/* chacha-merged.c version 20080118 D. J. Bernstein Public domain. */ #include #include #include #include "utils.h" #include "chacha20.h" struct chacha_ctx { uint32_t input[16]; }; #define LOAD32_LE(SRC) get_unaligned_le32(SRC) #define STORE32_LE(DST, W) store32_le((DST), (W)) static inline void store32_le(uint8_t dst[4], uint32_t w) { dst[0] = (uint8_t) w; w >>= 8; dst[1] = (uint8_t) w; w >>= 8; dst[2] = (uint8_t) w; w >>= 8; dst[3] = (uint8_t) w; } #define ROTL32(X, B) rotl32((X), (B)) static inline uint32_t rotl32(const uint32_t x, const int b) { return (x << b) | (x >> (32 - b)); } typedef struct chacha_ctx chacha_ctx; #define U32C(v) (v##U) #define U32V(v) ((uint32_t)(v) &U32C(0xFFFFFFFF)) #define ROTATE(v, c) (ROTL32(v, c)) #define XOR(v, w) ((v) ^ (w)) #define PLUS(v, w) (U32V((v) + (w))) #define PLUSONE(v) (PLUS((v), 1)) #define QUARTERROUND(a, b, c, d) \ a = PLUS(a, b); \ d = ROTATE(XOR(d, a), 16); \ c = PLUS(c, d); \ b = ROTATE(XOR(b, c), 12); \ a = PLUS(a, b); \ d = ROTATE(XOR(d, a), 8); \ c = PLUS(c, d); \ b = ROTATE(XOR(b, c), 7); static void chacha_keysetup(chacha_ctx *ctx, const uint8_t *k) { ctx->input[0] = U32C(0x61707865); ctx->input[1] = U32C(0x3320646e); ctx->input[2] = U32C(0x79622d32); ctx->input[3] = U32C(0x6b206574); ctx->input[4] = LOAD32_LE(k + 0); ctx->input[5] = LOAD32_LE(k + 4); ctx->input[6] = LOAD32_LE(k + 8); ctx->input[7] = LOAD32_LE(k + 12); ctx->input[8] = LOAD32_LE(k + 16); ctx->input[9] = LOAD32_LE(k + 20); ctx->input[10] = LOAD32_LE(k + 24); ctx->input[11] = LOAD32_LE(k + 28); } static void chacha_ivsetup(chacha_ctx *ctx, const uint8_t *iv, const uint8_t *counter) { ctx->input[12] = counter == NULL ? 0 : LOAD32_LE(counter + 0); ctx->input[13] = counter == NULL ? 0 : LOAD32_LE(counter + 4); ctx->input[14] = LOAD32_LE(iv + 0); ctx->input[15] = LOAD32_LE(iv + 4); } static void chacha20_encrypt_bytes(chacha_ctx *ctx, const uint8_t *m, uint8_t *c, unsigned long long bytes) { uint32_t x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15; uint32_t j0, j1, j2, j3, j4, j5, j6, j7, j8, j9, j10, j11, j12, j13, j14, j15; uint8_t *ctarget = NULL; uint8_t tmp[64]; unsigned int i; if (!bytes) { return; /* LCOV_EXCL_LINE */ } j0 = ctx->input[0]; j1 = ctx->input[1]; j2 = ctx->input[2]; j3 = ctx->input[3]; j4 = ctx->input[4]; j5 = ctx->input[5]; j6 = ctx->input[6]; j7 = ctx->input[7]; j8 = ctx->input[8]; j9 = ctx->input[9]; j10 = ctx->input[10]; j11 = ctx->input[11]; j12 = ctx->input[12]; j13 = ctx->input[13]; j14 = ctx->input[14]; j15 = ctx->input[15]; for (;;) { if (bytes < 64) { memset(tmp, 0, 64); for (i = 0; i < bytes; ++i) { tmp[i] = m[i]; } m = tmp; ctarget = c; c = tmp; } x0 = j0; x1 = j1; x2 = j2; x3 = j3; x4 = j4; x5 = j5; x6 = j6; x7 = j7; x8 = j8; x9 = j9; x10 = j10; x11 = j11; x12 = j12; x13 = j13; x14 = j14; x15 = j15; for (i = 20; i > 0; i -= 2) { QUARTERROUND(x0, x4, x8, x12) QUARTERROUND(x1, x5, x9, x13) QUARTERROUND(x2, x6, x10, x14) QUARTERROUND(x3, x7, x11, x15) QUARTERROUND(x0, x5, x10, x15) QUARTERROUND(x1, x6, x11, x12) QUARTERROUND(x2, x7, x8, x13) QUARTERROUND(x3, x4, x9, x14) } x0 = PLUS(x0, j0); x1 = PLUS(x1, j1); x2 = PLUS(x2, j2); x3 = PLUS(x3, j3); x4 = PLUS(x4, j4); x5 = PLUS(x5, j5); x6 = PLUS(x6, j6); x7 = PLUS(x7, j7); x8 = PLUS(x8, j8); x9 = PLUS(x9, j9); x10 = PLUS(x10, j10); x11 = PLUS(x11, j11); x12 = PLUS(x12, j12); x13 = PLUS(x13, j13); x14 = PLUS(x14, j14); x15 = PLUS(x15, j15); x0 = XOR(x0, LOAD32_LE(m + 0)); x1 = XOR(x1, LOAD32_LE(m + 4)); x2 = XOR(x2, LOAD32_LE(m + 8)); x3 = XOR(x3, LOAD32_LE(m + 12)); x4 = XOR(x4, LOAD32_LE(m + 16)); x5 = XOR(x5, LOAD32_LE(m + 20)); x6 = XOR(x6, LOAD32_LE(m + 24)); x7 = XOR(x7, LOAD32_LE(m + 28)); x8 = XOR(x8, LOAD32_LE(m + 32)); x9 = XOR(x9, LOAD32_LE(m + 36)); x10 = XOR(x10, LOAD32_LE(m + 40)); x11 = XOR(x11, LOAD32_LE(m + 44)); x12 = XOR(x12, LOAD32_LE(m + 48)); x13 = XOR(x13, LOAD32_LE(m + 52)); x14 = XOR(x14, LOAD32_LE(m + 56)); x15 = XOR(x15, LOAD32_LE(m + 60)); j12 = PLUSONE(j12); /* LCOV_EXCL_START */ if (!j12) { j13 = PLUSONE(j13); } /* LCOV_EXCL_STOP */ STORE32_LE(c + 0, x0); STORE32_LE(c + 4, x1); STORE32_LE(c + 8, x2); STORE32_LE(c + 12, x3); STORE32_LE(c + 16, x4); STORE32_LE(c + 20, x5); STORE32_LE(c + 24, x6); STORE32_LE(c + 28, x7); STORE32_LE(c + 32, x8); STORE32_LE(c + 36, x9); STORE32_LE(c + 40, x10); STORE32_LE(c + 44, x11); STORE32_LE(c + 48, x12); STORE32_LE(c + 52, x13); STORE32_LE(c + 56, x14); STORE32_LE(c + 60, x15); if (bytes <= 64) { if (bytes < 64) { for (i = 0; i < (unsigned int) bytes; ++i) { ctarget[i] = c[i]; /* ctarget cannot be NULL */ } } ctx->input[12] = j12; ctx->input[13] = j13; return; } bytes -= 64; c += 64; m += 64; } } void chacha20_encrypt_msg(void *msg, size_t len, const void *nonce, const void *key) { struct chacha_ctx ctx; chacha_keysetup(&ctx, key); chacha_ivsetup(&ctx, nonce, NULL); chacha20_encrypt_bytes(&ctx, msg, msg, len); }