/* * Copyright (C) 2021 - This file is part of libecc project * * Authors: * Arnaud EBALARD * Ryad BENADJILA * * This software is licensed under a dual BSD and GPL v2 license. * See LICENSE file at the root folder of the project. */ #include #ifdef WITH_HASH_SM3 #include /* * 32-bit integer manipulation macros (big endian) */ #ifndef GET_UINT32_BE #define GET_UINT32_BE(n, b, i) \ do { \ (n) = ( ((u32) (b)[(i) ]) << 24 ) \ | ( ((u32) (b)[(i) + 1]) << 16 ) \ | ( ((u32) (b)[(i) + 2]) << 8 ) \ | ( ((u32) (b)[(i) + 3]) ); \ } while( 0 ) #endif #ifndef PUT_UINT32_BE #define PUT_UINT32_BE(n, b, i) \ do { \ (b)[(i) ] = (u8) ( (n) >> 24 ); \ (b)[(i) + 1] = (u8) ( (n) >> 16 ); \ (b)[(i) + 2] = (u8) ( (n) >> 8 ); \ (b)[(i) + 3] = (u8) ( (n) ); \ } while( 0 ) #endif /* * 64-bit integer manipulation macros (big endian) */ #ifndef PUT_UINT64_BE #define PUT_UINT64_BE(n,b,i) \ do { \ (b)[(i) ] = (u8) ( (n) >> 56 ); \ (b)[(i) + 1] = (u8) ( (n) >> 48 ); \ (b)[(i) + 2] = (u8) ( (n) >> 40 ); \ (b)[(i) + 3] = (u8) ( (n) >> 32 ); \ (b)[(i) + 4] = (u8) ( (n) >> 24 ); \ (b)[(i) + 5] = (u8) ( (n) >> 16 ); \ (b)[(i) + 6] = (u8) ( (n) >> 8 ); \ (b)[(i) + 7] = (u8) ( (n) ); \ } while( 0 ) #endif /* PUT_UINT64_BE */ static const u32 SM3_Tj_low = 0x79cc4519; static const u32 SM3_Tj_high = 0x7a879d8a; /* Boolean functions FF_j and GG_j for 0 <= j <= 15 */ #define FF_j_low(X, Y, Z) (((u32)(X)) ^ ((u32)(Y)) ^ ((u32)(Z))) #define GG_j_low(X, Y, Z) (((u32)(X)) ^ ((u32)(Y)) ^ ((u32)(Z))) /* Boolean functions FF_j and GG_j for 16 <= j <= 63 */ #define FF_j_high(X, Y, Z) ((((u32)(X)) & ((u32)(Y))) | \ (((u32)(X)) & ((u32)(Z))) | \ (((u32)(Y)) & ((u32)(Z)))) #define GG_j_high(X, Y, Z) ((((u32)(X)) & ((u32)(Y))) | \ ((~((u32)(X))) & ((u32)(Z)))) /* 32-bit bitwise cyclic shift. Only support shifts value y < 32 */ #define _SM3_ROTL_(x, y) ((((u32)(x)) << (y)) | \ (((u32)(x)) >> ((sizeof(u32) * 8) - (y)))) #define SM3_ROTL(x, y) ((((y) < (sizeof(u32) * 8)) && ((y) > 0)) ? (_SM3_ROTL_(x, y)) : (x)) /* Permutation Functions P_0 and P_1 */ #define SM3_P_0(X) (((u32)X) ^ SM3_ROTL((X), 9) ^ SM3_ROTL((X), 17)) #define SM3_P_1(X) (((u32)X) ^ SM3_ROTL((X), 15) ^ SM3_ROTL((X), 23)) /* SM3 Iterative Compression Process * NOTE: ctx and data sanity checks are performed by the caller (this is an internal function) */ ATTRIBUTE_WARN_UNUSED_RET static int sm3_process(sm3_context *ctx, const u8 data[SM3_BLOCK_SIZE]) { u32 A, B, C, D, E, F, G, H; u32 SS1, SS2, TT1, TT2; u32 W[68 + 64]; unsigned int j; int ret; /* Message Expansion Function ME */ for (j = 0; j < 16; j++) { GET_UINT32_BE(W[j], data, 4 * j); } for (j = 16; j < 68; j++) { W[j] = SM3_P_1(W[j - 16] ^ W[j - 9] ^ (SM3_ROTL(W[j - 3], 15))) ^ (SM3_ROTL(W[j - 13], 7)) ^ W[j - 6]; } for (j = 0; j < 64; j++) { W[j + 68] = W[j] ^ W[j + 4]; } /* Compression Function CF */ A = ctx->sm3_state[0]; B = ctx->sm3_state[1]; C = ctx->sm3_state[2]; D = ctx->sm3_state[3]; E = ctx->sm3_state[4]; F = ctx->sm3_state[5]; G = ctx->sm3_state[6]; H = ctx->sm3_state[7]; /* * Note: in a previous version of the code, we had two loops for j from * 0 to 15 and then from 16 to 63 with SM3_ROTL(SM3_Tj_low, (j & 0x1F)) * inside but clang-12 was smart enough to detect cases where SM3_ROTL * macro is useless. On the other side, clang address sanitizer does not * allow to remove the check for too high shift values in the macro * itself. Creating 3 distinct loops instead of 2 to remove the & 0x1F * is sufficient to satisfy everyone. */ for (j = 0; j < 16; j++) { SS1 = SM3_ROTL(SM3_ROTL(A, 12) + E + SM3_ROTL(SM3_Tj_low, j),7); SS2 = SS1 ^ SM3_ROTL(A, 12); TT1 = FF_j_low(A, B, C) + D + SS2 + W[j + 68]; TT2 = GG_j_low(E, F, G) + H + SS1 + W[j]; D = C; C = SM3_ROTL(B, 9); B = A; A = TT1; H = G; G = SM3_ROTL(F, 19); F = E; E = SM3_P_0(TT2); } for (j = 16; j < 32; j++) { SS1 = SM3_ROTL(SM3_ROTL(A, 12) + E + SM3_ROTL(SM3_Tj_high, j), 7); SS2 = SS1 ^ SM3_ROTL(A, 12); TT1 = FF_j_high(A, B, C) + D + SS2 + W[j + 68]; TT2 = GG_j_high(E, F, G) + H + SS1 + W[j]; D = C; C = SM3_ROTL(B, 9); B = A; A = TT1; H = G; G = SM3_ROTL(F, 19); F = E; E = SM3_P_0(TT2); } for (j = 32; j < 64; j++) { SS1 = SM3_ROTL(SM3_ROTL(A, 12) + E + SM3_ROTL(SM3_Tj_high, (j - 32)), 7); SS2 = SS1 ^ SM3_ROTL(A, 12); TT1 = FF_j_high(A, B, C) + D + SS2 + W[j + 68]; TT2 = GG_j_high(E, F, G) + H + SS1 + W[j]; D = C; C = SM3_ROTL(B, 9); B = A; A = TT1; H = G; G = SM3_ROTL(F, 19); F = E; E = SM3_P_0(TT2); } ctx->sm3_state[0] ^= A; ctx->sm3_state[1] ^= B; ctx->sm3_state[2] ^= C; ctx->sm3_state[3] ^= D; ctx->sm3_state[4] ^= E; ctx->sm3_state[5] ^= F; ctx->sm3_state[6] ^= G; ctx->sm3_state[7] ^= H; ret = 0; return ret; } /* Init hash function. Initialize state to SM3 defined IV. */ int sm3_init(sm3_context *ctx) { int ret; MUST_HAVE(ctx != NULL, ret, err); ctx->sm3_total = 0; ctx->sm3_state[0] = 0x7380166F; ctx->sm3_state[1] = 0x4914B2B9; ctx->sm3_state[2] = 0x172442D7; ctx->sm3_state[3] = 0xDA8A0600; ctx->sm3_state[4] = 0xA96F30BC; ctx->sm3_state[5] = 0x163138AA; ctx->sm3_state[6] = 0xE38DEE4D; ctx->sm3_state[7] = 0xB0FB0E4E; /* Tell that we are initialized */ ctx->magic = SM3_HASH_MAGIC; ret = 0; err: return ret; } /* Update hash function */ int sm3_update(sm3_context *ctx, const u8 *input, u32 ilen) { const u8 *data_ptr = input; u32 remain_ilen = ilen; u16 fill; u8 left; int ret; MUST_HAVE((input != NULL) || (ilen == 0), ret, err); SM3_HASH_CHECK_INITIALIZED(ctx, ret, err); /* Nothing to process, return */ if (ilen == 0) { ret = 0; goto err; } /* Get what's left in our local buffer */ left = (ctx->sm3_total & 0x3F); fill = (u16)(SM3_BLOCK_SIZE - left); ctx->sm3_total += ilen; if ((left > 0) && (remain_ilen >= fill)) { /* Copy data at the end of the buffer */ ret = local_memcpy(ctx->sm3_buffer + left, data_ptr, fill); EG(ret, err); ret = sm3_process(ctx, ctx->sm3_buffer); EG(ret, err); data_ptr += fill; remain_ilen -= fill; left = 0; } while (remain_ilen >= SM3_BLOCK_SIZE) { ret = sm3_process(ctx, data_ptr); EG(ret, err); data_ptr += SM3_BLOCK_SIZE; remain_ilen -= SM3_BLOCK_SIZE; } if (remain_ilen > 0) { ret = local_memcpy(ctx->sm3_buffer + left, data_ptr, remain_ilen); EG(ret, err); } ret = 0; err: return ret; } /* Finalize */ int sm3_final(sm3_context *ctx, u8 output[SM3_DIGEST_SIZE]) { unsigned int block_present = 0; u8 last_padded_block[2 * SM3_BLOCK_SIZE]; int ret; MUST_HAVE((output != NULL), ret, err); SM3_HASH_CHECK_INITIALIZED(ctx, ret, err); /* Fill in our last block with zeroes */ ret = local_memset(last_padded_block, 0, sizeof(last_padded_block)); EG(ret, err); /* This is our final step, so we proceed with the padding */ block_present = (ctx->sm3_total % SM3_BLOCK_SIZE); if (block_present != 0) { /* Copy what's left in our temporary context buffer */ ret = local_memcpy(last_padded_block, ctx->sm3_buffer, block_present); EG(ret, err); } /* Put the 0x80 byte, beginning of padding */ last_padded_block[block_present] = 0x80; /* Handle possible additional block */ if (block_present > (SM3_BLOCK_SIZE - 1 - sizeof(u64))) { /* We need an additional block */ PUT_UINT64_BE(8 * ctx->sm3_total, last_padded_block, (2 * SM3_BLOCK_SIZE) - sizeof(u64)); ret = sm3_process(ctx, last_padded_block); EG(ret, err); ret = sm3_process(ctx, last_padded_block + SM3_BLOCK_SIZE); EG(ret, err); } else { /* We do not need an additional block */ PUT_UINT64_BE(8 * ctx->sm3_total, last_padded_block, SM3_BLOCK_SIZE - sizeof(u64)); ret = sm3_process(ctx, last_padded_block); EG(ret, err); } /* Output the hash result */ PUT_UINT32_BE(ctx->sm3_state[0], output, 0); PUT_UINT32_BE(ctx->sm3_state[1], output, 4); PUT_UINT32_BE(ctx->sm3_state[2], output, 8); PUT_UINT32_BE(ctx->sm3_state[3], output, 12); PUT_UINT32_BE(ctx->sm3_state[4], output, 16); PUT_UINT32_BE(ctx->sm3_state[5], output, 20); PUT_UINT32_BE(ctx->sm3_state[6], output, 24); PUT_UINT32_BE(ctx->sm3_state[7], output, 28); /* Tell that we are uninitialized */ ctx->magic = WORD(0); ret = 0; err: return ret; } int sm3_scattered(const u8 **inputs, const u32 *ilens, u8 output[SM3_DIGEST_SIZE]) { sm3_context ctx; int pos = 0, ret; MUST_HAVE((inputs != NULL) && (ilens != NULL) && (output != NULL), ret, err); ret = sm3_init(&ctx); EG(ret, err); while (inputs[pos] != NULL) { ret = sm3_update(&ctx, inputs[pos], ilens[pos]); EG(ret, err); pos += 1; } ret = sm3_final(&ctx, output); err: return ret; } int sm3(const u8 *input, u32 ilen, u8 output[SM3_DIGEST_SIZE]) { sm3_context ctx; int ret; ret = sm3_init(&ctx); EG(ret, err); ret = sm3_update(&ctx, input, ilen); EG(ret, err); ret = sm3_final(&ctx, output); err: return ret; } #else /* WITH_HASH_SM3 */ /* * Dummy definition to avoid the empty translation unit ISO C warning */ typedef int dummy; #endif /* WITH_HASH_SM3 */