/*- * Copyright 2016 Vsevolod Stakhov * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* Workaround for memset_s */ #ifdef __APPLE__ #define __STDC_WANT_LIB_EXT1__ 1 #include #endif #include "config.h" #include "cryptobox.h" #include "platform_config.h" #include "chacha20/chacha.h" #include "catena/catena.h" #include "base64/base64.h" #include "ottery.h" #include "printf.h" #include "xxhash.h" #define MUM_TARGET_INDEPENDENT_HASH 1 /* For 32/64 bit equal hashes */ #include "../../contrib/mumhash/mum.h" #include "../../contrib/t1ha/t1ha.h" #ifdef HAVE_CPUID_H #include #endif #ifdef HAVE_OPENSSL #include /* Openssl >= 1.0.1d is required for GCM verification */ #if OPENSSL_VERSION_NUMBER >= 0x1000104fL #define HAVE_USABLE_OPENSSL 1 #endif #endif #ifdef HAVE_USABLE_OPENSSL #include #include #include #include #include #define CRYPTOBOX_CURVE_NID NID_X9_62_prime256v1 #endif #include #include #include #include unsigned cpu_config = 0; static gboolean cryptobox_loaded = FALSE; static const guchar n0[16] = {0}; #define CRYPTOBOX_ALIGNMENT 16 #define cryptobox_align_ptr(p, a) \ (void *) (((uintptr_t) (p) + ((uintptr_t) a - 1)) & ~((uintptr_t) a - 1)) static void rspamd_cryptobox_cpuid (gint cpu[4], gint info) { guint32 eax, ecx = 0, ebx = 0, edx = 0; eax = info; #if defined(__GNUC__) && (defined(__x86_64__) || defined(__i386__)) # if defined( __i386__ ) && defined ( __PIC__ ) /* in case of PIC under 32-bit EBX cannot be clobbered */ __asm__ volatile ("movl %%ebx, %%edi \n\t cpuid \n\t xchgl %%ebx, %%edi" : "=D" (ebx), "+a" (eax), "+c" (ecx), "=d" (edx)); # else __asm__ volatile ("cpuid" : "+b" (ebx), "+a" (eax), "+c" (ecx), "=d" (edx)); # endif cpu[0] = eax; cpu[1] = ebx; cpu[2] = ecx; cpu[3] = edx; #else memset (cpu, 0, sizeof (gint) * 4); #endif } static sig_atomic_t ok = 0; static jmp_buf j; static void rspamd_cryptobox_ill_handler (int signo) { ok = 0; longjmp (j, -1); } static gboolean rspamd_cryptobox_test_instr (gint instr) { void (*old_handler) (int); guint32 rd; #if defined(__GNUC__) ok = 1; old_handler = signal (SIGILL, rspamd_cryptobox_ill_handler); if (setjmp (j) != 0) { signal (SIGILL, old_handler); return FALSE; } switch (instr) { #ifdef HAVE_SSE2 case CPUID_SSE2: __asm__ volatile ("psubb %xmm0, %xmm0"); break; case CPUID_RDRAND: /* Use byte code here for compatibility */ __asm__ volatile (".byte 0x0f,0xc7,0xf0; setc %1" : "=a" (rd), "=qm" (ok) : : "edx" ); break; #endif #ifdef HAVE_SSE3 case CPUID_SSE3: __asm__ volatile ("movshdup %xmm0, %xmm0"); break; #endif #ifdef HAVE_SSSE3 case CPUID_SSSE3: __asm__ volatile ("pshufb %xmm0, %xmm0"); break; #endif #ifdef HAVE_SSE41 case CPUID_SSE41: __asm__ volatile ("pcmpeqq %xmm0, %xmm0"); break; #endif #ifdef HAVE_SSE42 case CPUID_SSE42: __asm__ volatile ("pushq %rax\n" "xorq %rax, %rax\n" "crc32 %rax, %rax\n" "popq %rax"); break; #endif #ifdef HAVE_AVX case CPUID_AVX: __asm__ volatile ("vpaddq %xmm0, %xmm0, %xmm0"); break; #endif #ifdef HAVE_AVX2 case CPUID_AVX2: __asm__ volatile ("vpaddq %ymm0, %ymm0, %ymm0");\ break; #endif default: return FALSE; break; } signal (SIGILL, old_handler); #endif (void)rd; /* Silence warning */ /* We actually never return here if SIGILL has been caught */ return ok == 1; } struct rspamd_cryptobox_library_ctx* rspamd_cryptobox_init (void) { gint cpu[4], nid; const guint32 osxsave_mask = (1 << 27); const guint32 fma_movbe_osxsave_mask = ((1 << 12) | (1 << 22) | (1 << 27)); const guint32 avx2_bmi12_mask = (1 << 5) | (1 << 3) | (1 << 8); gulong bit; static struct rspamd_cryptobox_library_ctx *ctx; GString *buf; if (cryptobox_loaded) { /* Ignore reload attempts */ return ctx; } cryptobox_loaded = TRUE; ctx = g_malloc0 (sizeof (*ctx)); rspamd_cryptobox_cpuid (cpu, 0); nid = cpu[0]; rspamd_cryptobox_cpuid (cpu, 1); if (nid > 1) { if ((cpu[3] & ((guint32)1 << 26))) { if (rspamd_cryptobox_test_instr (CPUID_SSE2)) { cpu_config |= CPUID_SSE2; } } if ((cpu[2] & ((guint32)1 << 0))) { if (rspamd_cryptobox_test_instr (CPUID_SSE3)) { cpu_config |= CPUID_SSE3; } } if ((cpu[2] & ((guint32)1 << 9))) { if (rspamd_cryptobox_test_instr (CPUID_SSSE3)) { cpu_config |= CPUID_SSSE3; } } if ((cpu[2] & ((guint32)1 << 19))) { if (rspamd_cryptobox_test_instr (CPUID_SSE41)) { cpu_config |= CPUID_SSE41; } } if ((cpu[2] & ((guint32)1 << 20))) { if (rspamd_cryptobox_test_instr (CPUID_SSE42)) { cpu_config |= CPUID_SSE42; } } if ((cpu[2] & ((guint32)1 << 30))) { if (rspamd_cryptobox_test_instr (CPUID_RDRAND)) { cpu_config |= CPUID_RDRAND; } } /* OSXSAVE */ if ((cpu[2] & osxsave_mask) == osxsave_mask) { if ((cpu[2] & ((guint32)1 << 28))) { if (rspamd_cryptobox_test_instr (CPUID_AVX)) { cpu_config |= CPUID_AVX; } } if (nid >= 7 && (cpu[2] & fma_movbe_osxsave_mask) == fma_movbe_osxsave_mask) { rspamd_cryptobox_cpuid (cpu, 7); if ((cpu[1] & avx2_bmi12_mask) == avx2_bmi12_mask) { if (rspamd_cryptobox_test_instr (CPUID_AVX2)) { cpu_config |= CPUID_AVX2; } } } } } buf = g_string_new (""); for (bit = 0x1; bit != 0; bit <<= 1) { if (cpu_config & bit) { switch (bit) { case CPUID_SSE2: rspamd_printf_gstring (buf, "sse2, "); break; case CPUID_SSE3: rspamd_printf_gstring (buf, "sse3, "); break; case CPUID_SSSE3: rspamd_printf_gstring (buf, "ssse3, "); break; case CPUID_SSE41: rspamd_printf_gstring (buf, "sse4.1, "); break; case CPUID_SSE42: rspamd_printf_gstring (buf, "sse4.2, "); break; case CPUID_AVX: rspamd_printf_gstring (buf, "avx, "); break; case CPUID_AVX2: rspamd_printf_gstring (buf, "avx2, "); break; case CPUID_RDRAND: rspamd_printf_gstring (buf, "rdrand, "); break; default: break; /* Silence warning */ } } } if (buf->len > 2) { /* Trim last chars */ g_string_erase (buf, buf->len - 2, 2); } ctx->cpu_extensions = buf->str; g_string_free (buf, FALSE); ctx->cpu_config = cpu_config; g_assert (sodium_init () != -1); ctx->chacha20_impl = chacha_load (); ctx->base64_impl = base64_load (); #if defined(HAVE_USABLE_OPENSSL) && (OPENSSL_VERSION_NUMBER < 0x10100000L || defined(LIBRESSL_VERSION_NUMBER)) /* Needed for old openssl api, not sure about LibreSSL */ ERR_load_EC_strings (); ERR_load_RAND_strings (); ERR_load_EVP_strings (); #endif return ctx; } void rspamd_cryptobox_deinit (struct rspamd_cryptobox_library_ctx *ctx) { if (ctx) { g_free (ctx->cpu_extensions); g_free (ctx); } } void rspamd_cryptobox_keypair (rspamd_pk_t pk, rspamd_sk_t sk, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { ottery_rand_bytes (sk, rspamd_cryptobox_MAX_SKBYTES); sk[0] &= 248; sk[31] &= 127; sk[31] |= 64; crypto_scalarmult_base (pk, sk); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EC_KEY *ec_sec; const BIGNUM *bn_sec; BIGNUM *bn_pub; const EC_POINT *ec_pub; gint len; ec_sec = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); g_assert (ec_sec != NULL); g_assert (EC_KEY_generate_key (ec_sec) != 0); bn_sec = EC_KEY_get0_private_key (ec_sec); g_assert (bn_sec != NULL); ec_pub = EC_KEY_get0_public_key (ec_sec); g_assert (ec_pub != NULL); bn_pub = EC_POINT_point2bn (EC_KEY_get0_group (ec_sec), ec_pub, POINT_CONVERSION_UNCOMPRESSED, NULL, NULL); len = BN_num_bytes (bn_sec); g_assert (len <= (gint)sizeof (rspamd_sk_t)); BN_bn2bin (bn_sec, sk); len = BN_num_bytes (bn_pub); g_assert (len <= (gint)rspamd_cryptobox_pk_bytes (mode)); BN_bn2bin (bn_pub, pk); BN_free (bn_pub); EC_KEY_free (ec_sec); #endif } } void rspamd_cryptobox_keypair_sig (rspamd_sig_pk_t pk, rspamd_sig_sk_t sk, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_sign_keypair (pk, sk); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EC_KEY *ec_sec; const BIGNUM *bn_sec; BIGNUM *bn_pub; const EC_POINT *ec_pub; gint len; ec_sec = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); g_assert (ec_sec != NULL); g_assert (EC_KEY_generate_key (ec_sec) != 0); bn_sec = EC_KEY_get0_private_key (ec_sec); g_assert (bn_sec != NULL); ec_pub = EC_KEY_get0_public_key (ec_sec); g_assert (ec_pub != NULL); bn_pub = EC_POINT_point2bn (EC_KEY_get0_group (ec_sec), ec_pub, POINT_CONVERSION_UNCOMPRESSED, NULL, NULL); len = BN_num_bytes (bn_sec); g_assert (len <= (gint)sizeof (rspamd_sk_t)); BN_bn2bin (bn_sec, sk); len = BN_num_bytes (bn_pub); g_assert (len <= (gint)rspamd_cryptobox_pk_bytes (mode)); BN_bn2bin (bn_pub, pk); BN_free (bn_pub); EC_KEY_free (ec_sec); #endif } } void rspamd_cryptobox_nm (rspamd_nm_t nm, const rspamd_pk_t pk, const rspamd_sk_t sk, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { guchar s[32]; guchar e[32]; memcpy (e, sk, 32); e[0] &= 248; e[31] &= 127; e[31] |= 64; if (crypto_scalarmult (s, e, pk) != -1) { hchacha (s, n0, nm, 20); } rspamd_explicit_memzero (e, 32); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EC_KEY *lk; EC_POINT *ec_pub; BIGNUM *bn_pub, *bn_sec; gint len; guchar s[32]; lk = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); g_assert (lk != NULL); bn_pub = BN_bin2bn (pk, rspamd_cryptobox_pk_bytes (mode), NULL); g_assert (bn_pub != NULL); bn_sec = BN_bin2bn (sk, sizeof (rspamd_sk_t), NULL); g_assert (bn_sec != NULL); g_assert (EC_KEY_set_private_key (lk, bn_sec) == 1); ec_pub = EC_POINT_bn2point (EC_KEY_get0_group (lk), bn_pub, NULL, NULL); g_assert (ec_pub != NULL); len = ECDH_compute_key (s, sizeof (s), ec_pub, lk, NULL); g_assert (len == sizeof (s)); /* Still do hchacha iteration since we are not using SHA1 KDF */ hchacha (s, n0, nm, 20); EC_KEY_free (lk); EC_POINT_free (ec_pub); BN_free (bn_sec); BN_free (bn_pub); #endif } } void rspamd_cryptobox_sign (guchar *sig, unsigned long long *siglen_p, const guchar *m, gsize mlen, const rspamd_sk_t sk, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_sign (sig, siglen_p, m, mlen, sk); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EC_KEY *lk; BIGNUM *bn_sec, *kinv = NULL, *rp = NULL; EVP_MD_CTX *sha_ctx; unsigned char h[64]; guint diglen = rspamd_cryptobox_signature_bytes (mode); /* Prehash */ sha_ctx = EVP_MD_CTX_create (); g_assert (EVP_DigestInit (sha_ctx, EVP_sha512()) == 1); EVP_DigestUpdate (sha_ctx, m, mlen); EVP_DigestFinal (sha_ctx, h, NULL); /* Key setup */ lk = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); g_assert (lk != NULL); bn_sec = BN_bin2bn (sk, sizeof (rspamd_sk_t), NULL); g_assert (bn_sec != NULL); g_assert (EC_KEY_set_private_key (lk, bn_sec) == 1); /* ECDSA */ g_assert (ECDSA_sign_setup (lk, NULL, &kinv, &rp) == 1); g_assert (ECDSA_sign_ex (0, h, sizeof (h), sig, &diglen, kinv, rp, lk) == 1); g_assert (diglen <= sizeof (rspamd_signature_t)); if (siglen_p) { *siglen_p = diglen; } EC_KEY_free (lk); EVP_MD_CTX_destroy (sha_ctx); BN_free (bn_sec); BN_free (kinv); BN_free (rp); #endif } } bool rspamd_cryptobox_verify (const guchar *sig, gsize siglen, const guchar *m, gsize mlen, const rspamd_pk_t pk, enum rspamd_cryptobox_mode mode) { bool ret = false; if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { if (siglen == rspamd_cryptobox_signature_bytes (RSPAMD_CRYPTOBOX_MODE_25519)) { ret = (crypto_sign_verify_detached (sig, m, mlen, pk) == 0); } } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EC_KEY *lk; EC_POINT *ec_pub; BIGNUM *bn_pub; EVP_MD_CTX *sha_ctx; unsigned char h[64]; /* Prehash */ sha_ctx = EVP_MD_CTX_create (); g_assert (EVP_DigestInit (sha_ctx, EVP_sha512()) == 1); EVP_DigestUpdate (sha_ctx, m, mlen); EVP_DigestFinal (sha_ctx, h, NULL); /* Key setup */ lk = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); g_assert (lk != NULL); bn_pub = BN_bin2bn (pk, rspamd_cryptobox_pk_bytes (mode), NULL); g_assert (bn_pub != NULL); ec_pub = EC_POINT_bn2point (EC_KEY_get0_group (lk), bn_pub, NULL, NULL); g_assert (ec_pub != NULL); g_assert (EC_KEY_set_public_key (lk, ec_pub) == 1); /* ECDSA */ ret = ECDSA_verify (0, h, sizeof (h), sig, siglen, lk) == 1; EC_KEY_free (lk); EVP_MD_CTX_destroy (sha_ctx); BN_free (bn_pub); EC_POINT_free (ec_pub); #endif } return ret; } static gsize rspamd_cryptobox_encrypt_ctx_len (enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return sizeof (chacha_state) + CRYPTOBOX_ALIGNMENT; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else return sizeof (EVP_CIPHER_CTX *) + CRYPTOBOX_ALIGNMENT; #endif } return 0; } static gsize rspamd_cryptobox_auth_ctx_len (enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return sizeof (crypto_onetimeauth_state) + _Alignof (crypto_onetimeauth_state); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else return sizeof (void *); #endif } return 0; } static void * rspamd_cryptobox_encrypt_init (void *enc_ctx, const rspamd_nonce_t nonce, const rspamd_nm_t nm, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); xchacha_init (s, (const chacha_key *) nm, (const chacha_iv24 *) nonce, 20); return s; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); memset (s, 0, sizeof (*s)); *s = EVP_CIPHER_CTX_new (); g_assert (EVP_EncryptInit_ex (*s, EVP_aes_256_gcm (), NULL, NULL, NULL) == 1); g_assert (EVP_CIPHER_CTX_ctrl (*s, EVP_CTRL_GCM_SET_IVLEN, rspamd_cryptobox_nonce_bytes (mode), NULL) == 1); g_assert (EVP_EncryptInit_ex (*s, NULL, NULL, nm, nonce) == 1); return s; #endif } return NULL; } static void * rspamd_cryptobox_auth_init (void *auth_ctx, void *enc_ctx, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; guchar RSPAMD_ALIGNED(32) subkey[CHACHA_BLOCKBYTES]; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); memset (subkey, 0, sizeof (subkey)); chacha_update (enc_ctx, subkey, subkey, sizeof (subkey)); crypto_onetimeauth_init (mac_ctx, subkey); rspamd_explicit_memzero (subkey, sizeof (subkey)); return mac_ctx; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else auth_ctx = enc_ctx; return auth_ctx; #endif } return NULL; } static gboolean rspamd_cryptobox_encrypt_update (void *enc_ctx, const guchar *in, gsize inlen, guchar *out, gsize *outlen, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { gsize r; chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); r = chacha_update (s, in, out, inlen); if (outlen != NULL) { *outlen = r; } return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = enc_ctx; gint r; r = inlen; g_assert (EVP_EncryptUpdate (*s, out, &r, in, inlen) == 1); if (outlen) { *outlen = r; } return TRUE; #endif } return FALSE; } static gboolean rspamd_cryptobox_auth_update (void *auth_ctx, const guchar *in, gsize inlen, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); crypto_onetimeauth_update (mac_ctx, in, inlen); return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else return TRUE; #endif } return FALSE; } static gsize rspamd_cryptobox_encrypt_final (void *enc_ctx, guchar *out, gsize remain, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); return chacha_final (s, out); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = enc_ctx; gint r = remain; g_assert (EVP_EncryptFinal_ex (*s, out, &r) == 1); return r; #endif } return 0; } static gboolean rspamd_cryptobox_auth_final (void *auth_ctx, rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); crypto_onetimeauth_final (mac_ctx, sig); return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = auth_ctx; g_assert (EVP_CIPHER_CTX_ctrl (*s, EVP_CTRL_GCM_GET_TAG, sizeof (rspamd_mac_t), sig) == 1); return TRUE; #endif } return FALSE; } static void * rspamd_cryptobox_decrypt_init (void *enc_ctx, const rspamd_nonce_t nonce, const rspamd_nm_t nm, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); xchacha_init (s, (const chacha_key *) nm, (const chacha_iv24 *) nonce, 20); return s; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); memset (s, 0, sizeof (*s)); *s = EVP_CIPHER_CTX_new (); g_assert (EVP_DecryptInit_ex(*s, EVP_aes_256_gcm (), NULL, NULL, NULL) == 1); g_assert (EVP_CIPHER_CTX_ctrl (*s, EVP_CTRL_GCM_SET_IVLEN, rspamd_cryptobox_nonce_bytes (mode), NULL) == 1); g_assert (EVP_DecryptInit_ex (*s, NULL, NULL, nm, nonce) == 1); return s; #endif } return NULL; } static void * rspamd_cryptobox_auth_verify_init (void *auth_ctx, void *enc_ctx, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; guchar RSPAMD_ALIGNED(32) subkey[CHACHA_BLOCKBYTES]; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); memset (subkey, 0, sizeof (subkey)); chacha_update (enc_ctx, subkey, subkey, sizeof (subkey)); crypto_onetimeauth_init (mac_ctx, subkey); rspamd_explicit_memzero (subkey, sizeof (subkey)); return mac_ctx; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else auth_ctx = enc_ctx; return auth_ctx; #endif } return NULL; } static gboolean rspamd_cryptobox_decrypt_update (void *enc_ctx, const guchar *in, gsize inlen, guchar *out, gsize *outlen, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { gsize r; chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); r = chacha_update (s, in, out, inlen); if (outlen != NULL) { *outlen = r; } return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = enc_ctx; gint r; r = outlen ? *outlen : inlen; g_assert (EVP_DecryptUpdate (*s, out, &r, in, inlen) == 1); if (outlen) { *outlen = r; } return TRUE; #endif } } static gboolean rspamd_cryptobox_auth_verify_update (void *auth_ctx, const guchar *in, gsize inlen, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); crypto_onetimeauth_update (mac_ctx, in, inlen); return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL /* We do not need to authenticate as a separate process */ return TRUE; #else #endif } return FALSE; } static gboolean rspamd_cryptobox_decrypt_final (void *enc_ctx, guchar *out, gsize remain, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { chacha_state *s; s = cryptobox_align_ptr (enc_ctx, CRYPTOBOX_ALIGNMENT); chacha_final (s, out); return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = enc_ctx; gint r = remain; if (EVP_DecryptFinal_ex (*s, out, &r) < 0) { return FALSE; } return TRUE; #endif } return FALSE; } static gboolean rspamd_cryptobox_auth_verify_final (void *auth_ctx, const rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { rspamd_mac_t mac; crypto_onetimeauth_state *mac_ctx; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); crypto_onetimeauth_final (mac_ctx, mac); if (crypto_verify_16 (mac, sig) != 0) { return FALSE; } return TRUE; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = auth_ctx; if (EVP_CIPHER_CTX_ctrl (*s, EVP_CTRL_GCM_SET_TAG, 16, (guchar *)sig) != 1) { return FALSE; } return TRUE; #endif } return FALSE; } static void rspamd_cryptobox_cleanup (void *enc_ctx, void *auth_ctx, enum rspamd_cryptobox_mode mode) { if (G_LIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { crypto_onetimeauth_state *mac_ctx; mac_ctx = cryptobox_align_ptr (auth_ctx, CRYPTOBOX_ALIGNMENT); rspamd_explicit_memzero (mac_ctx, sizeof (*mac_ctx)); } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else EVP_CIPHER_CTX **s = enc_ctx; EVP_CIPHER_CTX_cleanup (*s); EVP_CIPHER_CTX_free (*s); #endif } } void rspamd_cryptobox_encrypt_nm_inplace (guchar *data, gsize len, const rspamd_nonce_t nonce, const rspamd_nm_t nm, rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { gsize r; void *enc_ctx, *auth_ctx; enc_ctx = g_alloca (rspamd_cryptobox_encrypt_ctx_len (mode)); auth_ctx = g_alloca (rspamd_cryptobox_auth_ctx_len (mode)); enc_ctx = rspamd_cryptobox_encrypt_init (enc_ctx, nonce, nm, mode); auth_ctx = rspamd_cryptobox_auth_init (auth_ctx, enc_ctx, mode); rspamd_cryptobox_encrypt_update (enc_ctx, data, len, data, &r, mode); rspamd_cryptobox_encrypt_final (enc_ctx, data + r, len - r, mode); rspamd_cryptobox_auth_update (auth_ctx, data, len, mode); rspamd_cryptobox_auth_final (auth_ctx, sig, mode); rspamd_cryptobox_cleanup (enc_ctx, auth_ctx, mode); } static void rspamd_cryptobox_flush_outbuf (struct rspamd_cryptobox_segment *st, const guchar *buf, gsize len, gsize offset) { gsize cpy_len; while (len > 0) { cpy_len = MIN (len, st->len - offset); memcpy (st->data + offset, buf, cpy_len); st ++; buf += cpy_len; len -= cpy_len; offset = 0; } } void rspamd_cryptobox_encryptv_nm_inplace (struct rspamd_cryptobox_segment *segments, gsize cnt, const rspamd_nonce_t nonce, const rspamd_nm_t nm, rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { struct rspamd_cryptobox_segment *cur = segments, *start_seg = segments; guchar outbuf[CHACHA_BLOCKBYTES * 16]; void *enc_ctx, *auth_ctx; guchar *out, *in; gsize r, remain, inremain, seg_offset; enc_ctx = g_alloca (rspamd_cryptobox_encrypt_ctx_len (mode)); auth_ctx = g_alloca (rspamd_cryptobox_auth_ctx_len (mode)); enc_ctx = rspamd_cryptobox_encrypt_init (enc_ctx, nonce, nm, mode); auth_ctx = rspamd_cryptobox_auth_init (auth_ctx, enc_ctx, mode); remain = sizeof (outbuf); out = outbuf; inremain = cur->len; seg_offset = 0; for (;;) { if (cur - segments == (gint)cnt) { break; } if (cur->len <= remain) { memcpy (out, cur->data, cur->len); remain -= cur->len; out += cur->len; cur ++; if (remain == 0) { rspamd_cryptobox_encrypt_update (enc_ctx, outbuf, sizeof (outbuf), outbuf, NULL, mode); rspamd_cryptobox_auth_update (auth_ctx, outbuf, sizeof (outbuf), mode); rspamd_cryptobox_flush_outbuf (start_seg, outbuf, sizeof (outbuf), seg_offset); start_seg = cur; seg_offset = 0; remain = sizeof (outbuf); out = outbuf; } } else { memcpy (out, cur->data, remain); rspamd_cryptobox_encrypt_update (enc_ctx, outbuf, sizeof (outbuf), outbuf, NULL, mode); rspamd_cryptobox_auth_update (auth_ctx, outbuf, sizeof (outbuf), mode); rspamd_cryptobox_flush_outbuf (start_seg, outbuf, sizeof (outbuf), seg_offset); seg_offset = 0; inremain = cur->len - remain; in = cur->data + remain; out = outbuf; remain = 0; start_seg = cur; while (inremain > 0) { if (sizeof (outbuf) <= inremain) { memcpy (outbuf, in, sizeof (outbuf)); rspamd_cryptobox_encrypt_update (enc_ctx, outbuf, sizeof (outbuf), outbuf, NULL, mode); rspamd_cryptobox_auth_update (auth_ctx, outbuf, sizeof (outbuf), mode); memcpy (in, outbuf, sizeof (outbuf)); in += sizeof (outbuf); inremain -= sizeof (outbuf); remain = sizeof (outbuf); } else { memcpy (outbuf, in, inremain); remain = sizeof (outbuf) - inremain; out = outbuf + inremain; inremain = 0; } } seg_offset = cur->len - (sizeof (outbuf) - remain); cur ++; } } rspamd_cryptobox_encrypt_update (enc_ctx, outbuf, sizeof (outbuf) - remain, outbuf, &r, mode); out = outbuf + r; rspamd_cryptobox_encrypt_final (enc_ctx, out, sizeof (outbuf) - remain - r, mode); rspamd_cryptobox_auth_update (auth_ctx, outbuf, sizeof (outbuf) - remain, mode); rspamd_cryptobox_auth_final (auth_ctx, sig, mode); rspamd_cryptobox_flush_outbuf (start_seg, outbuf, sizeof (outbuf) - remain, seg_offset); rspamd_cryptobox_cleanup (enc_ctx, auth_ctx, mode); } gboolean rspamd_cryptobox_decrypt_nm_inplace (guchar *data, gsize len, const rspamd_nonce_t nonce, const rspamd_nm_t nm, const rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { gsize r = 0; gboolean ret = TRUE; void *enc_ctx, *auth_ctx; enc_ctx = g_alloca (rspamd_cryptobox_encrypt_ctx_len (mode)); auth_ctx = g_alloca (rspamd_cryptobox_auth_ctx_len (mode)); enc_ctx = rspamd_cryptobox_decrypt_init (enc_ctx, nonce, nm, mode); auth_ctx = rspamd_cryptobox_auth_verify_init (auth_ctx, enc_ctx, mode); rspamd_cryptobox_auth_verify_update (auth_ctx, data, len, mode); if (!rspamd_cryptobox_auth_verify_final (auth_ctx, sig, mode)) { ret = FALSE; } else { rspamd_cryptobox_decrypt_update (enc_ctx, data, len, data, &r, mode); ret = rspamd_cryptobox_decrypt_final (enc_ctx, data + r, len - r, mode); } rspamd_cryptobox_cleanup (enc_ctx, auth_ctx, mode); return ret; } gboolean rspamd_cryptobox_decrypt_inplace (guchar *data, gsize len, const rspamd_nonce_t nonce, const rspamd_pk_t pk, const rspamd_sk_t sk, const rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { guchar nm[rspamd_cryptobox_MAX_NMBYTES]; gboolean ret; rspamd_cryptobox_nm (nm, pk, sk, mode); ret = rspamd_cryptobox_decrypt_nm_inplace (data, len, nonce, nm, sig, mode); rspamd_explicit_memzero (nm, sizeof (nm)); return ret; } void rspamd_cryptobox_encrypt_inplace (guchar *data, gsize len, const rspamd_nonce_t nonce, const rspamd_pk_t pk, const rspamd_sk_t sk, rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { guchar nm[rspamd_cryptobox_MAX_NMBYTES]; rspamd_cryptobox_nm (nm, pk, sk, mode); rspamd_cryptobox_encrypt_nm_inplace (data, len, nonce, nm, sig, mode); rspamd_explicit_memzero (nm, sizeof (nm)); } void rspamd_cryptobox_encryptv_inplace (struct rspamd_cryptobox_segment *segments, gsize cnt, const rspamd_nonce_t nonce, const rspamd_pk_t pk, const rspamd_sk_t sk, rspamd_mac_t sig, enum rspamd_cryptobox_mode mode) { guchar nm[rspamd_cryptobox_MAX_NMBYTES]; rspamd_cryptobox_nm (nm, pk, sk, mode); rspamd_cryptobox_encryptv_nm_inplace (segments, cnt, nonce, nm, sig, mode); rspamd_explicit_memzero (nm, sizeof (nm)); } void rspamd_cryptobox_siphash (unsigned char *out, const unsigned char *in, unsigned long long inlen, const rspamd_sipkey_t k) { crypto_shorthash_siphash24 (out, in, inlen, k); } /* * Password-Based Key Derivation Function 2 (PKCS #5 v2.0). * Code based on IEEE Std 802.11-2007, Annex H.4.2. */ static gboolean rspamd_cryptobox_pbkdf2 (const char *pass, gsize pass_len, const guint8 *salt, gsize salt_len, guint8 *key, gsize key_len, unsigned int rounds) { guint8 *asalt, obuf[crypto_generichash_blake2b_BYTES_MAX]; guint8 d1[crypto_generichash_blake2b_BYTES_MAX], d2[crypto_generichash_blake2b_BYTES_MAX]; unsigned int i, j; unsigned int count; gsize r; if (rounds < 1 || key_len == 0) { return FALSE; } if (salt_len == 0 || salt_len > G_MAXSIZE - 4) { return FALSE; } asalt = g_malloc (salt_len + 4); memcpy (asalt, salt, salt_len); for (count = 1; key_len > 0; count++) { asalt[salt_len + 0] = (count >> 24) & 0xff; asalt[salt_len + 1] = (count >> 16) & 0xff; asalt[salt_len + 2] = (count >> 8) & 0xff; asalt[salt_len + 3] = count & 0xff; if (pass_len <= crypto_generichash_blake2b_KEYBYTES_MAX) { crypto_generichash_blake2b (d1, sizeof (d1), asalt, salt_len + 4, pass, pass_len); } else { guint8 k[crypto_generichash_blake2b_BYTES_MAX]; /* * We use additional blake2 iteration to store large key * XXX: it is not compatible with the original implementation but safe */ crypto_generichash_blake2b (k, sizeof (k), pass, pass_len, NULL, 0); crypto_generichash_blake2b (d1, sizeof (d1), asalt, salt_len + 4, k, sizeof (k)); } memcpy (obuf, d1, sizeof(obuf)); for (i = 1; i < rounds; i++) { if (pass_len <= crypto_generichash_blake2b_KEYBYTES_MAX) { crypto_generichash_blake2b (d2, sizeof (d2), d1, sizeof (d1), pass, pass_len); } else { guint8 k[crypto_generichash_blake2b_BYTES_MAX]; /* * We use additional blake2 iteration to store large key * XXX: it is not compatible with the original implementation but safe */ crypto_generichash_blake2b (k, sizeof (k), pass, pass_len, NULL, 0); crypto_generichash_blake2b (d2, sizeof (d2), d1, sizeof (d1), k, sizeof (k)); } memcpy (d1, d2, sizeof(d1)); for (j = 0; j < sizeof(obuf); j++) { obuf[j] ^= d1[j]; } } r = MIN(key_len, crypto_generichash_blake2b_BYTES_MAX); memcpy (key, obuf, r); key += r; key_len -= r; } rspamd_explicit_memzero (asalt, salt_len + 4); g_free (asalt); rspamd_explicit_memzero (d1, sizeof (d1)); rspamd_explicit_memzero (d2, sizeof (d2)); rspamd_explicit_memzero (obuf, sizeof (obuf)); return TRUE; } gboolean rspamd_cryptobox_pbkdf (const char *pass, gsize pass_len, const guint8 *salt, gsize salt_len, guint8 *key, gsize key_len, unsigned int complexity, enum rspamd_cryptobox_pbkdf_type type) { gboolean ret = FALSE; switch (type) { case RSPAMD_CRYPTOBOX_CATENA: if (catena (pass, pass_len, salt, salt_len, "rspamd", 6, 4, complexity, complexity, key_len, key) == 0) { ret = TRUE; } break; case RSPAMD_CRYPTOBOX_PBKDF2: default: ret = rspamd_cryptobox_pbkdf2 (pass, pass_len, salt, salt_len, key, key_len, complexity); break; } return ret; } guint rspamd_cryptobox_pk_bytes (enum rspamd_cryptobox_mode mode) { if (G_UNLIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return 32; } else { return 65; } } guint rspamd_cryptobox_pk_sig_bytes (enum rspamd_cryptobox_mode mode) { if (G_UNLIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return 32; } else { return 65; } } guint rspamd_cryptobox_nonce_bytes (enum rspamd_cryptobox_mode mode) { if (G_UNLIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return 24; } else { return 16; } } guint rspamd_cryptobox_sk_bytes (enum rspamd_cryptobox_mode mode) { return 32; } guint rspamd_cryptobox_sk_sig_bytes (enum rspamd_cryptobox_mode mode) { if (G_UNLIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return 64; } else { return 32; } } guint rspamd_cryptobox_signature_bytes (enum rspamd_cryptobox_mode mode) { static guint ssl_keylen; if (G_UNLIKELY (mode == RSPAMD_CRYPTOBOX_MODE_25519)) { return 64; } else { #ifndef HAVE_USABLE_OPENSSL g_assert (0); #else if (ssl_keylen == 0) { EC_KEY *lk; lk = EC_KEY_new_by_curve_name (CRYPTOBOX_CURVE_NID); ssl_keylen = ECDSA_size (lk); EC_KEY_free (lk); } #endif return ssl_keylen; } } guint rspamd_cryptobox_nm_bytes (enum rspamd_cryptobox_mode mode) { return 32; } guint rspamd_cryptobox_mac_bytes (enum rspamd_cryptobox_mode mode) { return 16; } void rspamd_cryptobox_hash_init (void *p, const guchar *key, gsize keylen) { if (key != NULL && keylen > 0) { crypto_generichash_blake2b_state *st = cryptobox_align_ptr (p, _Alignof(crypto_generichash_blake2b_state)); crypto_generichash_blake2b_init (st, key, keylen, crypto_generichash_blake2b_BYTES_MAX); } else { crypto_generichash_blake2b_state *st = cryptobox_align_ptr (p, _Alignof(crypto_generichash_blake2b_state)); crypto_generichash_blake2b_init (st, key, keylen, crypto_generichash_blake2b_BYTES_MAX); } } /** * Update hash with data portion */ void rspamd_cryptobox_hash_update (void *p, const guchar *data, gsize len) { crypto_generichash_blake2b_state *st = cryptobox_align_ptr (p, _Alignof(crypto_generichash_blake2b_state)); crypto_generichash_blake2b_update (st, data, len); } /** * Output hash to the buffer of rspamd_cryptobox_HASHBYTES length */ void rspamd_cryptobox_hash_final (void *p, guchar *out) { crypto_generichash_blake2b_state *st = cryptobox_align_ptr (p, _Alignof(crypto_generichash_blake2b_state)); crypto_generichash_blake2b_final (st, out, crypto_generichash_blake2b_BYTES_MAX); } /** * One in all function */ void rspamd_cryptobox_hash (guchar *out, const guchar *data, gsize len, const guchar *key, gsize keylen) { crypto_generichash_blake2b (out, crypto_generichash_blake2b_BYTES_MAX, data, len, key, keylen); } G_STATIC_ASSERT (sizeof (t1ha_context_t) <= sizeof (((rspamd_cryptobox_fast_hash_state_t *)NULL)->opaque)); G_STATIC_ASSERT (sizeof (XXH64_state_t) <= sizeof (((rspamd_cryptobox_fast_hash_state_t *)NULL)->opaque)); struct RSPAMD_ALIGNED(16) _mum_iuf { union { gint64 ll; unsigned char b[sizeof (guint64)]; } buf; gint64 h; unsigned rem; }; void rspamd_cryptobox_fast_hash_init (rspamd_cryptobox_fast_hash_state_t *st, guint64 seed) { t1ha_context_t *rst = (t1ha_context_t *)st->opaque; st->type = RSPAMD_CRYPTOBOX_T1HA; t1ha2_init (rst, seed, 0); } void rspamd_cryptobox_fast_hash_init_specific (rspamd_cryptobox_fast_hash_state_t *st, enum rspamd_cryptobox_fast_hash_type type, guint64 seed) { switch (type) { case RSPAMD_CRYPTOBOX_T1HA: case RSPAMD_CRYPTOBOX_HASHFAST: case RSPAMD_CRYPTOBOX_HASHFAST_INDEPENDENT: { t1ha_context_t *rst = (t1ha_context_t *) st->opaque; st->type = RSPAMD_CRYPTOBOX_T1HA; t1ha2_init (rst, seed, 0); break; } case RSPAMD_CRYPTOBOX_XXHASH64: { XXH64_state_t *xst = (XXH64_state_t *) st->opaque; st->type = RSPAMD_CRYPTOBOX_XXHASH64; XXH64_reset (xst, seed); break; } case RSPAMD_CRYPTOBOX_XXHASH32: { XXH32_state_t *xst = (XXH32_state_t *) st->opaque; st->type = RSPAMD_CRYPTOBOX_XXHASH32; XXH32_reset (xst, seed); break; } case RSPAMD_CRYPTOBOX_MUMHASH: { struct _mum_iuf *iuf = (struct _mum_iuf *) st->opaque; st->type = RSPAMD_CRYPTOBOX_MUMHASH; iuf->h = seed; iuf->buf.ll = 0; iuf->rem = 0; break; } } } void rspamd_cryptobox_fast_hash_update (rspamd_cryptobox_fast_hash_state_t *st, const void *data, gsize len) { if (G_LIKELY (st->type) == RSPAMD_CRYPTOBOX_T1HA) { t1ha_context_t *rst = (t1ha_context_t *) st->opaque; t1ha2_update (rst, data, len); } else { switch (st->type) { case RSPAMD_CRYPTOBOX_XXHASH64: { XXH64_state_t *xst = (XXH64_state_t *) st->opaque; XXH64_update (xst, data, len); break; } case RSPAMD_CRYPTOBOX_XXHASH32: { XXH32_state_t *xst = (XXH32_state_t *) st->opaque; XXH32_update (xst, data, len); break; } case RSPAMD_CRYPTOBOX_MUMHASH: { struct _mum_iuf *iuf = (struct _mum_iuf *) st->opaque; gsize drem = len; const guchar *p = data; if (iuf->rem > 0) { /* Process remainder */ if (drem >= iuf->rem) { memcpy (iuf->buf.b + sizeof (iuf->buf.ll) - iuf->rem, p, iuf->rem); drem -= iuf->rem; p += iuf->rem; iuf->h = mum_hash_step (iuf->h, iuf->buf.ll); iuf->rem = 0; } else { memcpy (iuf->buf.b + sizeof (iuf->buf.ll) - iuf->rem, p, drem); iuf->rem -= drem; drem = 0; } } while (drem >= sizeof (iuf->buf.ll)) { memcpy (iuf->buf.b, p, sizeof (iuf->buf.ll)); iuf->h = mum_hash_step (iuf->h, iuf->buf.ll); drem -= sizeof (iuf->buf.ll); p += sizeof (iuf->buf.ll); } /* Leftover */ if (drem > 0) { iuf->rem = sizeof (guint64) - drem; iuf->buf.ll = 0; memcpy (iuf->buf.b, p, drem); } break; } case RSPAMD_CRYPTOBOX_T1HA: case RSPAMD_CRYPTOBOX_HASHFAST: case RSPAMD_CRYPTOBOX_HASHFAST_INDEPENDENT: { t1ha_context_t *rst = (t1ha_context_t *) st->opaque; t1ha2_update (rst, data, len); break; } } } } guint64 rspamd_cryptobox_fast_hash_final (rspamd_cryptobox_fast_hash_state_t *st) { guint64 ret; if (G_LIKELY (st->type) == RSPAMD_CRYPTOBOX_T1HA) { t1ha_context_t *rst = (t1ha_context_t *) st->opaque; return t1ha2_final (rst, NULL); } else { switch (st->type) { case RSPAMD_CRYPTOBOX_XXHASH64: { XXH64_state_t *xst = (XXH64_state_t *) st->opaque; ret = XXH64_digest (xst); break; } case RSPAMD_CRYPTOBOX_XXHASH32: { XXH32_state_t *xst = (XXH32_state_t *) st->opaque; ret = XXH32_digest (xst); break; } case RSPAMD_CRYPTOBOX_MUMHASH: { struct _mum_iuf *iuf = (struct _mum_iuf *) st->opaque; iuf->h = mum_hash_step (iuf->h, iuf->buf.ll); ret = mum_hash_finish (iuf->h); break; } case RSPAMD_CRYPTOBOX_T1HA: case RSPAMD_CRYPTOBOX_HASHFAST: case RSPAMD_CRYPTOBOX_HASHFAST_INDEPENDENT: { t1ha_context_t *rst = (t1ha_context_t *) st->opaque; ret = t1ha2_final (rst, NULL); break; } } } return ret; } /** * One in all function */ static inline guint64 rspamd_cryptobox_fast_hash_machdep (const void *data, gsize len, guint64 seed) { return t1ha2_atonce (data, len, seed); } static inline guint64 rspamd_cryptobox_fast_hash_indep (const void *data, gsize len, guint64 seed) { return t1ha2_atonce (data, len, seed); } guint64 rspamd_cryptobox_fast_hash (const void *data, gsize len, guint64 seed) { return rspamd_cryptobox_fast_hash_machdep (data, len, seed); } guint64 rspamd_cryptobox_fast_hash_specific ( enum rspamd_cryptobox_fast_hash_type type, const void *data, gsize len, guint64 seed) { switch (type) { case RSPAMD_CRYPTOBOX_XXHASH32: return XXH32 (data, len, seed); case RSPAMD_CRYPTOBOX_XXHASH64: return XXH64 (data, len, seed); case RSPAMD_CRYPTOBOX_MUMHASH: return mum_hash (data, len, seed); case RSPAMD_CRYPTOBOX_T1HA: return t1ha2_atonce (data, len, seed); case RSPAMD_CRYPTOBOX_HASHFAST_INDEPENDENT: return rspamd_cryptobox_fast_hash_indep (data, len, seed); case RSPAMD_CRYPTOBOX_HASHFAST: default: return rspamd_cryptobox_fast_hash_machdep (data, len, seed); } }