/* Copyright 2001,2002,2003 Roger Dingledine, Matej Pfajfar. */ /* See LICENSE for licensing information */ /* $Id$ */ /** * \file crypto.c * * \brief Low-level cryptographic functions. **/ #include "orconfig.h" #ifdef MS_WINDOWS #define WIN32_WINNT 0x400 #define _WIN32_WINNT 0x400 #define WIN32_LEAN_AND_MEAN #include #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_CTYPE_H #include #endif #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_FCNTL_H #include #endif #ifdef HAVE_SYS_FCNTL_H #include #endif #include "crypto.h" #include "log.h" #include "aes.h" #include "util.h" #if OPENSSL_VERSION_NUMBER < 0x00905000l #error "We require openssl >= 0.9.5" #elif OPENSSL_VERSION_NUMBER < 0x00906000l #define OPENSSL_095 #endif /* Certain functions that return a success code in OpenSSL 0.9.6 return void * (and don't indicate errors) in OpenSSL version 0.9.5. * * [OpenSSL 0.9.5 matters, because it ships with Redhat 6.2.] */ #ifdef OPENSSL_095 #define RETURN_SSL_OUTCOME(exp) (exp); return 0 #else #define RETURN_SSL_OUTCOME(exp) return !(exp) #endif /** Macro: is k a valid RSA public or private key? */ #define PUBLIC_KEY_OK(k) ((k) && (k)->key && (k)->key->n) /** Macro: is k a valid RSA private key? */ #define PRIVATE_KEY_OK(k) ((k) && (k)->key && (k)->key->p) struct crypto_pk_env_t { int refs; /* reference counting so we don't have to copy keys */ RSA *key; }; struct crypto_cipher_env_t { unsigned char key[CIPHER_KEY_LEN]; aes_cnt_cipher_t *cipher; }; struct crypto_dh_env_t { DH *dh; }; /** Return the number of bytes added by padding method padding. */ static INLINE int crypto_get_rsa_padding_overhead(int padding) { switch(padding) { case RSA_NO_PADDING: return 0; case RSA_PKCS1_OAEP_PADDING: return 42; case RSA_PKCS1_PADDING: return 11; default: tor_assert(0); return -1; } } /** Given a padding method padding, return the correct OpenSSL constant. */ static INLINE int crypto_get_rsa_padding(int padding) { switch(padding) { case PK_NO_PADDING: return RSA_NO_PADDING; case PK_PKCS1_PADDING: return RSA_PKCS1_PADDING; case PK_PKCS1_OAEP_PADDING: return RSA_PKCS1_OAEP_PADDING; default: tor_assert(0); return -1; } } /** Boolean: has OpenSSL's crypto been initialized? */ static int _crypto_global_initialized = 0; /** Log all pending crypto errors at level severity. Use * doing to describe our current activities. */ static void crypto_log_errors(int severity, const char *doing) { int err; const char *msg, *lib, *func; while ((err = ERR_get_error()) != 0) { msg = (const char*)ERR_reason_error_string(err); lib = (const char*)ERR_lib_error_string(err); func = (const char*)ERR_func_error_string(err); if (!msg) msg = "(null)"; if (doing) { log(severity, "crypto error while %s: %s (in %s:%s)", doing, msg, lib,func); } else { log(severity, "crypto error: %s (in %s:%s)", msg, lib, func); } } } /** Initialize the crypto library. */ int crypto_global_init() { if (!_crypto_global_initialized) { ERR_load_crypto_strings(); _crypto_global_initialized = 1; } return 0; } /** Uninitialize the crypto library. */ int crypto_global_cleanup() { ERR_free_strings(); return 0; } /** used by tortls.c: wrap an RSA* in a crypto_pk_env_t. */ crypto_pk_env_t *_crypto_new_pk_env_rsa(RSA *rsa) { crypto_pk_env_t *env; tor_assert(rsa); env = tor_malloc(sizeof(crypto_pk_env_t)); env->refs = 1; env->key = rsa; return env; } /** used by tortls.c: return the RSA* from a crypto_pk_env_t. */ RSA *_crypto_pk_env_get_rsa(crypto_pk_env_t *env) { return env->key; } /** used by tortls.c: get an equivalent EVP_PKEY* for a crypto_pk_env_t. Iff * private is set, include the private-key portion of the key. */ EVP_PKEY *_crypto_pk_env_get_evp_pkey(crypto_pk_env_t *env, int private) { RSA *key = NULL; EVP_PKEY *pkey = NULL; tor_assert(env->key); if (private) { if (!(key = RSAPrivateKey_dup(env->key))) goto error; } else { if (!(key = RSAPublicKey_dup(env->key))) goto error; } if (!(pkey = EVP_PKEY_new())) goto error; if (!(EVP_PKEY_assign_RSA(pkey, key))) goto error; return pkey; error: if (pkey) EVP_PKEY_free(pkey); if (key) RSA_free(key); return NULL; } /** Used by tortls.c: Get the DH* from a crypto_dh_env_t. */ DH *_crypto_dh_env_get_dh(crypto_dh_env_t *dh) { return dh->dh; } /** Allocate and return storage for a public key. The key itself will not yet * be set. */ crypto_pk_env_t *crypto_new_pk_env(void) { RSA *rsa; rsa = RSA_new(); if (!rsa) return NULL; return _crypto_new_pk_env_rsa(rsa); } /** Release a reference to an asymmetric key; when all the references * are released, free the key. */ void crypto_free_pk_env(crypto_pk_env_t *env) { tor_assert(env); if(--env->refs > 0) return; if (env->key) RSA_free(env->key); free(env); } /** Create a new symmetric cipher for a given key and encryption flag * (1=encrypt, 0=decrypt). Return the crypto object on success; NULL * on failure. */ crypto_cipher_env_t * crypto_create_init_cipher(const char *key, int encrypt_mode) { int r; crypto_cipher_env_t *crypto = NULL; if (! (crypto = crypto_new_cipher_env())) { log_fn(LOG_WARN, "Unable to allocate crypto object"); return NULL; } if (crypto_cipher_set_key(crypto, key)) { crypto_log_errors(LOG_WARN, "setting symmetric key"); goto error; } if (encrypt_mode) r = crypto_cipher_encrypt_init_cipher(crypto); else r = crypto_cipher_decrypt_init_cipher(crypto); if (r) goto error; return crypto; error: if (crypto) crypto_free_cipher_env(crypto); return NULL; } /** Allocate and return a new symmetric cipher. */ crypto_cipher_env_t *crypto_new_cipher_env() { crypto_cipher_env_t *env; env = tor_malloc_zero(sizeof(crypto_cipher_env_t)); env->cipher = aes_new_cipher(); return env; } /** Free a symmetric cipher. */ void crypto_free_cipher_env(crypto_cipher_env_t *env) { tor_assert(env); tor_assert(env->cipher); aes_free_cipher(env->cipher); tor_free(env); } /* public key crypto */ /** Generate a new public/private keypair in env. Return 0 on * success, -1 on failure. */ int crypto_pk_generate_key(crypto_pk_env_t *env) { tor_assert(env); if (env->key) RSA_free(env->key); env->key = RSA_generate_key(PK_BYTES*8,65537, NULL, NULL); if (!env->key) { crypto_log_errors(LOG_WARN, "generating RSA key"); return -1; } return 0; } /** Read a PEM-encoded private key from src into env. */ static int crypto_pk_read_private_key_from_file(crypto_pk_env_t *env, FILE *src) { tor_assert(env && src); if (env->key) RSA_free(env->key); env->key = PEM_read_RSAPrivateKey(src, NULL, NULL, NULL); if (!env->key) { crypto_log_errors(LOG_WARN, "reading private key from file"); return -1; } return 0; } /** Read a PEM-encoded private key from the file named by * keyfile into env. Return 0 on success, -1 on failure. */ int crypto_pk_read_private_key_from_filename(crypto_pk_env_t *env, const char *keyfile) { FILE *f_pr; tor_assert(env && keyfile); /* open the keyfile */ f_pr=fopen(keyfile,"r"); if (!f_pr) return -1; /* read the private key */ if(crypto_pk_read_private_key_from_file(env, f_pr) < 0) { fclose(f_pr); return -1; } fclose(f_pr); /* check the private key */ if (crypto_pk_check_key(env) <= 0) return -1; return 0; } /** PEM-encode the public key portion of env and write it to a * newly allocated string. On success, set *dest to the new * string, *len to the string's length, and return 0. On * failure, return -1. */ int crypto_pk_write_public_key_to_string(crypto_pk_env_t *env, char **dest, int *len) { BUF_MEM *buf; BIO *b; tor_assert(env && env->key && dest); b = BIO_new(BIO_s_mem()); /* Create a memory BIO */ /* Now you can treat b as if it were a file. Just use the * PEM_*_bio_* functions instead of the non-bio variants. */ if(!PEM_write_bio_RSAPublicKey(b, env->key)) { crypto_log_errors(LOG_WARN, "writing public key to string"); return -1; } BIO_get_mem_ptr(b, &buf); BIO_set_close(b, BIO_NOCLOSE); /* so BIO_free doesn't free buf */ BIO_free(b); *dest = tor_malloc(buf->length+1); memcpy(*dest, buf->data, buf->length); (*dest)[buf->length] = 0; /* null terminate it */ *len = buf->length; BUF_MEM_free(buf); return 0; } /** Read a PEM-encoded public key from the first len characters of * src, and store the result in env. Return 0 on success, -1 on * failure. */ int crypto_pk_read_public_key_from_string(crypto_pk_env_t *env, const char *src, int len) { BIO *b; tor_assert(env && src); b = BIO_new(BIO_s_mem()); /* Create a memory BIO */ BIO_write(b, src, len); if (env->key) RSA_free(env->key); env->key = PEM_read_bio_RSAPublicKey(b, NULL, NULL, NULL); BIO_free(b); if(!env->key) { crypto_log_errors(LOG_WARN, "reading public key from string"); return -1; } return 0; } /* Write the private key from 'env' into the file named by 'fname', * PEM-encoded. Return 0 on success, -1 on failure. */ int crypto_pk_write_private_key_to_filename(crypto_pk_env_t *env, const char *fname) { BIO *bio; char *cp; long len; char *s; int r; tor_assert(PRIVATE_KEY_OK(env)); if (!(bio = BIO_new(BIO_s_mem()))) return -1; if (PEM_write_bio_RSAPrivateKey(bio, env->key, NULL,NULL,0,NULL,NULL) == 0) { crypto_log_errors(LOG_WARN, "writing private key"); BIO_free(bio); return -1; } len = BIO_get_mem_data(bio, &cp); s = tor_malloc(len+1); strncpy(s, cp, len); s[len] = '\0'; r = write_str_to_file(fname, s, 0); BIO_free(bio); free(s); return r; } /** Return true iff env has a valid key. */ int crypto_pk_check_key(crypto_pk_env_t *env) { int r; tor_assert(env); r = RSA_check_key(env->key); if (r <= 0) crypto_log_errors(LOG_WARN,"checking RSA key"); return r; } /** Compare the public-key components of a and b. Return -1 if a\b. */ int crypto_pk_cmp_keys(crypto_pk_env_t *a, crypto_pk_env_t *b) { int result; if (!a || !b) return -1; if (!a->key || !b->key) return -1; tor_assert(PUBLIC_KEY_OK(a)); tor_assert(PUBLIC_KEY_OK(b)); result = BN_cmp((a->key)->n, (b->key)->n); if (result) return result; return BN_cmp((a->key)->e, (b->key)->e); } /** Return the size of the public key modulus in env, in bytes. */ int crypto_pk_keysize(crypto_pk_env_t *env) { tor_assert(env && env->key); return RSA_size(env->key); } /** Increase the reference count of env. */ crypto_pk_env_t *crypto_pk_dup_key(crypto_pk_env_t *env) { tor_assert(env && env->key); env->refs++; return env; } /** Encrypt fromlen bytes from from with the public key * in env, using the padding method padding. On success, * write the result to to, and return the number of bytes * written. On failure, return -1. */ int crypto_pk_public_encrypt(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to, int padding) { int r; tor_assert(env && from && to); r = RSA_public_encrypt(fromlen, (unsigned char*)from, to, env->key, crypto_get_rsa_padding(padding)); if (r<0) { crypto_log_errors(LOG_WARN, "performing RSA encryption"); return -1; } return r; } /** Decrypt fromlen bytes from from with the private key * in env, using the padding method padding. On success, * write the result to to, and return the number of bytes * written. On failure, return -1. */ int crypto_pk_private_decrypt(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to, int padding, int warnOnFailure) { int r; tor_assert(env && from && to && env->key); if (!env->key->p) /* Not a private key */ return -1; r = RSA_private_decrypt(fromlen, (unsigned char*)from, to, env->key, crypto_get_rsa_padding(padding)); if (r<0) { crypto_log_errors(warnOnFailure?LOG_WARN:LOG_INFO, "performing RSA decryption"); return -1; } return r; } /** Check the signature in from (fromlen bytes long) with the * public key in env, using PKCS1 padding. On success, write the * signed data to to, and return the number of bytes written. * On failure, return -1. */ int crypto_pk_public_checksig(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to) { int r; tor_assert(env && from && to); r = RSA_public_decrypt(fromlen, (unsigned char*)from, to, env->key, RSA_PKCS1_PADDING); if (r<0) { crypto_log_errors(LOG_WARN, "checking RSA signature"); return -1; } return r; } /** Sign fromlen bytes of data from from with the private key in * env, using PKCS1 padding. On success, write the signature to * to, and return the number of bytes written. On failure, return * -1. */ int crypto_pk_private_sign(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to) { int r; tor_assert(env && from && to); if (!env->key->p) /* Not a private key */ return -1; r = RSA_private_encrypt(fromlen, (unsigned char*)from, to, env->key, RSA_PKCS1_PADDING); if (r<0) { crypto_log_errors(LOG_WARN, "generating RSA signature"); return -1; } return r; } /** 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. */ int crypto_pk_public_checksig_digest(crypto_pk_env_t *env, const unsigned char *data, int datalen, const unsigned char *sig, int siglen) { char digest[DIGEST_LEN]; char buf[PK_BYTES+1]; int r; tor_assert(env && data && sig); if (crypto_digest(data,datalen,digest)<0) { log_fn(LOG_WARN, "couldn't compute digest"); return -1; } r = crypto_pk_public_checksig(env,sig,siglen,buf); if (r != DIGEST_LEN) { log_fn(LOG_WARN, "Invalid signature"); return -1; } if (memcmp(buf, digest, DIGEST_LEN)) { log_fn(LOG_WARN, "Signature mismatched with digest."); return -1; } 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. */ int crypto_pk_private_sign_digest(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to) { char digest[DIGEST_LEN]; if (crypto_digest(from,fromlen,digest)<0) return -1; return crypto_pk_private_sign(env,digest,DIGEST_LEN,to); } /** Perform a hybrid (public/secret) encryption on fromlen * bytes of data from from, with padding type 'padding', * storing the results on to. * * If no padding is used, the public key must be at least as large as * from. * * Returns the number of bytes written on success, -1 on failure. * * The encrypted data consists of: * - The source data, padded and encrypted with the public key, if the * padded source data is no longer than the public key, and force * is false, OR * - The beginning of the source data prefixed with a 16-byte symmetric key, * padded and encrypted with the public key; followed by the rest of * the source data encrypted in AES-CTR mode with the symmetric key. */ int crypto_pk_public_hybrid_encrypt(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to, int padding, int force) { int overhead, pkeylen, outlen, r, symlen; crypto_cipher_env_t *cipher = NULL; char buf[PK_BYTES+1]; tor_assert(env && from && to); overhead = crypto_get_rsa_padding_overhead(crypto_get_rsa_padding(padding)); pkeylen = crypto_pk_keysize(env); if (padding == PK_NO_PADDING && fromlen < pkeylen) return -1; if (!force && fromlen+overhead <= pkeylen) { /* It all fits in a single encrypt. */ return crypto_pk_public_encrypt(env,from,fromlen,to,padding); } cipher = crypto_new_cipher_env(); if (!cipher) return -1; if (crypto_cipher_generate_key(cipher)<0) goto err; /* You can't just run around RSA-encrypting any bitstream: if it's * greater than the RSA key, then OpenSSL will happily encrypt, and * later decrypt to the wrong value. So we set the first bit of * 'cipher->key' to 0 if we aren't padding. This means that our * symmetric key is really only 127 bits. */ if (padding == PK_NO_PADDING) cipher->key[0] &= 0x7f; if (crypto_cipher_encrypt_init_cipher(cipher)<0) goto err; memcpy(buf, cipher->key, CIPHER_KEY_LEN); memcpy(buf+CIPHER_KEY_LEN, from, pkeylen-overhead-CIPHER_KEY_LEN); /* Length of symmetrically encrypted data. */ symlen = fromlen-(pkeylen-overhead-CIPHER_KEY_LEN); outlen = crypto_pk_public_encrypt(env,buf,pkeylen-overhead,to,padding); if (outlen!=pkeylen) { goto err; } r = crypto_cipher_encrypt(cipher, from+pkeylen-overhead-CIPHER_KEY_LEN, symlen, to+outlen); if (r<0) goto err; memset(buf, 0, sizeof(buf)); crypto_free_cipher_env(cipher); return outlen + symlen; err: memset(buf, 0, sizeof(buf)); if (cipher) crypto_free_cipher_env(cipher); return -1; } /** Invert crypto_pk_public_hybrid_encrypt. */ int crypto_pk_private_hybrid_decrypt(crypto_pk_env_t *env, const unsigned char *from, int fromlen, unsigned char *to, int padding, int warnOnFailure) { int overhead, pkeylen, outlen, r; crypto_cipher_env_t *cipher = NULL; char buf[PK_BYTES+1]; overhead = crypto_get_rsa_padding_overhead(crypto_get_rsa_padding(padding)); pkeylen = crypto_pk_keysize(env); if (fromlen <= pkeylen) { return crypto_pk_private_decrypt(env,from,fromlen,to,padding,warnOnFailure); } outlen = crypto_pk_private_decrypt(env,from,pkeylen,buf,padding,warnOnFailure); if (outlen<0) { log_fn(warnOnFailure?LOG_WARN:LOG_INFO, "Error decrypting public-key data"); return -1; } if (outlen < CIPHER_KEY_LEN) { log_fn(warnOnFailure?LOG_WARN:LOG_INFO, "No room for a symmetric key"); return -1; } cipher = crypto_create_init_cipher(buf, 0); if (!cipher) { return -1; } memcpy(to,buf+CIPHER_KEY_LEN,outlen-CIPHER_KEY_LEN); outlen -= CIPHER_KEY_LEN; r = crypto_cipher_decrypt(cipher, from+pkeylen, fromlen-pkeylen, to+outlen); if (r<0) goto err; memset(buf,0,sizeof(buf)); crypto_free_cipher_env(cipher); return outlen + (fromlen-pkeylen); err: memset(buf,0,sizeof(buf)); if (cipher) crypto_free_cipher_env(cipher); return -1; } /** ASN.1-encode the public portion of pk into dest. * Return -1 on error, or the number of characters used on success. */ int crypto_pk_asn1_encode(crypto_pk_env_t *pk, char *dest, int dest_len) { int len; unsigned char *buf, *cp; len = i2d_RSAPublicKey(pk->key, NULL); if (len < 0 || len > dest_len) return -1; cp = buf = tor_malloc(len+1); len = i2d_RSAPublicKey(pk->key, &cp); if (len < 0) { crypto_log_errors(LOG_WARN,"encoding public key"); tor_free(buf); return -1; } /* We don't encode directly into 'dest', because that would be illegal * type-punning. (C99 is smarter than me, C99 is smarter than me...) */ memcpy(dest,buf,len); tor_free(buf); return len; } /** Decode an ASN.1-encoded public key from str; return the result on * success and NULL on failure. */ crypto_pk_env_t *crypto_pk_asn1_decode(const char *str, int len) { RSA *rsa; unsigned char *buf; /* This ifdef suppresses a type warning. Take out the first case once * everybody is using openssl 0.9.7 or later. */ #if OPENSSL_VERSION_NUMBER < 0x00907000l unsigned char *cp; #else const unsigned char *cp; #endif cp = buf = tor_malloc(len); memcpy(buf,str,len); rsa = d2i_RSAPublicKey(NULL, &cp, len); tor_free(buf); if (!rsa) { crypto_log_errors(LOG_WARN,"decoding public key"); return NULL; } return _crypto_new_pk_env_rsa(rsa); } /** 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). */ int crypto_pk_get_digest(crypto_pk_env_t *pk, char *digest_out) { unsigned char *buf, *bufp; int len; len = i2d_RSAPublicKey(pk->key, NULL); if (len < 0) return -1; buf = bufp = tor_malloc(len+1); len = i2d_RSAPublicKey(pk->key, &bufp); if (len < 0) { crypto_log_errors(LOG_WARN,"encoding public key"); free(buf); return -1; } if (crypto_digest(buf, len, digest_out) < 0) { free(buf); return -1; } free(buf); return 0; } /** Given a private or public key pk, put a fingerprint of the * public key into fp_out (must have at least FINGERPRINT_LEN+1 bytes of * space). * * Fingerprints are computed as the SHA1 digest of the ASN.1 encoding * of the public key, converted to hexadecimal, in upper case, with a * space after every four digits. */ int crypto_pk_get_fingerprint(crypto_pk_env_t *pk, char *fp_out) { unsigned char *bufp; unsigned char digest[DIGEST_LEN]; unsigned char buf[FINGERPRINT_LEN+1]; int i; if (crypto_pk_get_digest(pk, digest)) { return -1; } bufp = buf; for (i = 0; i < DIGEST_LEN; ++i) { sprintf(bufp,"%02X",digest[i]); bufp += 2; if (i%2 && i != 19) { *bufp++ = ' '; } } *bufp = '\0'; tor_assert(strlen(buf) == FINGERPRINT_LEN); tor_assert(crypto_pk_check_fingerprint_syntax(buf)); strcpy(fp_out, buf); return 0; } /** Return true iff s is in the correct format for a fingerprint. */ int crypto_pk_check_fingerprint_syntax(const char *s) { int i; for (i = 0; i < FINGERPRINT_LEN; ++i) { if ((i%5) == 4) { if (!isspace((int)s[i])) return 0; } else { if (!isxdigit((int)s[i])) return 0; } } if (s[FINGERPRINT_LEN]) return 0; return 1; } /* symmetric crypto */ /** Generate a new random key for the symmetric cipher in env. * Return 0 on success, -1 on failure. Does not initialize the cipher. */ int crypto_cipher_generate_key(crypto_cipher_env_t *env) { tor_assert(env); return crypto_rand(CIPHER_KEY_LEN, env->key); } /** Set the symmetric key for the cipher in env to the first * CIPHER_KEY_LEN bytes of key. Does not initialize the cipher. */ int crypto_cipher_set_key(crypto_cipher_env_t *env, const unsigned char *key) { tor_assert(env && key); if (!env->key) return -1; memcpy(env->key, key, CIPHER_KEY_LEN); return 0; } /** Return a pointer to the key set for the cipher in env. */ const unsigned char *crypto_cipher_get_key(crypto_cipher_env_t *env) { return env->key; } /** Initialize the cipher in env for encryption. */ int crypto_cipher_encrypt_init_cipher(crypto_cipher_env_t *env) { tor_assert(env); aes_set_key(env->cipher, env->key, CIPHER_KEY_LEN*8); return 0; } /** Initialize the cipher in env for decryption. */ int crypto_cipher_decrypt_init_cipher(crypto_cipher_env_t *env) { tor_assert(env); aes_set_key(env->cipher, env->key, CIPHER_KEY_LEN*8); return 0; } /** Encrypt fromlen bytes from from using the cipher * env; on success, store the result to to and return 0. * On failure, return -1. */ int crypto_cipher_encrypt(crypto_cipher_env_t *env, const unsigned char *from, unsigned int fromlen, unsigned char *to) { tor_assert(env && env->cipher && from && fromlen && to); aes_crypt(env->cipher, from, fromlen, to); return 0; } /** Decrypt fromlen bytes from from using the cipher * env; on success, store the result to to and return 0. * On failure, return -1. */ int crypto_cipher_decrypt(crypto_cipher_env_t *env, const unsigned char *from, unsigned int fromlen, unsigned char *to) { tor_assert(env && from && to); aes_crypt(env->cipher, from, fromlen, to); return 0; } /** Move the position of the cipher stream backwards by delta bytes. */ int crypto_cipher_rewind(crypto_cipher_env_t *env, long delta) { return crypto_cipher_advance(env, -delta); } /** Move the position of the cipher stream forwards by delta bytes. */ int crypto_cipher_advance(crypto_cipher_env_t *env, long delta) { aes_adjust_counter(env->cipher, delta); return 0; } /* SHA-1 */ /** Compute the SHA1 digest of len bytes in data stored in * m. Write the DIGEST_LEN byte result into digest. */ int crypto_digest(const unsigned char *m, int len, unsigned char *digest) { tor_assert(m && digest); return (SHA1(m,len,digest) == NULL); } struct crypto_digest_env_t { SHA_CTX d; }; /** Allocate and return a new digest object. */ crypto_digest_env_t * crypto_new_digest_env(void) { crypto_digest_env_t *r; r = tor_malloc(sizeof(crypto_digest_env_t)); SHA1_Init(&r->d); return r; } /** Deallocate a digest object. */ void crypto_free_digest_env(crypto_digest_env_t *digest) { tor_free(digest); } /** Add len bytes from data to the digest object. */ void crypto_digest_add_bytes(crypto_digest_env_t *digest, const char *data, size_t len) { tor_assert(digest); tor_assert(data); /* Using the SHA1_*() calls directly means we don't support doing * sha1 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. */ SHA1_Update(&digest->d, (void*)data, len); } /** 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 \<= DIGEST_LEN. */ void crypto_digest_get_digest(crypto_digest_env_t *digest, char *out, size_t out_len) { static char r[DIGEST_LEN]; SHA_CTX tmpctx; tor_assert(digest && out); tor_assert(out_len <= DIGEST_LEN); /* memcpy into a temporary ctx, since SHA1_Final clears the context */ memcpy(&tmpctx, &digest->d, sizeof(SHA_CTX)); SHA1_Final(r, &tmpctx); memcpy(out, r, out_len); } /** Allocate and return a new digest object with the same state as * digest */ crypto_digest_env_t * crypto_digest_dup(const crypto_digest_env_t *digest) { crypto_digest_env_t *r; tor_assert(digest); r = tor_malloc(sizeof(crypto_digest_env_t)); memcpy(r,digest,sizeof(crypto_digest_env_t)); return r; } /** Replace the state of the digest object into with the state * of the digest object from. */ void crypto_digest_assign(crypto_digest_env_t *into, const crypto_digest_env_t *from) { tor_assert(into && from); memcpy(into,from,sizeof(crypto_digest_env_t)); } /* DH */ /** Shared P parameter for our DH key exchanged. */ static BIGNUM *dh_param_p = NULL; /** Shared G parameter for our DH key exchanges. */ static BIGNUM *dh_param_g = NULL; /** Initialize dh_param_p and dh_param_g if they are not already * set. */ static void init_dh_param() { BIGNUM *p, *g; int r; if (dh_param_p && dh_param_g) return; p = BN_new(); g = BN_new(); tor_assert(p && g); #if 0 /* This is from draft-ietf-ipsec-ike-modp-groups-05.txt. It's a safe prime, and supposedly it equals: 2^1536 - 2^1472 - 1 + 2^64 * { [2^1406 pi] + 741804 } */ r = BN_hex2bn(&p, "FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD1" "29024E088A67CC74020BBEA63B139B22514A08798E3404DD" "EF9519B3CD3A431B302B0A6DF25F14374FE1356D6D51C245" "E485B576625E7EC6F44C42E9A637ED6B0BFF5CB6F406B7ED" "EE386BFB5A899FA5AE9F24117C4B1FE649286651ECE45B3D" "C2007CB8A163BF0598DA48361C55D39A69163FA8FD24CF5F" "83655D23DCA3AD961C62F356208552BB9ED529077096966D" "670C354E4ABC9804F1746C08CA237327FFFFFFFFFFFFFFFF"); #endif /* This is from rfc2409, section 6.2. It's a safe prime, and supposedly it equals: 2^1024 - 2^960 - 1 + 2^64 * { [2^894 pi] + 129093 }. */ /* See also rfc 3536 */ r = BN_hex2bn(&p, "FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E08" "8A67CC74020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B" "302B0A6DF25F14374FE1356D6D51C245E485B576625E7EC6F44C42E9" "A637ED6B0BFF5CB6F406B7EDEE386BFB5A899FA5AE9F24117C4B1FE6" "49286651ECE65381FFFFFFFFFFFFFFFF"); tor_assert(r); r = BN_set_word(g, 2); tor_assert(r); dh_param_p = p; dh_param_g = g; } /** Allocate and return a new DH object for a key echange. */ crypto_dh_env_t *crypto_dh_new() { crypto_dh_env_t *res = NULL; if (!dh_param_p) init_dh_param(); res = tor_malloc(sizeof(crypto_dh_env_t)); res->dh = NULL; if (!(res->dh = DH_new())) goto err; if (!(res->dh->p = BN_dup(dh_param_p))) goto err; if (!(res->dh->g = BN_dup(dh_param_g))) goto err; return res; err: crypto_log_errors(LOG_WARN, "creating DH object"); if (res && res->dh) DH_free(res->dh); /* frees p and g too */ if (res) free(res); return NULL; } /** Return the length of the DH key in dh, in bytes. */ int crypto_dh_get_bytes(crypto_dh_env_t *dh) { tor_assert(dh); return DH_size(dh->dh); } /** Generate \ for our part of the key exchange. Return 0 on * success, -1 on failure. */ int crypto_dh_generate_public(crypto_dh_env_t *dh) { if (!DH_generate_key(dh->dh)) { crypto_log_errors(LOG_WARN, "generating DH key"); return -1; } return 0; } /** Generate g^x as necessary, and write the g^x for the key exchange * as a pubkey_len-byte value into pubkey. Return 0 on * success, -1 on failure. pubkey_len must be \>= DH_BYTES. */ int crypto_dh_get_public(crypto_dh_env_t *dh, char *pubkey, int pubkey_len) { int bytes; tor_assert(dh); if (!dh->dh->pub_key) { if (crypto_dh_generate_public(dh)<0) return -1; } tor_assert(dh->dh->pub_key); bytes = BN_num_bytes(dh->dh->pub_key); if (pubkey_len < bytes) return -1; memset(pubkey, 0, pubkey_len); BN_bn2bin(dh->dh->pub_key, pubkey+(pubkey_len-bytes)); return 0; } #undef MIN #define MIN(a,b) ((a)<(b)?(a):(b)) /** Given a DH key exchange object, and our peer's value of g^y (as a * pubkey_len byte value in pubkey) generate * secret_bytes_out bytes of shared key material and write them * to secret_out. * * (We generate key material by computing * SHA1( g^xy || "\x00" ) || SHA1( g^xy || "\x01" ) || ... * where || is concatenation.) */ int crypto_dh_compute_secret(crypto_dh_env_t *dh, const char *pubkey, int pubkey_len, char *secret_out, int secret_bytes_out) { unsigned char hash[DIGEST_LEN]; unsigned char *secret_tmp = NULL; BIGNUM *pubkey_bn = NULL; int secret_len; int i; tor_assert(dh); tor_assert(secret_bytes_out/DIGEST_LEN <= 255); if (!(pubkey_bn = BN_bin2bn(pubkey, pubkey_len, NULL))) goto error; secret_tmp = tor_malloc(crypto_dh_get_bytes(dh)+1); secret_len = DH_compute_key(secret_tmp, pubkey_bn, dh->dh); /* sometimes secret_len might be less than 128, e.g., 127. that's ok. */ for (i = 0; i < secret_bytes_out; i += DIGEST_LEN) { secret_tmp[secret_len] = (unsigned char) i/DIGEST_LEN; if (crypto_digest(secret_tmp, secret_len+1, hash)) goto error; memcpy(secret_out+i, hash, MIN(DIGEST_LEN, secret_bytes_out-i)); } secret_len = secret_bytes_out; goto done; error: secret_len = -1; done: crypto_log_errors(LOG_WARN, "completing DH handshake"); if (pubkey_bn) BN_free(pubkey_bn); tor_free(secret_tmp); return secret_len; } /** Free a DH key exchange object. */ void crypto_dh_free(crypto_dh_env_t *dh) { tor_assert(dh && dh->dh); DH_free(dh->dh); free(dh); } /* random numbers */ /** Seed OpenSSL's random number generator with DIGEST_LEN bytes from the * operating system. */ int crypto_seed_rng() { #ifdef MS_WINDOWS static int provider_set = 0; static HCRYPTPROV provider; char buf[DIGEST_LEN+1]; if (!provider_set) { if (!CryptAcquireContext(&provider, NULL, NULL, PROV_RSA_FULL, 0)) { if (GetLastError() != NTE_BAD_KEYSET) { log_fn(LOG_ERR,"Can't get CryptoAPI provider [1]"); return -1; } /* Yes, we need to try it twice. */ if (!CryptAcquireContext(&provider, NULL, NULL, PROV_RSA_FULL, CRYPT_NEWKEYSET)) { log_fn(LOG_ERR,"Can't get CryptoAPI provider [2]"); return -1; } } provider_set = 1; } if (!CryptGenRandom(provider, DIGEST_LEN, buf)) { log_fn(LOG_ERR,"Can't get entropy from CryptoAPI."); return -1; } RAND_seed(buf, DIGEST_LEN); /* And add the current screen state to the entopy pool for * good measure. */ RAND_screen(); return 0; #else static char *filenames[] = { "/dev/srandom", "/dev/urandom", "/dev/random", NULL }; int fd; int i, n; char buf[DIGEST_LEN+1]; for (i = 0; filenames[i]; ++i) { fd = open(filenames[i], O_RDONLY, 0); if (fd<0) continue; log_fn(LOG_INFO, "Seeding RNG from %s", filenames[i]); n = read(fd, buf, DIGEST_LEN); close(fd); if (n != DIGEST_LEN) { log_fn(LOG_WARN, "Error reading from entropy source"); return -1; } RAND_seed(buf, DIGEST_LEN); return 0; } log_fn(LOG_WARN, "Cannot seed RNG -- no entropy source found."); return -1; #endif } /** Write n bytes of strong random data to to. Return 0 on * success, -1 on failure. */ int crypto_rand(unsigned int n, unsigned char *to) { int r; tor_assert(to); r = RAND_bytes(to, n); if (r == 0) crypto_log_errors(LOG_WARN, "generating random data"); return (r == 1) ? 0 : -1; } /** Write n bytes of pseudorandom data to to. Return 0 on * success, -1 on failure. */ void crypto_pseudo_rand(unsigned int n, unsigned char *to) { tor_assert(to); if (RAND_pseudo_bytes(to, n) == -1) { log_fn(LOG_ERR, "RAND_pseudo_bytes failed unexpectedly."); crypto_log_errors(LOG_WARN, "generating random data"); exit(1); } } /** Return a pseudorandom integer, choosen uniformly from the values * between 0 and max-1. */ int crypto_pseudo_rand_int(unsigned int max) { unsigned int val; unsigned int cutoff; tor_assert(max < UINT_MAX); tor_assert(max > 0); /* don't div by 0 */ /* We ignore any values that are >= 'cutoff,' to avoid biasing the * distribution with clipping at the upper end of unsigned int's * range. */ cutoff = UINT_MAX - (UINT_MAX%max); while(1) { crypto_pseudo_rand(sizeof(val), (unsigned char*) &val); if (val < cutoff) return val % max; } } /** Base-64 encode srclen bytes of data from src. Write * the result into dest, if it will fit within destlen * bytes. Return the number of bytes written on success; -1 if * destlen is too short, or other failure. */ int base64_encode(char *dest, int destlen, const char *src, int srclen) { EVP_ENCODE_CTX ctx; int len, ret; /* 48 bytes of input -> 64 bytes of output plus newline. Plus one more byte, in case I'm wrong. */ if (destlen < ((srclen/48)+1)*66) return -1; EVP_EncodeInit(&ctx); EVP_EncodeUpdate(&ctx, dest, &len, (char*) src, srclen); EVP_EncodeFinal(&ctx, dest+len, &ret); ret += len; return ret; } /** Base-64 decode srclen bytes of data from src. Write * the result into dest, if it will fit within destlen * bytes. Return the number of bytes written on success; -1 if * destlen is too short, or other failure. */ int base64_decode(char *dest, int destlen, const char *src, int srclen) { EVP_ENCODE_CTX ctx; int len, ret; /* 64 bytes of input -> *up to* 48 bytes of output. Plus one more byte, in caes I'm wrong. */ if (destlen < ((srclen/64)+1)*49) return -1; EVP_DecodeInit(&ctx); EVP_DecodeUpdate(&ctx, dest, &len, (char*) src, srclen); EVP_DecodeFinal(&ctx, dest, &ret); ret += len; return ret; } /** Implements base32 encoding as in rfc3548. Limitation: Requires * that srclen*8 is a multiple of 5. */ void base32_encode(char *dest, int destlen, const char *src, int srclen) { int nbits, i, bit, v, u; nbits = srclen * 8; tor_assert((nbits%5) == 0); /* We need an even multiple of 5 bits. */ tor_assert((nbits/5)+1 <= destlen); /* We need enough space. */ for (i=0,bit=0; bit < nbits; ++i, bit+=5) { /* set v to the 16-bit value starting at src[bits/8], 0-padded. */ v = ((uint8_t)src[bit/8]) << 8; if (bit+5> (11-(bit%8))) & 0x1F; dest[i] = BASE32_CHARS[u]; } dest[i] = '\0'; } void base16_encode(char *dest, int destlen, const char *src, int srclen) { const char *end; char *cp; tor_assert(destlen >= srclen*2+1); cp = dest; end = src+srclen; while (src