/* Copyright (c) 2001, Matej Pfajfar. * Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2017, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file crypto_digest.c * \brief Block of functions related with digest and xof utilities and * operations. **/ #include "crypto_digest.h" #include "crypto.h" /* common functions */ #include "crypto_rsa.h" DISABLE_GCC_WARNING(redundant-decls) #include ENABLE_GCC_WARNING(redundant-decls) #include "container.h" /* public key crypto digest functions */ /** Check a siglen-byte long signature at sig against * datalen bytes of data at data, using the public key * in env. Return 0 if sig is a correct signature for * SHA1(data). Else return -1. */ MOCK_IMPL(int, crypto_pk_public_checksig_digest,(crypto_pk_t *env, const char *data, size_t datalen, const char *sig, size_t siglen)) { char digest[DIGEST_LEN]; char *buf; size_t buflen; int r; tor_assert(env); tor_assert(data); tor_assert(sig); tor_assert(datalen < SIZE_T_CEILING); tor_assert(siglen < SIZE_T_CEILING); if (crypto_digest(digest,data,datalen)<0) { log_warn(LD_BUG, "couldn't compute digest"); return -1; } buflen = crypto_pk_keysize(env); buf = tor_malloc(buflen); r = crypto_pk_public_checksig(env,buf,buflen,sig,siglen); if (r != DIGEST_LEN) { log_warn(LD_CRYPTO, "Invalid signature"); tor_free(buf); return -1; } if (tor_memneq(buf, digest, DIGEST_LEN)) { log_warn(LD_CRYPTO, "Signature mismatched with digest."); tor_free(buf); return -1; } tor_free(buf); return 0; } /** Compute a SHA1 digest of fromlen bytes of data stored at * from; sign the data with the private key in env, and * store it in to. Return the number of bytes written on * success, and -1 on failure. * * tolen is the number of writable bytes in to, and must be * at least the length of the modulus of env. */ int crypto_pk_private_sign_digest(crypto_pk_t *env, char *to, size_t tolen, const char *from, size_t fromlen) { int r; char digest[DIGEST_LEN]; if (crypto_digest(digest,from,fromlen)<0) return -1; r = crypto_pk_private_sign(env,to,tolen,digest,DIGEST_LEN); memwipe(digest, 0, sizeof(digest)); return r; } /** Given a private or public key pk, put a SHA1 hash of the * public key into digest_out (must have DIGEST_LEN bytes of space). * Return 0 on success, -1 on failure. */ int crypto_pk_get_digest(const crypto_pk_t *pk, char *digest_out) { char *buf; size_t buflen; int len; int rv = -1; buflen = crypto_pk_keysize(pk)*2; buf = tor_malloc(buflen); len = crypto_pk_asn1_encode(pk, buf, buflen); if (len < 0) goto done; if (crypto_digest(digest_out, buf, len) < 0) goto done; rv = 0; done: tor_free(buf); return rv; } /** Compute all digests of the DER encoding of pk, and store them * in digests_out. Return 0 on success, -1 on failure. */ int crypto_pk_get_common_digests(crypto_pk_t *pk, common_digests_t *digests_out) { char *buf; size_t buflen; int len; int rv = -1; buflen = crypto_pk_keysize(pk)*2; buf = tor_malloc(buflen); len = crypto_pk_asn1_encode(pk, buf, buflen); if (len < 0) goto done; if (crypto_common_digests(digests_out, (char*)buf, len) < 0) goto done; rv = 0; done: tor_free(buf); return rv; } /* Crypto digest functions */ /** Compute the SHA1 digest of the len bytes on data stored in * m. Write the DIGEST_LEN byte result into digest. * Return 0 on success, -1 on failure. */ int crypto_digest(char *digest, const char *m, size_t len) { tor_assert(m); tor_assert(digest); if (SHA1((const unsigned char*)m,len,(unsigned char*)digest) == NULL) return -1; return 0; } /** Compute a 256-bit digest of len bytes in data stored in m, * using the algorithm algorithm. Write the DIGEST_LEN256-byte result * into digest. Return 0 on success, -1 on failure. */ int crypto_digest256(char *digest, const char *m, size_t len, digest_algorithm_t algorithm) { tor_assert(m); tor_assert(digest); tor_assert(algorithm == DIGEST_SHA256 || algorithm == DIGEST_SHA3_256); int ret = 0; if (algorithm == DIGEST_SHA256) ret = (SHA256((const uint8_t*)m,len,(uint8_t*)digest) != NULL); else ret = (sha3_256((uint8_t *)digest, DIGEST256_LEN,(const uint8_t *)m, len) > -1); if (!ret) return -1; return 0; } /** Compute a 512-bit digest of len bytes in data stored in m, * using the algorithm algorithm. Write the DIGEST_LEN512-byte result * into digest. Return 0 on success, -1 on failure. */ int crypto_digest512(char *digest, const char *m, size_t len, digest_algorithm_t algorithm) { tor_assert(m); tor_assert(digest); tor_assert(algorithm == DIGEST_SHA512 || algorithm == DIGEST_SHA3_512); int ret = 0; if (algorithm == DIGEST_SHA512) ret = (SHA512((const unsigned char*)m,len,(unsigned char*)digest) != NULL); else ret = (sha3_512((uint8_t*)digest, DIGEST512_LEN, (const uint8_t*)m, len) > -1); if (!ret) return -1; return 0; } /** Set the common_digests_t in ds_out to contain every digest on the * len bytes in m that we know how to compute. Return 0 on * success, -1 on failure. */ int crypto_common_digests(common_digests_t *ds_out, const char *m, size_t len) { tor_assert(ds_out); memset(ds_out, 0, sizeof(*ds_out)); if (crypto_digest(ds_out->d[DIGEST_SHA1], m, len) < 0) return -1; if (crypto_digest256(ds_out->d[DIGEST_SHA256], m, len, DIGEST_SHA256) < 0) return -1; return 0; } /** Return the name of an algorithm, as used in directory documents. */ const char * crypto_digest_algorithm_get_name(digest_algorithm_t alg) { switch (alg) { case DIGEST_SHA1: return "sha1"; case DIGEST_SHA256: return "sha256"; case DIGEST_SHA512: return "sha512"; case DIGEST_SHA3_256: return "sha3-256"; case DIGEST_SHA3_512: return "sha3-512"; // LCOV_EXCL_START default: tor_fragile_assert(); return "??unknown_digest??"; // LCOV_EXCL_STOP } } /** Given the name of a digest algorithm, return its integer value, or -1 if * the name is not recognized. */ int crypto_digest_algorithm_parse_name(const char *name) { if (!strcmp(name, "sha1")) return DIGEST_SHA1; else if (!strcmp(name, "sha256")) return DIGEST_SHA256; else if (!strcmp(name, "sha512")) return DIGEST_SHA512; else if (!strcmp(name, "sha3-256")) return DIGEST_SHA3_256; else if (!strcmp(name, "sha3-512")) return DIGEST_SHA3_512; else return -1; } /** Given an algorithm, return the digest length in bytes. */ size_t crypto_digest_algorithm_get_length(digest_algorithm_t alg) { switch (alg) { case DIGEST_SHA1: return DIGEST_LEN; case DIGEST_SHA256: return DIGEST256_LEN; case DIGEST_SHA512: return DIGEST512_LEN; case DIGEST_SHA3_256: return DIGEST256_LEN; case DIGEST_SHA3_512: return DIGEST512_LEN; default: tor_assert(0); // LCOV_EXCL_LINE return 0; /* Unreachable */ // LCOV_EXCL_LINE } } /** Intermediate information about the digest of a stream of data. */ struct crypto_digest_t { digest_algorithm_t algorithm; /**< Which algorithm is in use? */ /** State for the digest we're using. Only one member of the * union is usable, depending on the value of algorithm. Note also * that space for other members might not even be allocated! */ union { SHA_CTX sha1; /**< state for SHA1 */ SHA256_CTX sha2; /**< state for SHA256 */ SHA512_CTX sha512; /**< state for SHA512 */ keccak_state sha3; /**< state for SHA3-[256,512] */ } d; }; #ifdef TOR_UNIT_TESTS digest_algorithm_t crypto_digest_get_algorithm(crypto_digest_t *digest) { tor_assert(digest); return digest->algorithm; } #endif /* defined(TOR_UNIT_TESTS) */ /** * Return the number of bytes we need to malloc in order to get a * crypto_digest_t for alg, or the number of bytes we need to wipe * when we free one. */ static size_t crypto_digest_alloc_bytes(digest_algorithm_t alg) { /* Helper: returns the number of bytes in the 'f' field of 'st' */ #define STRUCT_FIELD_SIZE(st, f) (sizeof( ((st*)0)->f )) /* Gives the length of crypto_digest_t through the end of the field 'd' */ #define END_OF_FIELD(f) (offsetof(crypto_digest_t, f) + \ STRUCT_FIELD_SIZE(crypto_digest_t, f)) switch (alg) { case DIGEST_SHA1: return END_OF_FIELD(d.sha1); case DIGEST_SHA256: return END_OF_FIELD(d.sha2); case DIGEST_SHA512: return END_OF_FIELD(d.sha512); case DIGEST_SHA3_256: case DIGEST_SHA3_512: return END_OF_FIELD(d.sha3); default: tor_assert(0); // LCOV_EXCL_LINE return 0; // LCOV_EXCL_LINE } #undef END_OF_FIELD #undef STRUCT_FIELD_SIZE } /** * Internal function: create and return a new digest object for 'algorithm'. * Does not typecheck the algorithm. */ static crypto_digest_t * crypto_digest_new_internal(digest_algorithm_t algorithm) { crypto_digest_t *r = tor_malloc(crypto_digest_alloc_bytes(algorithm)); r->algorithm = algorithm; switch (algorithm) { case DIGEST_SHA1: SHA1_Init(&r->d.sha1); break; case DIGEST_SHA256: SHA256_Init(&r->d.sha2); break; case DIGEST_SHA512: SHA512_Init(&r->d.sha512); break; case DIGEST_SHA3_256: keccak_digest_init(&r->d.sha3, 256); break; case DIGEST_SHA3_512: keccak_digest_init(&r->d.sha3, 512); break; default: tor_assert_unreached(); } return r; } /** Allocate and return a new digest object to compute SHA1 digests. */ crypto_digest_t * crypto_digest_new(void) { return crypto_digest_new_internal(DIGEST_SHA1); } /** Allocate and return a new digest object to compute 256-bit digests * using algorithm. */ crypto_digest_t * crypto_digest256_new(digest_algorithm_t algorithm) { tor_assert(algorithm == DIGEST_SHA256 || algorithm == DIGEST_SHA3_256); return crypto_digest_new_internal(algorithm); } /** Allocate and return a new digest object to compute 512-bit digests * using algorithm. */ crypto_digest_t * crypto_digest512_new(digest_algorithm_t algorithm) { tor_assert(algorithm == DIGEST_SHA512 || algorithm == DIGEST_SHA3_512); return crypto_digest_new_internal(algorithm); } /** Deallocate a digest object. */ void crypto_digest_free_(crypto_digest_t *digest) { if (!digest) return; size_t bytes = crypto_digest_alloc_bytes(digest->algorithm); memwipe(digest, 0, bytes); tor_free(digest); } /** Add len bytes from data to the digest object. */ void crypto_digest_add_bytes(crypto_digest_t *digest, const char *data, size_t len) { tor_assert(digest); tor_assert(data); /* Using the SHA*_*() calls directly means we don't support doing * SHA in hardware. But so far the delay of getting the question * to the hardware, and hearing the answer, is likely higher than * just doing it ourselves. Hashes are fast. */ switch (digest->algorithm) { case DIGEST_SHA1: SHA1_Update(&digest->d.sha1, (void*)data, len); break; case DIGEST_SHA256: SHA256_Update(&digest->d.sha2, (void*)data, len); break; case DIGEST_SHA512: SHA512_Update(&digest->d.sha512, (void*)data, len); break; case DIGEST_SHA3_256: /* FALLSTHROUGH */ case DIGEST_SHA3_512: keccak_digest_update(&digest->d.sha3, (const uint8_t *)data, len); break; default: /* LCOV_EXCL_START */ tor_fragile_assert(); break; /* LCOV_EXCL_STOP */ } } /** Compute the hash of the data that has been passed to the digest * object; write the first out_len bytes of the result to out. * out_len must be \<= DIGEST512_LEN. */ void crypto_digest_get_digest(crypto_digest_t *digest, char *out, size_t out_len) { unsigned char r[DIGEST512_LEN]; crypto_digest_t tmpenv; tor_assert(digest); tor_assert(out); tor_assert(out_len <= crypto_digest_algorithm_get_length(digest->algorithm)); /* The SHA-3 code handles copying into a temporary ctx, and also can handle * short output buffers by truncating appropriately. */ if (digest->algorithm == DIGEST_SHA3_256 || digest->algorithm == DIGEST_SHA3_512) { keccak_digest_sum(&digest->d.sha3, (uint8_t *)out, out_len); return; } const size_t alloc_bytes = crypto_digest_alloc_bytes(digest->algorithm); /* memcpy into a temporary ctx, since SHA*_Final clears the context */ memcpy(&tmpenv, digest, alloc_bytes); switch (digest->algorithm) { case DIGEST_SHA1: SHA1_Final(r, &tmpenv.d.sha1); break; case DIGEST_SHA256: SHA256_Final(r, &tmpenv.d.sha2); break; case DIGEST_SHA512: SHA512_Final(r, &tmpenv.d.sha512); break; //LCOV_EXCL_START case DIGEST_SHA3_256: /* FALLSTHROUGH */ case DIGEST_SHA3_512: default: log_warn(LD_BUG, "Handling unexpected algorithm %d", digest->algorithm); /* This is fatal, because it should never happen. */ tor_assert_unreached(); break; //LCOV_EXCL_STOP } memcpy(out, r, out_len); memwipe(r, 0, sizeof(r)); } /** Allocate and return a new digest object with the same state as * digest */ crypto_digest_t * crypto_digest_dup(const crypto_digest_t *digest) { tor_assert(digest); const size_t alloc_bytes = crypto_digest_alloc_bytes(digest->algorithm); return tor_memdup(digest, alloc_bytes); } /** Replace the state of the digest object into with the state * of the digest object from. Requires that 'into' and 'from' * have the same digest type. */ void crypto_digest_assign(crypto_digest_t *into, const crypto_digest_t *from) { tor_assert(into); tor_assert(from); tor_assert(into->algorithm == from->algorithm); const size_t alloc_bytes = crypto_digest_alloc_bytes(from->algorithm); memcpy(into,from,alloc_bytes); } /** Given a list of strings in lst, set the len_out-byte digest * at digest_out to the hash of the concatenation of those strings, * plus the optional string append, computed with the algorithm * alg. * out_len must be \<= DIGEST512_LEN. */ void crypto_digest_smartlist(char *digest_out, size_t len_out, const smartlist_t *lst, const char *append, digest_algorithm_t alg) { crypto_digest_smartlist_prefix(digest_out, len_out, NULL, lst, append, alg); } /** Given a list of strings in lst, set the len_out-byte digest * at digest_out to the hash of the concatenation of: the * optional string prepend, those strings, * and the optional string append, computed with the algorithm * alg. * len_out must be \<= DIGEST512_LEN. */ void crypto_digest_smartlist_prefix(char *digest_out, size_t len_out, const char *prepend, const smartlist_t *lst, const char *append, digest_algorithm_t alg) { crypto_digest_t *d = crypto_digest_new_internal(alg); if (prepend) crypto_digest_add_bytes(d, prepend, strlen(prepend)); SMARTLIST_FOREACH(lst, const char *, cp, crypto_digest_add_bytes(d, cp, strlen(cp))); if (append) crypto_digest_add_bytes(d, append, strlen(append)); crypto_digest_get_digest(d, digest_out, len_out); crypto_digest_free(d); } /** Compute the HMAC-SHA-256 of the msg_len bytes in msg, using * the key of length key_len. Store the DIGEST256_LEN-byte * result in hmac_out. Asserts on failure. */ void crypto_hmac_sha256(char *hmac_out, const char *key, size_t key_len, const char *msg, size_t msg_len) { unsigned char *rv = NULL; /* If we've got OpenSSL >=0.9.8 we can use its hmac implementation. */ tor_assert(key_len < INT_MAX); tor_assert(msg_len < INT_MAX); tor_assert(hmac_out); rv = HMAC(EVP_sha256(), key, (int)key_len, (unsigned char*)msg, (int)msg_len, (unsigned char*)hmac_out, NULL); tor_assert(rv); } /** Compute a MAC using SHA3-256 of msg_len bytes in msg using a * key of length key_len and a salt of length * salt_len. Store the result of len_out bytes in in * mac_out. This function can't fail. */ void crypto_mac_sha3_256(uint8_t *mac_out, size_t len_out, const uint8_t *key, size_t key_len, const uint8_t *msg, size_t msg_len) { crypto_digest_t *digest; const uint64_t key_len_netorder = tor_htonll(key_len); tor_assert(mac_out); tor_assert(key); tor_assert(msg); digest = crypto_digest256_new(DIGEST_SHA3_256); /* Order matters here that is any subsystem using this function should * expect this very precise ordering in the MAC construction. */ crypto_digest_add_bytes(digest, (const char *) &key_len_netorder, sizeof(key_len_netorder)); crypto_digest_add_bytes(digest, (const char *) key, key_len); crypto_digest_add_bytes(digest, (const char *) msg, msg_len); crypto_digest_get_digest(digest, (char *) mac_out, len_out); crypto_digest_free(digest); }