = aes_nohw_xor(t27, t36); |
| aes_word_t t39 = aes_nohw_and(t29, t38); |
| aes_word_t t40 = aes_nohw_xor(t25, t39); |
| aes_word_t t41 = aes_nohw_xor(t40, t37); |
| aes_word_t t42 = aes_nohw_xor(t29, t33); |
| aes_word_t t43 = aes_nohw_xor(t29, t40); |
| aes_word_t t44 = aes_nohw_xor(t33, t37); |
| aes_word_t t45 = aes_nohw_xor(t42, t41); |
| aes_word_t z0 = aes_nohw_and(t44, y15); |
| aes_word_t z1 = aes_nohw_and(t37, y6); |
| aes_word_t z2 = aes_nohw_and(t33, x7); |
| aes_word_t z3 = aes_nohw_and(t43, y16); |
| aes_word_t z4 = aes_nohw_and(t40, y1); |
| aes_word_t z5 = aes_nohw_and(t29, y7); |
| aes_word_t z6 = aes_nohw_and(t42, y11); |
| aes_word_t z7 = aes_nohw_and(t45, y17); |
| aes_word_t z8 = aes_nohw_and(t41, y10); |
| aes_word_t z9 = aes_nohw_and(t44, y12); |
| aes_word_t z10 = aes_nohw_and(t37, y3); |
| aes_word_t z11 = aes_nohw_and(t33, y4); |
| aes_word_t z12 = aes_nohw_and(t43, y13); |
| aes_word_t z13 = aes_nohw_and(t40, y5); |
| aes_word_t z14 = aes_nohw_and(t29, y2); |
| aes_word_t z15 = aes_nohw_and(t42, y9); |
| aes_word_t z16 = aes_nohw_and(t45, y14); |
| aes_word_t z17 = aes_nohw_and(t41, y8); |
| |
| // Figure 4, bottom linear transformation. |
| aes_word_t t46 = aes_nohw_xor(z15, z16); |
| aes_word_t t47 = aes_nohw_xor(z10, z11); |
| aes_word_t t48 = aes_nohw_xor(z5, z13); |
| aes_word_t t49 = aes_nohw_xor(z9, z10); |
| aes_word_t t50 = aes_nohw_xor(z2, z12); |
| aes_word_t t51 = aes_nohw_xor(z2, z5); |
| aes_word_t t52 = aes_nohw_xor(z7, z8); |
| aes_word_t t53 = aes_nohw_xor(z0, z3); |
| aes_word_t t54 = aes_nohw_xor(z6, z7); |
| aes_word_t t55 = aes_nohw_xor(z16, z17); |
| aes_word_t t56 = aes_nohw_xor(z12, t48); |
| aes_word_t t57 = aes_nohw_xor(t50, t53); |
| aes_word_t t58 = aes_nohw_xor(z4, t46); |
| aes_word_t t59 = aes_nohw_xor(z3, t54); |
| aes_word_t t60 = aes_nohw_xor(t46, t57); |
| aes_word_t t61 = aes_nohw_xor(z14, t57); |
| aes_word_t t62 = aes_nohw_xor(t52, t58); |
| aes_word_t t63 = aes_nohw_xor(t49, t58); |
| aes_word_t t64 = aes_nohw_xor(z4, t59); |
| aes_word_t t65 = aes_nohw_xor(t61, t62); |
| aes_word_t t66 = aes_nohw_xor(z1, t63); |
| aes_word_t s0 = aes_nohw_xor(t59, t63); |
| aes_word_t s6 = aes_nohw_xor(t56, aes_nohw_not(t62)); |
| aes_word_t s7 = aes_nohw_xor(t48, aes_nohw_not(t60)); |
| aes_word_t t67 = aes_nohw_xor(t64, t65); |
| aes_word_t s3 = aes_nohw_xor(t53, t66); |
| aes_word_t s4 = aes_nohw_xor(t51, t66); |
| aes_word_t s5 = aes_nohw_xor(t47, t65); |
| aes_word_t s1 = aes_nohw_xor(t64, aes_nohw_not(s3)); |
| aes_word_t s2 = aes_nohw_xor(t55, aes_nohw_not(t67)); |
| |
| batch->w[0] = s7; |
| batch->w[1] = s6; |
| batch->w[2] = s5; |
| batch->w[3] = s4; |
| batch->w[4] = s3; |
| batch->w[5] = s2; |
| batch->w[6] = s1; |
| batch->w[7] = s0; |
| } |
| |
| // aes_nohw_sub_bytes_inv_affine inverts the affine transform portion of the AES |
| // S-box, defined in FIPS PUB 197, section 5.1.1, step 2. |
| static void aes_nohw_sub_bytes_inv_affine(AES_NOHW_BATCH *batch) { |
| aes_word_t a0 = batch->w[0]; |
| aes_word_t a1 = batch->w[1]; |
| aes_word_t a2 = batch->w[2]; |
| aes_word_t a3 = batch->w[3]; |
| aes_word_t a4 = batch->w[4]; |
| aes_word_t a5 = batch->w[5]; |
| aes_word_t a6 = batch->w[6]; |
| aes_word_t a7 = batch->w[7]; |
| |
| // Apply the circulant [0 0 1 0 0 1 0 1]. This is the inverse of the circulant |
| // [1 0 0 0 1 1 1 1]. |
| aes_word_t b0 = aes_nohw_xor(a2, aes_nohw_xor(a5, a7)); |
| aes_word_t b1 = aes_nohw_xor(a3, aes_nohw_xor(a6, a0)); |
| aes_word_t b2 = aes_nohw_xor(a4, aes_nohw_xor(a7, a1)); |
| aes_word_t b3 = aes_nohw_xor(a5, aes_nohw_xor(a0, a2)); |
| aes_word_t b4 = aes_nohw_xor(a6, aes_nohw_xor(a1, a3)); |
| aes_word_t b5 = aes_nohw_xor(a7, aes_nohw_xor(a2, a4)); |
| aes_word_t b6 = aes_nohw_xor(a0, aes_nohw_xor(a3, a5)); |
| aes_word_t b7 = aes_nohw_xor(a1, aes_nohw_xor(a4, a6)); |
| |
| // XOR 0x05. Equivalently, we could XOR 0x63 before applying the circulant, |
| // but 0x05 has lower Hamming weight. (0x05 is the circulant applied to 0x63.) |
| batch->w[0] = aes_nohw_not(b0); |
| batch->w[1] = b1; |
| batch->w[2] = aes_nohw_not(b2); |
| batch->w[3] = b3; |
| batch->w[4] = b4; |
| batch->w[5] = b5; |
| batch->w[6] = b6; |
| batch->w[7] = b7; |
| } |
| |
| static void aes_nohw_inv_sub_bytes(AES_NOHW_BATCH *batch) { |
| // We implement the inverse S-box using the forwards implementation with the |
| // technique described in https://www.bearssl.org/constanttime.html#aes. |
| // |
| // The forwards S-box inverts its input and applies an affine transformation: |
| // S(x) = A(Inv(x)). Thus Inv(x) = InvA(S(x)). The inverse S-box is then: |
| // |
| // InvS(x) = Inv(InvA(x)). |
| // = InvA(S(InvA(x))) |
| aes_nohw_sub_bytes_inv_affine(batch); |
| aes_nohw_sub_bytes(batch); |
| aes_nohw_sub_bytes_inv_affine(batch); |
| } |
| |
| // aes_nohw_rotate_cols_right returns |v| with the columns in each row rotated |
| // to the right by |n|. This is a macro because |aes_nohw_shift_*| require |
| // constant shift counts in the SSE2 implementation. |
| #define aes_nohw_rotate_cols_right(/* aes_word_t */ v, /* const */ n) \ |
| (aes_nohw_or(aes_nohw_shift_right((v), (n)*4), \ |
| aes_nohw_shift_left((v), 16 - (n)*4))) |
| |
| static void aes_nohw_shift_rows(AES_NOHW_BATCH *batch) { |
| for (size_t i = 0; i < 8; i++) { |
| aes_word_t row0 = aes_nohw_and(batch->w[i], AES_NOHW_ROW0_MASK); |
| aes_word_t row1 = aes_nohw_and(batch->w[i], AES_NOHW_ROW1_MASK); |
| aes_word_t row2 = aes_nohw_and(batch->w[i], AES_NOHW_ROW2_MASK); |
| aes_word_t row3 = aes_nohw_and(batch->w[i], AES_NOHW_ROW3_MASK); |
| row1 = aes_nohw_rotate_cols_right(row1, 1); |
| row2 = aes_nohw_rotate_cols_right(row2, 2); |
| row3 = aes_nohw_rotate_cols_right(row3, 3); |
| batch->w[i] = aes_nohw_or(aes_nohw_or(row0, row1), aes_nohw_or(row2, row3)); |
| } |
| } |
| |
| static void aes_nohw_inv_shift_rows(AES_NOHW_BATCH *batch) { |
| for (size_t i = 0; i < 8; i++) { |
| aes_word_t row0 = aes_nohw_and(batch->w[i], AES_NOHW_ROW0_MASK); |
| aes_word_t row1 = aes_nohw_and(batch->w[i], AES_NOHW_ROW1_MASK); |
| aes_word_t row2 = aes_nohw_and(batch->w[i], AES_NOHW_ROW2_MASK); |
| aes_word_t row3 = aes_nohw_and(batch->w[i], AES_NOHW_ROW3_MASK); |
| row1 = aes_nohw_rotate_cols_right(row1, 3); |
| row2 = aes_nohw_rotate_cols_right(row2, 2); |
| row3 = aes_nohw_rotate_cols_right(row3, 1); |
| batch->w[i] = aes_nohw_or(aes_nohw_or(row0, row1), aes_nohw_or(row2, row3)); |
| } |
| } |
| |
| // aes_nohw_rotate_rows_down returns |v| with the rows in each column rotated |
| // down by one. |
| static inline aes_word_t aes_nohw_rotate_rows_down(aes_word_t v) { |
| #if defined(OPENSSL_SSE2) |
| return _mm_or_si128(_mm_srli_epi32(v, 8), _mm_slli_epi32(v, 24)); |
| #elif defined(OPENSSL_64_BIT) |
| return ((v >> 4) & UINT64_C(0x0fff0fff0fff0fff)) | |
| ((v << 12) & UINT64_C(0xf000f000f000f000)); |
| #else |
| return ((v >> 2) & 0x3f3f3f3f) | ((v << 6) & 0xc0c0c0c0); |
| #endif |
| } |
| |
| // aes_nohw_rotate_rows_twice returns |v| with the rows in each column rotated |
| // by two. |
| static inline aes_word_t aes_nohw_rotate_rows_twice(aes_word_t v) { |
| #if defined(OPENSSL_SSE2) |
| return _mm_or_si128(_mm_srli_epi32(v, 16), _mm_slli_epi32(v, 16)); |
| #elif defined(OPENSSL_64_BIT) |
| return ((v >> 8) & UINT64_C(0x00ff00ff00ff00ff)) | |
| ((v << 8) & UINT64_C(0xff00ff00ff00ff00)); |
| #else |
| return ((v >> 4) & 0x0f0f0f0f) | ((v << 4) & 0xf0f0f0f0); |
| #endif |
| } |
| |
| static void aes_nohw_mix_columns(AES_NOHW_BATCH *batch) { |
| // See https://eprint.iacr.org/2009/129.pdf, section 4.4 and appendix A. |
| aes_word_t a0 = batch->w[0]; |
| aes_word_t a1 = batch->w[1]; |
| aes_word_t a2 = batch->w[2]; |
| aes_word_t a3 = batch->w[3]; |
| aes_word_t a4 = batch->w[4]; |
| aes_word_t a5 = batch->w[5]; |
| aes_word_t a6 = batch->w[6]; |
| aes_word_t a7 = batch->w[7]; |
| |
| aes_word_t r0 = aes_nohw_rotate_rows_down(a0); |
| aes_word_t a0_r0 = aes_nohw_xor(a0, r0); |
| aes_word_t r1 = aes_nohw_rotate_rows_down(a1); |
| aes_word_t a1_r1 = aes_nohw_xor(a1, r1); |
| aes_word_t r2 = aes_nohw_rotate_rows_down(a2); |
| aes_word_t a2_r2 = aes_nohw_xor(a2, r2); |
| aes_word_t r3 = aes_nohw_rotate_rows_down(a3); |
| aes_word_t a3_r3 = aes_nohw_xor(a3, r3); |
| aes_word_t r4 = aes_nohw_rotate_rows_down(a4); |
| aes_word_t a4_r4 = aes_nohw_xor(a4, r4); |
| aes_word_t r5 = aes_nohw_rotate_rows_down(a5); |
| aes_word_t a5_r5 = aes_nohw_xor(a5, r5); |
| aes_word_t r6 = aes_nohw_rotate_rows_down(a6); |
| aes_word_t a6_r6 = aes_nohw_xor(a6, r6); |
| aes_word_t r7 = aes_nohw_rotate_rows_down(a7); |
| aes_word_t a7_r7 = aes_nohw_xor(a7, r7); |
| |
| batch->w[0] = |
| aes_nohw_xor(aes_nohw_xor(a7_r7, r0), aes_nohw_rotate_rows_twice(a0_r0)); |
| batch->w[1] = |
| aes_nohw_xor(aes_nohw_xor(a0_r0, a7_r7), |
| aes_nohw_xor(r1, aes_nohw_rotate_rows_twice(a1_r1))); |
| batch->w[2] = |
| aes_nohw_xor(aes_nohw_xor(a1_r1, r2), aes_nohw_rotate_rows_twice(a2_r2)); |
| batch->w[3] = |
| aes_nohw_xor(aes_nohw_xor(a2_r2, a7_r7), |
| aes_nohw_xor(r3, aes_nohw_rotate_rows_twice(a3_r3))); |
| batch->w[4] = |
| aes_nohw_xor(aes_nohw_xor(a3_r3, a7_r7), |
| aes_nohw_xor(r4, aes_nohw_rotate_rows_twice(a4_r4))); |
| batch->w[5] = |
| aes_nohw_xor(aes_nohw_xor(a4_r4, r5), aes_nohw_rotate_rows_twice(a5_r5)); |
| batch->w[6] = |
| aes_nohw_xor(aes_nohw_xor(a5_r5, r6), aes_nohw_rotate_rows_twice(a6_r6)); |
| batch->w[7] = |
| aes_nohw_xor(aes_nohw_xor(a6_r6, r7), aes_nohw_rotate_rows_twice(a7_r7)); |
| } |
| |
| static void aes_nohw_inv_mix_columns(AES_NOHW_BATCH *batch) { |
| aes_word_t a0 = batch->w[0]; |
| aes_word_t a1 = batch->w[1]; |
| aes_word_t a2 = batch->w[2]; |
| aes_word_t a3 = batch->w[3]; |
| aes_word_t a4 = batch->w[4]; |
| aes_word_t a5 = batch->w[5]; |
| aes_word_t a6 = batch->w[6]; |
| aes_word_t a7 = batch->w[7]; |
| |
| // bsaes-x86_64.pl describes the following decomposition of the inverse |
| // MixColumns matrix, credited to Jussi Kivilinna. This gives a much simpler |
| // multiplication. |
| // |
| // | 0e 0b 0d 09 | | 02 03 01 01 | | 05 00 04 00 | |
| // | 09 0e 0b 0d | = | 01 02 03 01 | x | 00 05 00 04 | |
| // | 0d 09 0e 0b | | 01 01 02 03 | | 04 00 05 00 | |
| // | 0b 0d 09 0e | | 03 01 01 02 | | 00 04 00 05 | |
| // |
| // First, apply the [5 0 4 0] matrix. Multiplying by 4 in F_(2^8) is described |
| // by the following bit equations: |
| // |
| // b0 = a6 |
| // b1 = a6 ^ a7 |
| // b2 = a0 ^ a7 |
| // b3 = a1 ^ a6 |
| // b4 = a2 ^ a6 ^ a7 |
| // b5 = a3 ^ a7 |
| // b6 = a4 |
| // b7 = a5 |
| // |
| // Each coefficient is given by: |
| // |
| // b_ij = 05·a_ij ⊕ 04·a_i(j+2) = 04·(a_ij ⊕ a_i(j+2)) ⊕ a_ij |
| // |
| // We combine the two equations below. Note a_i(j+2) is a row rotation. |
| aes_word_t a0_r0 = aes_nohw_xor(a0, aes_nohw_rotate_rows_twice(a0)); |
| aes_word_t a1_r1 = aes_nohw_xor(a1, aes_nohw_rotate_rows_twice(a1)); |
| aes_word_t a2_r2 = aes_nohw_xor(a2, aes_nohw_rotate_rows_twice(a2)); |
| aes_word_t a3_r3 = aes_nohw_xor(a3, aes_nohw_rotate_rows_twice(a3)); |
| aes_word_t a4_r4 = aes_nohw_xor(a4, aes_nohw_rotate_rows_twice(a4)); |
| aes_word_t a5_r5 = aes_nohw_xor(a5, aes_nohw_rotate_rows_twice(a5)); |
| aes_word_t a6_r6 = aes_nohw_xor(a6, aes_nohw_rotate_rows_twice(a6)); |
| aes_word_t a7_r7 = aes_nohw_xor(a7, aes_nohw_rotate_rows_twice(a7)); |
| |
| batch->w[0] = aes_nohw_xor(a0, a6_r6); |
| batch->w[1] = aes_nohw_xor(a1, aes_nohw_xor(a6_r6, a7_r7)); |
| batch->w[2] = aes_nohw_xor(a2, aes_nohw_xor(a0_r0, a7_r7)); |
| batch->w[3] = aes_nohw_xor(a3, aes_nohw_xor(a1_r1, a6_r6)); |
| batch->w[4] = |
| aes_nohw_xor(aes_nohw_xor(a4, a2_r2), aes_nohw_xor(a6_r6, a7_r7)); |
| batch->w[5] = aes_nohw_xor(a5, aes_nohw_xor(a3_r3, a7_r7)); |
| batch->w[6] = aes_nohw_xor(a6, a4_r4); |
| batch->w[7] = aes_nohw_xor(a7, a5_r5); |
| |
| // Apply the [02 03 01 01] matrix, which is just MixColumns. |
| aes_nohw_mix_columns(batch); |
| } |
| |
| static void aes_nohw_encrypt_batch(const AES_NOHW_SCHEDULE *key, |
| size_t num_rounds, AES_NOHW_BATCH *batch) { |
| aes_nohw_add_round_key(batch, &key->keys[0]); |
| for (size_t i = 1; i < num_rounds; i++) { |
| aes_nohw_sub_bytes(batch); |
| aes_nohw_shift_rows(batch); |
| aes_nohw_mix_columns(batch); |
| aes_nohw_add_round_key(batch, &key->keys[i]); |
| } |
| aes_nohw_sub_bytes(batch); |
| aes_nohw_shift_rows(batch); |
| aes_nohw_add_round_key(batch, &key->keys[num_rounds]); |
| } |
| |
| static void aes_nohw_decrypt_batch(const AES_NOHW_SCHEDULE *key, |
| size_t num_rounds, AES_NOHW_BATCH *batch) { |
| aes_nohw_add_round_key(batch, &key->keys[num_rounds]); |
| aes_nohw_inv_shift_rows(batch); |
| aes_nohw_inv_sub_bytes(batch); |
| for (size_t i = num_rounds - 1; i > 0; i--) { |
| aes_nohw_add_round_key(batch, &key->keys[i]); |
| aes_nohw_inv_mix_columns(batch); |
| aes_nohw_inv_shift_rows(batch); |
| aes_nohw_inv_sub_bytes(batch); |
| } |
| aes_nohw_add_round_key(batch, &key->keys[0]); |
| } |
| |
| |
| // Key schedule. |
| |
| static void aes_nohw_expand_round_keys(AES_NOHW_SCHEDULE *out, |
| const AES_KEY *key) { |
| for (size_t i = 0; i <= key->rounds; i++) { |
| // Copy the round key into each block in the batch. |
| for (size_t j = 0; j < AES_NOHW_BATCH_SIZE; j++) { |
| aes_word_t tmp[AES_NOHW_BLOCK_WORDS]; |
| memcpy(tmp, key->rd_key + 4 * i, 16); |
| aes_nohw_batch_set(&out->keys[i], tmp, j); |
| } |
| aes_nohw_transpose(&out->keys[i]); |
| } |
| } |
| |
| static const uint8_t aes_nohw_rcon[10] = {0x01, 0x02, 0x04, 0x08, 0x10, |
| 0x20, 0x40, 0x80, 0x1b, 0x36}; |
| |
| // aes_nohw_rcon_slice returns the |i|th group of |AES_NOHW_BATCH_SIZE| bits in |
| // |rcon|, stored in a |aes_word_t|. |
| static inline aes_word_t aes_nohw_rcon_slice(uint8_t rcon, size_t i) { |
| rcon = (rcon >> (i * AES_NOHW_BATCH_SIZE)) & ((1 << AES_NOHW_BATCH_SIZE) - 1); |
| #if defined(OPENSSL_SSE2) |
| return _mm_set_epi32(0, 0, 0, rcon); |
| #else |
| return ((aes_word_t)rcon); |
| #endif |
| } |
| |
| static void aes_nohw_sub_block(aes_word_t out[AES_NOHW_BLOCK_WORDS], |
| const aes_word_t in[AES_NOHW_BLOCK_WORDS]) { |
| AES_NOHW_BATCH batch; |
| memset(&batch, 0, sizeof(batch)); |
| aes_nohw_batch_set(&batch, in, 0); |
| aes_nohw_transpose(&batch); |
| aes_nohw_sub_bytes(&batch); |
| aes_nohw_transpose(&batch); |
| aes_nohw_batch_get(&batch, out, 0); |
| } |
| |
| static void aes_nohw_setup_key_128(AES_KEY *key, const uint8_t in[16]) { |
| key->rounds = 10; |
| |
| aes_word_t block[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_compact_block(block, in); |
| memcpy(key->rd_key, block, 16); |
| |
| for (size_t i = 1; i <= 10; i++) { |
| aes_word_t sub[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_sub_block(sub, block); |
| uint8_t rcon = aes_nohw_rcon[i - 1]; |
| for (size_t j = 0; j < AES_NOHW_BLOCK_WORDS; j++) { |
| // Incorporate |rcon| and the transformed word into the first word. |
| block[j] = aes_nohw_xor(block[j], aes_nohw_rcon_slice(rcon, j)); |
| block[j] = aes_nohw_xor( |
| block[j], |
| aes_nohw_shift_right(aes_nohw_rotate_rows_down(sub[j]), 12)); |
| // Propagate to the remaining words. Note this is reordered from the usual |
| // formulation to avoid needing masks. |
| aes_word_t v = block[j]; |
| block[j] = aes_nohw_xor(block[j], aes_nohw_shift_left(v, 4)); |
| block[j] = aes_nohw_xor(block[j], aes_nohw_shift_left(v, 8)); |
| block[j] = aes_nohw_xor(block[j], aes_nohw_shift_left(v, 12)); |
| } |
| memcpy(key->rd_key + 4 * i, block, 16); |
| } |
| } |
| |
| static void aes_nohw_setup_key_192(AES_KEY *key, const uint8_t in[24]) { |
| key->rounds = 12; |
| |
| aes_word_t storage1[AES_NOHW_BLOCK_WORDS], storage2[AES_NOHW_BLOCK_WORDS]; |
| aes_word_t *block1 = storage1, *block2 = storage2; |
| |
| // AES-192's key schedule is complex because each key schedule iteration |
| // produces six words, but we compute on blocks and each block is four words. |
| // We maintain a sliding window of two blocks, filled to 1.5 blocks at a time. |
| // We loop below every three blocks or two key schedule iterations. |
| // |
| // On entry to the loop, |block1| and the first half of |block2| contain the |
| // previous key schedule iteration. |block1| has been written to |key|, but |
| // |block2| has not as it is incomplete. |
| aes_nohw_compact_block(block1, in); |
| memcpy(key->rd_key, block1, 16); |
| |
| uint8_t half_block[16] = {0}; |
| memcpy(half_block, in + 16, 8); |
| aes_nohw_compact_block(block2, half_block); |
| |
| for (size_t i = 0; i < 4; i++) { |
| aes_word_t sub[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_sub_block(sub, block2); |
| uint8_t rcon = aes_nohw_rcon[2 * i]; |
| for (size_t j = 0; j < AES_NOHW_BLOCK_WORDS; j++) { |
| // Compute the first two words of the next key schedule iteration, which |
| // go in the second half of |block2|. The first two words of the previous |
| // iteration are in the first half of |block1|. Apply |rcon| here too |
| // because the shifts match. |
| block2[j] = aes_nohw_or( |
| block2[j], |
| aes_nohw_shift_left( |
| aes_nohw_xor(block1[j], aes_nohw_rcon_slice(rcon, j)), 8)); |
| // Incorporate the transformed word and propagate. Note the last word of |
| // the previous iteration corresponds to the second word of |copy|. This |
| // is incorporated into the first word of the next iteration, or the third |
| // word of |block2|. |
| block2[j] = aes_nohw_xor( |
| block2[j], aes_nohw_and(aes_nohw_shift_left( |
| aes_nohw_rotate_rows_down(sub[j]), 4), |
| AES_NOHW_COL2_MASK)); |
| block2[j] = aes_nohw_xor( |
| block2[j], |
| aes_nohw_and(aes_nohw_shift_left(block2[j], 4), AES_NOHW_COL3_MASK)); |
| |
| // Compute the remaining four words, which fill |block1|. Begin by moving |
| // the corresponding words of the previous iteration: the second half of |
| // |block1| and the first half of |block2|. |
| block1[j] = aes_nohw_shift_right(block1[j], 8); |
| block1[j] = aes_nohw_or(block1[j], aes_nohw_shift_left(block2[j], 8)); |
| // Incorporate the second word, computed previously in |block2|, and |
| // propagate. |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_right(block2[j], 12)); |
| aes_word_t v = block1[j]; |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 4)); |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 8)); |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 12)); |
| } |
| |
| // This completes two round keys. Note half of |block2| was computed in the |
| // previous loop iteration but was not yet output. |
| memcpy(key->rd_key + 4 * (3 * i + 1), block2, 16); |
| memcpy(key->rd_key + 4 * (3 * i + 2), block1, 16); |
| |
| aes_nohw_sub_block(sub, block1); |
| rcon = aes_nohw_rcon[2 * i + 1]; |
| for (size_t j = 0; j < AES_NOHW_BLOCK_WORDS; j++) { |
| // Compute the first four words of the next key schedule iteration in |
| // |block2|. Begin by moving the corresponding words of the previous |
| // iteration: the second half of |block2| and the first half of |block1|. |
| block2[j] = aes_nohw_shift_right(block2[j], 8); |
| block2[j] = aes_nohw_or(block2[j], aes_nohw_shift_left(block1[j], 8)); |
| // Incorporate rcon and the transformed word. Note the last word of the |
| // previous iteration corresponds to the last word of |copy|. |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_rcon_slice(rcon, j)); |
| block2[j] = aes_nohw_xor( |
| block2[j], |
| aes_nohw_shift_right(aes_nohw_rotate_rows_down(sub[j]), 12)); |
| // Propagate to the remaining words. |
| aes_word_t v = block2[j]; |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 4)); |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 8)); |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 12)); |
| |
| // Compute the last two words, which go in the first half of |block1|. The |
| // last two words of the previous iteration are in the second half of |
| // |block1|. |
| block1[j] = aes_nohw_shift_right(block1[j], 8); |
| // Propagate blocks and mask off the excess. |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_right(block2[j], 12)); |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(block1[j], 4)); |
| block1[j] = aes_nohw_and(block1[j], AES_NOHW_COL01_MASK); |
| } |
| |
| // |block2| has a complete round key. |block1| will be completed in the next |
| // iteration. |
| memcpy(key->rd_key + 4 * (3 * i + 3), block2, 16); |
| |
| // Swap blocks to restore the invariant. |
| aes_word_t *tmp = block1; |
| block1 = block2; |
| block2 = tmp; |
| } |
| } |
| |
| static void aes_nohw_setup_key_256(AES_KEY *key, const uint8_t in[32]) { |
| key->rounds = 14; |
| |
| // Each key schedule iteration produces two round keys. |
| aes_word_t block1[AES_NOHW_BLOCK_WORDS], block2[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_compact_block(block1, in); |
| memcpy(key->rd_key, block1, 16); |
| |
| aes_nohw_compact_block(block2, in + 16); |
| memcpy(key->rd_key + 4, block2, 16); |
| |
| for (size_t i = 2; i <= 14; i += 2) { |
| aes_word_t sub[AES_NOHW_BLOCK_WORDS]; |
| aes_nohw_sub_block(sub, block2); |
| uint8_t rcon = aes_nohw_rcon[i / 2 - 1]; |
| for (size_t j = 0; j < AES_NOHW_BLOCK_WORDS; j++) { |
| // Incorporate |rcon| and the transformed word into the first word. |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_rcon_slice(rcon, j)); |
| block1[j] = aes_nohw_xor( |
| block1[j], |
| aes_nohw_shift_right(aes_nohw_rotate_rows_down(sub[j]), 12)); |
| // Propagate to the remaining words. |
| aes_word_t v = block1[j]; |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 4)); |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 8)); |
| block1[j] = aes_nohw_xor(block1[j], aes_nohw_shift_left(v, 12)); |
| } |
| memcpy(key->rd_key + 4 * i, block1, 16); |
| |
| if (i == 14) { |
| break; |
| } |
| |
| aes_nohw_sub_block(sub, block1); |
| for (size_t j = 0; j < AES_NOHW_BLOCK_WORDS; j++) { |
| // Incorporate the transformed word into the first word. |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_right(sub[j], 12)); |
| // Propagate to the remaining words. |
| aes_word_t v = block2[j]; |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 4)); |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 8)); |
| block2[j] = aes_nohw_xor(block2[j], aes_nohw_shift_left(v, 12)); |
| } |
| memcpy(key->rd_key + 4 * (i + 1), block2, 16); |
| } |
| } |
| |
| |
| // External API. |
| |
| int aes_nohw_set_encrypt_key(const uint8_t *key, unsigned bits, |
| AES_KEY *aeskey) { |
| switch (bits) { |
| case 128: |
| aes_nohw_setup_key_128(aeskey, key); |
| return 0; |
| case 192: |
| aes_nohw_setup_key_192(aeskey, key); |
| return 0; |
| case 256: |
| aes_nohw_setup_key_256(aeskey, key); |
| return 0; |
| } |
| return 1; |
| } |
| |
| int aes_nohw_set_decrypt_key(const uint8_t *key, unsigned bits, |
| AES_KEY *aeskey) { |
| return aes_nohw_set_encrypt_key(key, bits, aeskey); |
| } |
| |
| void aes_nohw_encrypt(const uint8_t *in, uint8_t *out, const AES_KEY *key) { |
| AES_NOHW_SCHEDULE sched; |
| aes_nohw_expand_round_keys(&sched, key); |
| AES_NOHW_BATCH batch; |
| aes_nohw_to_batch(&batch, in, /*num_blocks=*/1); |
| aes_nohw_encrypt_batch(&sched, key->rounds, &batch); |
| aes_nohw_from_batch(out, /*num_blocks=*/1, &batch); |
| } |
| |
| void aes_nohw_decrypt(const uint8_t *in, uint8_t *out, const AES_KEY *key) { |
| AES_NOHW_SCHEDULE sched; |
| aes_nohw_expand_round_keys(&sched, key); |
| AES_NOHW_BATCH batch; |
| aes_nohw_to_batch(&batch, in, /*num_blocks=*/1); |
| aes_nohw_decrypt_batch(&sched, key->rounds, &batch); |
| aes_nohw_from_batch(out, /*num_blocks=*/1, &batch); |
| } |
| |
| static inline void aes_nohw_xor_block(uint8_t out[16], const uint8_t a[16], |
| const uint8_t b[16]) { |
| for (size_t i = 0; i < 16; i += sizeof(aes_word_t)) { |
| aes_word_t x, y; |
| memcpy(&x, a + i, sizeof(aes_word_t)); |
| memcpy(&y, b + i, sizeof(aes_word_t)); |
| x = aes_nohw_xor(x, y); |
| memcpy(out + i, &x, sizeof(aes_word_t)); |
| } |
| } |
| |
| void aes_nohw_ctr32_encrypt_blocks(const uint8_t *in, uint8_t *out, |
| size_t blocks, const AES_KEY *key, |
| const uint8_t ivec[16]) { |
| if (blocks == 0) { |
| return; |
| } |
| |
| AES_NOHW_SCHEDULE sched; |
| aes_nohw_expand_round_keys(&sched, key); |
| |
| // Make |AES_NOHW_BATCH_SIZE| copies of |ivec|. |
| alignas(AES_NOHW_WORD_SIZE) uint8_t ivs[AES_NOHW_BATCH_SIZE * 16]; |
| alignas(AES_NOHW_WORD_SIZE) uint8_t enc_ivs[AES_NOHW_BATCH_SIZE * 16]; |
| for (size_t i = 0; i < AES_NOHW_BATCH_SIZE; i++) { |
| memcpy(ivs + 16 * i, ivec, 16); |
| } |
| |
| uint32_t ctr = CRYPTO_load_u32_be(ivs + 12); |
| for (;;) { |
| // Update counters. |
| for (size_t i = 0; i < AES_NOHW_BATCH_SIZE; i++) { |
| CRYPTO_store_u32_be(ivs + 16 * i + 12, ctr + i); |
| } |
| |
| size_t todo = blocks >= AES_NOHW_BATCH_SIZE ? AES_NOHW_BATCH_SIZE : blocks; |
| AES_NOHW_BATCH batch; |
| aes_nohw_to_batch(&batch, ivs, todo); |
| aes_nohw_encrypt_batch(&sched, key->rounds, &batch); |
| aes_nohw_from_batch(enc_ivs, todo, &batch); |
| |
| for (size_t i = 0; i < todo; i++) { |
| aes_nohw_xor_block(out + 16 * i, in + 16 * i, enc_ivs + 16 * i); |
| } |
| |
| blocks -= todo; |
| if (blocks == 0) { |
| break; |
| } |
| |
| in += 16 * AES_NOHW_BATCH_SIZE; |
| out += 16 * AES_NOHW_BATCH_SIZE; |
| ctr += AES_NOHW_BATCH_SIZE; |
| } |
| } |
| |
| void aes_nohw_cbc_encrypt(const uint8_t *in, uint8_t *out, size_t len, |
| const AES_KEY *key, uint8_t *ivec, const int enc) { |
| assert(len % 16 == 0); |
| size_t blocks = len / 16; |
| if (blocks == 0) { |
| return; |
| } |
| |
| AES_NOHW_SCHEDULE sched; |
| aes_nohw_expand_round_keys(&sched, key); |
| alignas(AES_NOHW_WORD_SIZE) uint8_t iv[16]; |
| memcpy(iv, ivec, 16); |
| |
| if (enc) { |
| // CBC encryption is not parallelizable. |
| while (blocks > 0) { |
| aes_nohw_xor_block(iv, iv, in); |
| |
| AES_NOHW_BATCH batch; |
| aes_nohw_to_batch(&batch, iv, /*num_blocks=*/1); |
| aes_nohw_encrypt_batch(&sched, key->rounds, &batch); |
| aes_nohw_from_batch(out, /*num_blocks=*/1, &batch); |
| |
| memcpy(iv, out, 16); |
| |
| in += 16; |
| out += 16; |
| blocks--; |
| } |
| memcpy(ivec, iv, 16); |
| return; |
| } |
| |
| for (;;) { |
| size_t todo = blocks >= AES_NOHW_BATCH_SIZE ? AES_NOHW_BATCH_SIZE : blocks; |
| // Make a copy of the input so we can decrypt in-place. |
| alignas(AES_NOHW_WORD_SIZE) uint8_t copy[AES_NOHW_BATCH_SIZE * 16]; |
| memcpy(copy, in, todo * 16); |
| |
| AES_NOHW_BATCH batch; |
| aes_nohw_to_batch(&batch, in, todo); |
| aes_nohw_decrypt_batch(&sched, key->rounds, &batch); |
| aes_nohw_from_batch(out, todo, &batch); |
| |
| aes_nohw_xor_block(out, out, iv); |
| for (size_t i = 1; i < todo; i++) { |
| aes_nohw_xor_block(out + 16 * i, out + 16 * i, copy + 16 * (i - 1)); |
| } |
| |
| // Save the last block as the IV. |
| memcpy(iv, copy + 16 * (todo - 1), 16); |
| |
| blocks -= todo; |
| if (blocks == 0) { |
| break; |
| } |
| |
| in += 16 * AES_NOHW_BATCH_SIZE; |
| out += 16 * AES_NOHW_BATCH_SIZE; |
| } |
| |
| memcpy(ivec, iv, 16); |
| } |