/* This code is written by kerukuro for cppcrypto library (http://cppcrypto.sourceforge.net/) and released into public domain. */ /* adapted for VeraCrypt */ #include "chacha256.h" #include "cpu.h" #include "misc.h" #define rotater32(x,n) rotr32(x, n) #define rotatel32(x,n) rotl32(x, n) #if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE void chacha_ECRYPT_encrypt_bytes(size_t bytes, uint32* x, const unsigned char* m, unsigned char* out, unsigned char* output, unsigned int r); #endif static VC_INLINE void xor_block_512(const unsigned char* in, const unsigned char* prev, unsigned char* out) { #if CRYPTOPP_BOOL_SSE2_INTRINSICS_AVAILABLE && !defined(_UEFI) && (!defined (TC_WINDOWS_DRIVER) || (!defined (DEBUG) && defined (_WIN64))) if (HasSSE2()) { __m128i b1 = _mm_loadu_si128((const __m128i*) in); __m128i p1 = _mm_loadu_si128((const __m128i*) prev); __m128i b2 = _mm_loadu_si128((const __m128i*) (in + 16)); __m128i p2 = _mm_loadu_si128((const __m128i*) (prev + 16)); _mm_storeu_si128((__m128i*) out, _mm_xor_si128(b1, p1)); _mm_storeu_si128((__m128i*) (out + 16), _mm_xor_si128(b2, p2)); b1 = _mm_loadu_si128((const __m128i*) (in + 32)); p1 = _mm_loadu_si128((const __m128i*) (prev + 32)); b2 = _mm_loadu_si128((const __m128i*) (in + 48)); p2 = _mm_loadu_si128((const __m128i*) (prev + 48)); _mm_storeu_si128((__m128i*) (out + 32), _mm_xor_si128(b1, p1)); _mm_storeu_si128((__m128i*) (out + 48), _mm_xor_si128(b2, p2)); } else #endif { int i; for (i = 0; i < 64; i++) out[i] = in[i] ^ prev[i]; } } static VC_INLINE void chacha_core(uint32* x, int r) { int i; for (i = 0; i < r; i++) { x[0] += x[4]; x[12] = rotatel32(x[12] ^ x[0], 16); x[8] += x[12]; x[4] = rotatel32(x[4] ^ x[8], 12); x[0] += x[4]; x[12] = rotatel32(x[12] ^ x[0], 8); x[8] += x[12]; x[4] = rotatel32(x[4] ^ x[8], 7); x[1] += x[5]; x[13] = rotatel32(x[13] ^ x[1], 16); x[9] += x[13]; x[5] = rotatel32(x[5] ^ x[9], 12); x[1] += x[5]; x[13] = rotatel32(x[13] ^ x[1], 8); x[9] += x[13]; x[5] = rotatel32(x[5] ^ x[9], 7); x[2] += x[6]; x[14] = rotatel32(x[14] ^ x[2], 16); x[10] += x[14]; x[6] = rotatel32(x[6] ^ x[10], 12); x[2] += x[6]; x[14] = rotatel32(x[14] ^ x[2], 8); x[10] += x[14]; x[6] = rotatel32(x[6] ^ x[10], 7); x[3] += x[7]; x[15] = rotatel32(x[15] ^ x[3], 16); x[11] += x[15]; x[7] = rotatel32(x[7] ^ x[11], 12); x[3] += x[7]; x[15] = rotatel32(x[15] ^ x[3], 8); x[11] += x[15]; x[7] = rotatel32(x[7] ^ x[11], 7); x[0] += x[5]; x[15] = rotatel32(x[15] ^ x[0], 16); x[10] += x[15]; x[5] = rotatel32(x[5] ^ x[10], 12); x[0] += x[5]; x[15] = rotatel32(x[15] ^ x[0], 8); x[10] += x[15]; x[5] = rotatel32(x[5] ^ x[10], 7); x[1] += x[6]; x[12] = rotatel32(x[12] ^ x[1], 16); x[11] += x[12]; x[6] = rotatel32(x[6] ^ x[11], 12); x[1] += x[6]; x[12] = rotatel32(x[12] ^ x[1], 8); x[11] += x[12]; x[6] = rotatel32(x[6] ^ x[11], 7); x[2] += x[7]; x[13] = rotatel32(x[13] ^ x[2], 16); x[8] += x[13]; x[7] = rotatel32(x[7] ^ x[8], 12); x[2] += x[7]; x[13] = rotatel32(x[13] ^ x[2], 8); x[8] += x[13]; x[7] = rotatel32(x[7] ^ x[8], 7); x[3] += x[4]; x[14] = rotatel32(x[14] ^ x[3], 16); x[9] += x[14]; x[4] = rotatel32(x[4] ^ x[9], 12); x[3] += x[4]; x[14] = rotatel32(x[14] ^ x[3], 8); x[9] += x[14]; x[4] = rotatel32(x[4] ^ x[9], 7); } } static VC_INLINE void chacha_hash(const uint32* in, uint32* out, int r) { uint32 x[16]; int i; memcpy(x, in, 64); chacha_core(x, r); for (i = 0; i < 16; ++i) out[i] = x[i] + in[i]; } static VC_INLINE void incrementSalsaCounter(uint32* input, uint32* block, int r) { chacha_hash(input, block, r); if (!++input[12]) ++input[13]; } static VC_INLINE void do_encrypt(const unsigned char* in, size_t len, unsigned char* out, int r, size_t* posPtr, uint32* input, uint32* block) { size_t i = 0, pos = *posPtr; if (pos) { while (pos < len && pos < 64) { out[i] = in[i] ^ ((unsigned char*)block)[pos++]; ++i; } len -= i; } if (len) pos = 0; #if CRYPTOPP_SSSE3_AVAILABLE && !defined(_UEFI) && (!defined (TC_WINDOWS_DRIVER) || (!defined (DEBUG) && defined (_WIN64))) if (HasSSSE3()) { size_t fullblocks = len - len % 64; if (fullblocks) { chacha_ECRYPT_encrypt_bytes(fullblocks, input, in + i, out + i, (unsigned char*)block, r); i += fullblocks; len -= fullblocks; } if (len) { chacha_ECRYPT_encrypt_bytes(len, input, in + i, out + i, (unsigned char*)block, r); pos = len; } *posPtr = pos; return; } #endif for (; len; len -= VC_MIN(64, len)) { incrementSalsaCounter(input, block, r); if (len >= 64) { xor_block_512(in + i, (unsigned char*)block, out + i); i += 64; } else { for (; pos < len; pos++, i++) out[i] = in[i] ^ ((unsigned char*)block)[pos]; } } *posPtr = pos; } void ChaCha256Init(ChaCha256Ctx* ctx, const unsigned char* key, const unsigned char* iv, int rounds) { ctx->internalRounds = rounds / 2; ctx->pos = 0; ctx->input_[12] = 0; ctx->input_[13] = 0; memcpy(ctx->input_ + 4, key, 32); memcpy(ctx->input_ + 14, iv, 8); ctx->input_[0] = 0x61707865; ctx->input_[1] = 0x3320646E; ctx->input_[2] = 0x79622D32; ctx->input_[3] = 0x6B206574; } void ChaCha256Encrypt(ChaCha256Ctx* ctx, const unsigned char* in, size_t len, unsigned char* out) { do_encrypt(in, len, out, ctx->internalRounds, &ctx->pos, ctx->input_, ctx->block_); }