/* 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_s2k.c * * \brief Functions for deriving keys from human-readable passphrases. */ #define CRYPTO_S2K_PRIVATE #include "compat.h" #include "crypto.h" #include "crypto_digest.h" #include "crypto_hkdf.h" #include "crypto_rand.h" #include "crypto_s2k.h" #include "crypto_util.h" #include "util.h" #include #if defined(HAVE_LIBSCRYPT_H) && defined(HAVE_LIBSCRYPT_SCRYPT) #define HAVE_SCRYPT #include #endif /* Encoded secrets take the form: u8 type; u8 salt_and_parameters[depends on type]; u8 key[depends on type]; As a special case, if the encoded secret is exactly 29 bytes long, type 0 is understood. Recognized types are: 00 -- RFC2440. salt_and_parameters is 9 bytes. key is 20 bytes. salt_and_parameters is 8 bytes random salt, 1 byte iteration info. 01 -- PKBDF2_SHA1. salt_and_parameters is 17 bytes. key is 20 bytes. salt_and_parameters is 16 bytes random salt, 1 byte iteration info. 02 -- SCRYPT_SALSA208_SHA256. salt_and_parameters is 18 bytes. key is 32 bytes. salt_and_parameters is 18 bytes random salt, 2 bytes iteration info. */ #define S2K_TYPE_RFC2440 0 #define S2K_TYPE_PBKDF2 1 #define S2K_TYPE_SCRYPT 2 #define PBKDF2_SPEC_LEN 17 #define PBKDF2_KEY_LEN 20 #define SCRYPT_SPEC_LEN 18 #define SCRYPT_KEY_LEN 32 /** Given an algorithm ID (one of S2K_TYPE_*), return the length of the * specifier part of it, without the prefix type byte. Return -1 if it is not * a valid algorithm ID. */ static int secret_to_key_spec_len(uint8_t type) { switch (type) { case S2K_TYPE_RFC2440: return S2K_RFC2440_SPECIFIER_LEN; case S2K_TYPE_PBKDF2: return PBKDF2_SPEC_LEN; case S2K_TYPE_SCRYPT: return SCRYPT_SPEC_LEN; default: return -1; } } /** Given an algorithm ID (one of S2K_TYPE_*), return the length of the * its preferred output. */ static int secret_to_key_key_len(uint8_t type) { switch (type) { case S2K_TYPE_RFC2440: return DIGEST_LEN; case S2K_TYPE_PBKDF2: return DIGEST_LEN; case S2K_TYPE_SCRYPT: return DIGEST256_LEN; // LCOV_EXCL_START default: tor_fragile_assert(); return -1; // LCOV_EXCL_STOP } } /** Given a specifier in spec_and_key of length * spec_and_key_len, along with its prefix algorithm ID byte, and along * with a key if key_included is true, check whether the whole * specifier-and-key is of valid length, and return the algorithm type if it * is. Set *legacy_out to 1 iff this is a legacy password hash or * legacy specifier. Return an error code on failure. */ static int secret_to_key_get_type(const uint8_t *spec_and_key, size_t spec_and_key_len, int key_included, int *legacy_out) { size_t legacy_len = S2K_RFC2440_SPECIFIER_LEN; uint8_t type; int total_len; if (key_included) legacy_len += DIGEST_LEN; if (spec_and_key_len == legacy_len) { *legacy_out = 1; return S2K_TYPE_RFC2440; } *legacy_out = 0; if (spec_and_key_len == 0) return S2K_BAD_LEN; type = spec_and_key[0]; total_len = secret_to_key_spec_len(type); if (total_len < 0) return S2K_BAD_ALGORITHM; if (key_included) { int keylen = secret_to_key_key_len(type); if (keylen < 0) return S2K_BAD_ALGORITHM; total_len += keylen; } if ((size_t)total_len + 1 == spec_and_key_len) return type; else return S2K_BAD_LEN; } /** * Write a new random s2k specifier of type type, without prefixing * type byte, to spec_out, which must have enough room. May adjust * parameter choice based on flags. */ static int make_specifier(uint8_t *spec_out, uint8_t type, unsigned flags) { int speclen = secret_to_key_spec_len(type); if (speclen < 0) return S2K_BAD_ALGORITHM; crypto_rand((char*)spec_out, speclen); switch (type) { case S2K_TYPE_RFC2440: /* Hash 64 k of data. */ spec_out[S2K_RFC2440_SPECIFIER_LEN-1] = 96; break; case S2K_TYPE_PBKDF2: /* 131 K iterations */ spec_out[PBKDF2_SPEC_LEN-1] = 17; break; case S2K_TYPE_SCRYPT: if (flags & S2K_FLAG_LOW_MEM) { /* N = 1<<12 */ spec_out[SCRYPT_SPEC_LEN-2] = 12; } else { /* N = 1<<15 */ spec_out[SCRYPT_SPEC_LEN-2] = 15; } /* r = 8; p = 2. */ spec_out[SCRYPT_SPEC_LEN-1] = (3u << 4) | (1u << 0); break; // LCOV_EXCL_START - we should have returned above. default: tor_fragile_assert(); return S2K_BAD_ALGORITHM; // LCOV_EXCL_STOP } return speclen; } /** Implement RFC2440-style iterated-salted S2K conversion: convert the * secret_len-byte secret into a key_out_len byte * key_out. As in RFC2440, the first 8 bytes of s2k_specifier * are a salt; the 9th byte describes how much iteration to do. * If key_out_len > DIGEST_LEN, use HDKF to expand the result. */ void secret_to_key_rfc2440(char *key_out, size_t key_out_len, const char *secret, size_t secret_len, const char *s2k_specifier) { crypto_digest_t *d; uint8_t c; size_t count, tmplen; char *tmp; uint8_t buf[DIGEST_LEN]; tor_assert(key_out_len < SIZE_T_CEILING); #define EXPBIAS 6 c = s2k_specifier[8]; count = ((uint32_t)16 + (c & 15)) << ((c >> 4) + EXPBIAS); #undef EXPBIAS d = crypto_digest_new(); tmplen = 8+secret_len; tmp = tor_malloc(tmplen); memcpy(tmp,s2k_specifier,8); memcpy(tmp+8,secret,secret_len); secret_len += 8; while (count) { if (count >= secret_len) { crypto_digest_add_bytes(d, tmp, secret_len); count -= secret_len; } else { crypto_digest_add_bytes(d, tmp, count); count = 0; } } crypto_digest_get_digest(d, (char*)buf, sizeof(buf)); if (key_out_len <= sizeof(buf)) { memcpy(key_out, buf, key_out_len); } else { crypto_expand_key_material_rfc5869_sha256(buf, DIGEST_LEN, (const uint8_t*)s2k_specifier, 8, (const uint8_t*)"EXPAND", 6, (uint8_t*)key_out, key_out_len); } memwipe(tmp, 0, tmplen); memwipe(buf, 0, sizeof(buf)); tor_free(tmp); crypto_digest_free(d); } /** * Helper: given a valid specifier without prefix type byte in spec, * whose length must be correct, and given a secret passphrase secret * of length secret_len, compute the key and store it into * key_out, which must have enough room for secret_to_key_key_len(type) * bytes. Return the number of bytes written on success and an error code * on failure. */ STATIC int secret_to_key_compute_key(uint8_t *key_out, size_t key_out_len, const uint8_t *spec, size_t spec_len, const char *secret, size_t secret_len, int type) { int rv; if (key_out_len > INT_MAX) return S2K_BAD_LEN; switch (type) { case S2K_TYPE_RFC2440: secret_to_key_rfc2440((char*)key_out, key_out_len, secret, secret_len, (const char*)spec); return (int)key_out_len; case S2K_TYPE_PBKDF2: { uint8_t log_iters; if (spec_len < 1 || secret_len > INT_MAX || spec_len > INT_MAX) return S2K_BAD_LEN; log_iters = spec[spec_len-1]; if (log_iters > 31) return S2K_BAD_PARAMS; rv = PKCS5_PBKDF2_HMAC_SHA1(secret, (int)secret_len, spec, (int)spec_len-1, (1<> 4; log_p = (spec[spec_len-1]) & 15; if (log_N > 63) return S2K_BAD_PARAMS; N = ((uint64_t)1) << log_N; r = 1u << log_r; p = 1u << log_p; rv = libscrypt_scrypt((const uint8_t*)secret, secret_len, spec, spec_len-2, N, r, p, key_out, key_out_len); if (rv != 0) return S2K_FAILED; return (int)key_out_len; #else /* !(defined(HAVE_SCRYPT)) */ return S2K_NO_SCRYPT_SUPPORT; #endif /* defined(HAVE_SCRYPT) */ } default: return S2K_BAD_ALGORITHM; } } /** * Given a specifier previously constructed with secret_to_key_make_specifier * in spec of length spec_len, and a secret password in * secret of length secret_len, generate key_out_len * bytes of cryptographic material in key_out. The native output of * the secret-to-key function will be truncated if key_out_len is short, and * expanded with HKDF if key_out_len is long. Returns S2K_OKAY on success, * and an error code on failure. */ int secret_to_key_derivekey(uint8_t *key_out, size_t key_out_len, const uint8_t *spec, size_t spec_len, const char *secret, size_t secret_len) { int legacy_format = 0; int type = secret_to_key_get_type(spec, spec_len, 0, &legacy_format); int r; if (type < 0) return type; #ifndef HAVE_SCRYPT if (type == S2K_TYPE_SCRYPT) return S2K_NO_SCRYPT_SUPPORT; #endif if (! legacy_format) { ++spec; --spec_len; } r = secret_to_key_compute_key(key_out, key_out_len, spec, spec_len, secret, secret_len, type); if (r < 0) return r; else return S2K_OKAY; } /** * Construct a new s2k algorithm specifier and salt in buf, according * to the bitwise-or of some S2K_FLAG_* options in flags. Up to * buf_len bytes of storage may be used in buf. Return the * number of bytes used on success and an error code on failure. */ int secret_to_key_make_specifier(uint8_t *buf, size_t buf_len, unsigned flags) { int rv; int spec_len; #ifdef HAVE_SCRYPT uint8_t type = S2K_TYPE_SCRYPT; #else uint8_t type = S2K_TYPE_RFC2440; #endif if (flags & S2K_FLAG_NO_SCRYPT) type = S2K_TYPE_RFC2440; if (flags & S2K_FLAG_USE_PBKDF2) type = S2K_TYPE_PBKDF2; spec_len = secret_to_key_spec_len(type); if ((int)buf_len < spec_len + 1) return S2K_TRUNCATED; buf[0] = type; rv = make_specifier(buf+1, type, flags); if (rv < 0) return rv; else return rv + 1; } /** * Hash a passphrase from secret of length secret_len, according * to the bitwise-or of some S2K_FLAG_* options in flags, and store the * hash along with salt and hashing parameters into buf. Up to * buf_len bytes of storage may be used in buf. Set * *len_out to the number of bytes used and return S2K_OKAY on success; * and return an error code on failure. */ int secret_to_key_new(uint8_t *buf, size_t buf_len, size_t *len_out, const char *secret, size_t secret_len, unsigned flags) { int key_len; int spec_len; int type; int rv; spec_len = secret_to_key_make_specifier(buf, buf_len, flags); if (spec_len < 0) return spec_len; type = buf[0]; key_len = secret_to_key_key_len(type); if (key_len < 0) return key_len; if ((int)buf_len < key_len + spec_len) return S2K_TRUNCATED; rv = secret_to_key_compute_key(buf + spec_len, key_len, buf + 1, spec_len-1, secret, secret_len, type); if (rv < 0) return rv; *len_out = spec_len + key_len; return S2K_OKAY; } /** * Given a hashed passphrase in spec_and_key of length * spec_and_key_len as generated by secret_to_key_new(), verify whether * it is a hash of the passphrase secret of length secret_len. * Return S2K_OKAY on a match, S2K_BAD_SECRET on a well-formed hash that * doesn't match this secret, and another error code on other errors. */ int secret_to_key_check(const uint8_t *spec_and_key, size_t spec_and_key_len, const char *secret, size_t secret_len) { int is_legacy = 0; int type = secret_to_key_get_type(spec_and_key, spec_and_key_len, 1, &is_legacy); uint8_t buf[32]; int spec_len; int key_len; int rv; if (type < 0) return type; if (! is_legacy) { spec_and_key++; spec_and_key_len--; } spec_len = secret_to_key_spec_len(type); key_len = secret_to_key_key_len(type); tor_assert(spec_len > 0); tor_assert(key_len > 0); tor_assert(key_len <= (int) sizeof(buf)); tor_assert((int)spec_and_key_len == spec_len + key_len); rv = secret_to_key_compute_key(buf, key_len, spec_and_key, spec_len, secret, secret_len, type); if (rv < 0) goto done; if (tor_memeq(buf, spec_and_key + spec_len, key_len)) rv = S2K_OKAY; else rv = S2K_BAD_SECRET; done: memwipe(buf, 0, sizeof(buf)); return rv; }