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- /* Copyright (c) 2001, Matej Pfajfar.
- * Copyright (c) 2001-2004, Roger Dingledine.
- * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
- * Copyright (c) 2007-2016, The Tor Project, Inc. */
- /* See LICENSE for licensing information */
- /**
- * \file crypto.c
- * \brief Wrapper functions to present a consistent interface to
- * public-key and symmetric cryptography operations from OpenSSL and
- * other places.
- **/
- #include "orconfig.h"
- #ifdef _WIN32
- #include <winsock2.h>
- #include <windows.h>
- #include <wincrypt.h>
- /* Windows defines this; so does OpenSSL 0.9.8h and later. We don't actually
- * use either definition. */
- #undef OCSP_RESPONSE
- #endif
- #define CRYPTO_PRIVATE
- #include "crypto.h"
- #include "compat_openssl.h"
- #include "crypto_curve25519.h"
- #include "crypto_ed25519.h"
- #include "crypto_format.h"
- DISABLE_GCC_WARNING(redundant-decls)
- #include <openssl/err.h>
- #include <openssl/rsa.h>
- #include <openssl/pem.h>
- #include <openssl/evp.h>
- #include <openssl/engine.h>
- #include <openssl/rand.h>
- #include <openssl/bn.h>
- #include <openssl/dh.h>
- #include <openssl/conf.h>
- #include <openssl/hmac.h>
- ENABLE_GCC_WARNING(redundant-decls)
- #if __GNUC__ && GCC_VERSION >= 402
- #if GCC_VERSION >= 406
- #pragma GCC diagnostic pop
- #else
- #pragma GCC diagnostic warning "-Wredundant-decls"
- #endif
- #endif
- #ifdef HAVE_CTYPE_H
- #include <ctype.h>
- #endif
- #ifdef HAVE_UNISTD_H
- #include <unistd.h>
- #endif
- #ifdef HAVE_FCNTL_H
- #include <fcntl.h>
- #endif
- #ifdef HAVE_SYS_FCNTL_H
- #include <sys/fcntl.h>
- #endif
- #ifdef HAVE_SYS_SYSCALL_H
- #include <sys/syscall.h>
- #endif
- #ifdef HAVE_SYS_RANDOM_H
- #include <sys/random.h>
- #endif
- #include "torlog.h"
- #include "torint.h"
- #include "aes.h"
- #include "util.h"
- #include "container.h"
- #include "compat.h"
- #include "sandbox.h"
- #include "util_format.h"
- #include "keccak-tiny/keccak-tiny.h"
- #ifdef ANDROID
- /* Android's OpenSSL seems to have removed all of its Engine support. */
- #define DISABLE_ENGINES
- #endif
- #if OPENSSL_VERSION_NUMBER >= OPENSSL_VER(1,1,0,0,5) && \
- !defined(LIBRESSL_VERSION_NUMBER)
- /* OpenSSL as of 1.1.0pre4 has an "new" thread API, which doesn't require
- * seting up various callbacks.
- *
- * OpenSSL 1.1.0pre4 has a messed up `ERR_remove_thread_state()` prototype,
- * while the previous one was restored in pre5, and the function made a no-op
- * (along with a deprecated annotation, which produces a compiler warning).
- *
- * While it is possible to support all three versions of the thread API,
- * a version that existed only for one snapshot pre-release is kind of
- * pointless, so let's not.
- */
- #define NEW_THREAD_API
- #endif
- /** Longest recognized */
- #define MAX_DNS_LABEL_SIZE 63
- /** Largest strong entropy request */
- #define MAX_STRONGEST_RAND_SIZE 256
- #ifndef NEW_THREAD_API
- /** A number of preallocated mutexes for use by OpenSSL. */
- static tor_mutex_t **openssl_mutexes_ = NULL;
- /** How many mutexes have we allocated for use by OpenSSL? */
- static int n_openssl_mutexes_ = 0;
- #endif
- /** A public key, or a public/private key-pair. */
- struct crypto_pk_t
- {
- int refs; /**< reference count, so we don't have to copy keys */
- RSA *key; /**< The key itself */
- };
- /** A structure to hold the first half (x, g^x) of a Diffie-Hellman handshake
- * while we're waiting for the second.*/
- struct crypto_dh_t {
- DH *dh; /**< The openssl DH object */
- };
- static int setup_openssl_threading(void);
- static int tor_check_dh_key(int severity, const BIGNUM *bn);
- /** Return the number of bytes added by padding method <b>padding</b>.
- */
- static inline int
- crypto_get_rsa_padding_overhead(int padding)
- {
- switch (padding)
- {
- case RSA_PKCS1_OAEP_PADDING: return PKCS1_OAEP_PADDING_OVERHEAD;
- default: tor_assert(0); return -1; // LCOV_EXCL_LINE
- }
- }
- /** Given a padding method <b>padding</b>, return the correct OpenSSL constant.
- */
- static inline int
- crypto_get_rsa_padding(int padding)
- {
- switch (padding)
- {
- case PK_PKCS1_OAEP_PADDING: return RSA_PKCS1_OAEP_PADDING;
- default: tor_assert(0); return -1; // LCOV_EXCL_LINE
- }
- }
- /** Boolean: has OpenSSL's crypto been initialized? */
- static int crypto_early_initialized_ = 0;
- /** Boolean: has OpenSSL's crypto been initialized? */
- static int crypto_global_initialized_ = 0;
- /** Log all pending crypto errors at level <b>severity</b>. Use
- * <b>doing</b> to describe our current activities.
- */
- static void
- crypto_log_errors(int severity, const char *doing)
- {
- unsigned long 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 (!lib) lib = "(null)";
- if (!func) func = "(null)";
- if (BUG(!doing)) doing = "(null)";
- tor_log(severity, LD_CRYPTO, "crypto error while %s: %s (in %s:%s)",
- doing, msg, lib, func);
- }
- }
- #ifndef DISABLE_ENGINES
- /** Log any OpenSSL engines we're using at NOTICE. */
- static void
- log_engine(const char *fn, ENGINE *e)
- {
- if (e) {
- const char *name, *id;
- name = ENGINE_get_name(e);
- id = ENGINE_get_id(e);
- log_notice(LD_CRYPTO, "Default OpenSSL engine for %s is %s [%s]",
- fn, name?name:"?", id?id:"?");
- } else {
- log_info(LD_CRYPTO, "Using default implementation for %s", fn);
- }
- }
- #endif
- #ifndef DISABLE_ENGINES
- /** Try to load an engine in a shared library via fully qualified path.
- */
- static ENGINE *
- try_load_engine(const char *path, const char *engine)
- {
- ENGINE *e = ENGINE_by_id("dynamic");
- if (e) {
- if (!ENGINE_ctrl_cmd_string(e, "ID", engine, 0) ||
- !ENGINE_ctrl_cmd_string(e, "DIR_LOAD", "2", 0) ||
- !ENGINE_ctrl_cmd_string(e, "DIR_ADD", path, 0) ||
- !ENGINE_ctrl_cmd_string(e, "LOAD", NULL, 0)) {
- ENGINE_free(e);
- e = NULL;
- }
- }
- return e;
- }
- #endif
- /* Returns a trimmed and human-readable version of an openssl version string
- * <b>raw_version</b>. They are usually in the form of 'OpenSSL 1.0.0b 10
- * May 2012' and this will parse them into a form similar to '1.0.0b' */
- static char *
- parse_openssl_version_str(const char *raw_version)
- {
- const char *end_of_version = NULL;
- /* The output should be something like "OpenSSL 1.0.0b 10 May 2012. Let's
- trim that down. */
- if (!strcmpstart(raw_version, "OpenSSL ")) {
- raw_version += strlen("OpenSSL ");
- end_of_version = strchr(raw_version, ' ');
- }
- if (end_of_version)
- return tor_strndup(raw_version,
- end_of_version-raw_version);
- else
- return tor_strdup(raw_version);
- }
- static char *crypto_openssl_version_str = NULL;
- /* Return a human-readable version of the run-time openssl version number. */
- const char *
- crypto_openssl_get_version_str(void)
- {
- if (crypto_openssl_version_str == NULL) {
- const char *raw_version = OpenSSL_version(OPENSSL_VERSION);
- crypto_openssl_version_str = parse_openssl_version_str(raw_version);
- }
- return crypto_openssl_version_str;
- }
- static char *crypto_openssl_header_version_str = NULL;
- /* Return a human-readable version of the compile-time openssl version
- * number. */
- const char *
- crypto_openssl_get_header_version_str(void)
- {
- if (crypto_openssl_header_version_str == NULL) {
- crypto_openssl_header_version_str =
- parse_openssl_version_str(OPENSSL_VERSION_TEXT);
- }
- return crypto_openssl_header_version_str;
- }
- /** Make sure that openssl is using its default PRNG. Return 1 if we had to
- * adjust it; 0 otherwise. */
- STATIC int
- crypto_force_rand_ssleay(void)
- {
- RAND_METHOD *default_method;
- default_method = RAND_OpenSSL();
- if (RAND_get_rand_method() != default_method) {
- log_notice(LD_CRYPTO, "It appears that one of our engines has provided "
- "a replacement the OpenSSL RNG. Resetting it to the default "
- "implementation.");
- RAND_set_rand_method(default_method);
- return 1;
- }
- return 0;
- }
- /** Set up the siphash key if we haven't already done so. */
- int
- crypto_init_siphash_key(void)
- {
- static int have_seeded_siphash = 0;
- struct sipkey key;
- if (have_seeded_siphash)
- return 0;
- crypto_rand((char*) &key, sizeof(key));
- siphash_set_global_key(&key);
- have_seeded_siphash = 1;
- return 0;
- }
- /** Initialize the crypto library. Return 0 on success, -1 on failure.
- */
- int
- crypto_early_init(void)
- {
- if (!crypto_early_initialized_) {
- crypto_early_initialized_ = 1;
- ERR_load_crypto_strings();
- OpenSSL_add_all_algorithms();
- setup_openssl_threading();
- unsigned long version_num = OpenSSL_version_num();
- const char *version_str = OpenSSL_version(OPENSSL_VERSION);
- if (version_num == OPENSSL_VERSION_NUMBER &&
- !strcmp(version_str, OPENSSL_VERSION_TEXT)) {
- log_info(LD_CRYPTO, "OpenSSL version matches version from headers "
- "(%lx: %s).", version_num, version_str);
- } else {
- log_warn(LD_CRYPTO, "OpenSSL version from headers does not match the "
- "version we're running with. If you get weird crashes, that "
- "might be why. (Compiled with %lx: %s; running with %lx: %s).",
- (unsigned long)OPENSSL_VERSION_NUMBER, OPENSSL_VERSION_TEXT,
- version_num, version_str);
- }
- crypto_force_rand_ssleay();
- if (crypto_seed_rng() < 0)
- return -1;
- if (crypto_init_siphash_key() < 0)
- return -1;
- curve25519_init();
- ed25519_init();
- }
- return 0;
- }
- /** Initialize the crypto library. Return 0 on success, -1 on failure.
- */
- int
- crypto_global_init(int useAccel, const char *accelName, const char *accelDir)
- {
- if (!crypto_global_initialized_) {
- if (crypto_early_init() < 0)
- return -1;
- crypto_global_initialized_ = 1;
- if (useAccel > 0) {
- #ifdef DISABLE_ENGINES
- (void)accelName;
- (void)accelDir;
- log_warn(LD_CRYPTO, "No OpenSSL hardware acceleration support enabled.");
- #else
- ENGINE *e = NULL;
- log_info(LD_CRYPTO, "Initializing OpenSSL engine support.");
- ENGINE_load_builtin_engines();
- ENGINE_register_all_complete();
- if (accelName) {
- if (accelDir) {
- log_info(LD_CRYPTO, "Trying to load dynamic OpenSSL engine \"%s\""
- " via path \"%s\".", accelName, accelDir);
- e = try_load_engine(accelName, accelDir);
- } else {
- log_info(LD_CRYPTO, "Initializing dynamic OpenSSL engine \"%s\""
- " acceleration support.", accelName);
- e = ENGINE_by_id(accelName);
- }
- if (!e) {
- log_warn(LD_CRYPTO, "Unable to load dynamic OpenSSL engine \"%s\".",
- accelName);
- } else {
- log_info(LD_CRYPTO, "Loaded dynamic OpenSSL engine \"%s\".",
- accelName);
- }
- }
- if (e) {
- log_info(LD_CRYPTO, "Loaded OpenSSL hardware acceleration engine,"
- " setting default ciphers.");
- ENGINE_set_default(e, ENGINE_METHOD_ALL);
- }
- /* Log, if available, the intersection of the set of algorithms
- used by Tor and the set of algorithms available in the engine */
- log_engine("RSA", ENGINE_get_default_RSA());
- log_engine("DH", ENGINE_get_default_DH());
- #ifdef OPENSSL_1_1_API
- log_engine("EC", ENGINE_get_default_EC());
- #else
- log_engine("ECDH", ENGINE_get_default_ECDH());
- log_engine("ECDSA", ENGINE_get_default_ECDSA());
- #endif
- log_engine("RAND", ENGINE_get_default_RAND());
- log_engine("RAND (which we will not use)", ENGINE_get_default_RAND());
- log_engine("SHA1", ENGINE_get_digest_engine(NID_sha1));
- log_engine("3DES-CBC", ENGINE_get_cipher_engine(NID_des_ede3_cbc));
- log_engine("AES-128-ECB", ENGINE_get_cipher_engine(NID_aes_128_ecb));
- log_engine("AES-128-CBC", ENGINE_get_cipher_engine(NID_aes_128_cbc));
- #ifdef NID_aes_128_ctr
- log_engine("AES-128-CTR", ENGINE_get_cipher_engine(NID_aes_128_ctr));
- #endif
- #ifdef NID_aes_128_gcm
- log_engine("AES-128-GCM", ENGINE_get_cipher_engine(NID_aes_128_gcm));
- #endif
- log_engine("AES-256-CBC", ENGINE_get_cipher_engine(NID_aes_256_cbc));
- #ifdef NID_aes_256_gcm
- log_engine("AES-256-GCM", ENGINE_get_cipher_engine(NID_aes_256_gcm));
- #endif
- #endif
- } else {
- log_info(LD_CRYPTO, "NOT using OpenSSL engine support.");
- }
- if (crypto_force_rand_ssleay()) {
- if (crypto_seed_rng() < 0)
- return -1;
- }
- evaluate_evp_for_aes(-1);
- evaluate_ctr_for_aes();
- }
- return 0;
- }
- /** Free crypto resources held by this thread. */
- void
- crypto_thread_cleanup(void)
- {
- #ifndef NEW_THREAD_API
- ERR_remove_thread_state(NULL);
- #endif
- }
- /** used internally: quicly validate a crypto_pk_t object as a private key.
- * Return 1 iff the public key is valid, 0 if obviously invalid.
- */
- static int
- crypto_pk_private_ok(const crypto_pk_t *k)
- {
- #ifdef OPENSSL_1_1_API
- if (!k || !k->key)
- return 0;
- const BIGNUM *p, *q;
- RSA_get0_factors(k->key, &p, &q);
- return p != NULL; /* XXX/yawning: Should we check q? */
- #else
- return k && k->key && k->key->p;
- #endif
- }
- /** used by tortls.c: wrap an RSA* in a crypto_pk_t. */
- crypto_pk_t *
- crypto_new_pk_from_rsa_(RSA *rsa)
- {
- crypto_pk_t *env;
- tor_assert(rsa);
- env = tor_malloc(sizeof(crypto_pk_t));
- env->refs = 1;
- env->key = rsa;
- return env;
- }
- /** Helper, used by tor-checkkey.c and tor-gencert.c. Return the RSA from a
- * crypto_pk_t. */
- RSA *
- crypto_pk_get_rsa_(crypto_pk_t *env)
- {
- return env->key;
- }
- /** used by tortls.c: get an equivalent EVP_PKEY* for a crypto_pk_t. Iff
- * private is set, include the private-key portion of the key. Return a valid
- * pointer on success, and NULL on failure. */
- MOCK_IMPL(EVP_PKEY *,
- crypto_pk_get_evp_pkey_,(crypto_pk_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_t.
- */
- DH *
- crypto_dh_get_dh_(crypto_dh_t *dh)
- {
- return dh->dh;
- }
- /** Allocate and return storage for a public key. The key itself will not yet
- * be set.
- */
- MOCK_IMPL(crypto_pk_t *,
- crypto_pk_new,(void))
- {
- RSA *rsa;
- rsa = RSA_new();
- tor_assert(rsa);
- return crypto_new_pk_from_rsa_(rsa);
- }
- /** Release a reference to an asymmetric key; when all the references
- * are released, free the key.
- */
- void
- crypto_pk_free(crypto_pk_t *env)
- {
- if (!env)
- return;
- if (--env->refs > 0)
- return;
- tor_assert(env->refs == 0);
- if (env->key)
- RSA_free(env->key);
- tor_free(env);
- }
- /** Allocate and return a new symmetric cipher using the provided key and iv.
- * The key is <b>bits</b> bits long; the IV is CIPHER_IV_LEN bytes. Both
- * must be provided. Key length must be 128, 192, or 256 */
- crypto_cipher_t *
- crypto_cipher_new_with_iv_and_bits(const uint8_t *key,
- const uint8_t *iv,
- int bits)
- {
- tor_assert(key);
- tor_assert(iv);
- return aes_new_cipher((const uint8_t*)key, (const uint8_t*)iv, bits);
- }
- /** Allocate and return a new symmetric cipher using the provided key and iv.
- * The key is CIPHER_KEY_LEN bytes; the IV is CIPHER_IV_LEN bytes. Both
- * must be provided.
- */
- crypto_cipher_t *
- crypto_cipher_new_with_iv(const char *key, const char *iv)
- {
- return crypto_cipher_new_with_iv_and_bits((uint8_t*)key, (uint8_t*)iv,
- 128);
- }
- /** Return a new crypto_cipher_t with the provided <b>key</b> and an IV of all
- * zero bytes and key length <b>bits</b>. Key length must be 128, 192, or
- * 256. */
- crypto_cipher_t *
- crypto_cipher_new_with_bits(const char *key, int bits)
- {
- char zeroiv[CIPHER_IV_LEN];
- memset(zeroiv, 0, sizeof(zeroiv));
- return crypto_cipher_new_with_iv_and_bits((uint8_t*)key, (uint8_t*)zeroiv,
- bits);
- }
- /** Return a new crypto_cipher_t with the provided <b>key</b> (of
- * CIPHER_KEY_LEN bytes) and an IV of all zero bytes. */
- crypto_cipher_t *
- crypto_cipher_new(const char *key)
- {
- return crypto_cipher_new_with_bits(key, 128);
- }
- /** Free a symmetric cipher.
- */
- void
- crypto_cipher_free(crypto_cipher_t *env)
- {
- if (!env)
- return;
- aes_cipher_free(env);
- }
- /* public key crypto */
- /** Generate a <b>bits</b>-bit new public/private keypair in <b>env</b>.
- * Return 0 on success, -1 on failure.
- */
- MOCK_IMPL(int,
- crypto_pk_generate_key_with_bits,(crypto_pk_t *env, int bits))
- {
- tor_assert(env);
- if (env->key) {
- RSA_free(env->key);
- env->key = NULL;
- }
- {
- BIGNUM *e = BN_new();
- RSA *r = NULL;
- if (!e)
- goto done;
- if (! BN_set_word(e, 65537))
- goto done;
- r = RSA_new();
- if (!r)
- goto done;
- if (RSA_generate_key_ex(r, bits, e, NULL) == -1)
- goto done;
- env->key = r;
- r = NULL;
- done:
- if (e)
- BN_clear_free(e);
- if (r)
- RSA_free(r);
- }
- if (!env->key) {
- crypto_log_errors(LOG_WARN, "generating RSA key");
- return -1;
- }
- return 0;
- }
- /** Read a PEM-encoded private key from the <b>len</b>-byte string <b>s</b>
- * into <b>env</b>. Return 0 on success, -1 on failure. If len is -1,
- * the string is nul-terminated.
- */
- /* Used here, and used for testing. */
- int
- crypto_pk_read_private_key_from_string(crypto_pk_t *env,
- const char *s, ssize_t len)
- {
- BIO *b;
- tor_assert(env);
- tor_assert(s);
- tor_assert(len < INT_MAX && len < SSIZE_T_CEILING);
- /* Create a read-only memory BIO, backed by the string 's' */
- b = BIO_new_mem_buf((char*)s, (int)len);
- if (!b)
- return -1;
- if (env->key)
- RSA_free(env->key);
- env->key = PEM_read_bio_RSAPrivateKey(b,NULL,NULL,NULL);
- BIO_free(b);
- if (!env->key) {
- crypto_log_errors(LOG_WARN, "Error parsing private key");
- return -1;
- }
- return 0;
- }
- /** Read a PEM-encoded private key from the file named by
- * <b>keyfile</b> into <b>env</b>. Return 0 on success, -1 on failure.
- */
- int
- crypto_pk_read_private_key_from_filename(crypto_pk_t *env,
- const char *keyfile)
- {
- char *contents;
- int r;
- /* Read the file into a string. */
- contents = read_file_to_str(keyfile, 0, NULL);
- if (!contents) {
- log_warn(LD_CRYPTO, "Error reading private key from \"%s\"", keyfile);
- return -1;
- }
- /* Try to parse it. */
- r = crypto_pk_read_private_key_from_string(env, contents, -1);
- memwipe(contents, 0, strlen(contents));
- tor_free(contents);
- if (r)
- return -1; /* read_private_key_from_string already warned, so we don't.*/
- /* Make sure it's valid. */
- if (crypto_pk_check_key(env) <= 0)
- return -1;
- return 0;
- }
- /** Helper function to implement crypto_pk_write_*_key_to_string. Return 0 on
- * success, -1 on failure. */
- static int
- crypto_pk_write_key_to_string_impl(crypto_pk_t *env, char **dest,
- size_t *len, int is_public)
- {
- BUF_MEM *buf;
- BIO *b;
- int r;
- tor_assert(env);
- tor_assert(env->key);
- tor_assert(dest);
- b = BIO_new(BIO_s_mem()); /* Create a memory BIO */
- if (!b)
- return -1;
- /* Now you can treat b as if it were a file. Just use the
- * PEM_*_bio_* functions instead of the non-bio variants.
- */
- if (is_public)
- r = PEM_write_bio_RSAPublicKey(b, env->key);
- else
- r = PEM_write_bio_RSAPrivateKey(b, env->key, NULL,NULL,0,NULL,NULL);
- if (!r) {
- crypto_log_errors(LOG_WARN, "writing RSA key to string");
- BIO_free(b);
- return -1;
- }
- BIO_get_mem_ptr(b, &buf);
- *dest = tor_malloc(buf->length+1);
- memcpy(*dest, buf->data, buf->length);
- (*dest)[buf->length] = 0; /* nul terminate it */
- *len = buf->length;
- BIO_free(b);
- return 0;
- }
- /** PEM-encode the public key portion of <b>env</b> and write it to a
- * newly allocated string. On success, set *<b>dest</b> to the new
- * string, *<b>len</b> to the string's length, and return 0. On
- * failure, return -1.
- */
- int
- crypto_pk_write_public_key_to_string(crypto_pk_t *env, char **dest,
- size_t *len)
- {
- return crypto_pk_write_key_to_string_impl(env, dest, len, 1);
- }
- /** PEM-encode the private key portion of <b>env</b> and write it to a
- * newly allocated string. On success, set *<b>dest</b> to the new
- * string, *<b>len</b> to the string's length, and return 0. On
- * failure, return -1.
- */
- int
- crypto_pk_write_private_key_to_string(crypto_pk_t *env, char **dest,
- size_t *len)
- {
- return crypto_pk_write_key_to_string_impl(env, dest, len, 0);
- }
- /** Read a PEM-encoded public key from the first <b>len</b> characters of
- * <b>src</b>, and store the result in <b>env</b>. Return 0 on success, -1 on
- * failure.
- */
- int
- crypto_pk_read_public_key_from_string(crypto_pk_t *env, const char *src,
- size_t len)
- {
- BIO *b;
- tor_assert(env);
- tor_assert(src);
- tor_assert(len<INT_MAX);
- b = BIO_new(BIO_s_mem()); /* Create a memory BIO */
- if (!b)
- return -1;
- BIO_write(b, src, (int)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 <b>env</b> into the file named by <b>fname</b>,
- * PEM-encoded. Return 0 on success, -1 on failure.
- */
- int
- crypto_pk_write_private_key_to_filename(crypto_pk_t *env,
- const char *fname)
- {
- BIO *bio;
- char *cp;
- long len;
- char *s;
- int r;
- tor_assert(crypto_pk_private_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);
- tor_assert(len >= 0);
- s = tor_malloc(len+1);
- memcpy(s, cp, len);
- s[len]='\0';
- r = write_str_to_file(fname, s, 0);
- BIO_free(bio);
- memwipe(s, 0, strlen(s));
- tor_free(s);
- return r;
- }
- /** Return true iff <b>env</b> has a valid key.
- */
- int
- crypto_pk_check_key(crypto_pk_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;
- }
- /** Return true iff <b>key</b> contains the private-key portion of the RSA
- * key. */
- int
- crypto_pk_key_is_private(const crypto_pk_t *key)
- {
- tor_assert(key);
- return crypto_pk_private_ok(key);
- }
- /** Return true iff <b>env</b> contains a public key whose public exponent
- * equals 65537.
- */
- int
- crypto_pk_public_exponent_ok(crypto_pk_t *env)
- {
- tor_assert(env);
- tor_assert(env->key);
- const BIGNUM *e;
- #ifdef OPENSSL_1_1_API
- const BIGNUM *n, *d;
- RSA_get0_key(env->key, &n, &e, &d);
- #else
- e = env->key->e;
- #endif
- return BN_is_word(e, 65537);
- }
- /** Compare the public-key components of a and b. Return less than 0
- * if a\<b, 0 if a==b, and greater than 0 if a\>b. A NULL key is
- * considered to be less than all non-NULL keys, and equal to itself.
- *
- * Note that this may leak information about the keys through timing.
- */
- int
- crypto_pk_cmp_keys(const crypto_pk_t *a, const crypto_pk_t *b)
- {
- int result;
- char a_is_non_null = (a != NULL) && (a->key != NULL);
- char b_is_non_null = (b != NULL) && (b->key != NULL);
- char an_argument_is_null = !a_is_non_null | !b_is_non_null;
- result = tor_memcmp(&a_is_non_null, &b_is_non_null, sizeof(a_is_non_null));
- if (an_argument_is_null)
- return result;
- const BIGNUM *a_n, *a_e;
- const BIGNUM *b_n, *b_e;
- #ifdef OPENSSL_1_1_API
- const BIGNUM *a_d, *b_d;
- RSA_get0_key(a->key, &a_n, &a_e, &a_d);
- RSA_get0_key(b->key, &b_n, &b_e, &b_d);
- #else
- a_n = a->key->n;
- a_e = a->key->e;
- b_n = b->key->n;
- b_e = b->key->e;
- #endif
- tor_assert(a_n != NULL && a_e != NULL);
- tor_assert(b_n != NULL && b_e != NULL);
- result = BN_cmp(a_n, b_n);
- if (result)
- return result;
- return BN_cmp(a_e, b_e);
- }
- /** Compare the public-key components of a and b. Return non-zero iff
- * a==b. A NULL key is considered to be distinct from all non-NULL
- * keys, and equal to itself.
- *
- * Note that this may leak information about the keys through timing.
- */
- int
- crypto_pk_eq_keys(const crypto_pk_t *a, const crypto_pk_t *b)
- {
- return (crypto_pk_cmp_keys(a, b) == 0);
- }
- /** Return the size of the public key modulus in <b>env</b>, in bytes. */
- size_t
- crypto_pk_keysize(const crypto_pk_t *env)
- {
- tor_assert(env);
- tor_assert(env->key);
- return (size_t) RSA_size((RSA*)env->key);
- }
- /** Return the size of the public key modulus of <b>env</b>, in bits. */
- int
- crypto_pk_num_bits(crypto_pk_t *env)
- {
- tor_assert(env);
- tor_assert(env->key);
- #ifdef OPENSSL_1_1_API
- /* It's so stupid that there's no other way to check that n is valid
- * before calling RSA_bits().
- */
- const BIGNUM *n, *e, *d;
- RSA_get0_key(env->key, &n, &e, &d);
- tor_assert(n != NULL);
- return RSA_bits(env->key);
- #else
- tor_assert(env->key->n);
- return BN_num_bits(env->key->n);
- #endif
- }
- /** Increase the reference count of <b>env</b>, and return it.
- */
- crypto_pk_t *
- crypto_pk_dup_key(crypto_pk_t *env)
- {
- tor_assert(env);
- tor_assert(env->key);
- env->refs++;
- return env;
- }
- #ifdef TOR_UNIT_TESTS
- /** For testing: replace dest with src. (Dest must have a refcount
- * of 1) */
- void
- crypto_pk_assign_(crypto_pk_t *dest, const crypto_pk_t *src)
- {
- tor_assert(dest);
- tor_assert(dest->refs == 1);
- tor_assert(src);
- RSA_free(dest->key);
- dest->key = RSAPrivateKey_dup(src->key);
- }
- #endif
- /** Make a real honest-to-goodness copy of <b>env</b>, and return it.
- * Returns NULL on failure. */
- crypto_pk_t *
- crypto_pk_copy_full(crypto_pk_t *env)
- {
- RSA *new_key;
- int privatekey = 0;
- tor_assert(env);
- tor_assert(env->key);
- if (crypto_pk_private_ok(env)) {
- new_key = RSAPrivateKey_dup(env->key);
- privatekey = 1;
- } else {
- new_key = RSAPublicKey_dup(env->key);
- }
- if (!new_key) {
- /* LCOV_EXCL_START
- *
- * We can't cause RSA*Key_dup() to fail, so we can't really test this.
- */
- log_err(LD_CRYPTO, "Unable to duplicate a %s key: openssl failed.",
- privatekey?"private":"public");
- crypto_log_errors(LOG_ERR,
- privatekey ? "Duplicating a private key" :
- "Duplicating a public key");
- tor_fragile_assert();
- return NULL;
- /* LCOV_EXCL_STOP */
- }
- return crypto_new_pk_from_rsa_(new_key);
- }
- /** Encrypt <b>fromlen</b> bytes from <b>from</b> with the public key
- * in <b>env</b>, using the padding method <b>padding</b>. On success,
- * write the result to <b>to</b>, and return the number of bytes
- * written. On failure, return -1.
- *
- * <b>tolen</b> is the number of writable bytes in <b>to</b>, and must be
- * at least the length of the modulus of <b>env</b>.
- */
- int
- crypto_pk_public_encrypt(crypto_pk_t *env, char *to, size_t tolen,
- const char *from, size_t fromlen, int padding)
- {
- int r;
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen<INT_MAX);
- tor_assert(tolen >= crypto_pk_keysize(env));
- r = RSA_public_encrypt((int)fromlen,
- (unsigned char*)from, (unsigned char*)to,
- env->key, crypto_get_rsa_padding(padding));
- if (r<0) {
- crypto_log_errors(LOG_WARN, "performing RSA encryption");
- return -1;
- }
- return r;
- }
- /** Decrypt <b>fromlen</b> bytes from <b>from</b> with the private key
- * in <b>env</b>, using the padding method <b>padding</b>. On success,
- * write the result to <b>to</b>, and return the number of bytes
- * written. On failure, return -1.
- *
- * <b>tolen</b> is the number of writable bytes in <b>to</b>, and must be
- * at least the length of the modulus of <b>env</b>.
- */
- int
- crypto_pk_private_decrypt(crypto_pk_t *env, char *to,
- size_t tolen,
- const char *from, size_t fromlen,
- int padding, int warnOnFailure)
- {
- int r;
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(env->key);
- tor_assert(fromlen<INT_MAX);
- tor_assert(tolen >= crypto_pk_keysize(env));
- if (!crypto_pk_key_is_private(env))
- /* Not a private key */
- return -1;
- r = RSA_private_decrypt((int)fromlen,
- (unsigned char*)from, (unsigned char*)to,
- env->key, crypto_get_rsa_padding(padding));
- if (r<0) {
- crypto_log_errors(warnOnFailure?LOG_WARN:LOG_DEBUG,
- "performing RSA decryption");
- return -1;
- }
- return r;
- }
- /** Check the signature in <b>from</b> (<b>fromlen</b> bytes long) with the
- * public key in <b>env</b>, using PKCS1 padding. On success, write the
- * signed data to <b>to</b>, and return the number of bytes written.
- * On failure, return -1.
- *
- * <b>tolen</b> is the number of writable bytes in <b>to</b>, and must be
- * at least the length of the modulus of <b>env</b>.
- */
- int
- crypto_pk_public_checksig(const crypto_pk_t *env, char *to,
- size_t tolen,
- const char *from, size_t fromlen)
- {
- int r;
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < INT_MAX);
- tor_assert(tolen >= crypto_pk_keysize(env));
- r = RSA_public_decrypt((int)fromlen,
- (unsigned char*)from, (unsigned char*)to,
- env->key, RSA_PKCS1_PADDING);
- if (r<0) {
- crypto_log_errors(LOG_INFO, "checking RSA signature");
- return -1;
- }
- return r;
- }
- /** Check a siglen-byte long signature at <b>sig</b> against
- * <b>datalen</b> bytes of data at <b>data</b>, using the public key
- * in <b>env</b>. Return 0 if <b>sig</b> is a correct signature for
- * SHA1(data). Else return -1.
- */
- 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;
- }
- /** Sign <b>fromlen</b> bytes of data from <b>from</b> with the private key in
- * <b>env</b>, using PKCS1 padding. On success, write the signature to
- * <b>to</b>, and return the number of bytes written. On failure, return
- * -1.
- *
- * <b>tolen</b> is the number of writable bytes in <b>to</b>, and must be
- * at least the length of the modulus of <b>env</b>.
- */
- int
- crypto_pk_private_sign(const crypto_pk_t *env, char *to, size_t tolen,
- const char *from, size_t fromlen)
- {
- int r;
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < INT_MAX);
- tor_assert(tolen >= crypto_pk_keysize(env));
- if (!crypto_pk_key_is_private(env))
- /* Not a private key */
- return -1;
- r = RSA_private_encrypt((int)fromlen,
- (unsigned char*)from, (unsigned char*)to,
- (RSA*)env->key, RSA_PKCS1_PADDING);
- if (r<0) {
- crypto_log_errors(LOG_WARN, "generating RSA signature");
- return -1;
- }
- return r;
- }
- /** Compute a SHA1 digest of <b>fromlen</b> bytes of data stored at
- * <b>from</b>; sign the data with the private key in <b>env</b>, and
- * store it in <b>to</b>. Return the number of bytes written on
- * success, and -1 on failure.
- *
- * <b>tolen</b> is the number of writable bytes in <b>to</b>, and must be
- * at least the length of the modulus of <b>env</b>.
- */
- 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;
- }
- /** Perform a hybrid (public/secret) encryption on <b>fromlen</b>
- * bytes of data from <b>from</b>, with padding type 'padding',
- * storing the results on <b>to</b>.
- *
- * 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 <b>force</b>
- * 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_t *env,
- char *to, size_t tolen,
- const char *from,
- size_t fromlen,
- int padding, int force)
- {
- int overhead, outlen, r;
- size_t pkeylen, symlen;
- crypto_cipher_t *cipher = NULL;
- char *buf = NULL;
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < SIZE_T_CEILING);
- overhead = crypto_get_rsa_padding_overhead(crypto_get_rsa_padding(padding));
- pkeylen = crypto_pk_keysize(env);
- if (!force && fromlen+overhead <= pkeylen) {
- /* It all fits in a single encrypt. */
- return crypto_pk_public_encrypt(env,to,
- tolen,
- from,fromlen,padding);
- }
- tor_assert(tolen >= fromlen + overhead + CIPHER_KEY_LEN);
- tor_assert(tolen >= pkeylen);
- char key[CIPHER_KEY_LEN];
- crypto_rand(key, sizeof(key)); /* generate a new key. */
- cipher = crypto_cipher_new(key);
- buf = tor_malloc(pkeylen+1);
- memcpy(buf, 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,to,tolen,buf,pkeylen-overhead,padding);
- if (outlen!=(int)pkeylen) {
- goto err;
- }
- r = crypto_cipher_encrypt(cipher, to+outlen,
- from+pkeylen-overhead-CIPHER_KEY_LEN, symlen);
- if (r<0) goto err;
- memwipe(buf, 0, pkeylen);
- memwipe(key, 0, sizeof(key));
- tor_free(buf);
- crypto_cipher_free(cipher);
- tor_assert(outlen+symlen < INT_MAX);
- return (int)(outlen + symlen);
- err:
- memwipe(buf, 0, pkeylen);
- memwipe(key, 0, sizeof(key));
- tor_free(buf);
- crypto_cipher_free(cipher);
- return -1;
- }
- /** Invert crypto_pk_public_hybrid_encrypt. Returns the number of bytes
- * written on success, -1 on failure. */
- int
- crypto_pk_private_hybrid_decrypt(crypto_pk_t *env,
- char *to,
- size_t tolen,
- const char *from,
- size_t fromlen,
- int padding, int warnOnFailure)
- {
- int outlen, r;
- size_t pkeylen;
- crypto_cipher_t *cipher = NULL;
- char *buf = NULL;
- tor_assert(fromlen < SIZE_T_CEILING);
- pkeylen = crypto_pk_keysize(env);
- if (fromlen <= pkeylen) {
- return crypto_pk_private_decrypt(env,to,tolen,from,fromlen,padding,
- warnOnFailure);
- }
- buf = tor_malloc(pkeylen);
- outlen = crypto_pk_private_decrypt(env,buf,pkeylen,from,pkeylen,padding,
- warnOnFailure);
- if (outlen<0) {
- log_fn(warnOnFailure?LOG_WARN:LOG_DEBUG, LD_CRYPTO,
- "Error decrypting public-key data");
- goto err;
- }
- if (outlen < CIPHER_KEY_LEN) {
- log_fn(warnOnFailure?LOG_WARN:LOG_INFO, LD_CRYPTO,
- "No room for a symmetric key");
- goto err;
- }
- cipher = crypto_cipher_new(buf);
- if (!cipher) {
- goto err;
- }
- memcpy(to,buf+CIPHER_KEY_LEN,outlen-CIPHER_KEY_LEN);
- outlen -= CIPHER_KEY_LEN;
- tor_assert(tolen - outlen >= fromlen - pkeylen);
- r = crypto_cipher_decrypt(cipher, to+outlen, from+pkeylen, fromlen-pkeylen);
- if (r<0)
- goto err;
- memwipe(buf,0,pkeylen);
- tor_free(buf);
- crypto_cipher_free(cipher);
- tor_assert(outlen + fromlen < INT_MAX);
- return (int)(outlen + (fromlen-pkeylen));
- err:
- memwipe(buf,0,pkeylen);
- tor_free(buf);
- crypto_cipher_free(cipher);
- return -1;
- }
- /** ASN.1-encode the public portion of <b>pk</b> into <b>dest</b>.
- * Return -1 on error, or the number of characters used on success.
- */
- int
- crypto_pk_asn1_encode(crypto_pk_t *pk, char *dest, size_t dest_len)
- {
- int len;
- unsigned char *buf = NULL;
- len = i2d_RSAPublicKey(pk->key, &buf);
- if (len < 0 || buf == NULL)
- return -1;
- if ((size_t)len > dest_len || dest_len > SIZE_T_CEILING) {
- OPENSSL_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);
- OPENSSL_free(buf);
- return len;
- }
- /** Decode an ASN.1-encoded public key from <b>str</b>; return the result on
- * success and NULL on failure.
- */
- crypto_pk_t *
- crypto_pk_asn1_decode(const char *str, size_t len)
- {
- RSA *rsa;
- unsigned char *buf;
- const unsigned char *cp;
- 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_from_rsa_(rsa);
- }
- /** Given a private or public key <b>pk</b>, put a SHA1 hash of the
- * public key into <b>digest_out</b> (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)
- {
- unsigned char *buf = NULL;
- int len;
- len = i2d_RSAPublicKey((RSA*)pk->key, &buf);
- if (len < 0 || buf == NULL)
- return -1;
- if (crypto_digest(digest_out, (char*)buf, len) < 0) {
- OPENSSL_free(buf);
- return -1;
- }
- OPENSSL_free(buf);
- return 0;
- }
- /** Compute all digests of the DER encoding of <b>pk</b>, and store them
- * in <b>digests_out</b>. Return 0 on success, -1 on failure. */
- int
- crypto_pk_get_common_digests(crypto_pk_t *pk, common_digests_t *digests_out)
- {
- unsigned char *buf = NULL;
- int len;
- len = i2d_RSAPublicKey(pk->key, &buf);
- if (len < 0 || buf == NULL)
- return -1;
- if (crypto_common_digests(digests_out, (char*)buf, len) < 0) {
- OPENSSL_free(buf);
- return -1;
- }
- OPENSSL_free(buf);
- return 0;
- }
- /** Copy <b>in</b> to the <b>outlen</b>-byte buffer <b>out</b>, adding spaces
- * every four characters. */
- void
- crypto_add_spaces_to_fp(char *out, size_t outlen, const char *in)
- {
- int n = 0;
- char *end = out+outlen;
- tor_assert(outlen < SIZE_T_CEILING);
- while (*in && out<end) {
- *out++ = *in++;
- if (++n == 4 && *in && out<end) {
- n = 0;
- *out++ = ' ';
- }
- }
- tor_assert(out<end);
- *out = '\0';
- }
- /** Given a private or public key <b>pk</b>, put a fingerprint of the
- * public key into <b>fp_out</b> (must have at least FINGERPRINT_LEN+1 bytes of
- * space). Return 0 on success, -1 on failure.
- *
- * 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.
- *
- * If <b>add_space</b> is false, omit the spaces.
- */
- int
- crypto_pk_get_fingerprint(crypto_pk_t *pk, char *fp_out, int add_space)
- {
- char digest[DIGEST_LEN];
- char hexdigest[HEX_DIGEST_LEN+1];
- if (crypto_pk_get_digest(pk, digest)) {
- return -1;
- }
- base16_encode(hexdigest,sizeof(hexdigest),digest,DIGEST_LEN);
- if (add_space) {
- crypto_add_spaces_to_fp(fp_out, FINGERPRINT_LEN+1, hexdigest);
- } else {
- strncpy(fp_out, hexdigest, HEX_DIGEST_LEN+1);
- }
- return 0;
- }
- /** Given a private or public key <b>pk</b>, put a hashed fingerprint of
- * the public key into <b>fp_out</b> (must have at least FINGERPRINT_LEN+1
- * bytes of space). Return 0 on success, -1 on failure.
- *
- * Hashed fingerprints are computed as the SHA1 digest of the SHA1 digest
- * of the ASN.1 encoding of the public key, converted to hexadecimal, in
- * upper case.
- */
- int
- crypto_pk_get_hashed_fingerprint(crypto_pk_t *pk, char *fp_out)
- {
- char digest[DIGEST_LEN], hashed_digest[DIGEST_LEN];
- if (crypto_pk_get_digest(pk, digest)) {
- return -1;
- }
- if (crypto_digest(hashed_digest, digest, DIGEST_LEN)) {
- return -1;
- }
- base16_encode(fp_out, FINGERPRINT_LEN + 1, hashed_digest, DIGEST_LEN);
- return 0;
- }
- /** Given a crypto_pk_t <b>pk</b>, allocate a new buffer containing the
- * Base64 encoding of the DER representation of the private key as a NUL
- * terminated string, and return it via <b>priv_out</b>. Return 0 on
- * sucess, -1 on failure.
- *
- * It is the caller's responsibility to sanitize and free the resulting buffer.
- */
- int
- crypto_pk_base64_encode(const crypto_pk_t *pk, char **priv_out)
- {
- unsigned char *der = NULL;
- int der_len;
- int ret = -1;
- *priv_out = NULL;
- der_len = i2d_RSAPrivateKey(pk->key, &der);
- if (der_len < 0 || der == NULL)
- return ret;
- size_t priv_len = base64_encode_size(der_len, 0) + 1;
- char *priv = tor_malloc_zero(priv_len);
- if (base64_encode(priv, priv_len, (char *)der, der_len, 0) >= 0) {
- *priv_out = priv;
- ret = 0;
- } else {
- tor_free(priv);
- }
- memwipe(der, 0, der_len);
- OPENSSL_free(der);
- return ret;
- }
- /** Given a string containing the Base64 encoded DER representation of the
- * private key <b>str</b>, decode and return the result on success, or NULL
- * on failure.
- */
- crypto_pk_t *
- crypto_pk_base64_decode(const char *str, size_t len)
- {
- crypto_pk_t *pk = NULL;
- char *der = tor_malloc_zero(len + 1);
- int der_len = base64_decode(der, len, str, len);
- if (der_len <= 0) {
- log_warn(LD_CRYPTO, "Stored RSA private key seems corrupted (base64).");
- goto out;
- }
- const unsigned char *dp = (unsigned char*)der; /* Shut the compiler up. */
- RSA *rsa = d2i_RSAPrivateKey(NULL, &dp, der_len);
- if (!rsa) {
- crypto_log_errors(LOG_WARN, "decoding private key");
- goto out;
- }
- pk = crypto_new_pk_from_rsa_(rsa);
- /* Make sure it's valid. */
- if (crypto_pk_check_key(pk) <= 0) {
- crypto_pk_free(pk);
- pk = NULL;
- goto out;
- }
- out:
- memwipe(der, 0, len + 1);
- tor_free(der);
- return pk;
- }
- /* symmetric crypto */
- /** Encrypt <b>fromlen</b> bytes from <b>from</b> using the cipher
- * <b>env</b>; on success, store the result to <b>to</b> and return 0.
- * Does not check for failure.
- */
- int
- crypto_cipher_encrypt(crypto_cipher_t *env, char *to,
- const char *from, size_t fromlen)
- {
- tor_assert(env);
- tor_assert(env);
- tor_assert(from);
- tor_assert(fromlen);
- tor_assert(to);
- tor_assert(fromlen < SIZE_T_CEILING);
- memcpy(to, from, fromlen);
- aes_crypt_inplace(env, to, fromlen);
- return 0;
- }
- /** Decrypt <b>fromlen</b> bytes from <b>from</b> using the cipher
- * <b>env</b>; on success, store the result to <b>to</b> and return 0.
- * Does not check for failure.
- */
- int
- crypto_cipher_decrypt(crypto_cipher_t *env, char *to,
- const char *from, size_t fromlen)
- {
- tor_assert(env);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < SIZE_T_CEILING);
- memcpy(to, from, fromlen);
- aes_crypt_inplace(env, to, fromlen);
- return 0;
- }
- /** Encrypt <b>len</b> bytes on <b>from</b> using the cipher in <b>env</b>;
- * on success. Does not check for failure.
- */
- void
- crypto_cipher_crypt_inplace(crypto_cipher_t *env, char *buf, size_t len)
- {
- tor_assert(len < SIZE_T_CEILING);
- aes_crypt_inplace(env, buf, len);
- }
- /** Encrypt <b>fromlen</b> bytes (at least 1) from <b>from</b> with the key in
- * <b>key</b> to the buffer in <b>to</b> of length
- * <b>tolen</b>. <b>tolen</b> must be at least <b>fromlen</b> plus
- * CIPHER_IV_LEN bytes for the initialization vector. On success, return the
- * number of bytes written, on failure, return -1.
- */
- int
- crypto_cipher_encrypt_with_iv(const char *key,
- char *to, size_t tolen,
- const char *from, size_t fromlen)
- {
- crypto_cipher_t *cipher;
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < INT_MAX);
- if (fromlen < 1)
- return -1;
- if (tolen < fromlen + CIPHER_IV_LEN)
- return -1;
- char iv[CIPHER_IV_LEN];
- crypto_rand(iv, sizeof(iv));
- cipher = crypto_cipher_new_with_iv(key, iv);
- memcpy(to, iv, CIPHER_IV_LEN);
- crypto_cipher_encrypt(cipher, to+CIPHER_IV_LEN, from, fromlen);
- crypto_cipher_free(cipher);
- memwipe(iv, 0, sizeof(iv));
- return (int)(fromlen + CIPHER_IV_LEN);
- }
- /** Decrypt <b>fromlen</b> bytes (at least 1+CIPHER_IV_LEN) from <b>from</b>
- * with the key in <b>key</b> to the buffer in <b>to</b> of length
- * <b>tolen</b>. <b>tolen</b> must be at least <b>fromlen</b> minus
- * CIPHER_IV_LEN bytes for the initialization vector. On success, return the
- * number of bytes written, on failure, return -1.
- */
- int
- crypto_cipher_decrypt_with_iv(const char *key,
- char *to, size_t tolen,
- const char *from, size_t fromlen)
- {
- crypto_cipher_t *cipher;
- tor_assert(key);
- tor_assert(from);
- tor_assert(to);
- tor_assert(fromlen < INT_MAX);
- if (fromlen <= CIPHER_IV_LEN)
- return -1;
- if (tolen < fromlen - CIPHER_IV_LEN)
- return -1;
- cipher = crypto_cipher_new_with_iv(key, from);
- crypto_cipher_encrypt(cipher, to, from+CIPHER_IV_LEN, fromlen-CIPHER_IV_LEN);
- crypto_cipher_free(cipher);
- return (int)(fromlen - CIPHER_IV_LEN);
- }
- /* SHA-1 */
- /** Compute the SHA1 digest of the <b>len</b> bytes on data stored in
- * <b>m</b>. Write the DIGEST_LEN byte result into <b>digest</b>.
- * Return 0 on success, 1 on failure.
- */
- int
- crypto_digest(char *digest, const char *m, size_t len)
- {
- tor_assert(m);
- tor_assert(digest);
- return (SHA1((const unsigned char*)m,len,(unsigned char*)digest) == NULL);
- }
- /** Compute a 256-bit digest of <b>len</b> bytes in data stored in <b>m</b>,
- * using the algorithm <b>algorithm</b>. Write the DIGEST_LEN256-byte result
- * into <b>digest</b>. 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);
- if (algorithm == DIGEST_SHA256)
- return (SHA256((const uint8_t*)m,len,(uint8_t*)digest) == NULL);
- else
- return (sha3_256((uint8_t *)digest, DIGEST256_LEN,(const uint8_t *)m, len)
- == -1);
- }
- /** Compute a 512-bit digest of <b>len</b> bytes in data stored in <b>m</b>,
- * using the algorithm <b>algorithm</b>. Write the DIGEST_LEN512-byte result
- * into <b>digest</b>. 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);
- if (algorithm == DIGEST_SHA512)
- return (SHA512((const unsigned char*)m,len,(unsigned char*)digest)
- == NULL);
- else
- return (sha3_512((uint8_t*)digest, DIGEST512_LEN, (const uint8_t*)m, len)
- == -1);
- }
- /** Set the common_digests_t in <b>ds_out</b> to contain every digest on the
- * <b>len</b> bytes in <b>m</b> 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";
- default:
- // LCOV_EXCL_START
- 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 <b>algorithm</b>. 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;
- };
- /**
- * Return the number of bytes we need to malloc in order to get a
- * crypto_digest_t for <b>alg</b>, 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) (STRUCT_OFFSET(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 <b>algorithm</b>. */
- 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 <b>algorithm</b>. */
- 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 <b>len</b> bytes from <b>data</b> 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 <b>out</b>.
- * <b>out_len</b> 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
- * <b>digest</b>
- */
- 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 <b>into</b> with the state
- * of the digest object <b>from</b>. 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 <b>lst</b>, set the <b>len_out</b>-byte digest
- * at <b>digest_out</b> to the hash of the concatenation of those strings,
- * plus the optional string <b>append</b>, computed with the algorithm
- * <b>alg</b>.
- * <b>out_len</b> 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 <b>lst</b>, set the <b>len_out</b>-byte digest
- * at <b>digest_out</b> to the hash of the concatenation of: the
- * optional string <b>prepend</b>, those strings,
- * and the optional string <b>append</b>, computed with the algorithm
- * <b>alg</b>.
- * <b>len_out</b> 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 <b>msg_len</b> bytes in <b>msg</b>, using
- * the <b>key</b> of length <b>key_len</b>. Store the DIGEST256_LEN-byte
- * result in <b>hmac_out</b>. 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);
- }
- /** Internal state for a eXtendable-Output Function (XOF). */
- struct crypto_xof_t {
- keccak_state s;
- };
- /** Allocate a new XOF object backed by SHAKE-256. The security level
- * provided is a function of the length of the output used. Read and
- * understand FIPS-202 A.2 "Additional Consideration for Extendable-Output
- * Functions" before using this construct.
- */
- crypto_xof_t *
- crypto_xof_new(void)
- {
- crypto_xof_t *xof;
- xof = tor_malloc(sizeof(crypto_xof_t));
- keccak_xof_init(&xof->s, 256);
- return xof;
- }
- /** Absorb bytes into a XOF object. Must not be called after a call to
- * crypto_xof_squeeze_bytes() for the same instance, and will assert
- * if attempted.
- */
- void
- crypto_xof_add_bytes(crypto_xof_t *xof, const uint8_t *data, size_t len)
- {
- int i = keccak_xof_absorb(&xof->s, data, len);
- tor_assert(i == 0);
- }
- /** Squeeze bytes out of a XOF object. Calling this routine will render
- * the XOF instance ineligible to absorb further data.
- */
- void
- crypto_xof_squeeze_bytes(crypto_xof_t *xof, uint8_t *out, size_t len)
- {
- int i = keccak_xof_squeeze(&xof->s, out, len);
- tor_assert(i == 0);
- }
- /** Cleanse and deallocate a XOF object. */
- void
- crypto_xof_free(crypto_xof_t *xof)
- {
- if (!xof)
- return;
- memwipe(xof, 0, sizeof(crypto_xof_t));
- tor_free(xof);
- }
- /* DH */
- /** Our DH 'g' parameter */
- #define DH_GENERATOR 2
- /** Shared P parameter for our circuit-crypto DH key exchanges. */
- static BIGNUM *dh_param_p = NULL;
- /** Shared P parameter for our TLS DH key exchanges. */
- static BIGNUM *dh_param_p_tls = NULL;
- /** Shared G parameter for our DH key exchanges. */
- static BIGNUM *dh_param_g = NULL;
- /** Validate a given set of Diffie-Hellman parameters. This is moderately
- * computationally expensive (milliseconds), so should only be called when
- * the DH parameters change. Returns 0 on success, * -1 on failure.
- */
- static int
- crypto_validate_dh_params(const BIGNUM *p, const BIGNUM *g)
- {
- DH *dh = NULL;
- int ret = -1;
- /* Copy into a temporary DH object, just so that DH_check() can be called. */
- if (!(dh = DH_new()))
- goto out;
- #ifdef OPENSSL_1_1_API
- BIGNUM *dh_p, *dh_g;
- if (!(dh_p = BN_dup(p)))
- goto out;
- if (!(dh_g = BN_dup(g)))
- goto out;
- if (!DH_set0_pqg(dh, dh_p, NULL, dh_g))
- goto out;
- #else
- if (!(dh->p = BN_dup(p)))
- goto out;
- if (!(dh->g = BN_dup(g)))
- goto out;
- #endif
- /* Perform the validation. */
- int codes = 0;
- if (!DH_check(dh, &codes))
- goto out;
- if (BN_is_word(g, DH_GENERATOR_2)) {
- /* Per https://wiki.openssl.org/index.php/Diffie-Hellman_parameters
- *
- * OpenSSL checks the prime is congruent to 11 when g = 2; while the
- * IETF's primes are congruent to 23 when g = 2.
- */
- BN_ULONG residue = BN_mod_word(p, 24);
- if (residue == 11 || residue == 23)
- codes &= ~DH_NOT_SUITABLE_GENERATOR;
- }
- if (codes != 0) /* Specifics on why the params suck is irrelevant. */
- goto out;
- /* Things are probably not evil. */
- ret = 0;
- out:
- if (dh)
- DH_free(dh);
- return ret;
- }
- /** Set the global Diffie-Hellman generator, used for both TLS and internal
- * DH stuff.
- */
- static void
- crypto_set_dh_generator(void)
- {
- BIGNUM *generator;
- int r;
- if (dh_param_g)
- return;
- generator = BN_new();
- tor_assert(generator);
- r = BN_set_word(generator, DH_GENERATOR);
- tor_assert(r);
- dh_param_g = generator;
- }
- /** Set the global TLS Diffie-Hellman modulus. Use the Apache mod_ssl DH
- * modulus. */
- void
- crypto_set_tls_dh_prime(void)
- {
- BIGNUM *tls_prime = NULL;
- int r;
- /* If the space is occupied, free the previous TLS DH prime */
- if (BUG(dh_param_p_tls)) {
- /* LCOV_EXCL_START
- *
- * We shouldn't be calling this twice.
- */
- BN_clear_free(dh_param_p_tls);
- dh_param_p_tls = NULL;
- /* LCOV_EXCL_STOP */
- }
- tls_prime = BN_new();
- tor_assert(tls_prime);
- /* This is the 1024-bit safe prime that Apache uses for its DH stuff; see
- * modules/ssl/ssl_engine_dh.c; Apache also uses a generator of 2 with this
- * prime.
- */
- r = BN_hex2bn(&tls_prime,
- "D67DE440CBBBDC1936D693D34AFD0AD50C84D239A45F520BB88174CB98"
- "BCE951849F912E639C72FB13B4B4D7177E16D55AC179BA420B2A29FE324A"
- "467A635E81FF5901377BEDDCFD33168A461AAD3B72DAE8860078045B07A7"
- "DBCA7874087D1510EA9FCC9DDD330507DD62DB88AEAA747DE0F4D6E2BD68"
- "B0E7393E0F24218EB3");
- tor_assert(r);
- tor_assert(tls_prime);
- dh_param_p_tls = tls_prime;
- crypto_set_dh_generator();
- tor_assert(0 == crypto_validate_dh_params(dh_param_p_tls, dh_param_g));
- }
- /** Initialize dh_param_p and dh_param_g if they are not already
- * set. */
- static void
- init_dh_param(void)
- {
- BIGNUM *circuit_dh_prime;
- int r;
- if (BUG(dh_param_p && dh_param_g))
- return; // LCOV_EXCL_LINE This function isn't supposed to be called twice.
- circuit_dh_prime = BN_new();
- tor_assert(circuit_dh_prime);
- /* 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 }.
- */
- r = BN_hex2bn(&circuit_dh_prime,
- "FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E08"
- "8A67CC74020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B"
- "302B0A6DF25F14374FE1356D6D51C245E485B576625E7EC6F44C42E9"
- "A637ED6B0BFF5CB6F406B7EDEE386BFB5A899FA5AE9F24117C4B1FE6"
- "49286651ECE65381FFFFFFFFFFFFFFFF");
- tor_assert(r);
- /* Set the new values as the global DH parameters. */
- dh_param_p = circuit_dh_prime;
- crypto_set_dh_generator();
- tor_assert(0 == crypto_validate_dh_params(dh_param_p, dh_param_g));
- if (!dh_param_p_tls) {
- crypto_set_tls_dh_prime();
- }
- }
- /** Number of bits to use when choosing the x or y value in a Diffie-Hellman
- * handshake. Since we exponentiate by this value, choosing a smaller one
- * lets our handhake go faster.
- */
- #define DH_PRIVATE_KEY_BITS 320
- /** Allocate and return a new DH object for a key exchange. Returns NULL on
- * failure.
- */
- crypto_dh_t *
- crypto_dh_new(int dh_type)
- {
- crypto_dh_t *res = tor_malloc_zero(sizeof(crypto_dh_t));
- tor_assert(dh_type == DH_TYPE_CIRCUIT || dh_type == DH_TYPE_TLS ||
- dh_type == DH_TYPE_REND);
- if (!dh_param_p)
- init_dh_param();
- if (!(res->dh = DH_new()))
- goto err;
- #ifdef OPENSSL_1_1_API
- BIGNUM *dh_p = NULL, *dh_g = NULL;
- if (dh_type == DH_TYPE_TLS) {
- dh_p = BN_dup(dh_param_p_tls);
- } else {
- dh_p = BN_dup(dh_param_p);
- }
- if (!dh_p)
- goto err;
- dh_g = BN_dup(dh_param_g);
- if (!dh_g) {
- BN_free(dh_p);
- goto err;
- }
- if (!DH_set0_pqg(res->dh, dh_p, NULL, dh_g)) {
- goto err;
- }
- if (!DH_set_length(res->dh, DH_PRIVATE_KEY_BITS))
- goto err;
- #else
- if (dh_type == DH_TYPE_TLS) {
- if (!(res->dh->p = BN_dup(dh_param_p_tls)))
- goto err;
- } else {
- if (!(res->dh->p = BN_dup(dh_param_p)))
- goto err;
- }
- if (!(res->dh->g = BN_dup(dh_param_g)))
- goto err;
- res->dh->length = DH_PRIVATE_KEY_BITS;
- #endif
- return res;
- err:
- /* LCOV_EXCL_START
- * This error condition is only reached when an allocation fails */
- crypto_log_errors(LOG_WARN, "creating DH object");
- if (res->dh) DH_free(res->dh); /* frees p and g too */
- tor_free(res);
- return NULL;
- /* LCOV_EXCL_STOP */
- }
- /** Return a copy of <b>dh</b>, sharing its internal state. */
- crypto_dh_t *
- crypto_dh_dup(const crypto_dh_t *dh)
- {
- crypto_dh_t *dh_new = tor_malloc_zero(sizeof(crypto_dh_t));
- tor_assert(dh);
- tor_assert(dh->dh);
- dh_new->dh = dh->dh;
- DH_up_ref(dh->dh);
- return dh_new;
- }
- /** Return the length of the DH key in <b>dh</b>, in bytes.
- */
- int
- crypto_dh_get_bytes(crypto_dh_t *dh)
- {
- tor_assert(dh);
- return DH_size(dh->dh);
- }
- /** Generate \<x,g^x\> for our part of the key exchange. Return 0 on
- * success, -1 on failure.
- */
- int
- crypto_dh_generate_public(crypto_dh_t *dh)
- {
- #ifndef OPENSSL_1_1_API
- again:
- #endif
- if (!DH_generate_key(dh->dh)) {
- /* LCOV_EXCL_START
- * To test this we would need some way to tell openssl to break DH. */
- crypto_log_errors(LOG_WARN, "generating DH key");
- return -1;
- /* LCOV_EXCL_STOP */
- }
- #ifdef OPENSSL_1_1_API
- /* OpenSSL 1.1.x doesn't appear to let you regenerate a DH key, without
- * recreating the DH object. I have no idea what sort of aliasing madness
- * can occur here, so do the check, and just bail on failure.
- */
- const BIGNUM *pub_key, *priv_key;
- DH_get0_key(dh->dh, &pub_key, &priv_key);
- if (tor_check_dh_key(LOG_WARN, pub_key)<0) {
- log_warn(LD_CRYPTO, "Weird! Our own DH key was invalid. I guess once-in-"
- "the-universe chances really do happen. Treating as a failure.");
- return -1;
- }
- #else
- if (tor_check_dh_key(LOG_WARN, dh->dh->pub_key)<0) {
- /* LCOV_EXCL_START
- * If this happens, then openssl's DH implementation is busted. */
- log_warn(LD_CRYPTO, "Weird! Our own DH key was invalid. I guess once-in-"
- "the-universe chances really do happen. Trying again.");
- /* Free and clear the keys, so OpenSSL will actually try again. */
- BN_clear_free(dh->dh->pub_key);
- BN_clear_free(dh->dh->priv_key);
- dh->dh->pub_key = dh->dh->priv_key = NULL;
- goto again;
- /* LCOV_EXCL_STOP */
- }
- #endif
- return 0;
- }
- /** Generate g^x as necessary, and write the g^x for the key exchange
- * as a <b>pubkey_len</b>-byte value into <b>pubkey</b>. Return 0 on
- * success, -1 on failure. <b>pubkey_len</b> must be \>= DH_BYTES.
- */
- int
- crypto_dh_get_public(crypto_dh_t *dh, char *pubkey, size_t pubkey_len)
- {
- int bytes;
- tor_assert(dh);
- const BIGNUM *dh_pub;
- #ifdef OPENSSL_1_1_API
- const BIGNUM *dh_priv;
- DH_get0_key(dh->dh, &dh_pub, &dh_priv);
- #else
- dh_pub = dh->dh->pub_key;
- #endif
- if (!dh_pub) {
- if (crypto_dh_generate_public(dh)<0)
- return -1;
- else {
- #ifdef OPENSSL_1_1_API
- DH_get0_key(dh->dh, &dh_pub, &dh_priv);
- #else
- dh_pub = dh->dh->pub_key;
- #endif
- }
- }
- tor_assert(dh_pub);
- bytes = BN_num_bytes(dh_pub);
- tor_assert(bytes >= 0);
- if (pubkey_len < (size_t)bytes) {
- log_warn(LD_CRYPTO,
- "Weird! pubkey_len (%d) was smaller than DH_BYTES (%d)",
- (int) pubkey_len, bytes);
- return -1;
- }
- memset(pubkey, 0, pubkey_len);
- BN_bn2bin(dh_pub, (unsigned char*)(pubkey+(pubkey_len-bytes)));
- return 0;
- }
- /** Check for bad Diffie-Hellman public keys (g^x). Return 0 if the key is
- * okay (in the subgroup [2,p-2]), or -1 if it's bad.
- * See http://www.cl.cam.ac.uk/ftp/users/rja14/psandqs.ps.gz for some tips.
- */
- static int
- tor_check_dh_key(int severity, const BIGNUM *bn)
- {
- BIGNUM *x;
- char *s;
- tor_assert(bn);
- x = BN_new();
- tor_assert(x);
- if (BUG(!dh_param_p))
- init_dh_param(); //LCOV_EXCL_LINE we already checked whether we did this.
- BN_set_word(x, 1);
- if (BN_cmp(bn,x)<=0) {
- log_fn(severity, LD_CRYPTO, "DH key must be at least 2.");
- goto err;
- }
- BN_copy(x,dh_param_p);
- BN_sub_word(x, 1);
- if (BN_cmp(bn,x)>=0) {
- log_fn(severity, LD_CRYPTO, "DH key must be at most p-2.");
- goto err;
- }
- BN_clear_free(x);
- return 0;
- err:
- BN_clear_free(x);
- s = BN_bn2hex(bn);
- log_fn(severity, LD_CRYPTO, "Rejecting insecure DH key [%s]", s);
- OPENSSL_free(s);
- return -1;
- }
- /** Given a DH key exchange object, and our peer's value of g^y (as a
- * <b>pubkey_len</b>-byte value in <b>pubkey</b>) generate
- * <b>secret_bytes_out</b> bytes of shared key material and write them
- * to <b>secret_out</b>. Return the number of bytes generated on success,
- * or -1 on failure.
- *
- * (We generate key material by computing
- * SHA1( g^xy || "\x00" ) || SHA1( g^xy || "\x01" ) || ...
- * where || is concatenation.)
- */
- ssize_t
- crypto_dh_compute_secret(int severity, crypto_dh_t *dh,
- const char *pubkey, size_t pubkey_len,
- char *secret_out, size_t secret_bytes_out)
- {
- char *secret_tmp = NULL;
- BIGNUM *pubkey_bn = NULL;
- size_t secret_len=0, secret_tmp_len=0;
- int result=0;
- tor_assert(dh);
- tor_assert(secret_bytes_out/DIGEST_LEN <= 255);
- tor_assert(pubkey_len < INT_MAX);
- if (!(pubkey_bn = BN_bin2bn((const unsigned char*)pubkey,
- (int)pubkey_len, NULL)))
- goto error;
- if (tor_check_dh_key(severity, pubkey_bn)<0) {
- /* Check for invalid public keys. */
- log_fn(severity, LD_CRYPTO,"Rejected invalid g^x");
- goto error;
- }
- secret_tmp_len = crypto_dh_get_bytes(dh);
- secret_tmp = tor_malloc(secret_tmp_len);
- result = DH_compute_key((unsigned char*)secret_tmp, pubkey_bn, dh->dh);
- if (result < 0) {
- log_warn(LD_CRYPTO,"DH_compute_key() failed.");
- goto error;
- }
- secret_len = result;
- if (crypto_expand_key_material_TAP((uint8_t*)secret_tmp, secret_len,
- (uint8_t*)secret_out, secret_bytes_out)<0)
- goto error;
- secret_len = secret_bytes_out;
- goto done;
- error:
- result = -1;
- done:
- crypto_log_errors(LOG_WARN, "completing DH handshake");
- if (pubkey_bn)
- BN_clear_free(pubkey_bn);
- if (secret_tmp) {
- memwipe(secret_tmp, 0, secret_tmp_len);
- tor_free(secret_tmp);
- }
- if (result < 0)
- return result;
- else
- return secret_len;
- }
- /** Given <b>key_in_len</b> bytes of negotiated randomness in <b>key_in</b>
- * ("K"), expand it into <b>key_out_len</b> bytes of negotiated key material in
- * <b>key_out</b> by taking the first <b>key_out_len</b> bytes of
- * H(K | [00]) | H(K | [01]) | ....
- *
- * This is the key expansion algorithm used in the "TAP" circuit extension
- * mechanism; it shouldn't be used for new protocols.
- *
- * Return 0 on success, -1 on failure.
- */
- int
- crypto_expand_key_material_TAP(const uint8_t *key_in, size_t key_in_len,
- uint8_t *key_out, size_t key_out_len)
- {
- int i, r = -1;
- uint8_t *cp, *tmp = tor_malloc(key_in_len+1);
- uint8_t digest[DIGEST_LEN];
- /* If we try to get more than this amount of key data, we'll repeat blocks.*/
- tor_assert(key_out_len <= DIGEST_LEN*256);
- memcpy(tmp, key_in, key_in_len);
- for (cp = key_out, i=0; cp < key_out+key_out_len;
- ++i, cp += DIGEST_LEN) {
- tmp[key_in_len] = i;
- if (crypto_digest((char*)digest, (const char *)tmp, key_in_len+1))
- goto exit;
- memcpy(cp, digest, MIN(DIGEST_LEN, key_out_len-(cp-key_out)));
- }
- r = 0;
- exit:
- memwipe(tmp, 0, key_in_len+1);
- tor_free(tmp);
- memwipe(digest, 0, sizeof(digest));
- return r;
- }
- /** Expand some secret key material according to RFC5869, using SHA256 as the
- * underlying hash. The <b>key_in_len</b> bytes at <b>key_in</b> are the
- * secret key material; the <b>salt_in_len</b> bytes at <b>salt_in</b> and the
- * <b>info_in_len</b> bytes in <b>info_in_len</b> are the algorithm's "salt"
- * and "info" parameters respectively. On success, write <b>key_out_len</b>
- * bytes to <b>key_out</b> and return 0. Assert on failure.
- */
- int
- crypto_expand_key_material_rfc5869_sha256(
- const uint8_t *key_in, size_t key_in_len,
- const uint8_t *salt_in, size_t salt_in_len,
- const uint8_t *info_in, size_t info_in_len,
- uint8_t *key_out, size_t key_out_len)
- {
- uint8_t prk[DIGEST256_LEN];
- uint8_t tmp[DIGEST256_LEN + 128 + 1];
- uint8_t mac[DIGEST256_LEN];
- int i;
- uint8_t *outp;
- size_t tmp_len;
- crypto_hmac_sha256((char*)prk,
- (const char*)salt_in, salt_in_len,
- (const char*)key_in, key_in_len);
- /* If we try to get more than this amount of key data, we'll repeat blocks.*/
- tor_assert(key_out_len <= DIGEST256_LEN * 256);
- tor_assert(info_in_len <= 128);
- memset(tmp, 0, sizeof(tmp));
- outp = key_out;
- i = 1;
- while (key_out_len) {
- size_t n;
- if (i > 1) {
- memcpy(tmp, mac, DIGEST256_LEN);
- memcpy(tmp+DIGEST256_LEN, info_in, info_in_len);
- tmp[DIGEST256_LEN+info_in_len] = i;
- tmp_len = DIGEST256_LEN + info_in_len + 1;
- } else {
- memcpy(tmp, info_in, info_in_len);
- tmp[info_in_len] = i;
- tmp_len = info_in_len + 1;
- }
- crypto_hmac_sha256((char*)mac,
- (const char*)prk, DIGEST256_LEN,
- (const char*)tmp, tmp_len);
- n = key_out_len < DIGEST256_LEN ? key_out_len : DIGEST256_LEN;
- memcpy(outp, mac, n);
- key_out_len -= n;
- outp += n;
- ++i;
- }
- memwipe(tmp, 0, sizeof(tmp));
- memwipe(mac, 0, sizeof(mac));
- return 0;
- }
- /** Free a DH key exchange object.
- */
- void
- crypto_dh_free(crypto_dh_t *dh)
- {
- if (!dh)
- return;
- tor_assert(dh->dh);
- DH_free(dh->dh);
- tor_free(dh);
- }
- /* random numbers */
- /** How many bytes of entropy we add at once.
- *
- * This is how much entropy OpenSSL likes to add right now, so maybe it will
- * work for us too. */
- #define ADD_ENTROPY 32
- /** Set the seed of the weak RNG to a random value. */
- void
- crypto_seed_weak_rng(tor_weak_rng_t *rng)
- {
- unsigned seed;
- crypto_rand((void*)&seed, sizeof(seed));
- tor_init_weak_random(rng, seed);
- }
- #ifdef TOR_UNIT_TESTS
- int break_strongest_rng_syscall = 0;
- int break_strongest_rng_fallback = 0;
- #endif
- /** Try to get <b>out_len</b> bytes of the strongest entropy we can generate,
- * via system calls, storing it into <b>out</b>. Return 0 on success, -1 on
- * failure. A maximum request size of 256 bytes is imposed.
- */
- static int
- crypto_strongest_rand_syscall(uint8_t *out, size_t out_len)
- {
- tor_assert(out_len <= MAX_STRONGEST_RAND_SIZE);
- #ifdef TOR_UNIT_TESTS
- if (break_strongest_rng_syscall)
- return -1;
- #endif
- #if defined(_WIN32)
- static int provider_set = 0;
- static HCRYPTPROV provider;
- if (!provider_set) {
- if (!CryptAcquireContext(&provider, NULL, NULL, PROV_RSA_FULL,
- CRYPT_VERIFYCONTEXT)) {
- log_warn(LD_CRYPTO, "Can't get CryptoAPI provider [1]");
- return -1;
- }
- provider_set = 1;
- }
- if (!CryptGenRandom(provider, out_len, out)) {
- log_warn(LD_CRYPTO, "Can't get entropy from CryptoAPI.");
- return -1;
- }
- return 0;
- #elif defined(__linux__) && defined(SYS_getrandom)
- static int getrandom_works = 1; /* Be optimitic about our chances... */
- /* getrandom() isn't as straight foward as getentropy(), and has
- * no glibc wrapper.
- *
- * As far as I can tell from getrandom(2) and the source code, the
- * requests we issue will always succeed (though it will block on the
- * call if /dev/urandom isn't seeded yet), since we are NOT specifying
- * GRND_NONBLOCK and the request is <= 256 bytes.
- *
- * The manpage is unclear on what happens if a signal interrupts the call
- * while the request is blocked due to lack of entropy....
- *
- * We optimistically assume that getrandom() is available and functional
- * because it is the way of the future, and 2 branch mispredicts pale in
- * comparision to the overheads involved with failing to open
- * /dev/srandom followed by opening and reading from /dev/urandom.
- */
- if (PREDICT_LIKELY(getrandom_works)) {
- long ret;
- /* A flag of '0' here means to read from '/dev/urandom', and to
- * block if insufficient entropy is available to service the
- * request.
- */
- const unsigned int flags = 0;
- do {
- ret = syscall(SYS_getrandom, out, out_len, flags);
- } while (ret == -1 && ((errno == EINTR) ||(errno == EAGAIN)));
- if (PREDICT_UNLIKELY(ret == -1)) {
- /* LCOV_EXCL_START we can't actually make the syscall fail in testing. */
- tor_assert(errno != EAGAIN);
- tor_assert(errno != EINTR);
- /* Probably ENOSYS. */
- log_warn(LD_CRYPTO, "Can't get entropy from getrandom().");
- getrandom_works = 0; /* Don't bother trying again. */
- return -1;
- /* LCOV_EXCL_STOP */
- }
- tor_assert(ret == (long)out_len);
- return 0;
- }
- return -1; /* getrandom() previously failed unexpectedly. */
- #elif defined(HAVE_GETENTROPY)
- /* getentropy() is what Linux's getrandom() wants to be when it grows up.
- * the only gotcha is that requests are limited to 256 bytes.
- */
- return getentropy(out, out_len);
- #else
- (void) out;
- #endif
- /* This platform doesn't have a supported syscall based random. */
- return -1;
- }
- /** Try to get <b>out_len</b> bytes of the strongest entropy we can generate,
- * via the per-platform fallback mechanism, storing it into <b>out</b>.
- * Return 0 on success, -1 on failure. A maximum request size of 256 bytes
- * is imposed.
- */
- static int
- crypto_strongest_rand_fallback(uint8_t *out, size_t out_len)
- {
- #ifdef TOR_UNIT_TESTS
- if (break_strongest_rng_fallback)
- return -1;
- #endif
- #ifdef _WIN32
- /* Windows exclusively uses crypto_strongest_rand_syscall(). */
- (void)out;
- (void)out_len;
- return -1;
- #else
- static const char *filenames[] = {
- "/dev/srandom", "/dev/urandom", "/dev/random", NULL
- };
- int fd, i;
- size_t n;
- for (i = 0; filenames[i]; ++i) {
- log_debug(LD_FS, "Opening %s for entropy", filenames[i]);
- fd = open(sandbox_intern_string(filenames[i]), O_RDONLY, 0);
- if (fd<0) continue;
- log_info(LD_CRYPTO, "Reading entropy from \"%s\"", filenames[i]);
- n = read_all(fd, (char*)out, out_len, 0);
- close(fd);
- if (n != out_len) {
- /* LCOV_EXCL_START
- * We can't make /dev/foorandom actually fail. */
- log_warn(LD_CRYPTO,
- "Error reading from entropy source (read only %lu bytes).",
- (unsigned long)n);
- return -1;
- /* LCOV_EXCL_STOP */
- }
- return 0;
- }
- return -1;
- #endif
- }
- /** Try to get <b>out_len</b> bytes of the strongest entropy we can generate,
- * storing it into <b>out</b>. Return 0 on success, -1 on failure. A maximum
- * request size of 256 bytes is imposed.
- */
- STATIC int
- crypto_strongest_rand_raw(uint8_t *out, size_t out_len)
- {
- static const size_t sanity_min_size = 16;
- static const int max_attempts = 3;
- tor_assert(out_len <= MAX_STRONGEST_RAND_SIZE);
- /* For buffers >= 16 bytes (128 bits), we sanity check the output by
- * zero filling the buffer and ensuring that it actually was at least
- * partially modified.
- *
- * Checking that any individual byte is non-zero seems like it would
- * fail too often (p = out_len * 1/256) for comfort, but this is an
- * "adjust according to taste" sort of check.
- */
- memwipe(out, 0, out_len);
- for (int i = 0; i < max_attempts; i++) {
- /* Try to use the syscall/OS favored mechanism to get strong entropy. */
- if (crypto_strongest_rand_syscall(out, out_len) != 0) {
- /* Try to use the less-favored mechanism to get strong entropy. */
- if (crypto_strongest_rand_fallback(out, out_len) != 0) {
- /* Welp, we tried. Hopefully the calling code terminates the process
- * since we're basically boned without good entropy.
- */
- log_warn(LD_CRYPTO,
- "Cannot get strong entropy: no entropy source found.");
- return -1;
- }
- }
- if ((out_len < sanity_min_size) || !tor_mem_is_zero((char*)out, out_len))
- return 0;
- }
- /* LCOV_EXCL_START
- *
- * We tried max_attempts times to fill a buffer >= 128 bits long,
- * and each time it returned all '0's. Either the system entropy
- * source is busted, or the user should go out and buy a ticket to
- * every lottery on the planet.
- */
- log_warn(LD_CRYPTO, "Strong OS entropy returned all zero buffer.");
- return -1;
- /* LCOV_EXCL_STOP */
- }
- /** Try to get <b>out_len</b> bytes of the strongest entropy we can generate,
- * storing it into <b>out</b>.
- */
- void
- crypto_strongest_rand(uint8_t *out, size_t out_len)
- {
- #define DLEN SHA512_DIGEST_LENGTH
- /* We're going to hash DLEN bytes from the system RNG together with some
- * bytes from the openssl PRNG, in order to yield DLEN bytes.
- */
- uint8_t inp[DLEN*2];
- uint8_t tmp[DLEN];
- tor_assert(out);
- while (out_len) {
- crypto_rand((char*) inp, DLEN);
- if (crypto_strongest_rand_raw(inp+DLEN, DLEN) < 0) {
- // LCOV_EXCL_START
- log_err(LD_CRYPTO, "Failed to load strong entropy when generating an "
- "important key. Exiting.");
- /* Die with an assertion so we get a stack trace. */
- tor_assert(0);
- // LCOV_EXCL_STOP
- }
- if (out_len >= DLEN) {
- SHA512(inp, sizeof(inp), out);
- out += DLEN;
- out_len -= DLEN;
- } else {
- SHA512(inp, sizeof(inp), tmp);
- memcpy(out, tmp, out_len);
- break;
- }
- }
- memwipe(tmp, 0, sizeof(tmp));
- memwipe(inp, 0, sizeof(inp));
- #undef DLEN
- }
- /** Seed OpenSSL's random number generator with bytes from the operating
- * system. Return 0 on success, -1 on failure.
- */
- int
- crypto_seed_rng(void)
- {
- int rand_poll_ok = 0, load_entropy_ok = 0;
- uint8_t buf[ADD_ENTROPY];
- /* OpenSSL has a RAND_poll function that knows about more kinds of
- * entropy than we do. We'll try calling that, *and* calling our own entropy
- * functions. If one succeeds, we'll accept the RNG as seeded. */
- rand_poll_ok = RAND_poll();
- if (rand_poll_ok == 0)
- log_warn(LD_CRYPTO, "RAND_poll() failed."); // LCOV_EXCL_LINE
- load_entropy_ok = !crypto_strongest_rand_raw(buf, sizeof(buf));
- if (load_entropy_ok) {
- RAND_seed(buf, sizeof(buf));
- }
- memwipe(buf, 0, sizeof(buf));
- if ((rand_poll_ok || load_entropy_ok) && RAND_status() == 1)
- return 0;
- else
- return -1;
- }
- /** Write <b>n</b> bytes of strong random data to <b>to</b>. Supports mocking
- * for unit tests.
- *
- * This function is not allowed to fail; if it would fail to generate strong
- * entropy, it must terminate the process instead.
- */
- MOCK_IMPL(void,
- crypto_rand, (char *to, size_t n))
- {
- crypto_rand_unmocked(to, n);
- }
- /** Write <b>n</b> bytes of strong random data to <b>to</b>. Most callers
- * will want crypto_rand instead.
- *
- * This function is not allowed to fail; if it would fail to generate strong
- * entropy, it must terminate the process instead.
- */
- void
- crypto_rand_unmocked(char *to, size_t n)
- {
- int r;
- if (n == 0)
- return;
- tor_assert(n < INT_MAX);
- tor_assert(to);
- r = RAND_bytes((unsigned char*)to, (int)n);
- /* We consider a PRNG failure non-survivable. Let's assert so that we get a
- * stack trace about where it happened.
- */
- tor_assert(r >= 0);
- }
- /** Return a pseudorandom integer, chosen uniformly from the values
- * between 0 and <b>max</b>-1 inclusive. <b>max</b> must be between 1 and
- * INT_MAX+1, inclusive. */
- int
- crypto_rand_int(unsigned int max)
- {
- unsigned int val;
- unsigned int cutoff;
- tor_assert(max <= ((unsigned int)INT_MAX)+1);
- 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_rand((char*)&val, sizeof(val));
- if (val < cutoff)
- return val % max;
- }
- }
- /** Return a pseudorandom integer, chosen uniformly from the values i such
- * that min <= i < max.
- *
- * <b>min</b> MUST be in range [0, <b>max</b>).
- * <b>max</b> MUST be in range (min, INT_MAX].
- */
- int
- crypto_rand_int_range(unsigned int min, unsigned int max)
- {
- tor_assert(min < max);
- tor_assert(max <= INT_MAX);
- /* The overflow is avoided here because crypto_rand_int() returns a value
- * between 0 and (max - min) inclusive. */
- return min + crypto_rand_int(max - min);
- }
- /** As crypto_rand_int_range, but supports uint64_t. */
- uint64_t
- crypto_rand_uint64_range(uint64_t min, uint64_t max)
- {
- tor_assert(min < max);
- return min + crypto_rand_uint64(max - min);
- }
- /** As crypto_rand_int_range, but supports time_t. */
- time_t
- crypto_rand_time_range(time_t min, time_t max)
- {
- tor_assert(min < max);
- return min + (time_t)crypto_rand_uint64(max - min);
- }
- /** Return a pseudorandom 64-bit integer, chosen uniformly from the values
- * between 0 and <b>max</b>-1 inclusive. */
- uint64_t
- crypto_rand_uint64(uint64_t max)
- {
- uint64_t val;
- uint64_t cutoff;
- tor_assert(max < UINT64_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 = UINT64_MAX - (UINT64_MAX%max);
- while (1) {
- crypto_rand((char*)&val, sizeof(val));
- if (val < cutoff)
- return val % max;
- }
- }
- /** Return a pseudorandom double d, chosen uniformly from the range
- * 0.0 <= d < 1.0.
- */
- double
- crypto_rand_double(void)
- {
- /* We just use an unsigned int here; we don't really care about getting
- * more than 32 bits of resolution */
- unsigned int u;
- crypto_rand((char*)&u, sizeof(u));
- #if SIZEOF_INT == 4
- #define UINT_MAX_AS_DOUBLE 4294967296.0
- #elif SIZEOF_INT == 8
- #define UINT_MAX_AS_DOUBLE 1.8446744073709552e+19
- #else
- #error SIZEOF_INT is neither 4 nor 8
- #endif
- return ((double)u) / UINT_MAX_AS_DOUBLE;
- }
- /** Generate and return a new random hostname starting with <b>prefix</b>,
- * ending with <b>suffix</b>, and containing no fewer than
- * <b>min_rand_len</b> and no more than <b>max_rand_len</b> random base32
- * characters. Does not check for failure.
- *
- * Clip <b>max_rand_len</b> to MAX_DNS_LABEL_SIZE.
- **/
- char *
- crypto_random_hostname(int min_rand_len, int max_rand_len, const char *prefix,
- const char *suffix)
- {
- char *result, *rand_bytes;
- int randlen, rand_bytes_len;
- size_t resultlen, prefixlen;
- if (max_rand_len > MAX_DNS_LABEL_SIZE)
- max_rand_len = MAX_DNS_LABEL_SIZE;
- if (min_rand_len > max_rand_len)
- min_rand_len = max_rand_len;
- randlen = crypto_rand_int_range(min_rand_len, max_rand_len+1);
- prefixlen = strlen(prefix);
- resultlen = prefixlen + strlen(suffix) + randlen + 16;
- rand_bytes_len = ((randlen*5)+7)/8;
- if (rand_bytes_len % 5)
- rand_bytes_len += 5 - (rand_bytes_len%5);
- rand_bytes = tor_malloc(rand_bytes_len);
- crypto_rand(rand_bytes, rand_bytes_len);
- result = tor_malloc(resultlen);
- memcpy(result, prefix, prefixlen);
- base32_encode(result+prefixlen, resultlen-prefixlen,
- rand_bytes, rand_bytes_len);
- tor_free(rand_bytes);
- strlcpy(result+prefixlen+randlen, suffix, resultlen-(prefixlen+randlen));
- return result;
- }
- /** Return a randomly chosen element of <b>sl</b>; or NULL if <b>sl</b>
- * is empty. */
- void *
- smartlist_choose(const smartlist_t *sl)
- {
- int len = smartlist_len(sl);
- if (len)
- return smartlist_get(sl,crypto_rand_int(len));
- return NULL; /* no elements to choose from */
- }
- /** Scramble the elements of <b>sl</b> into a random order. */
- void
- smartlist_shuffle(smartlist_t *sl)
- {
- int i;
- /* From the end of the list to the front, choose at random from the
- positions we haven't looked at yet, and swap that position into the
- current position. Remember to give "no swap" the same probability as
- any other swap. */
- for (i = smartlist_len(sl)-1; i > 0; --i) {
- int j = crypto_rand_int(i+1);
- smartlist_swap(sl, i, j);
- }
- }
- /**
- * Destroy the <b>sz</b> bytes of data stored at <b>mem</b>, setting them to
- * the value <b>byte</b>.
- * If <b>mem</b> is NULL or <b>sz</b> is zero, nothing happens.
- *
- * This function is preferable to memset, since many compilers will happily
- * optimize out memset() when they can convince themselves that the data being
- * cleared will never be read.
- *
- * Right now, our convention is to use this function when we are wiping data
- * that's about to become inaccessible, such as stack buffers that are about
- * to go out of scope or structures that are about to get freed. (In
- * practice, it appears that the compilers we're currently using will optimize
- * out the memset()s for stack-allocated buffers, but not those for
- * about-to-be-freed structures. That could change, though, so we're being
- * wary.) If there are live reads for the data, then you can just use
- * memset().
- */
- void
- memwipe(void *mem, uint8_t byte, size_t sz)
- {
- if (sz == 0) {
- return;
- }
- /* If sz is nonzero, then mem must not be NULL. */
- tor_assert(mem != NULL);
- /* Data this large is likely to be an underflow. */
- tor_assert(sz < SIZE_T_CEILING);
- /* Because whole-program-optimization exists, we may not be able to just
- * have this function call "memset". A smart compiler could inline it, then
- * eliminate dead memsets, and declare itself to be clever. */
- #if defined(SecureZeroMemory) || defined(HAVE_SECUREZEROMEMORY)
- /* Here's what you do on windows. */
- SecureZeroMemory(mem,sz);
- #elif defined(HAVE_RTLSECUREZEROMEMORY)
- RtlSecureZeroMemory(mem,sz);
- #elif defined(HAVE_EXPLICIT_BZERO)
- /* The BSDs provide this. */
- explicit_bzero(mem, sz);
- #elif defined(HAVE_MEMSET_S)
- /* This is in the C99 standard. */
- memset_s(mem, sz, 0, sz);
- #else
- /* This is a slow and ugly function from OpenSSL that fills 'mem' with junk
- * based on the pointer value, then uses that junk to update a global
- * variable. It's an elaborate ruse to trick the compiler into not
- * optimizing out the "wipe this memory" code. Read it if you like zany
- * programming tricks! In later versions of Tor, we should look for better
- * not-optimized-out memory wiping stuff...
- *
- * ...or maybe not. In practice, there are pure-asm implementations of
- * OPENSSL_cleanse() on most platforms, which ought to do the job.
- **/
- OPENSSL_cleanse(mem, sz);
- #endif
- /* Just in case some caller of memwipe() is relying on getting a buffer
- * filled with a particular value, fill the buffer.
- *
- * If this function gets inlined, this memset might get eliminated, but
- * that's okay: We only care about this particular memset in the case where
- * the caller should have been using memset(), and the memset() wouldn't get
- * eliminated. In other words, this is here so that we won't break anything
- * if somebody accidentally calls memwipe() instead of memset().
- **/
- memset(mem, byte, sz);
- }
- #ifndef OPENSSL_THREADS
- #error OpenSSL has been built without thread support. Tor requires an \
- OpenSSL library with thread support enabled.
- #endif
- #ifndef NEW_THREAD_API
- /** Helper: OpenSSL uses this callback to manipulate mutexes. */
- static void
- openssl_locking_cb_(int mode, int n, const char *file, int line)
- {
- (void)file;
- (void)line;
- if (!openssl_mutexes_)
- /* This is not a really good fix for the
- * "release-freed-lock-from-separate-thread-on-shutdown" problem, but
- * it can't hurt. */
- return;
- if (mode & CRYPTO_LOCK)
- tor_mutex_acquire(openssl_mutexes_[n]);
- else
- tor_mutex_release(openssl_mutexes_[n]);
- }
- static void
- tor_set_openssl_thread_id(CRYPTO_THREADID *threadid)
- {
- CRYPTO_THREADID_set_numeric(threadid, tor_get_thread_id());
- }
- #endif
- #if 0
- /* This code is disabled, because OpenSSL never actually uses these callbacks.
- */
- /** OpenSSL helper type: wraps a Tor mutex so that OpenSSL can use it
- * as a lock. */
- struct CRYPTO_dynlock_value {
- tor_mutex_t *lock;
- };
- /** OpenSSL callback function to allocate a lock: see CRYPTO_set_dynlock_*
- * documentation in OpenSSL's docs for more info. */
- static struct CRYPTO_dynlock_value *
- openssl_dynlock_create_cb_(const char *file, int line)
- {
- struct CRYPTO_dynlock_value *v;
- (void)file;
- (void)line;
- v = tor_malloc(sizeof(struct CRYPTO_dynlock_value));
- v->lock = tor_mutex_new();
- return v;
- }
- /** OpenSSL callback function to acquire or release a lock: see
- * CRYPTO_set_dynlock_* documentation in OpenSSL's docs for more info. */
- static void
- openssl_dynlock_lock_cb_(int mode, struct CRYPTO_dynlock_value *v,
- const char *file, int line)
- {
- (void)file;
- (void)line;
- if (mode & CRYPTO_LOCK)
- tor_mutex_acquire(v->lock);
- else
- tor_mutex_release(v->lock);
- }
- /** OpenSSL callback function to free a lock: see CRYPTO_set_dynlock_*
- * documentation in OpenSSL's docs for more info. */
- static void
- openssl_dynlock_destroy_cb_(struct CRYPTO_dynlock_value *v,
- const char *file, int line)
- {
- (void)file;
- (void)line;
- tor_mutex_free(v->lock);
- tor_free(v);
- }
- #endif
- /** @{ */
- /** Helper: Construct mutexes, and set callbacks to help OpenSSL handle being
- * multithreaded. Returns 0. */
- static int
- setup_openssl_threading(void)
- {
- #ifndef NEW_THREAD_API
- int i;
- int n = CRYPTO_num_locks();
- n_openssl_mutexes_ = n;
- openssl_mutexes_ = tor_calloc(n, sizeof(tor_mutex_t *));
- for (i=0; i < n; ++i)
- openssl_mutexes_[i] = tor_mutex_new();
- CRYPTO_set_locking_callback(openssl_locking_cb_);
- CRYPTO_THREADID_set_callback(tor_set_openssl_thread_id);
- #endif
- #if 0
- CRYPTO_set_dynlock_create_callback(openssl_dynlock_create_cb_);
- CRYPTO_set_dynlock_lock_callback(openssl_dynlock_lock_cb_);
- CRYPTO_set_dynlock_destroy_callback(openssl_dynlock_destroy_cb_);
- #endif
- return 0;
- }
- /** Uninitialize the crypto library. Return 0 on success. Does not detect
- * failure.
- */
- int
- crypto_global_cleanup(void)
- {
- EVP_cleanup();
- #ifndef NEW_THREAD_API
- ERR_remove_thread_state(NULL);
- #endif
- ERR_free_strings();
- if (dh_param_p)
- BN_clear_free(dh_param_p);
- if (dh_param_p_tls)
- BN_clear_free(dh_param_p_tls);
- if (dh_param_g)
- BN_clear_free(dh_param_g);
- #ifndef DISABLE_ENGINES
- ENGINE_cleanup();
- #endif
- CONF_modules_unload(1);
- CRYPTO_cleanup_all_ex_data();
- #ifndef NEW_THREAD_API
- if (n_openssl_mutexes_) {
- int n = n_openssl_mutexes_;
- tor_mutex_t **ms = openssl_mutexes_;
- int i;
- openssl_mutexes_ = NULL;
- n_openssl_mutexes_ = 0;
- for (i=0;i<n;++i) {
- tor_mutex_free(ms[i]);
- }
- tor_free(ms);
- }
- #endif
- tor_free(crypto_openssl_version_str);
- tor_free(crypto_openssl_header_version_str);
- return 0;
- }
- /** @} */
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