Files
wolfssl/src/ssl.c
T
Daniel Pouzzner 8c7ab8eb4f Merge pull request #10686 from Frauschi/openssl_group_align
Align wolfSSL_set1_groups_list() arg handling with OpenSSL
2026-07-03 01:17:33 -05:00

16920 lines
500 KiB
C

/* ssl.c
*
* Copyright (C) 2006-2026 wolfSSL Inc.
*
* This file is part of wolfSSL.
*
* wolfSSL is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* wolfSSL is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335, USA
*/
#include <wolfssl/wolfcrypt/libwolfssl_sources.h>
#if defined(OPENSSL_EXTRA) && !defined(_WIN32) && !defined(_GNU_SOURCE)
/* turn on GNU extensions for XISASCII */
#define _GNU_SOURCE 1
#endif
#if !defined(WOLFCRYPT_ONLY) || defined(OPENSSL_EXTRA) || \
defined(OPENSSL_EXTRA_X509_SMALL)
#include <wolfssl/internal.h>
#include <wolfssl/error-ssl.h>
#include <wolfssl/wolfcrypt/error-crypt.h>
#include <wolfssl/wolfcrypt/coding.h>
#include <wolfssl/wolfcrypt/kdf.h>
#ifdef NO_INLINE
#include <wolfssl/wolfcrypt/misc.h>
#else
#define WOLFSSL_MISC_INCLUDED
#include <wolfcrypt/src/misc.c>
#endif
#ifdef HAVE_ERRNO_H
#include <errno.h>
#endif
#if !defined(WOLFSSL_ALLOW_NO_SUITES) && !defined(WOLFCRYPT_ONLY)
#if defined(NO_DH) && !defined(HAVE_ECC) && !defined(WOLFSSL_STATIC_RSA) \
&& !defined(WOLFSSL_STATIC_DH) && !defined(WOLFSSL_STATIC_PSK) \
&& !defined(HAVE_CURVE25519) && !defined(HAVE_CURVE448)
#error "No cipher suites defined because DH disabled, ECC disabled, " \
"and no static suites defined. Please see top of README"
#endif
#ifdef WOLFSSL_CERT_GEN
/* need access to Cert struct for creating certificate */
#include <wolfssl/wolfcrypt/asn_public.h>
#endif
#endif
#if !defined(WOLFCRYPT_ONLY) && (defined(OPENSSL_EXTRA) \
|| defined(OPENSSL_EXTRA_X509_SMALL) \
|| defined(HAVE_WEBSERVER) || defined(WOLFSSL_KEY_GEN))
#include <wolfssl/openssl/evp.h>
/* openssl headers end, wolfssl internal headers next */
#endif
#include <wolfssl/wolfcrypt/wc_encrypt.h>
#ifndef NO_RSA
#include <wolfssl/wolfcrypt/rsa.h>
#endif
#ifdef OPENSSL_EXTRA
/* openssl headers begin */
#include <wolfssl/openssl/ssl.h>
#include <wolfssl/openssl/aes.h>
#ifndef WOLFCRYPT_ONLY
#include <wolfssl/openssl/hmac.h>
#include <wolfssl/openssl/cmac.h>
#endif
#include <wolfssl/openssl/crypto.h>
#include <wolfssl/openssl/des.h>
#include <wolfssl/openssl/bn.h>
#include <wolfssl/openssl/buffer.h>
#include <wolfssl/openssl/dh.h>
#include <wolfssl/openssl/rsa.h>
#include <wolfssl/openssl/fips_rand.h>
#include <wolfssl/openssl/pem.h>
#include <wolfssl/openssl/ec.h>
#include <wolfssl/openssl/ec25519.h>
#include <wolfssl/openssl/ed25519.h>
#include <wolfssl/openssl/ec448.h>
#include <wolfssl/openssl/ed448.h>
#include <wolfssl/openssl/ecdsa.h>
#include <wolfssl/openssl/ecdh.h>
#include <wolfssl/openssl/err.h>
#include <wolfssl/openssl/modes.h>
#include <wolfssl/openssl/opensslv.h>
#include <wolfssl/openssl/rc4.h>
#include <wolfssl/openssl/stack.h>
#include <wolfssl/openssl/x509_vfy.h>
/* openssl headers end, wolfssl internal headers next */
#include <wolfssl/wolfcrypt/hmac.h>
#include <wolfssl/wolfcrypt/random.h>
#include <wolfssl/wolfcrypt/des3.h>
#include <wolfssl/wolfcrypt/ecc.h>
#include <wolfssl/wolfcrypt/md4.h>
#include <wolfssl/wolfcrypt/md5.h>
#include <wolfssl/wolfcrypt/arc4.h>
#include <wolfssl/wolfcrypt/curve25519.h>
#include <wolfssl/wolfcrypt/ed25519.h>
#include <wolfssl/wolfcrypt/curve448.h>
#if defined(HAVE_FALCON)
#include <wolfssl/wolfcrypt/falcon.h>
#endif /* HAVE_FALCON */
#if defined(WOLFSSL_HAVE_MLDSA)
#include <wolfssl/wolfcrypt/wc_mldsa.h>
#endif /* WOLFSSL_HAVE_MLDSA */
#if defined(OPENSSL_ALL) || defined(HAVE_STUNNEL)
#ifdef HAVE_OCSP
#include <wolfssl/openssl/ocsp.h>
#endif
#include <wolfssl/openssl/lhash.h>
#include <wolfssl/openssl/txt_db.h>
#endif /* WITH_STUNNEL */
#if defined(WOLFSSL_SHA512) || defined(WOLFSSL_SHA384)
#include <wolfssl/wolfcrypt/sha512.h>
#endif
#if defined(WOLFCRYPT_HAVE_SRP) && !defined(NO_SHA256) \
&& !defined(WC_NO_RNG)
#include <wolfssl/wolfcrypt/srp.h>
#endif
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
#include <wolfssl/openssl/x509v3.h>
int wolfssl_bn_get_value(WOLFSSL_BIGNUM* bn, mp_int* mpi);
int wolfssl_bn_set_value(WOLFSSL_BIGNUM** bn, mp_int* mpi);
#endif
#if defined(WOLFSSL_QT)
#include <wolfssl/wolfcrypt/sha.h>
#endif
#ifdef NO_ASN
#include <wolfssl/wolfcrypt/dh.h>
#endif
#endif /* !WOLFCRYPT_ONLY || OPENSSL_EXTRA */
#if !defined(WOLFCRYPT_ONLY) && defined(WOLFSSL_SYS_CRYPTO_POLICY)
/* The system wide crypto-policy. Configured by wolfSSL_crypto_policy_enable.
* */
static struct SystemCryptoPolicy crypto_policy;
#endif /* !WOLFCRYPT_ONLY && WOLFSSL_SYS_CRYPTO_POLICY */
/*
* ssl.c Build Options:
*
* See also: tls.c for TLS extension/protocol options, tls13.c for TLS 1.3,
* internal.c for handshake internals, wc_port.c for platform/memory.
*
* OpenSSL Compatibility:
* OPENSSL_EXTRA: Enable OpenSSL compatibility API default: off
* OPENSSL_ALL: Enable all OpenSSL compat APIs default: off
* OPENSSL_EXTRA_X509_SMALL: Minimal OpenSSL X509 compat APIs default: off
* OPENSSL_EXTRA_NO_ASN1: OpenSSL extra without ASN1 objects default: off
* OPENSSL_COMPATIBLE_DEFAULTS:
* Default behavior compatible with OpenSSL default: off
* NO_WOLFSSL_STUB: Disable stubs for unimplemented funcs default: off
* WOLFSSL_DEBUG_OPENSSL: Debug logging for OpenSSL compat layer default: off
* WOLFSSL_HAVE_ERROR_QUEUE: OpenSSL-compatible error queue default: off
* WOLFSSL_ERROR_CODE_OPENSSL: Use OpenSSL-compatible error codes default: off
* WOLFSSL_CIPHER_INTERNALNAME:
* Use wolfSSL internal cipher suite names default: off
* NO_CIPHER_SUITE_ALIASES: Disable cipher suite name aliases default: off
* WOLFSSL_SET_CIPHER_BYTES: Set cipher suites by raw byte values default: off
* WOLFSSL_OLD_SET_CURVES_LIST:
* Old-style curve list parsing for compat default: off
* WOLFSSL_NO_OPENSSL_RAND_CB: Disable OpenSSL RAND callback compat default: off
* NO_ERROR_STRINGS: Disable human-readable error strings default: off
* WOLFSSL_PUBLIC_ASN: Make ASN parsing functions public default: off
*
* Extra Data / BIO:
* HAVE_EX_DATA: Enable ex_data on SSL/CTX/X509 objects default: off
* HAVE_EX_DATA_CLEANUP_HOOKS: Cleanup callbacks for ex_data default: off
* HAVE_EX_DATA_CRYPTO: ex_data support for wolfCrypt objects default: off
* MAX_EX_DATA: Max ex_data entries per object default: 5
* NO_BIO: Disable BIO abstraction layer default: off
*
* Session & Cache:
* NO_SESSION_CACHE: Disable server session cache default: off
* NO_SESSION_CACHE_REF: wolfSSL_get_session returns ssl->session
* reference instead of ClientCache ref default: off
* SESSION_CACHE_DYNAMIC_MEM: Dynamically allocate session cache default: off
* NO_CLIENT_CACHE: Disable client-side session cache default: off
* SESSION_CERTS: Store full cert chain in session default: off
* WOLFSSL_SESSION_ID_CTX: Session ID context for cache sharing default: off
*
* I/O & Transport:
* USE_WOLFSSL_IO: Use built-in I/O callbacks default: on
* WOLFSSL_USER_IO: Application provides custom I/O default: off
* WOLFSSL_NO_SOCK: Build without socket support default: off
* NO_WRITEV: Disable writev() scatter/gather I/O default: off
* WOLFSSL_DTLS_MTU: Enable DTLS MTU management APIs default: off
* WOLFSSL_DTLS_DROP_STATS: Track DTLS packet drop statistics default: off
* WOLFSSL_MULTICAST: Enable DTLS multicast support default: off
*
* Callbacks & Features:
* WOLFSSL_CHECK_ALERT_ON_ERR: Check alerts on handshake error default: off
* ATOMIC_USER: User-defined record layer callbacks default: off
* HAVE_WRITE_DUP: Separate threads for SSL read/write default: off
* WOLFSSL_CALLBACKS: Handshake monitoring callbacks default: off
* NO_HANDSHAKE_DONE_CB: Disable handshake completion callback default: off
* WOLFSSL_SHUTDOWNONCE: Send close_notify only once default: off
* WOLFSSL_COPY_CERT: Copy certificate buffer (own copy) default: off
* WOLFSSL_COPY_KEY: Copy private key buffer (own copy) default: off
* WOLF_PRIVATE_KEY_ID: Reference private keys by ID default: off
* WOLFSSL_REFCNT_ERROR_RETURN:
* Return errors on ref counting failures default: off
* WOLFSSL_ALLOW_MAX_FRAGMENT_ADJUST:
* Allow runtime max fragment size adjustment default: off
* WOLFSSL_ALLOW_NO_SUITES: Allow SSL objects with no cipher suites default: off
*
* Certificates & Keys:
* KEEP_PEER_CERT: Keep peer cert after handshake default: off
* KEEP_OUR_CERT: Keep our cert after handshake default: off
* WOLFSSL_STATIC_RSA: Enable static RSA key exchange default: off
* WOLFSSL_HAVE_CERT_SERVICE: Certificate service callbacks default: off
* WOLFSSL_SYS_CA_CERTS: Load system CA certs from OS default: off
*
* Application Compatibility:
* HAVE_CURL: APIs for libcurl compatibility default: off
* HAVE_LIGHTY: APIs for lighttpd compatibility default: off
* HAVE_MEMCACHED: APIs for memcached compatibility default: off
* WOLFSSL_APACHE_HTTPD: APIs for Apache httpd compatibility default: off
* WOLFSSL_NGINX: APIs for nginx compatibility default: off
* WOLFSSL_HAPROXY: APIs for HAProxy compatibility default: off
* WOLFSSL_ASIO: APIs for Boost.Asio compatibility default: off
* WOLFSSL_PYTHON: APIs for Python module compatibility default: off
* WOLFSSL_QT: APIs for Qt framework compatibility default: off
* WOLFSSL_JNI: APIs for Java JNI/JSSE compatibility default: off
*
* Protocol Features:
* WOLFSSL_HAVE_WOLFSCEP: Enable wolfSCEP protocol support default: off
* WOLFCRYPT_HAVE_SRP: Enable SRP protocol support default: off
* HAVE_LIBZ: Enable zlib TLS compression default: off
* WOLFSSL_EXTRA: Extra SSL session info APIs default: off
* WOLFSSL_WPAS_SMALL: Minimal wpa_supplicant/hostapd APIs default: off
* HAVE_FUZZER: Fuzzing callback support default: off
*
* Memory & Threading:
* WOLFSSL_STATIC_MEMORY_LEAN: Lean static memory allocation default: off
* WOLFSSL_THREADED_CRYPT: Multi-threaded crypto operations default: off
* WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS:
* Thread-safe cleanup via atomics default: off
* WOLFSSL_ATOMIC_INITIALIZER: Static init for atomic variables default: off
* WOLFSSL_DEBUG_MEMORY: Log malloc/free with file/line info default: off
* WOLFSSL_NO_REALLOC: Disable realloc, use malloc+copy+free default: off
* WOLFSSL_HEAP_TEST: Heap-related testing utilities default: off
*
* Debugging & Build:
* SHOW_SIZES: Display struct sizes at init default: off
* WOLFSSL_DEBUG_TRACE_ERROR_CODES:
* Trace error code origins for debugging default: off
* HAVE_ATEXIT: Register wolfSSL_Cleanup via atexit default: off
* WOLFSSL_SYS_CRYPTO_POLICY: Honor system crypto policy settings default: off
*
* Hardware TLS:
* WOLFSSL_RENESAS_TSIP_TLS: Renesas TSIP hardware crypto for TLS default: off
* WOLFSSL_RENESAS_FSPSM_TLS: Renesas FSP Security Module for TLS default: off
* WOLFSSL_EGD_NBLOCK: Non-blocking EGD entropy support default: off
*/
#define WOLFSSL_SSL_MISC_INCLUDED
#include "src/ssl_misc.c"
#define WOLFSSL_EVP_INCLUDED
#include "wolfcrypt/src/evp.c"
/* Crypto code uses EVP APIs. */
#define WOLFSSL_SSL_CRYPTO_INCLUDED
#include "src/ssl_crypto.c"
#ifndef WOLFCRYPT_ONLY
#define WOLFSSL_SSL_CERTMAN_INCLUDED
#include "src/ssl_certman.c"
#define WOLFSSL_SSL_SESS_INCLUDED
#include "src/ssl_sess.c"
#define WOLFSSL_SSL_API_CERT_INCLUDED
#include "src/ssl_api_cert.c"
#define WOLFSSL_SSL_API_PK_INCLUDED
#include "src/ssl_api_pk.c"
#endif
#if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) && \
!defined(WOLFCRYPT_ONLY)
/* Convert shortname to NID.
*
* For OpenSSL compatibility.
*
* @param [in] sn Short name of OID.
* @return NID corresponding to shortname on success.
* @return WC_NID_undef when not recognized.
*/
int wc_OBJ_sn2nid(const char *sn)
{
const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
size_t i;
WOLFSSL_ENTER("wc_OBJ_sn2nid");
for (i = 0; i < wolfssl_object_info_sz; i++, obj_info++) {
if (XSTRCMP(sn, obj_info->sName) == 0)
return obj_info->nid;
}
WOLFSSL_MSG("short name not found in table");
return WC_NID_undef;
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
#ifndef WOLFCRYPT_ONLY
#if !defined(NO_RSA) || !defined(NO_DH) || defined(HAVE_ECC) || \
(defined(OPENSSL_EXTRA) && defined(WOLFSSL_KEY_GEN) && !defined(NO_DSA))
#define HAVE_GLOBAL_RNG /* consolidate flags for using globalRNG */
static WC_RNG globalRNG;
static volatile int initGlobalRNG = 0;
#if defined(OPENSSL_EXTRA) || !defined(WOLFSSL_MUTEX_INITIALIZER)
static WC_MAYBE_UNUSED wolfSSL_Mutex globalRNGMutex
WOLFSSL_MUTEX_INITIALIZER_CLAUSE(globalRNGMutex);
#endif
#ifndef WOLFSSL_MUTEX_INITIALIZER
static int globalRNGMutex_valid = 0;
#endif
#if defined(OPENSSL_EXTRA) && defined(HAVE_HASHDRBG)
static WOLFSSL_DRBG_CTX* gDrbgDefCtx = NULL;
#endif
WC_RNG* wolfssl_get_global_rng(void)
{
WC_RNG* ret = NULL;
if (initGlobalRNG == 0)
WOLFSSL_MSG("Global RNG no Init");
else
ret = &globalRNG;
return ret;
}
/* Make a global RNG and return.
*
* @return Global RNG on success.
* @return NULL on error.
*/
WC_RNG* wolfssl_make_global_rng(void)
{
WC_RNG* ret;
#ifdef HAVE_GLOBAL_RNG
/* Get the global random number generator instead. */
ret = wolfssl_get_global_rng();
#ifdef OPENSSL_EXTRA
if (ret == NULL) {
/* Create a global random if possible. */
(void)wolfSSL_RAND_Init();
ret = wolfssl_get_global_rng();
}
#endif
#else
WOLFSSL_ERROR_MSG("Bad RNG Init");
ret = NULL;
#endif
return ret;
}
/* Too many defines to check explicitly - prototype it and always include
* for RSA, DH, ECC and DSA for BN. */
WC_RNG* wolfssl_make_rng(WC_RNG* rng, int* local);
/* Make a random number generator or get global if possible.
*
* Global may not be available and NULL will be returned.
*
* @param [in, out] rng Local random number generator.
* @param [out] local Local random number generator returned.
* @return NULL on failure.
* @return A random number generator object.
*/
WC_RNG* wolfssl_make_rng(WC_RNG* rng, int* local)
{
WC_RNG* ret = NULL;
#ifdef WOLFSSL_SMALL_STACK
int freeRng = 0;
/* Allocate RNG object . */
if (rng == NULL) {
rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
freeRng = 1;
}
#endif
if (rng != NULL) {
if (wc_InitRng(rng) == 0) {
ret = rng;
*local = 1;
}
else {
WOLFSSL_MSG("Bad RNG Init");
#ifdef WOLFSSL_SMALL_STACK
if (freeRng) {
XFREE(rng, NULL, DYNAMIC_TYPE_RNG);
rng = NULL;
}
#endif
}
}
if (ret == NULL) {
#ifdef HAVE_GLOBAL_RNG
WOLFSSL_MSG("trying global RNG");
#endif
ret = wolfssl_make_global_rng();
}
return ret;
}
#endif
#ifdef OPENSSL_EXTRA
/* WOLFSSL_NO_OPENSSL_RAND_CB: Allows way to reduce code size for
* OPENSSL_EXTRA where RAND callbacks are not used */
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
static const WOLFSSL_RAND_METHOD* gRandMethods = NULL;
static wolfSSL_Mutex gRandMethodMutex
WOLFSSL_MUTEX_INITIALIZER_CLAUSE(gRandMethodMutex);
#ifndef WOLFSSL_MUTEX_INITIALIZER
static int gRandMethodsInit = 0;
#endif
#endif /* !WOLFSSL_NO_OPENSSL_RAND_CB */
#endif /* OPENSSL_EXTRA */
#define WOLFSSL_SSL_BN_INCLUDED
#include "src/ssl_bn.c"
#ifndef OPENSSL_EXTRA_NO_ASN1
#define WOLFSSL_SSL_ASN1_INCLUDED
#include "src/ssl_asn1.c"
#endif /* OPENSSL_EXTRA_NO_ASN1 */
#define WOLFSSL_PK_INCLUDED
#include "src/pk.c"
#define WOLFSSL_EVP_PK_INCLUDED
#include "wolfcrypt/src/evp_pk.c"
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
/* copies over data of "in" to "out" */
static void wolfSSL_CIPHER_copy(WOLFSSL_CIPHER* in, WOLFSSL_CIPHER* out)
{
if (in == NULL || out == NULL)
return;
*out = *in;
}
#if defined(OPENSSL_ALL)
static WOLFSSL_X509_OBJECT* wolfSSL_X509_OBJECT_dup(WOLFSSL_X509_OBJECT* obj)
{
WOLFSSL_X509_OBJECT* ret = NULL;
if (obj) {
ret = wolfSSL_X509_OBJECT_new();
if (ret) {
ret->type = obj->type;
switch (ret->type) {
case WOLFSSL_X509_LU_NONE:
break;
case WOLFSSL_X509_LU_X509:
ret->data.x509 = wolfSSL_X509_dup(obj->data.x509);
break;
case WOLFSSL_X509_LU_CRL:
#if defined(HAVE_CRL)
ret->data.crl = wolfSSL_X509_CRL_dup(obj->data.crl);
#endif
break;
}
}
}
return ret;
}
#endif /* OPENSSL_ALL */
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */
#define WOLFSSL_SSL_SK_INCLUDED
#include "src/ssl_sk.c"
#include <wolfssl/wolfcrypt/hpke.h>
#define WOLFSSL_SSL_ECH_INCLUDED
#include "src/ssl_ech.c"
#ifdef OPENSSL_EXTRA
static int wolfSSL_parse_cipher_list(WOLFSSL_CTX* ctx, WOLFSSL* ssl,
Suites* suites, const char* list);
#endif
#if defined(WOLFSSL_RENESAS_TSIP_TLS) || defined(WOLFSSL_RENESAS_FSPSM_TLS)
#include <wolfssl/wolfcrypt/port/Renesas/renesas_cmn.h>
#endif
/* prevent multiple mutex initializations */
/* note, initRefCount is not used for thread synchronization, only for
* bookkeeping while inits_count_mutex is held.
*/
static volatile WC_THREADSHARED int initRefCount = 0;
/* init ref count mutex */
static WC_THREADSHARED wolfSSL_Mutex inits_count_mutex
WOLFSSL_MUTEX_INITIALIZER_CLAUSE(inits_count_mutex);
#ifndef WOLFSSL_MUTEX_INITIALIZER
static WC_THREADSHARED volatile int inits_count_mutex_valid = 0;
#endif
#ifdef NO_TLS
static const WOLFSSL_METHOD gNoTlsMethod;
#endif
/* Create a new WOLFSSL_CTX struct and return the pointer to created struct.
WOLFSSL_METHOD pointer passed in is given to ctx to manage.
This function frees the passed in WOLFSSL_METHOD struct on failure and on
success is freed when ctx is freed.
*/
WOLFSSL_CTX* wolfSSL_CTX_new_ex(WOLFSSL_METHOD* method, void* heap)
{
WOLFSSL_CTX* ctx = NULL;
WOLFSSL_ENTER("wolfSSL_CTX_new_ex");
if (initRefCount == 0) {
/* user no longer forced to call Init themselves */
int ret = wolfSSL_Init();
if (ret != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("wolfSSL_Init failed");
WOLFSSL_LEAVE("wolfSSL_CTX_new_ex", 0);
XFREE(method, heap, DYNAMIC_TYPE_METHOD);
return NULL;
}
}
#ifndef NO_TLS
if (method == NULL)
return ctx;
#else
/* a blank TLS method */
method = (WOLFSSL_METHOD*)&gNoTlsMethod;
#endif
ctx = (WOLFSSL_CTX*)XMALLOC(sizeof(WOLFSSL_CTX), heap, DYNAMIC_TYPE_CTX);
if (ctx) {
int ret;
ret = InitSSL_Ctx(ctx, method, heap);
#ifdef WOLFSSL_STATIC_MEMORY
if (heap != NULL) {
ctx->onHeapHint = 1; /* free the memory back to heap when done */
}
#endif
if (ret < 0) {
WOLFSSL_MSG("Init CTX failed");
wolfSSL_CTX_free(ctx);
ctx = NULL;
}
#if defined(OPENSSL_EXTRA) && defined(WOLFCRYPT_HAVE_SRP) \
&& !defined(NO_SHA256) && !defined(WC_NO_RNG)
else {
ctx->srp = (Srp*)XMALLOC(sizeof(Srp), heap, DYNAMIC_TYPE_SRP);
if (ctx->srp == NULL){
WOLFSSL_MSG("Init CTX failed");
wolfSSL_CTX_free(ctx);
return NULL;
}
XMEMSET(ctx->srp, 0, sizeof(Srp));
}
#endif
}
else {
WOLFSSL_MSG("Alloc CTX failed, method freed");
XFREE(method, heap, DYNAMIC_TYPE_METHOD);
}
#ifdef OPENSSL_COMPATIBLE_DEFAULTS
if (ctx) {
wolfSSL_CTX_set_verify(ctx, WOLFSSL_VERIFY_NONE, NULL);
wolfSSL_CTX_set_mode(ctx, WOLFSSL_MODE_AUTO_RETRY);
if (wolfSSL_CTX_set_min_proto_version(ctx,
(method->version.major == DTLS_MAJOR) ?
DTLS1_VERSION : SSL3_VERSION) != WOLFSSL_SUCCESS ||
#ifdef HAVE_ANON
wolfSSL_CTX_allow_anon_cipher(ctx) != WOLFSSL_SUCCESS ||
#endif
wolfSSL_CTX_set_group_messages(ctx) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Setting OpenSSL CTX defaults failed");
wolfSSL_CTX_free(ctx);
ctx = NULL;
}
}
#endif
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
/* Load the crypto-policy ciphers if configured. */
if (ctx && wolfSSL_crypto_policy_is_enabled()) {
const char * list = wolfSSL_crypto_policy_get_ciphers();
int ret = 0;
if (list != NULL && *list != '\0') {
if (AllocateCtxSuites(ctx) != 0) {
WOLFSSL_MSG("allocate ctx suites failed");
wolfSSL_CTX_free(ctx);
ctx = NULL;
}
else {
ret = wolfSSL_parse_cipher_list(ctx, NULL, ctx->suites, list);
if (ret != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("parse cipher list failed");
wolfSSL_CTX_free(ctx);
ctx = NULL;
}
}
}
}
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
WOLFSSL_LEAVE("wolfSSL_CTX_new_ex", 0);
return ctx;
}
WOLFSSL_ABI
WOLFSSL_CTX* wolfSSL_CTX_new(WOLFSSL_METHOD* method)
{
#ifdef WOLFSSL_HEAP_TEST
/* if testing the heap hint then set top level CTX to have test value */
return wolfSSL_CTX_new_ex(method, (void*)WOLFSSL_HEAP_TEST);
#else
return wolfSSL_CTX_new_ex(method, NULL);
#endif
}
/* increases CTX reference count to track proper time to "free" */
int wolfSSL_CTX_up_ref(WOLFSSL_CTX* ctx)
{
int ret;
wolfSSL_RefWithMutexInc(&ctx->ref, &ret);
#ifdef WOLFSSL_REFCNT_ERROR_RETURN
return ((ret == 0) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE);
#else
(void)ret;
return WOLFSSL_SUCCESS;
#endif
}
WOLFSSL_ABI
void wolfSSL_CTX_free(WOLFSSL_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_CTX_free");
if (ctx) {
FreeSSL_Ctx(ctx);
}
WOLFSSL_LEAVE("wolfSSL_CTX_free", 0);
}
#ifdef HAVE_ENCRYPT_THEN_MAC
/**
* Sets whether Encrypt-Then-MAC extension can be negotiated against context.
* The default value: enabled.
*
* ctx SSL/TLS context.
* set Whether to allow or not: 1 is allow and 0 is disallow.
* returns WOLFSSL_SUCCESS
*/
int wolfSSL_CTX_AllowEncryptThenMac(WOLFSSL_CTX *ctx, int set)
{
ctx->disallowEncThenMac = !set;
return WOLFSSL_SUCCESS;
}
/**
* Sets whether Encrypt-Then-MAC extension can be negotiated against context.
* The default value comes from context.
*
* ctx SSL/TLS context.
* set Whether to allow or not: 1 is allow and 0 is disallow.
* returns WOLFSSL_SUCCESS
*/
int wolfSSL_AllowEncryptThenMac(WOLFSSL *ssl, int set)
{
ssl->options.disallowEncThenMac = !set;
return WOLFSSL_SUCCESS;
}
#endif
#ifdef SINGLE_THREADED
/* no locking in single threaded mode, allow a CTX level rng to be shared with
* WOLFSSL objects, WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_new_rng(WOLFSSL_CTX* ctx)
{
WC_RNG* rng;
int ret;
if (ctx == NULL) {
return BAD_FUNC_ARG;
}
rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), ctx->heap, DYNAMIC_TYPE_RNG);
if (rng == NULL) {
return MEMORY_E;
}
#ifndef HAVE_FIPS
ret = wc_InitRng_ex(rng, ctx->heap, ctx->devId);
#else
ret = wc_InitRng(rng);
#endif
if (ret != 0) {
XFREE(rng, ctx->heap, DYNAMIC_TYPE_RNG);
return ret;
}
ctx->rng = rng;
return WOLFSSL_SUCCESS;
}
#endif
WOLFSSL_ABI
WOLFSSL* wolfSSL_new(WOLFSSL_CTX* ctx)
{
WOLFSSL* ssl = NULL;
int ret = 0;
WOLFSSL_ENTER("wolfSSL_new");
if (ctx == NULL) {
WOLFSSL_MSG("wolfSSL_new ctx is null");
return NULL;
}
ssl = (WOLFSSL*) XMALLOC(sizeof(WOLFSSL), ctx->heap, DYNAMIC_TYPE_SSL);
if (ssl == NULL) {
WOLFSSL_MSG_EX("ssl xmalloc failed to allocate %d bytes",
(int)sizeof(WOLFSSL));
}
else {
ret = InitSSL(ssl, ctx, 0);
if (ret < 0) {
WOLFSSL_MSG_EX("wolfSSL_new failed during InitSSL. err = %d", ret);
FreeSSL(ssl, ctx->heap);
ssl = NULL;
}
else if (ret == 0) {
WOLFSSL_MSG("wolfSSL_new InitSSL success");
}
else {
/* Only success (0) or negative values should ever be seen. */
WOLFSSL_MSG_EX("WARNING: wolfSSL_new unexpected InitSSL return"
" value = %d", ret);
} /* InitSSL check */
} /* ssl XMALLOC success */
WOLFSSL_LEAVE("wolfSSL_new InitSSL =", ret);
(void)ret;
return ssl;
}
WOLFSSL_ABI
void wolfSSL_free(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_free");
if (ssl) {
WOLFSSL_MSG_EX("Free SSL: %p", (wc_ptr_t)ssl);
FreeSSL(ssl, ssl->ctx->heap);
}
else {
WOLFSSL_MSG("Free SSL: wolfSSL_free already null");
}
WOLFSSL_LEAVE("wolfSSL_free", 0);
}
int wolfSSL_is_server(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
return ssl->options.side == WOLFSSL_SERVER_END;
}
#ifdef HAVE_WRITE_DUP
/*
* Release resources around WriteDup object
*
* ssl WOLFSSL object
*
* no return, destruction so make best attempt
*/
void FreeWriteDup(WOLFSSL* ssl)
{
int doFree = 0;
WOLFSSL_ENTER("FreeWriteDup");
if (ssl->dupWrite) {
if (wc_LockMutex(&ssl->dupWrite->dupMutex) == 0) {
ssl->dupWrite->dupCount--;
if (ssl->dupWrite->dupCount == 0) {
doFree = 1;
} else {
WOLFSSL_MSG("WriteDup count not zero, no full free");
}
wc_UnLockMutex(&ssl->dupWrite->dupMutex);
}
}
if (doFree) {
#ifdef WOLFSSL_DTLS13
struct Dtls13RecordNumber* rn = ssl->dupWrite->sendAckList;
while (rn != NULL) {
struct Dtls13RecordNumber* next = rn->next;
XFREE(rn, ssl->heap, DYNAMIC_TYPE_DTLS_MSG);
rn = next;
}
#endif
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
Free_HS_Hashes(ssl->dupWrite->postHandshakeHashState, ssl->heap);
{
CertReqCtx* ctx = ssl->dupWrite->postHandshakeCertReqCtx;
while (ctx != NULL) {
CertReqCtx* nxt = ctx->next;
XFREE(ctx, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
ctx = nxt;
}
}
#endif /* WOLFSSL_TLS13 && WOLFSSL_POST_HANDSHAKE_AUTH */
wc_FreeMutex(&ssl->dupWrite->dupMutex);
XFREE(ssl->dupWrite, ssl->heap, DYNAMIC_TYPE_WRITEDUP);
ssl->dupWrite = NULL;
WOLFSSL_MSG("Did WriteDup full free, count to zero");
}
}
/*
* duplicate existing ssl members into dup needed for writing
*
* dup write only WOLFSSL
* ssl existing WOLFSSL
*
* 0 on success
*/
static int DupSSL(WOLFSSL* dup, WOLFSSL* ssl)
{
word16 tmp_weOwnRng;
#ifdef HAVE_ONE_TIME_AUTH
#ifdef HAVE_POLY1305
Poly1305* tmp_poly1305 = NULL;
#endif
#endif
/* shared dupWrite setup */
ssl->dupWrite = (WriteDup*)XMALLOC(sizeof(WriteDup), ssl->heap,
DYNAMIC_TYPE_WRITEDUP);
if (ssl->dupWrite == NULL) {
return MEMORY_E;
}
XMEMSET(ssl->dupWrite, 0, sizeof(WriteDup));
if (wc_InitMutex(&ssl->dupWrite->dupMutex) != 0) {
XFREE(ssl->dupWrite, ssl->heap, DYNAMIC_TYPE_WRITEDUP);
ssl->dupWrite = NULL;
return BAD_MUTEX_E;
}
/* Pre-allocate any objects that can fail BEFORE performing destructive
* state mutations on ssl, so an allocation failure cannot leave ssl
* with a zeroed encrypt context and a poisoned dupWrite.
* dup->heap == ssl->heap here because dup was initialised with ssl->ctx;
* use ssl->heap consistently for cleanup symmetry. */
#ifdef HAVE_ONE_TIME_AUTH
#ifdef HAVE_POLY1305
if (ssl->auth.setup && ssl->auth.poly1305 != NULL) {
tmp_poly1305 = (Poly1305*)XMALLOC(sizeof(Poly1305), ssl->heap,
DYNAMIC_TYPE_CIPHER);
if (tmp_poly1305 == NULL) {
wc_FreeMutex(&ssl->dupWrite->dupMutex);
XFREE(ssl->dupWrite, ssl->heap, DYNAMIC_TYPE_WRITEDUP);
ssl->dupWrite = NULL;
return MEMORY_E;
}
}
#endif
#endif
ssl->dupWrite->dupCount = 2; /* both sides have a count to start */
dup->dupWrite = ssl->dupWrite; /* each side uses */
tmp_weOwnRng = dup->options.weOwnRng;
/* copy write parts over to dup writer */
XMEMCPY(&dup->specs, &ssl->specs, sizeof(CipherSpecs));
XMEMCPY(&dup->options, &ssl->options, sizeof(Options));
XMEMCPY(&dup->keys, &ssl->keys, sizeof(Keys));
XMEMCPY(&dup->encrypt, &ssl->encrypt, sizeof(Ciphers));
XMEMCPY(&dup->version, &ssl->version, sizeof(ProtocolVersion));
XMEMCPY(&dup->chVersion, &ssl->chVersion, sizeof(ProtocolVersion));
/* dup side now owns encrypt/write ciphers */
XMEMSET(&ssl->encrypt, 0, sizeof(Ciphers));
#ifdef HAVE_ONE_TIME_AUTH
#ifdef HAVE_POLY1305
if (tmp_poly1305 != NULL) {
dup->auth.poly1305 = tmp_poly1305;
dup->auth.setup = 1;
}
#endif
#endif
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version)) {
/* Copy TLS 1.3 application traffic secrets so the write side can
* derive updated keys when wolfSSL_update_keys() is called. */
XMEMCPY(dup->clientSecret, ssl->clientSecret, SECRET_LEN);
XMEMCPY(dup->serverSecret, ssl->serverSecret, SECRET_LEN);
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls) {
/* Copy epoch array (contains only value types -- safe to memcpy). */
XMEMCPY(dup->dtls13Epochs, ssl->dtls13Epochs,
sizeof(ssl->dtls13Epochs));
/* Re-point dtls13EncryptEpoch into dup's own epoch array. */
if (ssl->dtls13EncryptEpoch != NULL) {
dup->dtls13EncryptEpoch =
&dup->dtls13Epochs[ssl->dtls13EncryptEpoch -
ssl->dtls13Epochs];
}
/* Copy current write epoch number. */
dup->dtls13Epoch = ssl->dtls13Epoch;
/* Transfer record-number encryption cipher ownership to dup. */
XMEMCPY(&dup->dtlsRecordNumberEncrypt,
&ssl->dtlsRecordNumberEncrypt, sizeof(RecordNumberCiphers));
XMEMSET(&ssl->dtlsRecordNumberEncrypt,
0, sizeof(RecordNumberCiphers));
}
#endif /* WOLFSSL_DTLS13 */
}
#endif /* WOLFSSL_TLS13 */
dup->IOCB_WriteCtx = ssl->IOCB_WriteCtx;
dup->CBIOSend = ssl->CBIOSend;
#ifdef OPENSSL_EXTRA
dup->cbioFlag = ssl->cbioFlag;
#endif
dup->wfd = ssl->wfd;
dup->wflags = ssl->wflags;
#ifndef WOLFSSL_AEAD_ONLY
dup->hmac = ssl->hmac;
#endif
#ifdef HAVE_TRUNCATED_HMAC
dup->truncated_hmac = ssl->truncated_hmac;
#endif
/* Restore rng option */
dup->options.weOwnRng = tmp_weOwnRng;
/* unique side dup setup */
dup->dupSide = WRITE_DUP_SIDE;
ssl->dupSide = READ_DUP_SIDE;
return 0;
}
/*
* duplicate a WOLFSSL object post handshake for writing only
* turn existing object into read only. Allows concurrent access from two
* different threads.
*
* ssl existing WOLFSSL object
*
* return dup'd WOLFSSL object on success
*/
WOLFSSL* wolfSSL_write_dup(WOLFSSL* ssl)
{
WOLFSSL* dup = NULL;
int ret = 0;
(void)ret;
WOLFSSL_ENTER("wolfSSL_write_dup");
if (ssl == NULL) {
return ssl;
}
if (ssl->options.handShakeDone == 0) {
WOLFSSL_MSG("wolfSSL_write_dup called before handshake complete");
return NULL;
}
if (ssl->dupWrite) {
WOLFSSL_MSG("wolfSSL_write_dup already called once");
return NULL;
}
dup = (WOLFSSL*) XMALLOC(sizeof(WOLFSSL), ssl->ctx->heap, DYNAMIC_TYPE_SSL);
if (dup) {
if ( (ret = InitSSL(dup, ssl->ctx, 1)) < 0) {
FreeSSL(dup, ssl->ctx->heap);
dup = NULL;
} else if ( (ret = DupSSL(dup, ssl)) < 0) {
FreeSSL(dup, ssl->ctx->heap);
dup = NULL;
}
}
WOLFSSL_LEAVE("wolfSSL_write_dup", ret);
return dup;
}
/*
* Notify write dup side of fatal error or close notify
*
* ssl WOLFSSL object
* err Notify err
*
* 0 on success
*/
int NotifyWriteSide(WOLFSSL* ssl, int err)
{
int ret;
WOLFSSL_ENTER("NotifyWriteSide");
ret = wc_LockMutex(&ssl->dupWrite->dupMutex);
if (ret == 0) {
ssl->dupWrite->dupErr = err;
ret = wc_UnLockMutex(&ssl->dupWrite->dupMutex);
}
return ret;
}
#endif /* HAVE_WRITE_DUP */
#ifdef HAVE_POLY1305
/* set if to use old poly 1 for yes 0 to use new poly */
int wolfSSL_use_old_poly(WOLFSSL* ssl, int value)
{
(void)ssl;
(void)value;
#ifndef WOLFSSL_NO_TLS12
WOLFSSL_ENTER("wolfSSL_use_old_poly");
WOLFSSL_MSG("Warning SSL connection auto detects old/new and this function"
"is depreciated");
ssl->options.oldPoly = (word16)value;
WOLFSSL_LEAVE("wolfSSL_use_old_poly", 0);
#endif
return 0;
}
#endif
WOLFSSL_ABI
int wolfSSL_set_fd(WOLFSSL* ssl, int fd)
{
int ret;
WOLFSSL_ENTER("wolfSSL_set_fd");
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
ret = wolfSSL_set_read_fd(ssl, fd);
if (ret == WOLFSSL_SUCCESS) {
ret = wolfSSL_set_write_fd(ssl, fd);
}
return ret;
}
int wolfSSL_set_read_fd(WOLFSSL* ssl, int fd)
{
WOLFSSL_ENTER("wolfSSL_set_read_fd");
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
ssl->rfd = fd; /* not used directly to allow IO callbacks */
ssl->IOCB_ReadCtx = &ssl->rfd;
#ifdef WOLFSSL_DTLS
ssl->buffers.dtlsCtx.connected = 0;
if (ssl->options.dtls) {
ssl->IOCB_ReadCtx = &ssl->buffers.dtlsCtx;
ssl->buffers.dtlsCtx.rfd = fd;
}
#endif
WOLFSSL_LEAVE("wolfSSL_set_read_fd", WOLFSSL_SUCCESS);
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_write_fd(WOLFSSL* ssl, int fd)
{
WOLFSSL_ENTER("wolfSSL_set_write_fd");
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
ssl->wfd = fd; /* not used directly to allow IO callbacks */
ssl->IOCB_WriteCtx = &ssl->wfd;
#ifdef WOLFSSL_DTLS
ssl->buffers.dtlsCtx.connected = 0;
if (ssl->options.dtls) {
ssl->IOCB_WriteCtx = &ssl->buffers.dtlsCtx;
ssl->buffers.dtlsCtx.wfd = fd;
}
#endif
WOLFSSL_LEAVE("wolfSSL_set_write_fd", WOLFSSL_SUCCESS);
return WOLFSSL_SUCCESS;
}
/**
* Get the name of cipher at priority level passed in.
*/
char* wolfSSL_get_cipher_list(int priority)
{
const CipherSuiteInfo* ciphers = GetCipherNames();
if (priority >= GetCipherNamesSize() || priority < 0) {
return 0;
}
return (char*)ciphers[priority].name;
}
/**
* Get the name of cipher at priority level passed in.
*/
char* wolfSSL_get_cipher_list_ex(WOLFSSL* ssl, int priority)
{
if (ssl == NULL) {
return NULL;
}
else {
const char* cipher;
if ((cipher = wolfSSL_get_cipher_name_internal(ssl)) != NULL) {
if (priority == 0) {
return (char*)cipher;
}
else {
return NULL;
}
}
else {
return wolfSSL_get_cipher_list(priority);
}
}
}
int wolfSSL_get_ciphers(char* buf, int len)
{
const CipherSuiteInfo* ciphers = GetCipherNames();
int ciphersSz = GetCipherNamesSize();
int i;
if (buf == NULL || len <= 0)
return BAD_FUNC_ARG;
/* Add each member to the buffer delimited by a : */
for (i = 0; i < ciphersSz; i++) {
int cipherNameSz = (int)XSTRLEN(ciphers[i].name);
if (cipherNameSz + 1 < len) {
XSTRNCPY(buf, ciphers[i].name, (size_t)len);
buf += cipherNameSz;
if (i < ciphersSz - 1)
*buf++ = ':';
*buf = 0;
len -= cipherNameSz + 1;
}
else
return BUFFER_E;
}
return WOLFSSL_SUCCESS;
}
#ifndef NO_ERROR_STRINGS
/* places a list of all supported cipher suites in TLS_* format into "buf"
* return WOLFSSL_SUCCESS on success */
int wolfSSL_get_ciphers_iana(char* buf, int len)
{
const CipherSuiteInfo* ciphers = GetCipherNames();
int ciphersSz = GetCipherNamesSize();
int i;
int cipherNameSz;
if (buf == NULL || len <= 0)
return BAD_FUNC_ARG;
/* Add each member to the buffer delimited by a : */
for (i = 0; i < ciphersSz; i++) {
#ifndef NO_CIPHER_SUITE_ALIASES
if (ciphers[i].flags & WOLFSSL_CIPHER_SUITE_FLAG_NAMEALIAS)
continue;
#endif
cipherNameSz = (int)XSTRLEN(ciphers[i].name_iana);
if (cipherNameSz + 1 < len) {
XSTRNCPY(buf, ciphers[i].name_iana, (size_t)len);
buf += cipherNameSz;
if (i < ciphersSz - 1)
*buf++ = ':';
*buf = 0;
len -= cipherNameSz + 1;
}
else
return BUFFER_E;
}
return WOLFSSL_SUCCESS;
}
#endif /* NO_ERROR_STRINGS */
const char* wolfSSL_get_shared_ciphers(WOLFSSL* ssl, char* buf, int len)
{
const char* cipher;
if (ssl == NULL || buf == NULL || len <= 0)
return NULL;
cipher = wolfSSL_get_cipher_name_iana(ssl);
if (cipher == NULL)
return NULL;
len = (int)min((word32)len, (word32)(XSTRLEN(cipher) + 1));
XMEMCPY(buf, cipher, (size_t)len);
return buf;
}
int wolfSSL_get_fd(const WOLFSSL* ssl)
{
int fd = -1;
WOLFSSL_ENTER("wolfSSL_get_fd");
if (ssl) {
fd = ssl->rfd;
}
WOLFSSL_LEAVE("wolfSSL_get_fd", fd);
return fd;
}
int wolfSSL_get_wfd(const WOLFSSL* ssl)
{
int fd = -1;
WOLFSSL_ENTER("wolfSSL_get_fd");
if (ssl) {
fd = ssl->wfd;
}
WOLFSSL_LEAVE("wolfSSL_get_fd", fd);
return fd;
}
#ifdef WOLFSSL_WOLFSENTRY_HOOKS
int wolfSSL_CTX_set_AcceptFilter(
WOLFSSL_CTX *ctx,
NetworkFilterCallback_t AcceptFilter,
void *AcceptFilter_arg)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->AcceptFilter = AcceptFilter;
ctx->AcceptFilter_arg = AcceptFilter_arg;
return 0;
}
int wolfSSL_set_AcceptFilter(
WOLFSSL *ssl,
NetworkFilterCallback_t AcceptFilter,
void *AcceptFilter_arg)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->AcceptFilter = AcceptFilter;
ssl->AcceptFilter_arg = AcceptFilter_arg;
return 0;
}
int wolfSSL_CTX_set_ConnectFilter(
WOLFSSL_CTX *ctx,
NetworkFilterCallback_t ConnectFilter,
void *ConnectFilter_arg)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->ConnectFilter = ConnectFilter;
ctx->ConnectFilter_arg = ConnectFilter_arg;
return 0;
}
int wolfSSL_set_ConnectFilter(
WOLFSSL *ssl,
NetworkFilterCallback_t ConnectFilter,
void *ConnectFilter_arg)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->ConnectFilter = ConnectFilter;
ssl->ConnectFilter_arg = ConnectFilter_arg;
return 0;
}
#endif /* WOLFSSL_WOLFSENTRY_HOOKS */
#ifndef NO_TLS
/* return underlying connect or accept, WOLFSSL_SUCCESS on ok */
int wolfSSL_negotiate(WOLFSSL* ssl)
{
int err = WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR);
WOLFSSL_ENTER("wolfSSL_negotiate");
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
#ifndef NO_WOLFSSL_SERVER
if (ssl->options.side == WOLFSSL_SERVER_END) {
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version))
err = wolfSSL_accept_TLSv13(ssl);
else
#endif
err = wolfSSL_accept(ssl);
}
#endif
#ifndef NO_WOLFSSL_CLIENT
if (ssl->options.side == WOLFSSL_CLIENT_END) {
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version))
err = wolfSSL_connect_TLSv13(ssl);
else
#endif
err = wolfSSL_connect(ssl);
}
#endif
(void)ssl;
WOLFSSL_LEAVE("wolfSSL_negotiate", err);
return err;
}
#endif /* !NO_TLS */
WOLFSSL_ABI
WC_RNG* wolfSSL_GetRNG(WOLFSSL* ssl)
{
if (ssl) {
return ssl->rng;
}
return NULL;
}
#ifndef WOLFSSL_LEANPSK
/* object size based on build */
int wolfSSL_GetObjectSize(void)
{
#ifdef SHOW_SIZES
printf("sizeof suites = %lu\n", (unsigned long)sizeof(Suites));
printf("sizeof ciphers(2) = %lu\n", (unsigned long)sizeof(Ciphers));
#ifndef NO_RC4
printf("\tsizeof arc4 = %lu\n", (unsigned long)sizeof(Arc4));
#endif
printf("\tsizeof aes = %lu\n", (unsigned long)sizeof(Aes));
#ifndef NO_DES3
printf("\tsizeof des3 = %lu\n", (unsigned long)sizeof(Des3));
#endif
#ifdef HAVE_CHACHA
printf("\tsizeof chacha = %lu\n", (unsigned long)sizeof(ChaCha));
#endif
#ifdef WOLFSSL_SM4
printf("\tsizeof sm4 = %lu\n", (unsigned long)sizeof(Sm4));
#endif
printf("sizeof cipher specs = %lu\n", (unsigned long)
sizeof(CipherSpecs));
printf("sizeof keys = %lu\n", (unsigned long)sizeof(Keys));
printf("sizeof Hashes(2) = %lu\n", (unsigned long)sizeof(Hashes));
#ifndef NO_MD5
printf("\tsizeof MD5 = %lu\n", (unsigned long)sizeof(wc_Md5));
#endif
#ifndef NO_SHA
printf("\tsizeof SHA = %lu\n", (unsigned long)sizeof(wc_Sha));
#endif
#ifdef WOLFSSL_SHA224
printf("\tsizeof SHA224 = %lu\n", (unsigned long)sizeof(wc_Sha224));
#endif
#ifndef NO_SHA256
printf("\tsizeof SHA256 = %lu\n", (unsigned long)sizeof(wc_Sha256));
#endif
#ifdef WOLFSSL_SHA384
printf("\tsizeof SHA384 = %lu\n", (unsigned long)sizeof(wc_Sha384));
#endif
#ifdef WOLFSSL_SHA384
printf("\tsizeof SHA512 = %lu\n", (unsigned long)sizeof(wc_Sha512));
#endif
#ifdef WOLFSSL_SM3
printf("\tsizeof sm3 = %lu\n", (unsigned long)sizeof(Sm3));
#endif
printf("sizeof Buffers = %lu\n", (unsigned long)sizeof(Buffers));
printf("sizeof Options = %lu\n", (unsigned long)sizeof(Options));
printf("sizeof Arrays = %lu\n", (unsigned long)sizeof(Arrays));
#ifndef NO_RSA
printf("sizeof RsaKey = %lu\n", (unsigned long)sizeof(RsaKey));
#endif
#ifdef HAVE_ECC
printf("sizeof ecc_key = %lu\n", (unsigned long)sizeof(ecc_key));
#endif
printf("sizeof WOLFSSL_CIPHER = %lu\n", (unsigned long)
sizeof(WOLFSSL_CIPHER));
printf("sizeof WOLFSSL_SESSION = %lu\n", (unsigned long)
sizeof(WOLFSSL_SESSION));
printf("sizeof WOLFSSL = %lu\n", (unsigned long)sizeof(WOLFSSL));
printf("sizeof WOLFSSL_CTX = %lu\n", (unsigned long)
sizeof(WOLFSSL_CTX));
#endif
return sizeof(WOLFSSL);
}
int wolfSSL_CTX_GetObjectSize(void)
{
return sizeof(WOLFSSL_CTX);
}
int wolfSSL_METHOD_GetObjectSize(void)
{
return sizeof(WOLFSSL_METHOD);
}
#endif
#ifdef WOLFSSL_STATIC_MEMORY
int wolfSSL_CTX_load_static_memory(WOLFSSL_CTX** ctx,
wolfSSL_method_func method, unsigned char* buf, unsigned int sz, int flag,
int maxSz)
{
WOLFSSL_HEAP_HINT* hint = NULL;
if (ctx == NULL || buf == NULL) {
return BAD_FUNC_ARG;
}
if (*ctx == NULL && method == NULL) {
return BAD_FUNC_ARG;
}
/* If there is a heap already, capture it in hint. */
if (*ctx && (*ctx)->heap != NULL) {
hint = (*ctx)->heap;
}
if (wc_LoadStaticMemory(&hint, buf, sz, flag, maxSz)) {
WOLFSSL_MSG("Error loading static memory");
return WOLFSSL_FAILURE;
}
if (*ctx) {
if ((*ctx)->heap == NULL) {
(*ctx)->heap = (void*)hint;
}
}
else {
/* create ctx if needed */
*ctx = wolfSSL_CTX_new_ex(method(hint), hint);
if (*ctx == NULL) {
WOLFSSL_MSG("Error creating ctx");
return WOLFSSL_FAILURE;
}
}
return WOLFSSL_SUCCESS;
}
int wolfSSL_is_static_memory(WOLFSSL* ssl, WOLFSSL_MEM_CONN_STATS* mem_stats)
{
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
WOLFSSL_ENTER("wolfSSL_is_static_memory");
#ifndef WOLFSSL_STATIC_MEMORY_LEAN
/* fill out statistics if wanted and WOLFMEM_TRACK_STATS flag */
if (mem_stats != NULL && ssl->heap != NULL) {
WOLFSSL_HEAP_HINT* hint = ((WOLFSSL_HEAP_HINT*)(ssl->heap));
WOLFSSL_HEAP* heap = hint->memory;
if (heap->flag & WOLFMEM_TRACK_STATS && hint->stats != NULL) {
XMEMCPY(mem_stats, hint->stats, sizeof(WOLFSSL_MEM_CONN_STATS));
}
}
#endif
(void)mem_stats;
return (ssl->heap) ? 1 : 0;
}
int wolfSSL_CTX_is_static_memory(WOLFSSL_CTX* ctx, WOLFSSL_MEM_STATS* mem_stats)
{
if (ctx == NULL) {
return BAD_FUNC_ARG;
}
WOLFSSL_ENTER("wolfSSL_CTX_is_static_memory");
#ifndef WOLFSSL_STATIC_MEMORY_LEAN
/* fill out statistics if wanted */
if (mem_stats != NULL && ctx->heap != NULL) {
WOLFSSL_HEAP* heap = ((WOLFSSL_HEAP_HINT*)(ctx->heap))->memory;
if (wolfSSL_GetMemStats(heap, mem_stats) != 1) {
return MEMORY_E;
}
}
#endif
(void)mem_stats;
return (ctx->heap) ? 1 : 0;
}
#endif /* WOLFSSL_STATIC_MEMORY */
#ifndef NO_TLS
/* return max record layer size plaintext input size */
int wolfSSL_GetMaxOutputSize(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_GetMaxOutputSize");
if (ssl == NULL)
return BAD_FUNC_ARG;
if (ssl->options.handShakeState != HANDSHAKE_DONE) {
WOLFSSL_MSG("Handshake not complete yet");
return BAD_FUNC_ARG;
}
return min(OUTPUT_RECORD_SIZE, wolfssl_local_GetMaxPlaintextSize(ssl));
}
/* return record layer size of plaintext input size */
int wolfSSL_GetOutputSize(WOLFSSL* ssl, int inSz)
{
int maxSize;
WOLFSSL_ENTER("wolfSSL_GetOutputSize");
if (inSz < 0)
return BAD_FUNC_ARG;
maxSize = wolfSSL_GetMaxOutputSize(ssl);
if (maxSize < 0)
return maxSize; /* error */
if (inSz > maxSize)
return INPUT_SIZE_E;
return wolfssl_local_GetRecordSize(ssl, inSz, 1);
}
static int wolfSSL_write_internal(WOLFSSL* ssl, const void* data, size_t sz)
{
int ret = 0;
WOLFSSL_ENTER("wolfSSL_write");
if (ssl == NULL || data == NULL)
return BAD_FUNC_ARG;
#ifdef WOLFSSL_QUIC
if (WOLFSSL_IS_QUIC(ssl)) {
WOLFSSL_MSG("SSL_write() on QUIC not allowed");
return BAD_FUNC_ARG;
}
#endif
#ifdef HAVE_WRITE_DUP
if (ssl->dupSide == READ_DUP_SIDE) {
WOLFSSL_MSG("Read dup side cannot write");
return WRITE_DUP_WRITE_E;
}
/* Only enter special dupWrite logic when error is cleared. This will help
* with handling async data and other edge case errors. */
if (ssl->dupWrite != NULL && ssl->error == 0) {
int dupErr = 0; /* local copy */
/* Lock ssl->dupWrite to gather what needs to be done. */
if (wc_LockMutex(&ssl->dupWrite->dupMutex) != 0)
return BAD_MUTEX_E;
dupErr = ssl->dupWrite->dupErr;
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version)) {
/* TLS 1.3: if the read side received a KeyUpdate(update_requested)
* it cannot respond; send the response from here. */
ssl->keys.keyUpdateRespond |= ssl->dupWrite->keyUpdateRespond;
ssl->dupWrite->keyUpdateRespond = 0;
#ifdef WOLFSSL_POST_HANDSHAKE_AUTH
ssl->postHandshakeAuthPending |=
ssl->dupWrite->postHandshakeAuthPending;
ssl->dupWrite->postHandshakeAuthPending = 0;
if (ssl->postHandshakeAuthPending) {
/* Take ownership of the delegated auth state. */
CertReqCtx** tail = &ssl->dupWrite->postHandshakeCertReqCtx;
while (*tail != NULL)
tail = &(*tail)->next;
*tail = ssl->certReqCtx;
ssl->certReqCtx = ssl->dupWrite->postHandshakeCertReqCtx;
ssl->dupWrite->postHandshakeCertReqCtx = NULL;
FreeHandshakeHashes(ssl);
ssl->hsHashes = ssl->dupWrite->postHandshakeHashState;
ssl->dupWrite->postHandshakeHashState = NULL;
ssl->options.sendVerify = ssl->dupWrite->postHandshakeSendVerify;
ssl->options.sigAlgo = ssl->dupWrite->postHandshakeSigAlgo;
ssl->options.hashAlgo = ssl->dupWrite->postHandshakeHashAlgo;
}
#endif /* WOLFSSL_POST_HANDSHAKE_AUTH */
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls) {
/* Schedule key update to be sent. */
if (ssl->keys.keyUpdateRespond)
ssl->dtls13DoKeyUpdate = 1;
/* Copy over ACKs */
ssl->dtls13Rtx.sendAcks |= ssl->dupWrite->sendAcks;
if (ssl->dupWrite->sendAcks) {
/* Insert each record number so the
* ACK message is properly ordered. */
struct Dtls13RecordNumber* rn;
for (rn = ssl->dupWrite->sendAckList; rn != NULL;
rn = rn->next) {
ret = Dtls13RtxAddAck(ssl, rn->epoch, rn->seq);
if (ret != 0)
break;
}
/* Clear only on success so no ACKs get dropped */
if (ret == 0) {
rn = ssl->dupWrite->sendAckList;
ssl->dupWrite->sendAckList = NULL;
ssl->dupWrite->sendAcks = 0;
while (rn != NULL) {
struct Dtls13RecordNumber* next = rn->next;
XFREE(rn, ssl->heap, DYNAMIC_TYPE_DTLS_MSG);
rn = next;
}
}
}
/* Remove KeyUpdate record from RTX list. */
if (ssl->dupWrite->keyUpdateAcked) {
Dtls13RtxRemoveRecord(ssl, ssl->dupWrite->keyUpdateEpoch,
ssl->dupWrite->keyUpdateSeq);
}
/* Store if KeyUpdate was ACKed. */
ssl->dtls13KeyUpdateAcked |= ssl->dupWrite->keyUpdateAcked;
ssl->dupWrite->keyUpdateAcked = 0;
}
#endif /* WOLFSSL_DTLS13 */
}
#endif /* WOLFSSL_TLS13 */
wc_UnLockMutex(&ssl->dupWrite->dupMutex);
if (dupErr != 0) {
WOLFSSL_MSG("Write dup error from other side");
ssl->error = dupErr;
return WOLFSSL_FATAL_ERROR;
}
if (ret != 0) {
ssl->error = ret;
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version)) {
#ifdef WOLFSSL_POST_HANDSHAKE_AUTH
/* Read side received a CertificateRequest but couldn't write;
* send Certificate+CertificateVerify+Finished from the write side. */
if (ssl->postHandshakeAuthPending) {
/* reset handshake states */
ssl->postHandshakeAuthPending = 0;
ssl->options.clientState = CLIENT_HELLO_COMPLETE;
ssl->options.connectState = FIRST_REPLY_DONE;
ssl->options.handShakeState = CLIENT_HELLO_COMPLETE;
ssl->options.processReply = 0; /* doProcessInit */
if (wolfSSL_connect_TLSv13(ssl) != WOLFSSL_SUCCESS) {
if (ssl->error != WC_NO_ERR_TRACE(WANT_WRITE) &&
ssl->error != WC_NO_ERR_TRACE(WC_PENDING_E)) {
WOLFSSL_MSG("Post-handshake auth send failed");
ssl->error = POST_HAND_AUTH_ERROR;
}
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* WOLFSSL_POST_HANDSHAKE_AUTH */
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls) {
if (ssl->dtls13KeyUpdateAcked)
ret = DoDtls13KeyUpdateAck(ssl);
ssl->dtls13KeyUpdateAcked = 0;
if (ret == 0)
ret = Dtls13DoScheduledWork(ssl);
}
else
#endif /* WOLFSSL_DTLS13 */
if (ssl->keys.keyUpdateRespond) /* cleared in SendTls13KeyUpdate */
ret = Tls13UpdateKeys(ssl);
if (ret != 0) {
ssl->error = ret;
return WOLFSSL_FATAL_ERROR;
}
/* WANT_WRITE is safe to clear. Data is buffered in output buffer
* or in DTLS RTX queue */
ret = 0;
}
#endif /* WOLFSSL_TLS13 */
}
#endif
#ifdef HAVE_ERRNO_H
errno = 0;
#endif
#ifdef OPENSSL_EXTRA
if (ssl->CBIS != NULL) {
ssl->CBIS(ssl, WOLFSSL_CB_WRITE, WOLFSSL_SUCCESS);
ssl->cbmode = WOLFSSL_CB_WRITE;
}
#endif
ret = SendData(ssl, data, sz);
WOLFSSL_LEAVE("wolfSSL_write", ret);
if (ret < 0)
return WOLFSSL_FATAL_ERROR;
else
return ret;
}
WOLFSSL_ABI
int wolfSSL_write(WOLFSSL* ssl, const void* data, int sz)
{
WOLFSSL_ENTER("wolfSSL_write");
if (sz < 0)
return BAD_FUNC_ARG;
return wolfSSL_write_internal(ssl, data, (size_t)sz);
}
int wolfSSL_inject(WOLFSSL* ssl, const void* data, int sz)
{
int maxLength;
int usedLength;
WOLFSSL_ENTER("wolfSSL_inject");
if (ssl == NULL || data == NULL || sz <= 0)
return BAD_FUNC_ARG;
usedLength = (int)(ssl->buffers.inputBuffer.length -
ssl->buffers.inputBuffer.idx);
maxLength = (int)(ssl->buffers.inputBuffer.bufferSize -
(word32)usedLength);
if (sz > maxLength) {
/* Need to make space */
int ret;
if (ssl->buffers.clearOutputBuffer.length > 0) {
/* clearOutputBuffer points into so reallocating inputBuffer will
* invalidate clearOutputBuffer and lose app data */
WOLFSSL_MSG("Can't inject while there is application data to read");
return APP_DATA_READY;
}
ret = GrowInputBuffer(ssl, sz, usedLength);
if (ret < 0)
return ret;
}
XMEMCPY(ssl->buffers.inputBuffer.buffer + ssl->buffers.inputBuffer.idx,
data, sz);
ssl->buffers.inputBuffer.length += sz;
return WOLFSSL_SUCCESS;
}
int wolfSSL_write_ex(WOLFSSL* ssl, const void* data, size_t sz, size_t* wr)
{
int ret;
if (wr != NULL) {
*wr = 0;
}
ret = wolfSSL_write_internal(ssl, data, sz);
if (ret >= 0) {
if (wr != NULL) {
*wr = (size_t)ret;
}
/* handle partial write cases, if not set then a partial write is
* considered a failure case, or if set and ret is 0 then is a fail */
if (ret == 0 && ssl->options.partialWrite) {
ret = 0;
}
else if ((size_t)ret < sz && !ssl->options.partialWrite) {
ret = 0;
}
else {
/* wrote out all application data, or wrote out 1 byte or more with
* partial write flag set */
ret = 1;
}
}
else {
ret = 0;
}
return ret;
}
static int wolfSSL_read_internal(WOLFSSL* ssl, void* data, size_t sz, int peek)
{
int ret;
WOLFSSL_ENTER("wolfSSL_read_internal");
if (ssl == NULL || data == NULL)
return BAD_FUNC_ARG;
#ifdef WOLFSSL_QUIC
if (WOLFSSL_IS_QUIC(ssl)) {
WOLFSSL_MSG("SSL_read() on QUIC not allowed");
return BAD_FUNC_ARG;
}
#endif
#if defined(WOLFSSL_ERROR_CODE_OPENSSL) && defined(OPENSSL_EXTRA)
/* This additional logic is meant to simulate following openSSL behavior:
* After bidirectional SSL_shutdown complete, SSL_read returns 0 and
* SSL_get_error_code returns SSL_ERROR_ZERO_RETURN.
* This behavior is used to know the disconnect of the underlying
* transport layer.
*
* In this logic, CBIORecv is called with a read size of 0 to check the
* transport layer status. It also returns WOLFSSL_FAILURE so that
* SSL_read does not return a positive number on failure.
*/
/* make sure bidirectional TLS shutdown completes */
if (ssl->error == WOLFSSL_ERROR_SYSCALL || ssl->options.shutdownDone) {
/* ask the underlying transport the connection is closed */
if (ssl->CBIORecv(ssl, (char*)data, 0, ssl->IOCB_ReadCtx)
== WC_NO_ERR_TRACE(WOLFSSL_CBIO_ERR_CONN_CLOSE))
{
ssl->options.isClosed = 1;
ssl->error = WOLFSSL_ERROR_ZERO_RETURN;
}
return WOLFSSL_FAILURE;
}
#endif
#ifdef HAVE_WRITE_DUP
if (ssl->dupWrite && ssl->dupSide == WRITE_DUP_SIDE) {
WOLFSSL_MSG("Write dup side cannot read");
return WRITE_DUP_READ_E;
}
#endif
#ifdef HAVE_ERRNO_H
errno = 0;
#endif
ret = ReceiveData(ssl, (byte*)data, sz, peek);
#ifdef HAVE_WRITE_DUP
if (ssl->dupWrite) {
if (ssl->error != 0 && ssl->error != WC_NO_ERR_TRACE(WANT_READ)
#ifdef WOLFSSL_ASYNC_CRYPT
&& ssl->error != WC_NO_ERR_TRACE(WC_PENDING_E)
#endif
) {
int notifyErr;
WOLFSSL_MSG("Notifying write side of fatal read error");
notifyErr = NotifyWriteSide(ssl, ssl->error);
if (notifyErr < 0) {
ret = ssl->error = notifyErr;
}
}
}
#endif
WOLFSSL_LEAVE("wolfSSL_read_internal", ret);
if (ret < 0)
return WOLFSSL_FATAL_ERROR;
else
return ret;
}
int wolfSSL_peek(WOLFSSL* ssl, void* data, int sz)
{
WOLFSSL_ENTER("wolfSSL_peek");
if (sz < 0)
return BAD_FUNC_ARG;
return wolfSSL_read_internal(ssl, data, (size_t)sz, TRUE);
}
WOLFSSL_ABI
int wolfSSL_read(WOLFSSL* ssl, void* data, int sz)
{
WOLFSSL_ENTER("wolfSSL_read");
if (sz < 0)
return BAD_FUNC_ARG;
#ifdef OPENSSL_EXTRA
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
if (ssl->CBIS != NULL) {
ssl->CBIS(ssl, WOLFSSL_CB_READ, WOLFSSL_SUCCESS);
ssl->cbmode = WOLFSSL_CB_READ;
}
#endif
return wolfSSL_read_internal(ssl, data, (size_t)sz, FALSE);
}
/* returns 0 on failure and 1 on read */
int wolfSSL_read_ex(WOLFSSL* ssl, void* data, size_t sz, size_t* rd)
{
int ret;
#ifdef OPENSSL_EXTRA
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
if (ssl->CBIS != NULL) {
ssl->CBIS(ssl, WOLFSSL_CB_READ, WOLFSSL_SUCCESS);
ssl->cbmode = WOLFSSL_CB_READ;
}
#endif
ret = wolfSSL_read_internal(ssl, data, sz, FALSE);
if (ret > 0 && rd != NULL) {
*rd = (size_t)ret;
}
return ret > 0 ? 1 : 0;
}
#endif /* !NO_TLS */
#define WOLFSSL_SSL_API_DTLS_INCLUDED
#include "src/ssl_api_dtls.c"
/* helpers to set the device id, WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_SetDevId(WOLFSSL* ssl, int devId)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->devId = devId;
return WOLFSSL_SUCCESS;
}
WOLFSSL_ABI
int wolfSSL_CTX_SetDevId(WOLFSSL_CTX* ctx, int devId)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->devId = devId;
return WOLFSSL_SUCCESS;
}
/* helpers to get device id and heap */
WOLFSSL_ABI
int wolfSSL_CTX_GetDevId(WOLFSSL_CTX* ctx, WOLFSSL* ssl)
{
int devId = INVALID_DEVID;
if (ssl != NULL)
devId = ssl->devId;
if (ctx != NULL && devId == INVALID_DEVID)
devId = ctx->devId;
return devId;
}
void* wolfSSL_CTX_GetHeap(WOLFSSL_CTX* ctx, WOLFSSL* ssl)
{
void* heap = NULL;
if (ctx != NULL)
heap = ctx->heap;
else if (ssl != NULL)
heap = ssl->heap;
return heap;
}
#ifndef NO_TLS
#ifndef WOLFSSL_LEANPSK
int wolfSSL_send(WOLFSSL* ssl, const void* data, int sz, int flags)
{
int ret;
int oldFlags;
WOLFSSL_ENTER("wolfSSL_send");
if (ssl == NULL || data == NULL || sz < 0)
return BAD_FUNC_ARG;
oldFlags = ssl->wflags;
ssl->wflags = flags;
ret = wolfSSL_write(ssl, data, sz);
ssl->wflags = oldFlags;
WOLFSSL_LEAVE("wolfSSL_send", ret);
return ret;
}
int wolfSSL_recv(WOLFSSL* ssl, void* data, int sz, int flags)
{
int ret;
int oldFlags;
WOLFSSL_ENTER("wolfSSL_recv");
if (ssl == NULL || data == NULL || sz < 0)
return BAD_FUNC_ARG;
oldFlags = ssl->rflags;
ssl->rflags = flags;
ret = wolfSSL_read(ssl, data, sz);
ssl->rflags = oldFlags;
WOLFSSL_LEAVE("wolfSSL_recv", ret);
return ret;
}
#endif
int wolfSSL_SendUserCanceled(WOLFSSL* ssl)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
WOLFSSL_ENTER("wolfSSL_recv");
if (ssl != NULL) {
ssl->error = SendAlert(ssl, alert_warning, user_canceled);
if (ssl->error < 0) {
WOLFSSL_ERROR(ssl->error);
}
else {
ret = wolfSSL_shutdown(ssl);
}
}
WOLFSSL_LEAVE("wolfSSL_SendUserCanceled", ret);
return ret;
}
/* WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_shutdown(WOLFSSL* ssl)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR);
WOLFSSL_ENTER("wolfSSL_shutdown");
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
if (ssl->options.quietShutdown) {
WOLFSSL_MSG("quiet shutdown, no close notify sent");
ret = WOLFSSL_SUCCESS;
}
else {
/* Try to flush the buffer first, it might contain the alert */
if (ssl->error == WC_NO_ERR_TRACE(WANT_WRITE) &&
ssl->buffers.outputBuffer.length > 0) {
ret = SendBuffered(ssl);
if (ret != 0) {
ssl->error = ret;
/* for error tracing */
if (ret != WC_NO_ERR_TRACE(WANT_WRITE))
WOLFSSL_ERROR(ret);
ret = WOLFSSL_FATAL_ERROR;
WOLFSSL_LEAVE("wolfSSL_shutdown", ret);
return ret;
}
ssl->error = WOLFSSL_ERROR_NONE;
/* we succeeded in sending the alert now */
if (ssl->options.sentNotify) {
/* just after we send the alert, if we didn't receive the alert
* from the other peer yet, return WOLFSSL_STHUDOWN_NOT_DONE */
if (!ssl->options.closeNotify) {
ret = WOLFSSL_SHUTDOWN_NOT_DONE;
WOLFSSL_LEAVE("wolfSSL_shutdown", ret);
return ret;
}
else {
ssl->options.shutdownDone = 1;
ret = WOLFSSL_SUCCESS;
}
}
}
/* try to send close notify, not an error if can't */
if (!ssl->options.isClosed && !ssl->options.connReset &&
!ssl->options.sentNotify) {
ssl->error = SendAlert(ssl, alert_warning, close_notify);
/* the alert is now sent or sitting in the buffer,
* where will be sent eventually */
if (ssl->error == 0 || ssl->error == WC_NO_ERR_TRACE(WANT_WRITE))
ssl->options.sentNotify = 1;
if (ssl->error < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
if (ssl->options.closeNotify) {
ret = WOLFSSL_SUCCESS;
ssl->options.shutdownDone = 1;
}
else {
ret = WOLFSSL_SHUTDOWN_NOT_DONE;
WOLFSSL_LEAVE("wolfSSL_shutdown", ret);
return ret;
}
}
#ifdef WOLFSSL_SHUTDOWNONCE
if (ssl->options.isClosed || ssl->options.connReset) {
/* Shutdown has already occurred.
* Caller is free to ignore this error. */
return SSL_SHUTDOWN_ALREADY_DONE_E;
}
#endif
/* wolfSSL_shutdown called again for bidirectional shutdown */
if (ssl->options.sentNotify && !ssl->options.closeNotify) {
ret = ProcessReply(ssl);
if ((ret == WC_NO_ERR_TRACE(ZERO_RETURN)) ||
(ret == WC_NO_ERR_TRACE(SOCKET_ERROR_E))) {
/* simulate OpenSSL behavior */
ssl->options.shutdownDone = 1;
/* Clear error */
ssl->error = WOLFSSL_ERROR_NONE;
ret = WOLFSSL_SUCCESS;
}
else if (ret == WC_NO_ERR_TRACE(MEMORY_E)) {
ret = WOLFSSL_FATAL_ERROR;
}
else if (ret == WC_NO_ERR_TRACE(WANT_READ)) {
ssl->error = ret;
ret = WOLFSSL_FATAL_ERROR;
}
else if (ssl->error == WOLFSSL_ERROR_NONE) {
ret = WOLFSSL_SHUTDOWN_NOT_DONE;
}
else {
WOLFSSL_ERROR(ssl->error);
ret = WOLFSSL_FATAL_ERROR;
}
}
}
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
/* reset WOLFSSL structure state for possible reuse */
if (ret == WOLFSSL_SUCCESS) {
if (wolfSSL_clear(ssl) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("could not clear WOLFSSL");
ret = WOLFSSL_FATAL_ERROR;
}
}
#endif
WOLFSSL_LEAVE("wolfSSL_shutdown", ret);
return ret;
}
#endif /* !NO_TLS */
/* get current error state value */
int wolfSSL_state(WOLFSSL* ssl)
{
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
return ssl->error;
}
WOLFSSL_ABI
int wolfSSL_get_error(WOLFSSL* ssl, int ret)
{
WOLFSSL_ENTER("wolfSSL_get_error");
if (ret > 0)
return WOLFSSL_ERROR_NONE;
if (ssl == NULL)
return BAD_FUNC_ARG;
WOLFSSL_LEAVE("wolfSSL_get_error", ssl->error);
/* make sure converted types are handled in SetErrorString() too */
if (ssl->error == WC_NO_ERR_TRACE(WANT_READ))
return WOLFSSL_ERROR_WANT_READ; /* convert to OpenSSL type */
else if (ssl->error == WC_NO_ERR_TRACE(WANT_WRITE))
return WOLFSSL_ERROR_WANT_WRITE; /* convert to OpenSSL type */
else if (ssl->error == WC_NO_ERR_TRACE(ZERO_RETURN) ||
ssl->options.shutdownDone)
return WOLFSSL_ERROR_ZERO_RETURN; /* convert to OpenSSL type */
#ifdef OPENSSL_EXTRA
else if (ssl->error == WC_NO_ERR_TRACE(MATCH_SUITE_ERROR))
return WOLFSSL_ERROR_SYSCALL; /* convert to OpenSSL type */
else if (ssl->error == WC_NO_ERR_TRACE(SOCKET_PEER_CLOSED_E))
return WOLFSSL_ERROR_SYSCALL; /* convert to OpenSSL type */
#endif
#ifdef WOLFSSL_ASYNC_CRYPT
else if (ssl->error == WC_NO_ERR_TRACE(MP_WOULDBLOCK))
return WC_PENDING_E; /* map non-blocking crypto */
#endif
return ssl->error;
}
/* retrieve alert history, WOLFSSL_SUCCESS on ok */
int wolfSSL_get_alert_history(WOLFSSL* ssl, WOLFSSL_ALERT_HISTORY *h)
{
if (ssl && h) {
*h = ssl->alert_history;
}
return WOLFSSL_SUCCESS;
}
#ifdef OPENSSL_EXTRA
/* returns SSL_WRITING, SSL_READING or SSL_NOTHING */
int wolfSSL_want(WOLFSSL* ssl)
{
int rw_state = WOLFSSL_NOTHING;
if (ssl) {
if (ssl->error == WC_NO_ERR_TRACE(WANT_READ))
rw_state = WOLFSSL_READING;
else if (ssl->error == WC_NO_ERR_TRACE(WANT_WRITE))
rw_state = WOLFSSL_WRITING;
}
return rw_state;
}
#endif
/* return TRUE if current error is want read */
int wolfSSL_want_read(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_want_read");
if (ssl->error == WC_NO_ERR_TRACE(WANT_READ))
return 1;
return 0;
}
/* return TRUE if current error is want write */
int wolfSSL_want_write(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_want_write");
if (ssl->error == WC_NO_ERR_TRACE(WANT_WRITE))
return 1;
return 0;
}
char* wolfSSL_ERR_error_string(unsigned long errNumber, char* data)
{
WOLFSSL_ENTER("wolfSSL_ERR_error_string");
if (data) {
SetErrorString((int)errNumber, data);
return data;
}
else {
static char tmp[WOLFSSL_MAX_ERROR_SZ] = {0};
SetErrorString((int)errNumber, tmp);
return tmp;
}
}
void wolfSSL_ERR_error_string_n(unsigned long e, char* buf, unsigned long len)
{
WOLFSSL_ENTER("wolfSSL_ERR_error_string_n");
if (len >= WOLFSSL_MAX_ERROR_SZ)
wolfSSL_ERR_error_string(e, buf);
else {
WOLFSSL_MSG("Error buffer too short, truncating");
if (len) {
char tmp[WOLFSSL_MAX_ERROR_SZ];
wolfSSL_ERR_error_string(e, tmp);
XMEMCPY(buf, tmp, len-1);
buf[len-1] = '\0';
}
}
}
/* don't free temporary arrays at end of handshake */
void wolfSSL_KeepArrays(WOLFSSL* ssl)
{
if (ssl)
ssl->options.saveArrays = 1;
}
/* user doesn't need temporary arrays anymore, Free */
void wolfSSL_FreeArrays(WOLFSSL* ssl)
{
if (ssl && ssl->options.handShakeState == HANDSHAKE_DONE) {
ssl->options.saveArrays = 0;
FreeArrays(ssl, 1);
}
}
/* Set option to indicate that the resources are not to be freed after
* handshake.
*
* ssl The SSL/TLS object.
* returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
*/
int wolfSSL_KeepHandshakeResources(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->options.keepResources = 1;
return 0;
}
/* Free the handshake resources after handshake.
*
* ssl The SSL/TLS object.
* returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
*/
int wolfSSL_FreeHandshakeResources(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
FreeHandshakeResources(ssl);
return 0;
}
/* Use the client's order of preference when matching cipher suites.
*
* ssl The SSL/TLS context object.
* returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
*/
int wolfSSL_CTX_UseClientSuites(WOLFSSL_CTX* ctx)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->useClientOrder = 1;
return 0;
}
/* Use the client's order of preference when matching cipher suites.
*
* ssl The SSL/TLS object.
* returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
*/
int wolfSSL_UseClientSuites(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->options.useClientOrder = 1;
return 0;
}
const byte* wolfSSL_GetMacSecret(WOLFSSL* ssl, int verify)
{
#ifndef WOLFSSL_AEAD_ONLY
if (ssl == NULL)
return NULL;
if ( (ssl->options.side == WOLFSSL_CLIENT_END && !verify) ||
(ssl->options.side == WOLFSSL_SERVER_END && verify) )
return ssl->keys.client_write_MAC_secret;
else
return ssl->keys.server_write_MAC_secret;
#else
(void)ssl;
(void)verify;
return NULL;
#endif
}
int wolfSSL_GetSide(WOLFSSL* ssl)
{
if (ssl)
return ssl->options.side;
return BAD_FUNC_ARG;
}
#ifdef ATOMIC_USER
void wolfSSL_CTX_SetMacEncryptCb(WOLFSSL_CTX* ctx, CallbackMacEncrypt cb)
{
if (ctx)
ctx->MacEncryptCb = cb;
}
void wolfSSL_SetMacEncryptCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->MacEncryptCtx = ctx;
}
void* wolfSSL_GetMacEncryptCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->MacEncryptCtx;
return NULL;
}
void wolfSSL_CTX_SetDecryptVerifyCb(WOLFSSL_CTX* ctx, CallbackDecryptVerify cb)
{
if (ctx)
ctx->DecryptVerifyCb = cb;
}
void wolfSSL_SetDecryptVerifyCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->DecryptVerifyCtx = ctx;
}
void* wolfSSL_GetDecryptVerifyCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->DecryptVerifyCtx;
return NULL;
}
#if defined(HAVE_ENCRYPT_THEN_MAC) && !defined(WOLFSSL_AEAD_ONLY)
/**
* Set the callback, against the context, that encrypts then MACs.
*
* ctx SSL/TLS context.
* cb Callback function to use with Encrypt-Then-MAC.
*/
void wolfSSL_CTX_SetEncryptMacCb(WOLFSSL_CTX* ctx, CallbackEncryptMac cb)
{
if (ctx)
ctx->EncryptMacCb = cb;
}
/**
* Set the context to use with callback that encrypts then MACs.
*
* ssl SSL/TLS object.
* ctx Callback function's context.
*/
void wolfSSL_SetEncryptMacCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->EncryptMacCtx = ctx;
}
/**
* Get the context being used with callback that encrypts then MACs.
*
* ssl SSL/TLS object.
* returns callback function's context or NULL if SSL/TLS object is NULL.
*/
void* wolfSSL_GetEncryptMacCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->EncryptMacCtx;
return NULL;
}
/**
* Set the callback, against the context, that MAC verifies then decrypts.
*
* ctx SSL/TLS context.
* cb Callback function to use with Encrypt-Then-MAC.
*/
void wolfSSL_CTX_SetVerifyDecryptCb(WOLFSSL_CTX* ctx, CallbackVerifyDecrypt cb)
{
if (ctx)
ctx->VerifyDecryptCb = cb;
}
/**
* Set the context to use with callback that MAC verifies then decrypts.
*
* ssl SSL/TLS object.
* ctx Callback function's context.
*/
void wolfSSL_SetVerifyDecryptCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->VerifyDecryptCtx = ctx;
}
/**
* Get the context being used with callback that MAC verifies then decrypts.
*
* ssl SSL/TLS object.
* returns callback function's context or NULL if SSL/TLS object is NULL.
*/
void* wolfSSL_GetVerifyDecryptCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->VerifyDecryptCtx;
return NULL;
}
#endif /* HAVE_ENCRYPT_THEN_MAC !WOLFSSL_AEAD_ONLY */
const byte* wolfSSL_GetClientWriteKey(WOLFSSL* ssl)
{
if (ssl)
return ssl->keys.client_write_key;
return NULL;
}
const byte* wolfSSL_GetClientWriteIV(WOLFSSL* ssl)
{
if (ssl)
return ssl->keys.client_write_IV;
return NULL;
}
const byte* wolfSSL_GetServerWriteKey(WOLFSSL* ssl)
{
if (ssl)
return ssl->keys.server_write_key;
return NULL;
}
const byte* wolfSSL_GetServerWriteIV(WOLFSSL* ssl)
{
if (ssl)
return ssl->keys.server_write_IV;
return NULL;
}
int wolfSSL_GetKeySize(WOLFSSL* ssl)
{
if (ssl)
return ssl->specs.key_size;
return BAD_FUNC_ARG;
}
int wolfSSL_GetIVSize(WOLFSSL* ssl)
{
if (ssl)
return ssl->specs.iv_size;
return BAD_FUNC_ARG;
}
int wolfSSL_GetBulkCipher(WOLFSSL* ssl)
{
if (ssl)
return ssl->specs.bulk_cipher_algorithm;
return BAD_FUNC_ARG;
}
int wolfSSL_GetCipherType(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
#ifndef WOLFSSL_AEAD_ONLY
if (ssl->specs.cipher_type == block)
return WOLFSSL_BLOCK_TYPE;
if (ssl->specs.cipher_type == stream)
return WOLFSSL_STREAM_TYPE;
#endif
if (ssl->specs.cipher_type == aead)
return WOLFSSL_AEAD_TYPE;
return WOLFSSL_FATAL_ERROR;
}
int wolfSSL_GetCipherBlockSize(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
return ssl->specs.block_size;
}
int wolfSSL_GetAeadMacSize(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
return ssl->specs.aead_mac_size;
}
int wolfSSL_IsTLSv1_1(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
if (ssl->options.tls1_1)
return 1;
return 0;
}
int wolfSSL_GetHmacSize(WOLFSSL* ssl)
{
/* AEAD ciphers don't have HMAC keys */
if (ssl)
return (ssl->specs.cipher_type != aead) ? ssl->specs.hash_size : 0;
return BAD_FUNC_ARG;
}
#ifdef WORD64_AVAILABLE
int wolfSSL_GetPeerSequenceNumber(WOLFSSL* ssl, word64 *seq)
{
if ((ssl == NULL) || (seq == NULL))
return BAD_FUNC_ARG;
*seq = ((word64)ssl->keys.peer_sequence_number_hi << 32) |
ssl->keys.peer_sequence_number_lo;
return !(*seq);
}
int wolfSSL_GetSequenceNumber(WOLFSSL* ssl, word64 *seq)
{
if ((ssl == NULL) || (seq == NULL))
return BAD_FUNC_ARG;
*seq = ((word64)ssl->keys.sequence_number_hi << 32) |
ssl->keys.sequence_number_lo;
return !(*seq);
}
#endif
#endif /* ATOMIC_USER */
#if !defined(NO_FILESYSTEM) && !defined(NO_STDIO_FILESYSTEM) \
&& defined(XFPRINTF)
void wolfSSL_ERR_print_errors_fp(XFILE fp, int err)
{
char data[WOLFSSL_MAX_ERROR_SZ + 1];
WOLFSSL_ENTER("wolfSSL_ERR_print_errors_fp");
SetErrorString(err, data);
if (XFPRINTF(fp, "%s", data) < 0)
WOLFSSL_MSG("fprintf failed in wolfSSL_ERR_print_errors_fp");
}
#if defined(OPENSSL_EXTRA) || defined(DEBUG_WOLFSSL_VERBOSE)
void wolfSSL_ERR_dump_errors_fp(XFILE fp)
{
wc_ERR_print_errors_fp(fp);
}
void wolfSSL_ERR_print_errors_cb (int (*cb)(const char *str, size_t len,
void *u), void *u)
{
wc_ERR_print_errors_cb(cb, u);
}
#endif
#endif /* !NO_FILESYSTEM && !NO_STDIO_FILESYSTEM && XFPRINTF */
/*
* TODO This ssl parameter needs to be changed to const once our ABI checker
* stops flagging qualifier additions as ABI breaking.
*/
WOLFSSL_ABI
int wolfSSL_pending(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_pending");
if (ssl == NULL)
return WOLFSSL_FAILURE;
return (int)ssl->buffers.clearOutputBuffer.length;
}
int wolfSSL_has_pending(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_has_pending");
if (ssl == NULL)
return WOLFSSL_FAILURE;
return ssl->buffers.clearOutputBuffer.length > 0;
}
#ifndef WOLFSSL_LEANPSK
/* turn on handshake group messages for context */
int wolfSSL_CTX_set_group_messages(WOLFSSL_CTX* ctx)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->groupMessages = 1;
return WOLFSSL_SUCCESS;
}
int wolfSSL_CTX_clear_group_messages(WOLFSSL_CTX* ctx)
{
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->groupMessages = 0;
return WOLFSSL_SUCCESS;
}
#endif
#if !defined(NO_WOLFSSL_CLIENT) && !defined(NO_TLS)
/* connect enough to get peer cert chain */
int wolfSSL_connect_cert(WOLFSSL* ssl)
{
int ret;
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->options.certOnly = 1;
ret = wolfSSL_connect(ssl);
ssl->options.certOnly = 0;
return ret;
}
#endif
#ifndef WOLFSSL_LEANPSK
/* turn on handshake group messages for ssl object */
int wolfSSL_set_group_messages(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->options.groupMessages = 1;
return WOLFSSL_SUCCESS;
}
int wolfSSL_clear_group_messages(WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->options.groupMessages = 0;
return WOLFSSL_SUCCESS;
}
/* make minVersion the internal equivalent SSL version */
static int SetMinVersionHelper(byte* minVersion, int version)
{
(void)minVersion;
switch (version) {
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
case WOLFSSL_SSLV3:
*minVersion = SSLv3_MINOR;
break;
#endif
#ifndef NO_TLS
#ifndef NO_OLD_TLS
#ifdef WOLFSSL_ALLOW_TLSV10
case WOLFSSL_TLSV1:
*minVersion = TLSv1_MINOR;
break;
#endif
case WOLFSSL_TLSV1_1:
*minVersion = TLSv1_1_MINOR;
break;
#endif
#ifndef WOLFSSL_NO_TLS12
case WOLFSSL_TLSV1_2:
*minVersion = TLSv1_2_MINOR;
break;
#endif
#endif
#ifdef WOLFSSL_TLS13
case WOLFSSL_TLSV1_3:
*minVersion = TLSv1_3_MINOR;
break;
#endif
#ifdef WOLFSSL_DTLS
case WOLFSSL_DTLSV1:
*minVersion = DTLS_MINOR;
break;
case WOLFSSL_DTLSV1_2:
*minVersion = DTLSv1_2_MINOR;
break;
#ifdef WOLFSSL_DTLS13
case WOLFSSL_DTLSV1_3:
*minVersion = DTLSv1_3_MINOR;
break;
#endif /* WOLFSSL_DTLS13 */
#endif /* WOLFSSL_DTLS */
default:
WOLFSSL_MSG("Bad function argument");
return BAD_FUNC_ARG;
}
return WOLFSSL_SUCCESS;
}
/* Set minimum downgrade version allowed, WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_CTX_SetMinVersion(WOLFSSL_CTX* ctx, int version)
{
WOLFSSL_ENTER("wolfSSL_CTX_SetMinVersion");
if (ctx == NULL) {
WOLFSSL_MSG("Bad function argument");
return BAD_FUNC_ARG;
}
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
if (crypto_policy.enabled) {
return CRYPTO_POLICY_FORBIDDEN;
}
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
return SetMinVersionHelper(&ctx->minDowngrade, version);
}
/* Set minimum downgrade version allowed, WOLFSSL_SUCCESS on ok */
int wolfSSL_SetMinVersion(WOLFSSL* ssl, int version)
{
WOLFSSL_ENTER("wolfSSL_SetMinVersion");
if (ssl == NULL) {
WOLFSSL_MSG("Bad function argument");
return BAD_FUNC_ARG;
}
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
if (crypto_policy.enabled) {
return CRYPTO_POLICY_FORBIDDEN;
}
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
return SetMinVersionHelper(&ssl->options.minDowngrade, version);
}
/* Function to get version as WOLFSSL_ enum value for wolfSSL_SetVersion */
int wolfSSL_GetVersion(const WOLFSSL* ssl)
{
if (ssl == NULL)
return BAD_FUNC_ARG;
if (ssl->version.major == SSLv3_MAJOR) {
switch (ssl->version.minor) {
case SSLv3_MINOR :
return WOLFSSL_SSLV3;
case TLSv1_MINOR :
return WOLFSSL_TLSV1;
case TLSv1_1_MINOR :
return WOLFSSL_TLSV1_1;
case TLSv1_2_MINOR :
return WOLFSSL_TLSV1_2;
case TLSv1_3_MINOR :
return WOLFSSL_TLSV1_3;
default:
break;
}
}
#ifdef WOLFSSL_DTLS
if (ssl->version.major == DTLS_MAJOR) {
switch (ssl->version.minor) {
case DTLS_MINOR :
return WOLFSSL_DTLSV1;
case DTLSv1_2_MINOR :
return WOLFSSL_DTLSV1_2;
case DTLSv1_3_MINOR :
return WOLFSSL_DTLSV1_3;
default:
break;
}
}
#endif /* WOLFSSL_DTLS */
return VERSION_ERROR;
}
int wolfSSL_SetVersion(WOLFSSL* ssl, int version)
{
word16 haveRSA = 1;
word16 havePSK = 0;
int keySz = 0;
WOLFSSL_ENTER("wolfSSL_SetVersion");
if (ssl == NULL) {
WOLFSSL_MSG("Bad function argument");
return BAD_FUNC_ARG;
}
switch (version) {
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
case WOLFSSL_SSLV3:
ssl->version = MakeSSLv3();
break;
#endif
#ifndef NO_TLS
#ifndef NO_OLD_TLS
#ifdef WOLFSSL_ALLOW_TLSV10
case WOLFSSL_TLSV1:
ssl->version = MakeTLSv1();
break;
#endif
case WOLFSSL_TLSV1_1:
ssl->version = MakeTLSv1_1();
break;
#endif
#ifndef WOLFSSL_NO_TLS12
case WOLFSSL_TLSV1_2:
ssl->version = MakeTLSv1_2();
break;
#endif
#ifdef WOLFSSL_TLS13
case WOLFSSL_TLSV1_3:
ssl->version = MakeTLSv1_3();
break;
#endif /* WOLFSSL_TLS13 */
#endif
default:
WOLFSSL_MSG("Bad function argument");
return BAD_FUNC_ARG;
}
ssl->options.downgrade = 0;
#ifdef NO_RSA
haveRSA = 0;
#endif
#ifndef NO_PSK
havePSK = ssl->options.havePSK;
#endif
#ifndef NO_CERTS
keySz = ssl->buffers.keySz;
#endif
if (AllocateSuites(ssl) != 0)
return WOLFSSL_FAILURE;
InitSuites(ssl->suites, ssl->version, keySz, haveRSA, havePSK,
ssl->options.haveDH, ssl->options.haveECDSAsig,
ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
ssl->options.useAnon, TRUE, TRUE, TRUE, TRUE, ssl->options.side);
return WOLFSSL_SUCCESS;
}
#endif /* !leanpsk */
#if defined(OPENSSL_EXTRA) && !defined(WOLFSSL_NO_OPENSSL_RAND_CB)
static int wolfSSL_RAND_InitMutex(void);
#endif
/* If we don't have static mutex initializers, but we do have static atomic
* initializers, activate WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS to leverage
* the latter.
*
* See further explanation below in wolfSSL_Init().
*/
#ifndef WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
#if !defined(WOLFSSL_MUTEX_INITIALIZER) && !defined(SINGLE_THREADED) && \
defined(WOLFSSL_ATOMIC_OPS) && defined(WOLFSSL_ATOMIC_INITIALIZER)
#define WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS 1
#else
#define WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS 0
#endif
#elif defined(WOLFSSL_MUTEX_INITIALIZER) || defined(SINGLE_THREADED)
#undef WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
#define WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS 0
#endif
#if WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
#ifndef WOLFSSL_ATOMIC_OPS
#error WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS requires WOLFSSL_ATOMIC_OPS
#endif
#ifndef WOLFSSL_ATOMIC_INITIALIZER
#error WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS requires WOLFSSL_ATOMIC_INITIALIZER
#endif
static wolfSSL_Atomic_Int inits_count_mutex_atomic_initing_flag =
WOLFSSL_ATOMIC_INITIALIZER(0);
#endif /* WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS && !WOLFSSL_MUTEX_INITIALIZER */
#if defined(OPENSSL_EXTRA) && defined(HAVE_ATEXIT)
static void AtExitCleanup(void)
{
if (initRefCount > 0) {
initRefCount = 1;
(void)wolfSSL_Cleanup();
#if WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
if (inits_count_mutex_valid == 1) {
(void)wc_FreeMutex(&inits_count_mutex);
inits_count_mutex_valid = 0;
inits_count_mutex_atomic_initing_flag = 0;
}
#endif
}
}
#endif
WOLFSSL_ABI
int wolfSSL_Init(void)
{
int ret = WOLFSSL_SUCCESS;
#if !defined(NO_SESSION_CACHE) && defined(ENABLE_SESSION_CACHE_ROW_LOCK)
int i;
#endif
WOLFSSL_ENTER("wolfSSL_Init");
#if defined(LIBWOLFSSL_CMAKE_OUTPUT)
WOLFSSL_MSG(LIBWOLFSSL_CMAKE_OUTPUT);
#else
WOLFSSL_MSG("No extra wolfSSL cmake messages found");
#endif
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (inits_count_mutex_valid == 0) {
#if WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
/* Without this mitigation, if two threads enter wolfSSL_Init() at the
* same time, and both see zero inits_count_mutex_valid, then both will
* run wc_InitMutex(&inits_count_mutex), leading to process corruption
* or (best case) a resource leak.
*
* When WOLFSSL_ATOMIC_INITIALIZER() is available, we can mitigate this
* by use an atomic counting int as a mutex.
*/
if (wolfSSL_Atomic_Int_FetchAdd(&inits_count_mutex_atomic_initing_flag,
1) != 0)
{
(void)wolfSSL_Atomic_Int_FetchSub(
&inits_count_mutex_atomic_initing_flag, 1);
return DEADLOCK_AVERTED_E;
}
#endif /* WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS */
if (wc_InitMutex(&inits_count_mutex) != 0) {
WOLFSSL_MSG("Bad Init Mutex count");
#if WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
(void)wolfSSL_Atomic_Int_FetchSub(
&inits_count_mutex_atomic_initing_flag, 1);
#endif
return BAD_MUTEX_E;
}
else {
inits_count_mutex_valid = 1;
}
}
#endif /* !WOLFSSL_MUTEX_INITIALIZER */
if (wc_LockMutex(&inits_count_mutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex count");
return BAD_MUTEX_E;
}
#if FIPS_VERSION_GE(5,1)
if ((ret == WOLFSSL_SUCCESS) && (initRefCount == 0)) {
ret = wolfCrypt_SetPrivateKeyReadEnable_fips(1, WC_KEYTYPE_ALL);
if (ret == 0)
ret = WOLFSSL_SUCCESS;
}
#endif
if ((ret == WOLFSSL_SUCCESS) && (initRefCount == 0)) {
/* Initialize crypto for use with TLS connection */
if (wolfCrypt_Init() != 0) {
WOLFSSL_MSG("Bad wolfCrypt Init");
ret = WC_INIT_E;
}
#if defined(HAVE_GLOBAL_RNG) && !defined(WOLFSSL_MUTEX_INITIALIZER)
if (ret == WOLFSSL_SUCCESS) {
if (wc_InitMutex(&globalRNGMutex) != 0) {
WOLFSSL_MSG("Bad Init Mutex rng");
ret = BAD_MUTEX_E;
}
else {
globalRNGMutex_valid = 1;
}
}
#endif
#ifdef WC_RNG_SEED_CB
wc_SetSeed_Cb(WC_GENERATE_SEED_DEFAULT);
#endif
#ifdef OPENSSL_EXTRA
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if ((ret == WOLFSSL_SUCCESS) && (wolfSSL_RAND_InitMutex() != 0)) {
ret = BAD_MUTEX_E;
}
#endif
if ((ret == WOLFSSL_SUCCESS) &&
(wolfSSL_RAND_seed(NULL, 0) != WOLFSSL_SUCCESS)) {
WOLFSSL_MSG("wolfSSL_RAND_seed failed");
ret = WC_INIT_E;
}
#endif
#ifndef NO_SESSION_CACHE
#ifdef ENABLE_SESSION_CACHE_ROW_LOCK
for (i = 0; i < SESSION_ROWS; ++i) {
SessionCache[i].lock_valid = 0;
}
for (i = 0; (ret == WOLFSSL_SUCCESS) && (i < SESSION_ROWS); ++i) {
if (wc_InitRwLock(&SessionCache[i].row_lock) != 0) {
WOLFSSL_MSG("Bad Init Mutex session");
ret = BAD_MUTEX_E;
}
else {
SessionCache[i].lock_valid = 1;
}
}
#else
if (ret == WOLFSSL_SUCCESS) {
if (wc_InitRwLock(&session_lock) != 0) {
WOLFSSL_MSG("Bad Init Mutex session");
ret = BAD_MUTEX_E;
}
else {
session_lock_valid = 1;
}
}
#endif
#ifndef NO_CLIENT_CACHE
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (ret == WOLFSSL_SUCCESS) {
if (wc_InitMutex(&clisession_mutex) != 0) {
WOLFSSL_MSG("Bad Init Mutex session");
ret = BAD_MUTEX_E;
}
else {
clisession_mutex_valid = 1;
}
}
#endif
#endif
#endif
#if defined(OPENSSL_EXTRA) && defined(HAVE_ATEXIT)
/* OpenSSL registers cleanup using atexit */
if ((ret == WOLFSSL_SUCCESS) && (atexit(AtExitCleanup) != 0)) {
WOLFSSL_MSG("Bad atexit registration");
ret = WC_INIT_E;
}
#endif
}
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
/* System wide crypto policy disabled by default. */
XMEMSET(&crypto_policy, 0, sizeof(crypto_policy));
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
if (ret == WOLFSSL_SUCCESS) {
initRefCount = initRefCount + 1;
}
else {
initRefCount = 1; /* Force cleanup */
}
wc_UnLockMutex(&inits_count_mutex);
if (ret != WOLFSSL_SUCCESS) {
(void)wolfSSL_Cleanup(); /* Ignore any error from cleanup */
}
return ret;
}
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
/* Helper function for wolfSSL_crypto_policy_enable and
* wolfSSL_crypto_policy_enable_buffer.
*
* Parses the crypto policy string, verifies values,
* and sets in global crypto policy struct. Not thread
* safe. String length has already been verified.
*
* Returns WOLFSSL_SUCCESS on success.
* Returns CRYPTO_POLICY_FORBIDDEN if already enabled.
* Returns < 0 on misc error.
* */
static int crypto_policy_parse(void)
{
const char * hdr = WOLFSSL_SECLEVEL_STR;
int sec_level = 0;
size_t i = 0;
/* All policies should begin with "@SECLEVEL=<N>" (N={0..5}) followed
* by bulk cipher list. */
if (XMEMCMP(crypto_policy.str, hdr, strlen(hdr)) != 0) {
WOLFSSL_MSG("error: crypto policy: invalid header");
return WOLFSSL_BAD_FILE;
}
{
/* Extract the security level. */
char * policy_mem = crypto_policy.str;
policy_mem += strlen(hdr);
sec_level = (int) (*policy_mem - '0');
}
if (sec_level < MIN_WOLFSSL_SEC_LEVEL ||
sec_level > MAX_WOLFSSL_SEC_LEVEL) {
WOLFSSL_MSG_EX("error: invalid SECLEVEL: %d", sec_level);
return WOLFSSL_BAD_FILE;
}
/* Remove trailing '\r' or '\n'. */
for (i = 0; i < MAX_WOLFSSL_CRYPTO_POLICY_SIZE; ++i) {
if (crypto_policy.str[i] == '\0') {
break;
}
if (crypto_policy.str[i] == '\r' || crypto_policy.str[i] == '\n') {
crypto_policy.str[i] = '\0';
break;
}
}
#if defined(DEBUG_WOLFSSL_VERBOSE)
WOLFSSL_MSG_EX("info: SECLEVEL=%d", sec_level);
WOLFSSL_MSG_EX("info: using crypto-policy file: %s, %ld", policy_file, sz);
#endif /* DEBUG_WOLFSSL_VERBOSE */
crypto_policy.secLevel = sec_level;
crypto_policy.enabled = 1;
return WOLFSSL_SUCCESS;
}
#ifndef NO_FILESYSTEM
/* Enables wolfSSL system wide crypto-policy, using the given policy
* file arg. If NULL is passed, then the default system crypto-policy
* file that was set at configure time will be used instead.
*
* While enabled:
* - TLS methods, min key sizes, and cipher lists are all configured
* automatically by the policy.
* - Attempting to use lesser strength parameters will fail with
* error CRYPTO_POLICY_FORBIDDEN.
*
* Disable with wolfSSL_crypto_policy_disable.
*
* Note: the wolfSSL_crypto_policy_X API are not thread safe, and should
* only be called at program init time.
*
* Returns WOLFSSL_SUCCESS on success.
* Returns CRYPTO_POLICY_FORBIDDEN if already enabled.
* Returns < 0 on misc error.
* */
int wolfSSL_crypto_policy_enable(const char * policy_file)
{
XFILE file;
long sz = 0;
size_t n_read = 0;
WOLFSSL_ENTER("wolfSSL_crypto_policy_enable");
if (wolfSSL_crypto_policy_is_enabled()) {
WOLFSSL_MSG_EX("error: crypto policy already enabled: %s",
policy_file);
return CRYPTO_POLICY_FORBIDDEN;
}
if (policy_file == NULL) {
/* Use the configure-time default if NULL passed. */
policy_file = WC_STRINGIFY(WOLFSSL_CRYPTO_POLICY_FILE);
}
if (policy_file == NULL || *policy_file == '\0') {
WOLFSSL_MSG("error: crypto policy empty file");
return BAD_FUNC_ARG;
}
XMEMSET(&crypto_policy, 0, sizeof(crypto_policy));
file = XFOPEN(policy_file, "rb");
if (file == XBADFILE) {
WOLFSSL_MSG_EX("error: crypto policy file open failed: %s",
policy_file);
return WOLFSSL_BAD_FILE;
}
if (XFSEEK(file, 0, XSEEK_END) != 0) {
WOLFSSL_MSG_EX("error: crypto policy file seek end failed: %s",
policy_file);
XFCLOSE(file);
return WOLFSSL_BAD_FILE;
}
sz = XFTELL(file);
if (XFSEEK(file, 0, XSEEK_SET) != 0) {
WOLFSSL_MSG_EX("error: crypto policy file seek failed: %s",
policy_file);
XFCLOSE(file);
return WOLFSSL_BAD_FILE;
}
if (sz <= 0 || sz > MAX_WOLFSSL_CRYPTO_POLICY_SIZE) {
WOLFSSL_MSG_EX("error: crypto policy file %s, invalid size: %ld",
policy_file, sz);
XFCLOSE(file);
return WOLFSSL_BAD_FILE;
}
n_read = XFREAD(crypto_policy.str, 1, sz, file);
XFCLOSE(file);
if (n_read != (size_t) sz) {
WOLFSSL_MSG_EX("error: crypto policy file %s: read %zu, "
"expected %ld", policy_file, n_read, sz);
return WOLFSSL_BAD_FILE;
}
crypto_policy.str[n_read] = '\0';
return crypto_policy_parse();
}
#endif /* ! NO_FILESYSTEM */
/* Same behavior as wolfSSL_crypto_policy_enable, but loads
* via memory buf instead of file.
*
* Returns WOLFSSL_SUCCESS on success.
* Returns CRYPTO_POLICY_FORBIDDEN if already enabled.
* Returns < 0 on misc error.
* */
int wolfSSL_crypto_policy_enable_buffer(const char * buf)
{
size_t sz = 0;
WOLFSSL_ENTER("wolfSSL_crypto_policy_enable_buffer");
if (wolfSSL_crypto_policy_is_enabled()) {
WOLFSSL_MSG_EX("error: crypto policy already enabled");
return CRYPTO_POLICY_FORBIDDEN;
}
if (buf == NULL || *buf == '\0') {
return BAD_FUNC_ARG;
}
sz = XSTRLEN(buf);
if (sz == 0 || sz > MAX_WOLFSSL_CRYPTO_POLICY_SIZE) {
return BAD_FUNC_ARG;
}
XMEMSET(&crypto_policy, 0, sizeof(crypto_policy));
XMEMCPY(crypto_policy.str, buf, sz);
return crypto_policy_parse();
}
/* Returns whether the system wide crypto-policy is enabled.
*
* Returns 1 if enabled.
* 0 if disabled.
* */
int wolfSSL_crypto_policy_is_enabled(void)
{
WOLFSSL_ENTER("wolfSSL_crypto_policy_is_enabled");
return crypto_policy.enabled == 1;
}
/* Disables the system wide crypto-policy.
* note: SSL and CTX structures already instantiated will
* keep their security policy parameters. This will only
* affect new instantiations.
* */
void wolfSSL_crypto_policy_disable(void)
{
WOLFSSL_ENTER("wolfSSL_crypto_policy_disable");
crypto_policy.enabled = 0;
XMEMSET(&crypto_policy, 0, sizeof(crypto_policy));
return;
}
/* Get the crypto-policy bulk cipher list string.
* String is not owned by caller, should not be freed.
*
* Returns pointer to bulk cipher list string.
* Returns NULL if NOT enabled, or on error.
* */
const char * wolfSSL_crypto_policy_get_ciphers(void)
{
WOLFSSL_ENTER("wolfSSL_crypto_policy_get_ciphers");
if (crypto_policy.enabled == 1) {
/* The crypto policy config will have
* this form:
* "@SECLEVEL=2:kEECDH:kRSA..." */
return crypto_policy.str;
}
return NULL;
}
/* Get the configured crypto-policy security level.
* A security level of 0 does not impose any additional
* restrictions.
*
* Returns 1 - 5 if enabled.
* Returns 0 if NOT enabled.
* */
int wolfSSL_crypto_policy_get_level(void)
{
if (crypto_policy.enabled == 1) {
return crypto_policy.secLevel;
}
return 0;
}
/* Get security level from ssl structure.
* @param ssl a pointer to WOLFSSL structure
*/
int wolfSSL_get_security_level(const WOLFSSL * ssl)
{
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
return ssl->secLevel;
}
#ifndef NO_WOLFSSL_STUB
/*
* Set security level (wolfSSL doesn't support setting the security level).
*
* The security level can only be set through a system wide crypto-policy
* with wolfSSL_crypto_policy_enable().
*
* @param ssl a pointer to WOLFSSL structure
* @param level security level
*/
void wolfSSL_set_security_level(WOLFSSL * ssl, int level)
{
WOLFSSL_ENTER("wolfSSL_set_security_level");
(void)ssl;
(void)level;
}
#endif /* !NO_WOLFSSL_STUB */
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
#define WOLFSSL_SSL_LOAD_INCLUDED
#include <src/ssl_load.c>
#define WOLFSSL_SSL_API_CRL_OCSP_INCLUDED
#include "src/ssl_api_crl_ocsp.c"
void wolfSSL_load_error_strings(void)
{
/* compatibility only */
}
int wolfSSL_library_init(void)
{
WOLFSSL_ENTER("wolfSSL_library_init");
if (wolfSSL_Init() == WOLFSSL_SUCCESS)
return WOLFSSL_SUCCESS;
else
return WOLFSSL_FATAL_ERROR;
}
#ifdef HAVE_SECRET_CALLBACK
int wolfSSL_set_session_secret_cb(WOLFSSL* ssl, SessionSecretCb cb, void* ctx)
{
WOLFSSL_ENTER("wolfSSL_set_session_secret_cb");
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->sessionSecretCb = cb;
ssl->sessionSecretCtx = ctx;
if (cb != NULL) {
/* If using a pre-set key, assume session resumption. */
ssl->session->sessionIDSz = 0;
ssl->options.resuming = 1;
}
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_session_ticket_ext_cb(WOLFSSL* ssl, TicketParseCb cb,
void *ctx)
{
WOLFSSL_ENTER("wolfSSL_set_session_ticket_ext_cb");
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->ticketParseCb = cb;
ssl->ticketParseCtx = ctx;
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_secret_cb(WOLFSSL* ssl, TlsSecretCb cb, void* ctx)
{
WOLFSSL_ENTER("wolfSSL_set_secret_cb");
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
ssl->tlsSecretCb = cb;
ssl->tlsSecretCtx = ctx;
return WOLFSSL_SUCCESS;
}
#ifdef SHOW_SECRETS
int tlsShowSecrets(WOLFSSL* ssl, void* secret, int secretSz,
void* ctx)
{
/* Wireshark Pre-Master-Secret Format:
* CLIENT_RANDOM <clientrandom> <mastersecret>
*/
const char* CLIENT_RANDOM_LABEL = "CLIENT_RANDOM";
int i, pmsPos = 0;
char pmsBuf[13 + 1 + 64 + 1 + 96 + 1 + 1];
byte clientRandom[RAN_LEN];
int clientRandomSz;
(void)ctx;
clientRandomSz = (int)wolfSSL_get_client_random(ssl, clientRandom,
sizeof(clientRandom));
if (clientRandomSz <= 0) {
printf("Error getting server random %d\n", clientRandomSz);
return BAD_FUNC_ARG;
}
XSNPRINTF(&pmsBuf[pmsPos], sizeof(pmsBuf) - pmsPos, "%s ",
CLIENT_RANDOM_LABEL);
pmsPos += XSTRLEN(CLIENT_RANDOM_LABEL) + 1;
for (i = 0; i < clientRandomSz; i++) {
XSNPRINTF(&pmsBuf[pmsPos], sizeof(pmsBuf) - pmsPos, "%02x",
clientRandom[i]);
pmsPos += 2;
}
XSNPRINTF(&pmsBuf[pmsPos], sizeof(pmsBuf) - pmsPos, " ");
pmsPos += 1;
for (i = 0; i < secretSz; i++) {
XSNPRINTF(&pmsBuf[pmsPos], sizeof(pmsBuf) - pmsPos, "%02x",
((byte*)secret)[i]);
pmsPos += 2;
}
XSNPRINTF(&pmsBuf[pmsPos], sizeof(pmsBuf) - pmsPos, "\n");
pmsPos += 1;
/* print master secret */
puts(pmsBuf);
#if !defined(NO_FILESYSTEM) && defined(WOLFSSL_SSLKEYLOGFILE)
{
FILE* f = XFOPEN(WOLFSSL_SSLKEYLOGFILE_OUTPUT, "a");
if (f != XBADFILE) {
XFWRITE(pmsBuf, 1, pmsPos, f);
XFCLOSE(f);
}
}
#endif
return 0;
}
#endif /* SHOW_SECRETS */
#endif
#ifdef OPENSSL_EXTRA
/*
* check if the list has TLS13 and pre-TLS13 suites
* @param list cipher suite list that user want to set
* (caller required to check for NULL)
* @return mixed: 0, only pre-TLS13: 1, only TLS13: 2
*/
static int CheckcipherList(const char* list)
{
int ret;
int findTLSv13Suites = 0;
int findbeforeSuites = 0;
byte cipherSuite0;
byte cipherSuite1;
int flags;
char* next = (char*)list;
do {
char* current = next;
char name[MAX_SUITE_NAME + 1];
word32 length = MAX_SUITE_NAME;
word32 current_length;
byte major = INVALID_BYTE;
byte minor = INVALID_BYTE;
next = XSTRSTR(next, ":");
if (next) {
current_length = (word32)(next - current);
++next; /* increment to skip ':' */
}
else {
current_length = (word32)XSTRLEN(current);
}
if (current_length == 0) {
break;
}
if (current_length < length) {
length = current_length;
}
XMEMCPY(name, current, length);
name[length] = 0;
if (XSTRCMP(name, "ALL") == 0 ||
XSTRCMP(name, "DEFAULT") == 0 ||
XSTRCMP(name, "HIGH") == 0)
{
findTLSv13Suites = 1;
findbeforeSuites = 1;
break;
}
ret = GetCipherSuiteFromName(name, &cipherSuite0,
&cipherSuite1, &major, &minor, &flags);
if (ret == 0) {
if (cipherSuite0 == TLS13_BYTE || minor == TLSv1_3_MINOR) {
/* TLSv13 suite */
findTLSv13Suites = 1;
}
else {
findbeforeSuites = 1;
}
}
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
/* check if mixed due to names like RSA:ECDHE+AESGCM etc. */
if (ret != 0) {
char* subStr = name;
char* subStrNext;
do {
subStrNext = XSTRSTR(subStr, "+");
if ((XSTRCMP(subStr, "ECDHE") == 0) ||
(XSTRCMP(subStr, "RSA") == 0)) {
return 0;
}
if (subStrNext && (XSTRLEN(subStrNext) > 0)) {
subStr = subStrNext + 1; /* +1 to skip past '+' */
}
} while (subStrNext != NULL);
}
#endif
if (findTLSv13Suites == 1 && findbeforeSuites == 1) {
/* list has mixed suites */
return 0;
}
} while (next);
if (findTLSv13Suites == 0 && findbeforeSuites == 1) {
ret = 1;/* only before TLSv13 suites */
}
else if (findTLSv13Suites == 1 && findbeforeSuites == 0) {
ret = 2;/* only TLSv13 suties */
}
else {
ret = 0;/* handle as mixed */
}
return ret;
}
/* parse some bulk lists like !eNULL / !aNULL
*
* returns WOLFSSL_SUCCESS on success and sets the cipher suite list
*/
static int wolfSSL_parse_cipher_list(WOLFSSL_CTX* ctx, WOLFSSL* ssl,
Suites* suites, const char* list)
{
int ret = 0;
int listattribute = 0;
int tls13Only = 0;
WC_DECLARE_VAR(suitesCpy, byte, WOLFSSL_MAX_SUITE_SZ, 0);
word16 suitesCpySz = 0;
word16 i = 0;
word16 j = 0;
if (suites == NULL || list == NULL) {
WOLFSSL_MSG("NULL argument");
return WOLFSSL_FAILURE;
}
listattribute = CheckcipherList(list);
if (listattribute == 0) {
/* list has mixed(pre-TLSv13 and TLSv13) suites
* update cipher suites the same as before
*/
return (SetCipherList_ex(ctx, ssl, suites, list)) ? WOLFSSL_SUCCESS :
WOLFSSL_FAILURE;
}
else if (listattribute == 1) {
/* list has only pre-TLSv13 suites.
* Only update before TLSv13 suites.
*/
tls13Only = 0;
}
else if (listattribute == 2) {
/* list has only TLSv13 suites. Only update TLv13 suites
* simulate set_ciphersuites() compatibility layer API
*/
tls13Only = 1;
if ((ctx != NULL && !IsAtLeastTLSv1_3(ctx->method->version)) ||
(ssl != NULL && !IsAtLeastTLSv1_3(ssl->version))) {
/* Silently ignore TLS 1.3 ciphers if we don't support it. */
return WOLFSSL_SUCCESS;
}
}
/* list contains ciphers either only for TLS 1.3 or <= TLS 1.2 */
#ifdef WOLFSSL_SMALL_STACK
if (suites->suiteSz > 0) {
suitesCpy = (byte*)XMALLOC(suites->suiteSz, NULL,
DYNAMIC_TYPE_TMP_BUFFER);
if (suitesCpy == NULL) {
return WOLFSSL_FAILURE;
}
XMEMSET(suitesCpy, 0, suites->suiteSz);
}
#else
XMEMSET(suitesCpy, 0, sizeof(suitesCpy));
#endif
if (suites->suiteSz > 0)
XMEMCPY(suitesCpy, suites->suites, suites->suiteSz);
suitesCpySz = suites->suiteSz;
ret = SetCipherList_ex(ctx, ssl, suites, list);
if (ret != 1) {
WC_FREE_VAR_EX(suitesCpy, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return WOLFSSL_FAILURE;
}
/* The idea in this section is that OpenSSL has two API to set ciphersuites.
* - SSL_CTX_set_cipher_list for setting TLS <= 1.2 suites
* - SSL_CTX_set_ciphersuites for setting TLS 1.3 suites
* Since we direct both API here we attempt to provide API compatibility. If
* we only get suites from <= 1.2 or == 1.3 then we will only update those
* suites and keep the suites from the other group.
* If downgrade is disabled, skip preserving the other group's suites. */
if ((ssl != NULL && !ssl->options.downgrade) ||
(ctx != NULL && !ctx->method->downgrade)) {
/* Downgrade disabled - don't preserve other group's suites */
WC_FREE_VAR_EX(suitesCpy, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return ret;
}
for (i = 0; i < suitesCpySz &&
suites->suiteSz <= (WOLFSSL_MAX_SUITE_SZ - SUITE_LEN); i += 2) {
/* Check for duplicates */
int duplicate = 0;
for (j = 0; j < suites->suiteSz; j += 2) {
if (suitesCpy[i] == suites->suites[j] &&
suitesCpy[i+1] == suites->suites[j+1]) {
duplicate = 1;
break;
}
}
if (!duplicate) {
if (tls13Only) {
/* Updating TLS 1.3 ciphers */
if (suitesCpy[i] != TLS13_BYTE) {
/* Only copy over <= TLS 1.2 ciphers */
/* TLS 1.3 ciphers take precedence */
suites->suites[suites->suiteSz++] = suitesCpy[i];
suites->suites[suites->suiteSz++] = suitesCpy[i+1];
}
}
else {
/* Updating <= TLS 1.2 ciphers */
if (suitesCpy[i] == TLS13_BYTE) {
/* Only copy over TLS 1.3 ciphers */
/* TLS 1.3 ciphers take precedence */
XMEMMOVE(suites->suites + SUITE_LEN, suites->suites,
suites->suiteSz);
suites->suites[0] = suitesCpy[i];
suites->suites[1] = suitesCpy[i+1];
suites->suiteSz += 2;
}
}
}
}
WC_FREE_VAR_EX(suitesCpy, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return ret;
}
#endif
int wolfSSL_CTX_set_cipher_list(WOLFSSL_CTX* ctx, const char* list)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_cipher_list");
if (ctx == NULL)
return WOLFSSL_FAILURE;
if (AllocateCtxSuites(ctx) != 0)
return WOLFSSL_FAILURE;
#ifdef OPENSSL_EXTRA
return wolfSSL_parse_cipher_list(ctx, NULL, ctx->suites, list);
#else
return (SetCipherList(ctx, ctx->suites, list)) ?
WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
#endif
}
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_SET_CIPHER_BYTES)
int wolfSSL_CTX_set_cipher_list_bytes(WOLFSSL_CTX* ctx, const byte* list,
const int listSz)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_cipher_list_bytes");
if (ctx == NULL)
return WOLFSSL_FAILURE;
if (AllocateCtxSuites(ctx) != 0)
return WOLFSSL_FAILURE;
return (SetCipherListFromBytes(ctx, ctx->suites, list, listSz)) ?
WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_SET_CIPHER_BYTES */
int wolfSSL_set_cipher_list(WOLFSSL* ssl, const char* list)
{
WOLFSSL_ENTER("wolfSSL_set_cipher_list");
if (ssl == NULL || ssl->ctx == NULL) {
return WOLFSSL_FAILURE;
}
if (AllocateSuites(ssl) != 0)
return WOLFSSL_FAILURE;
#ifdef OPENSSL_EXTRA
return wolfSSL_parse_cipher_list(NULL, ssl, ssl->suites, list);
#else
return (SetCipherList_ex(NULL, ssl, ssl->suites, list)) ?
WOLFSSL_SUCCESS :
WOLFSSL_FAILURE;
#endif
}
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_SET_CIPHER_BYTES)
int wolfSSL_set_cipher_list_bytes(WOLFSSL* ssl, const byte* list,
const int listSz)
{
WOLFSSL_ENTER("wolfSSL_set_cipher_list_bytes");
if (ssl == NULL || ssl->ctx == NULL) {
return WOLFSSL_FAILURE;
}
if (AllocateSuites(ssl) != 0)
return WOLFSSL_FAILURE;
return (SetCipherListFromBytes(ssl->ctx, ssl->suites, list, listSz))
? WOLFSSL_SUCCESS
: WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_SET_CIPHER_BYTES */
#ifdef HAVE_KEYING_MATERIAL
#define TLS_PRF_LABEL_CLIENT_FINISHED "client finished"
#define TLS_PRF_LABEL_SERVER_FINISHED "server finished"
#define TLS_PRF_LABEL_MASTER_SECRET "master secret"
#define TLS_PRF_LABEL_EXT_MASTER_SECRET "extended master secret"
#define TLS_PRF_LABEL_KEY_EXPANSION "key expansion"
static const struct ForbiddenLabels {
const char* label;
size_t labelLen;
} forbiddenLabels[] = {
{TLS_PRF_LABEL_CLIENT_FINISHED, XSTR_SIZEOF(TLS_PRF_LABEL_CLIENT_FINISHED)},
{TLS_PRF_LABEL_SERVER_FINISHED, XSTR_SIZEOF(TLS_PRF_LABEL_SERVER_FINISHED)},
{TLS_PRF_LABEL_MASTER_SECRET, XSTR_SIZEOF(TLS_PRF_LABEL_MASTER_SECRET)},
{TLS_PRF_LABEL_EXT_MASTER_SECRET,
XSTR_SIZEOF(TLS_PRF_LABEL_EXT_MASTER_SECRET)},
{TLS_PRF_LABEL_KEY_EXPANSION, XSTR_SIZEOF(TLS_PRF_LABEL_KEY_EXPANSION)},
{NULL, 0},
};
/**
* Implement RFC 5705
* TLS 1.3 uses a different exporter definition (section 7.5 of RFC 8446)
* @return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on error
*/
int wolfSSL_export_keying_material(WOLFSSL *ssl,
unsigned char *out, size_t outLen,
const char *label, size_t labelLen,
const unsigned char *context, size_t contextLen,
int use_context)
{
byte* seed = NULL;
word32 seedLen;
const struct ForbiddenLabels* fl;
WOLFSSL_ENTER("wolfSSL_export_keying_material");
if (ssl == NULL || out == NULL || label == NULL ||
(use_context && contextLen && context == NULL)) {
WOLFSSL_MSG("Bad argument");
return WOLFSSL_FAILURE;
}
/* Sanity check contextLen to prevent integer overflow when cast to word32
* and to ensure it fits in the 2-byte length encoding (max 65535). */
if (use_context && contextLen > WOLFSSL_MAX_16BIT) {
WOLFSSL_MSG("contextLen too large");
return WOLFSSL_FAILURE;
}
/* clientRandom + serverRandom
* OR
* clientRandom + serverRandom + ctx len encoding + ctx */
seedLen = !use_context ? (word32)SEED_LEN :
(word32)SEED_LEN + 2 + (word32)contextLen;
if (ssl->options.saveArrays == 0 || ssl->arrays == NULL) {
WOLFSSL_MSG("To export keying material wolfSSL needs to keep handshake "
"data. Call wolfSSL_KeepArrays before attempting to "
"export keyid material.");
return WOLFSSL_FAILURE;
}
/* check forbidden labels */
for (fl = &forbiddenLabels[0]; fl->label != NULL; fl++) {
if (labelLen >= fl->labelLen &&
XMEMCMP(label, fl->label, fl->labelLen) == 0) {
WOLFSSL_MSG("Forbidden label");
return WOLFSSL_FAILURE;
}
}
#ifdef WOLFSSL_TLS13
if (IsAtLeastTLSv1_3(ssl->version)) {
/* Path for TLS 1.3 */
if (!use_context) {
contextLen = 0;
context = (byte*)""; /* Give valid pointer for 0 length memcpy */
}
if (Tls13_Exporter(ssl, out, (word32)outLen, label, labelLen,
context, contextLen) != 0) {
WOLFSSL_MSG("Tls13_Exporter error");
return WOLFSSL_FAILURE;
}
return WOLFSSL_SUCCESS;
}
#endif
/* Path for <=TLS 1.2 */
seed = (byte*)XMALLOC(seedLen, NULL, DYNAMIC_TYPE_TMP_BUFFER);
if (seed == NULL) {
WOLFSSL_MSG("malloc error");
return WOLFSSL_FAILURE;
}
XMEMCPY(seed, ssl->arrays->clientRandom, RAN_LEN);
XMEMCPY(seed + RAN_LEN, ssl->arrays->serverRandom, RAN_LEN);
if (use_context) {
/* Encode len in big endian */
seed[SEED_LEN ] = (contextLen >> 8) & 0xFF;
seed[SEED_LEN + 1] = (contextLen) & 0xFF;
if (contextLen) {
/* 0 length context is allowed */
XMEMCPY(seed + SEED_LEN + 2, context, contextLen);
}
}
PRIVATE_KEY_UNLOCK();
if (wc_PRF_TLS(out, (word32)outLen, ssl->arrays->masterSecret, SECRET_LEN,
(byte*)label, (word32)labelLen, seed, seedLen,
IsAtLeastTLSv1_2(ssl), ssl->specs.mac_algorithm, ssl->heap,
ssl->devId) != 0) {
WOLFSSL_MSG("wc_PRF_TLS error");
PRIVATE_KEY_LOCK();
XFREE(seed, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return WOLFSSL_FAILURE;
}
PRIVATE_KEY_LOCK();
XFREE(seed, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return WOLFSSL_SUCCESS;
}
#endif /* HAVE_KEYING_MATERIAL */
/* EITHER SIDE METHODS */
#if !defined(NO_TLS) && (defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE))
WOLFSSL_METHOD* wolfSSLv23_method(void)
{
return wolfSSLv23_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv23_method_ex(void* heap)
{
WOLFSSL_METHOD* m = NULL;
WOLFSSL_ENTER("wolfSSLv23_method");
#if !defined(NO_WOLFSSL_CLIENT)
m = wolfSSLv23_client_method_ex(heap);
#elif !defined(NO_WOLFSSL_SERVER)
m = wolfSSLv23_server_method_ex(heap);
#else
(void)heap;
#endif
if (m != NULL) {
m->side = WOLFSSL_NEITHER_END;
}
return m;
}
#ifndef NO_OLD_TLS
#ifdef WOLFSSL_ALLOW_SSLV3
WOLFSSL_METHOD* wolfSSLv3_method(void)
{
return wolfSSLv3_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv3_method_ex(void* heap)
{
WOLFSSL_METHOD* m = NULL;
WOLFSSL_ENTER("wolfSSLv3_method_ex");
#if !defined(NO_WOLFSSL_CLIENT)
m = wolfSSLv3_client_method_ex(heap);
#elif !defined(NO_WOLFSSL_SERVER)
m = wolfSSLv3_server_method_ex(heap);
#endif
if (m != NULL) {
m->side = WOLFSSL_NEITHER_END;
}
return m;
}
#endif
#endif
#endif /* !NO_TLS && (OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE) */
/* client only parts */
#if !defined(NO_WOLFSSL_CLIENT) && !defined(NO_TLS)
#if defined(OPENSSL_EXTRA) && !defined(NO_OLD_TLS)
WOLFSSL_METHOD* wolfSSLv2_client_method(void)
{
WOLFSSL_STUB("wolfSSLv2_client_method");
return NULL;
}
#endif
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
WOLFSSL_METHOD* wolfSSLv3_client_method(void)
{
return wolfSSLv3_client_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv3_client_method_ex(void* heap)
{
WOLFSSL_METHOD* method =
(WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
heap, DYNAMIC_TYPE_METHOD);
(void)heap;
WOLFSSL_ENTER("wolfSSLv3_client_method_ex");
if (method)
InitSSL_Method(method, MakeSSLv3());
return method;
}
#endif /* WOLFSSL_ALLOW_SSLV3 && !NO_OLD_TLS */
WOLFSSL_METHOD* wolfSSLv23_client_method(void)
{
return wolfSSLv23_client_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv23_client_method_ex(void* heap)
{
WOLFSSL_METHOD* method =
(WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
heap, DYNAMIC_TYPE_METHOD);
(void)heap;
WOLFSSL_ENTER("wolfSSLv23_client_method_ex");
if (method) {
#if !defined(NO_SHA256) || defined(WOLFSSL_SHA384) || \
defined(WOLFSSL_SHA512)
#if defined(WOLFSSL_TLS13)
InitSSL_Method(method, MakeTLSv1_3());
#elif !defined(WOLFSSL_NO_TLS12)
InitSSL_Method(method, MakeTLSv1_2());
#elif !defined(NO_OLD_TLS)
InitSSL_Method(method, MakeTLSv1_1());
#endif
#else
#ifndef NO_OLD_TLS
InitSSL_Method(method, MakeTLSv1_1());
#endif
#endif
#if !defined(NO_OLD_TLS) || defined(WOLFSSL_TLS13)
method->downgrade = 1;
#endif
}
return method;
}
/* please see note at top of README if you get an error from connect */
WOLFSSL_ABI
int wolfSSL_connect(WOLFSSL* ssl)
{
#if !(defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && \
defined(WOLFSSL_TLS13))
int neededState;
byte advanceState;
#endif
int ret = 0;
(void)ret;
#ifdef HAVE_ERRNO_H
errno = 0;
#endif
if (ssl == NULL)
return BAD_FUNC_ARG;
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE)
if (ssl->options.side == WOLFSSL_NEITHER_END) {
ssl->error = InitSSL_Side(ssl, WOLFSSL_CLIENT_END);
if (ssl->error != WOLFSSL_SUCCESS) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->error = 0; /* expected to be zero here */
}
#ifdef OPENSSL_EXTRA
if (ssl->CBIS != NULL) {
ssl->CBIS(ssl, WOLFSSL_ST_CONNECT, WOLFSSL_SUCCESS);
ssl->cbmode = WOLFSSL_CB_WRITE;
}
#endif
#endif /* OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE */
#if defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && \
defined(WOLFSSL_TLS13)
return wolfSSL_connect_TLSv13(ssl);
#else
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3) {
WOLFSSL_MSG("TLS 1.3");
return wolfSSL_connect_TLSv13(ssl);
}
#endif
WOLFSSL_MSG("TLS 1.2 or lower");
WOLFSSL_ENTER("wolfSSL_connect");
/* make sure this wolfSSL object has arrays and rng setup. Protects
* case where the WOLFSSL object is reused via wolfSSL_clear() */
if ((ret = ReinitSSL(ssl, ssl->ctx, 0)) != 0) {
return ret;
}
#ifdef WOLFSSL_WOLFSENTRY_HOOKS
if ((ssl->ConnectFilter != NULL) &&
(ssl->options.connectState == CONNECT_BEGIN)) {
wolfSSL_netfilter_decision_t res;
if ((ssl->ConnectFilter(ssl, ssl->ConnectFilter_arg, &res) ==
WOLFSSL_SUCCESS) &&
(res == WOLFSSL_NETFILTER_REJECT)) {
ssl->error = SOCKET_FILTERED_E;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* WOLFSSL_WOLFSENTRY_HOOKS */
if (ssl->options.side != WOLFSSL_CLIENT_END) {
ssl->error = SIDE_ERROR;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_DTLS
if (ssl->version.major == DTLS_MAJOR) {
ssl->options.dtls = 1;
ssl->options.tls = 1;
ssl->options.tls1_1 = 1;
ssl->options.dtlsStateful = 1;
}
#endif
/* fragOffset is non-zero when sending fragments. On the last
* fragment, fragOffset is zero again, and the state can be
* advanced. */
advanceState = ssl->fragOffset == 0 &&
(ssl->options.connectState == CONNECT_BEGIN ||
ssl->options.connectState == HELLO_AGAIN ||
(ssl->options.connectState >= FIRST_REPLY_DONE &&
ssl->options.connectState <= FIRST_REPLY_FOURTH));
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls && IsAtLeastTLSv1_3(ssl->version))
advanceState = advanceState && !ssl->dtls13SendingAckOrRtx;
#endif /* WOLFSSL_DTLS13 */
if (ssl->buffers.outputBuffer.length > 0
#ifdef WOLFSSL_ASYNC_CRYPT
/* do not send buffered or advance state if last error was an
async pending operation */
&& ssl->error != WC_NO_ERR_TRACE(WC_PENDING_E)
#endif
) {
ret = SendBuffered(ssl);
if (ret == 0) {
if (ssl->fragOffset == 0 && !ssl->options.buildingMsg) {
if (advanceState) {
ssl->options.connectState++;
WOLFSSL_MSG("connect state: Advanced from last "
"buffered fragment send");
#ifdef WOLFSSL_ASYNC_IO
/* Cleanup async */
FreeAsyncCtx(ssl, 0);
#endif
}
}
else {
WOLFSSL_MSG("connect state: "
"Not advanced, more fragments to send");
}
}
else {
ssl->error = ret;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls)
ssl->dtls13SendingAckOrRtx = 0;
#endif /* WOLFSSL_DTLS13 */
}
ret = RetrySendAlert(ssl);
if (ret != 0) {
ssl->error = ret;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
switch (ssl->options.connectState) {
case CONNECT_BEGIN :
/* always send client hello first */
if ( (ssl->error = SendClientHello(ssl)) != 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.connectState = CLIENT_HELLO_SENT;
WOLFSSL_MSG("connect state: CLIENT_HELLO_SENT");
FALL_THROUGH;
case CLIENT_HELLO_SENT :
neededState = ssl->options.resuming ? SERVER_FINISHED_COMPLETE :
SERVER_HELLODONE_COMPLETE;
#ifdef WOLFSSL_DTLS
/* In DTLS, when resuming, we can go straight to FINISHED,
* or do a cookie exchange and then skip to FINISHED, assume
* we need the cookie exchange first. */
if (IsDtlsNotSctpMode(ssl))
neededState = SERVER_HELLOVERIFYREQUEST_COMPLETE;
#endif
/* get response */
WOLFSSL_MSG("Server state up to needed state.");
while (ssl->options.serverState < neededState) {
WOLFSSL_MSG("Progressing server state...");
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3)
return wolfSSL_connect_TLSv13(ssl);
#endif
WOLFSSL_MSG("ProcessReply...");
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
/* if resumption failed, reset needed state */
else if (neededState == SERVER_FINISHED_COMPLETE) {
if (!ssl->options.resuming) {
#ifdef WOLFSSL_DTLS
if (IsDtlsNotSctpMode(ssl))
neededState = SERVER_HELLOVERIFYREQUEST_COMPLETE;
else
#endif
neededState = SERVER_HELLODONE_COMPLETE;
}
}
WOLFSSL_MSG("ProcessReply done.");
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls && IsAtLeastTLSv1_3(ssl->version)
&& ssl->dtls13Rtx.sendAcks == 1
&& ssl->options.seenUnifiedHdr) {
/* we aren't negotiated the version yet, so we aren't sure
* the other end can speak v1.3. On the other side we have
* received a unified records, assuming that the
* ServerHello got lost, we will send an empty ACK. In case
* the server is a DTLS with version less than 1.3, it
* should just ignore the message */
ssl->dtls13Rtx.sendAcks = 0;
if ((ssl->error = SendDtls13Ack(ssl)) < 0) {
if (ssl->error == WC_NO_ERR_TRACE(WANT_WRITE))
ssl->dtls13SendingAckOrRtx = 1;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* WOLFSSL_DTLS13 */
}
ssl->options.connectState = HELLO_AGAIN;
WOLFSSL_MSG("connect state: HELLO_AGAIN");
FALL_THROUGH;
case HELLO_AGAIN :
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3)
return wolfSSL_connect_TLSv13(ssl);
#endif
#ifdef WOLFSSL_DTLS
if (ssl->options.serverState ==
SERVER_HELLOVERIFYREQUEST_COMPLETE) {
if (IsDtlsNotSctpMode(ssl)) {
/* re-init hashes, exclude first hello and verify request */
if ((ssl->error = InitHandshakeHashes(ssl)) != 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
if ( (ssl->error = SendClientHello(ssl)) != 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
}
#endif
ssl->options.connectState = HELLO_AGAIN_REPLY;
WOLFSSL_MSG("connect state: HELLO_AGAIN_REPLY");
FALL_THROUGH;
case HELLO_AGAIN_REPLY :
#ifdef WOLFSSL_DTLS
if (IsDtlsNotSctpMode(ssl)) {
neededState = ssl->options.resuming ?
SERVER_FINISHED_COMPLETE : SERVER_HELLODONE_COMPLETE;
/* get response */
while (ssl->options.serverState < neededState) {
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
/* if resumption failed, reset needed state */
if (neededState == SERVER_FINISHED_COMPLETE) {
if (!ssl->options.resuming)
neededState = SERVER_HELLODONE_COMPLETE;
}
}
}
#endif
ssl->options.connectState = FIRST_REPLY_DONE;
WOLFSSL_MSG("connect state: FIRST_REPLY_DONE");
FALL_THROUGH;
case FIRST_REPLY_DONE :
if (ssl->options.certOnly)
return WOLFSSL_SUCCESS;
#if !defined(NO_CERTS) && !defined(WOLFSSL_NO_CLIENT_AUTH)
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3)
return wolfSSL_connect_TLSv13(ssl);
#endif
if (ssl->options.sendVerify) {
if ( (ssl->error = SendCertificate(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
WOLFSSL_MSG("sent: certificate");
}
#endif
ssl->options.connectState = FIRST_REPLY_FIRST;
WOLFSSL_MSG("connect state: FIRST_REPLY_FIRST");
FALL_THROUGH;
case FIRST_REPLY_FIRST :
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3)
return wolfSSL_connect_TLSv13(ssl);
#endif
if (!ssl->options.resuming) {
if ( (ssl->error = SendClientKeyExchange(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
#ifdef WOLFSSL_EXTRA_ALERTS
if (ssl->error == WC_NO_ERR_TRACE(NO_PEER_KEY) ||
ssl->error == WC_NO_ERR_TRACE(PSK_KEY_ERROR)) {
SendAlert(ssl, alert_fatal, handshake_failure);
}
#endif
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
WOLFSSL_MSG("sent: client key exchange");
}
ssl->options.connectState = FIRST_REPLY_SECOND;
WOLFSSL_MSG("connect state: FIRST_REPLY_SECOND");
FALL_THROUGH;
#if !defined(WOLFSSL_NO_TLS12) || !defined(NO_OLD_TLS)
case FIRST_REPLY_SECOND :
/* CLIENT: Fail-safe for Server Authentication. */
if (!ssl->options.peerAuthGood) {
WOLFSSL_MSG("Server authentication did not happen");
ssl->error = NO_PEER_VERIFY;
return WOLFSSL_FATAL_ERROR;
}
#if !defined(NO_CERTS) && !defined(WOLFSSL_NO_CLIENT_AUTH)
if (ssl->options.sendVerify) {
if ( (ssl->error = SendCertificateVerify(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
WOLFSSL_MSG("sent: certificate verify");
}
#endif /* !NO_CERTS && !WOLFSSL_NO_CLIENT_AUTH */
ssl->options.connectState = FIRST_REPLY_THIRD;
WOLFSSL_MSG("connect state: FIRST_REPLY_THIRD");
FALL_THROUGH;
case FIRST_REPLY_THIRD :
if ( (ssl->error = SendChangeCipher(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
WOLFSSL_MSG("sent: change cipher spec");
ssl->options.connectState = FIRST_REPLY_FOURTH;
WOLFSSL_MSG("connect state: FIRST_REPLY_FOURTH");
FALL_THROUGH;
case FIRST_REPLY_FOURTH :
if ( (ssl->error = SendFinished(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
WOLFSSL_MSG("sent: finished");
ssl->options.connectState = FINISHED_DONE;
WOLFSSL_MSG("connect state: FINISHED_DONE");
FALL_THROUGH;
#ifdef WOLFSSL_DTLS13
case WAIT_FINISHED_ACK:
ssl->options.connectState = FINISHED_DONE;
FALL_THROUGH;
#endif /* WOLFSSL_DTLS13 */
case FINISHED_DONE :
/* get response */
while (ssl->options.serverState < SERVER_FINISHED_COMPLETE)
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.connectState = SECOND_REPLY_DONE;
WOLFSSL_MSG("connect state: SECOND_REPLY_DONE");
FALL_THROUGH;
case SECOND_REPLY_DONE:
#ifndef NO_HANDSHAKE_DONE_CB
if (ssl->hsDoneCb) {
int cbret = ssl->hsDoneCb(ssl, ssl->hsDoneCtx);
if (cbret < 0) {
ssl->error = cbret;
WOLFSSL_MSG("HandShake Done Cb don't continue error");
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* NO_HANDSHAKE_DONE_CB */
if (!ssl->options.dtls) {
if (!ssl->options.keepResources) {
FreeHandshakeResources(ssl);
}
}
#ifdef WOLFSSL_DTLS
else {
ssl->options.dtlsHsRetain = 1;
}
#endif /* WOLFSSL_DTLS */
#if defined(WOLFSSL_ASYNC_CRYPT) && defined(HAVE_SECURE_RENEGOTIATION)
/* This may be necessary in async so that we don't try to
* renegotiate again */
if (ssl->secure_renegotiation &&
ssl->secure_renegotiation->startScr) {
ssl->secure_renegotiation->startScr = 0;
}
#endif /* WOLFSSL_ASYNC_CRYPT && HAVE_SECURE_RENEGOTIATION */
#if defined(WOLFSSL_ASYNC_IO) && !defined(WOLFSSL_ASYNC_CRYPT)
/* Free the remaining async context if not using it for crypto */
FreeAsyncCtx(ssl, 1);
#endif
ssl->error = 0; /* clear the error */
WOLFSSL_LEAVE("wolfSSL_connect", WOLFSSL_SUCCESS);
return WOLFSSL_SUCCESS;
#endif /* !WOLFSSL_NO_TLS12 || !NO_OLD_TLS */
default:
WOLFSSL_MSG("Unknown connect state ERROR");
return WOLFSSL_FATAL_ERROR; /* unknown connect state */
}
#endif /* !WOLFSSL_NO_TLS12 || !NO_OLD_TLS || !WOLFSSL_TLS13 */
}
#endif /* !NO_WOLFSSL_CLIENT && !NO_TLS */
/* end client only parts */
/* server only parts */
#if !defined(NO_WOLFSSL_SERVER) && !defined(NO_TLS)
#if defined(OPENSSL_EXTRA) && !defined(NO_OLD_TLS)
WOLFSSL_METHOD* wolfSSLv2_server_method(void)
{
WOLFSSL_STUB("wolfSSLv2_server_method");
return 0;
}
#endif
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
WOLFSSL_METHOD* wolfSSLv3_server_method(void)
{
return wolfSSLv3_server_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv3_server_method_ex(void* heap)
{
WOLFSSL_METHOD* method =
(WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
heap, DYNAMIC_TYPE_METHOD);
(void)heap;
WOLFSSL_ENTER("wolfSSLv3_server_method_ex");
if (method) {
InitSSL_Method(method, MakeSSLv3());
method->side = WOLFSSL_SERVER_END;
}
return method;
}
#endif /* WOLFSSL_ALLOW_SSLV3 && !NO_OLD_TLS */
WOLFSSL_METHOD* wolfSSLv23_server_method(void)
{
return wolfSSLv23_server_method_ex(NULL);
}
WOLFSSL_METHOD* wolfSSLv23_server_method_ex(void* heap)
{
WOLFSSL_METHOD* method =
(WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
heap, DYNAMIC_TYPE_METHOD);
(void)heap;
WOLFSSL_ENTER("wolfSSLv23_server_method_ex");
if (method) {
#if !defined(NO_SHA256) || defined(WOLFSSL_SHA384) || \
defined(WOLFSSL_SHA512)
#ifdef WOLFSSL_TLS13
InitSSL_Method(method, MakeTLSv1_3());
#elif !defined(WOLFSSL_NO_TLS12)
InitSSL_Method(method, MakeTLSv1_2());
#elif !defined(NO_OLD_TLS)
InitSSL_Method(method, MakeTLSv1_1());
#endif
#else
#ifndef NO_OLD_TLS
InitSSL_Method(method, MakeTLSv1_1());
#else
#error Must have SHA256, SHA384 or SHA512 enabled for TLS 1.2
#endif
#endif
#if !defined(NO_OLD_TLS) || defined(WOLFSSL_TLS13)
method->downgrade = 1;
#endif
method->side = WOLFSSL_SERVER_END;
}
return method;
}
WOLFSSL_ABI
int wolfSSL_accept(WOLFSSL* ssl)
{
#if !(defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && \
defined(WOLFSSL_TLS13))
word16 havePSK = 0;
word16 haveAnon = 0;
word16 haveMcast = 0;
#endif
int ret = 0;
(void)ret;
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE)
if (ssl->options.side == WOLFSSL_NEITHER_END) {
WOLFSSL_MSG("Setting WOLFSSL_SSL to be server side");
ssl->error = InitSSL_Side(ssl, WOLFSSL_SERVER_END);
if (ssl->error != WOLFSSL_SUCCESS) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->error = 0; /* expected to be zero here */
}
#endif /* OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE */
#if defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && defined(WOLFSSL_TLS13)
return wolfSSL_accept_TLSv13(ssl);
#else
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3)
return wolfSSL_accept_TLSv13(ssl);
#endif
WOLFSSL_ENTER("wolfSSL_accept");
/* make sure this wolfSSL object has arrays and rng setup. Protects
* case where the WOLFSSL object is reused via wolfSSL_clear() */
if ((ret = ReinitSSL(ssl, ssl->ctx, 0)) != 0) {
return ret;
}
#ifdef WOLFSSL_WOLFSENTRY_HOOKS
if ((ssl->AcceptFilter != NULL) &&
((ssl->options.acceptState == ACCEPT_BEGIN)
#ifdef HAVE_SECURE_RENEGOTIATION
|| (ssl->options.acceptState == ACCEPT_BEGIN_RENEG)
#endif
))
{
wolfSSL_netfilter_decision_t res;
if ((ssl->AcceptFilter(ssl, ssl->AcceptFilter_arg, &res) ==
WOLFSSL_SUCCESS) &&
(res == WOLFSSL_NETFILTER_REJECT)) {
ssl->error = SOCKET_FILTERED_E;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* WOLFSSL_WOLFSENTRY_HOOKS */
#ifdef HAVE_ERRNO_H
errno = 0;
#endif
#ifndef NO_PSK
havePSK = ssl->options.havePSK;
#endif
(void)havePSK;
#ifdef HAVE_ANON
haveAnon = ssl->options.useAnon;
#endif
(void)haveAnon;
#ifdef WOLFSSL_MULTICAST
haveMcast = ssl->options.haveMcast;
#endif
(void)haveMcast;
if (ssl->options.side != WOLFSSL_SERVER_END) {
ssl->error = SIDE_ERROR;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#ifndef NO_CERTS
/* in case used set_accept_state after init */
if (!havePSK && !haveAnon && !haveMcast) {
#ifdef WOLFSSL_CERT_SETUP_CB
if (ssl->ctx->certSetupCb != NULL) {
WOLFSSL_MSG("CertSetupCb set. server cert and "
"key not checked");
}
else
#endif
{
if (!ssl->buffers.certificate ||
!ssl->buffers.certificate->buffer) {
WOLFSSL_MSG("accept error: server cert required");
ssl->error = NO_PRIVATE_KEY;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
if (!ssl->buffers.key || !ssl->buffers.key->buffer) {
/* allow no private key if using existing key */
#ifdef WOLF_PRIVATE_KEY_ID
if (ssl->devId != INVALID_DEVID
#ifdef HAVE_PK_CALLBACKS
|| wolfSSL_CTX_IsPrivatePkSet(ssl->ctx)
#endif
) {
WOLFSSL_MSG("Allowing no server private key "
"(external)");
}
else
#endif
{
WOLFSSL_MSG("accept error: server key required");
ssl->error = NO_PRIVATE_KEY;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
}
}
#endif
#ifdef WOLFSSL_DTLS
if (ssl->version.major == DTLS_MAJOR) {
ssl->options.dtls = 1;
ssl->options.tls = 1;
ssl->options.tls1_1 = 1;
if (!IsDtlsNotSctpMode(ssl) || IsSCR(ssl))
ssl->options.dtlsStateful = 1;
}
#endif
if (ssl->buffers.outputBuffer.length > 0
#ifdef WOLFSSL_ASYNC_CRYPT
/* do not send buffered or advance state if last error was an
async pending operation */
&& ssl->error != WC_NO_ERR_TRACE(WC_PENDING_E)
#endif
) {
ret = SendBuffered(ssl);
if (ret == 0) {
/* fragOffset is non-zero when sending fragments. On the last
* fragment, fragOffset is zero again, and the state can be
* advanced. */
if (ssl->fragOffset == 0 && !ssl->options.buildingMsg) {
if (ssl->options.acceptState == ACCEPT_FIRST_REPLY_DONE ||
ssl->options.acceptState == SERVER_HELLO_SENT ||
ssl->options.acceptState == CERT_SENT ||
ssl->options.acceptState == CERT_STATUS_SENT ||
ssl->options.acceptState == KEY_EXCHANGE_SENT ||
ssl->options.acceptState == CERT_REQ_SENT ||
ssl->options.acceptState == ACCEPT_SECOND_REPLY_DONE ||
ssl->options.acceptState == TICKET_SENT ||
ssl->options.acceptState == CHANGE_CIPHER_SENT) {
ssl->options.acceptState++;
WOLFSSL_MSG("accept state: Advanced from last "
"buffered fragment send");
#ifdef WOLFSSL_ASYNC_IO
/* Cleanup async */
FreeAsyncCtx(ssl, 0);
#endif
}
}
else {
WOLFSSL_MSG("accept state: "
"Not advanced, more fragments to send");
}
}
else {
ssl->error = ret;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_DTLS13
if (ssl->options.dtls)
ssl->dtls13SendingAckOrRtx = 0;
#endif /* WOLFSSL_DTLS13 */
}
ret = RetrySendAlert(ssl);
if (ret != 0) {
ssl->error = ret;
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
switch (ssl->options.acceptState) {
case ACCEPT_BEGIN :
#ifdef HAVE_SECURE_RENEGOTIATION
case ACCEPT_BEGIN_RENEG:
#endif
/* get response */
while (ssl->options.clientState < CLIENT_HELLO_COMPLETE)
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_TLS13
ssl->options.acceptState = ACCEPT_CLIENT_HELLO_DONE;
WOLFSSL_MSG("accept state ACCEPT_CLIENT_HELLO_DONE");
FALL_THROUGH;
case ACCEPT_CLIENT_HELLO_DONE :
if (ssl->options.tls1_3) {
return wolfSSL_accept_TLSv13(ssl);
}
#endif
ssl->options.acceptState = ACCEPT_FIRST_REPLY_DONE;
WOLFSSL_MSG("accept state ACCEPT_FIRST_REPLY_DONE");
FALL_THROUGH;
case ACCEPT_FIRST_REPLY_DONE :
if (ssl->options.returnOnGoodCh) {
/* Higher level in stack wants us to return. Simulate a
* WANT_WRITE to accomplish this. */
ssl->error = WANT_WRITE;
return WOLFSSL_FATAL_ERROR;
}
if ( (ssl->error = SendServerHello(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.acceptState = SERVER_HELLO_SENT;
WOLFSSL_MSG("accept state SERVER_HELLO_SENT");
FALL_THROUGH;
case SERVER_HELLO_SENT :
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3) {
return wolfSSL_accept_TLSv13(ssl);
}
#endif
#ifndef NO_CERTS
if (!ssl->options.resuming)
if ( (ssl->error = SendCertificate(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#endif
ssl->options.acceptState = CERT_SENT;
WOLFSSL_MSG("accept state CERT_SENT");
FALL_THROUGH;
case CERT_SENT :
#ifndef NO_CERTS
if (!ssl->options.resuming)
if ( (ssl->error = SendCertificateStatus(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
#endif
ssl->options.acceptState = CERT_STATUS_SENT;
WOLFSSL_MSG("accept state CERT_STATUS_SENT");
FALL_THROUGH;
case CERT_STATUS_SENT :
#ifdef WOLFSSL_TLS13
if (ssl->options.tls1_3) {
return wolfSSL_accept_TLSv13(ssl);
}
#endif
if (!ssl->options.resuming)
if ( (ssl->error = SendServerKeyExchange(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.acceptState = KEY_EXCHANGE_SENT;
WOLFSSL_MSG("accept state KEY_EXCHANGE_SENT");
FALL_THROUGH;
case KEY_EXCHANGE_SENT :
#ifndef NO_CERTS
if (!ssl->options.resuming) {
if (ssl->options.verifyPeer) {
if ( (ssl->error = SendCertificateRequest(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
else {
/* SERVER: Peer auth good if not verifying client. */
ssl->options.peerAuthGood = 1;
}
}
#endif
ssl->options.acceptState = CERT_REQ_SENT;
WOLFSSL_MSG("accept state CERT_REQ_SENT");
FALL_THROUGH;
case CERT_REQ_SENT :
if (!ssl->options.resuming)
if ( (ssl->error = SendServerHelloDone(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.acceptState = SERVER_HELLO_DONE;
WOLFSSL_MSG("accept state SERVER_HELLO_DONE");
FALL_THROUGH;
case SERVER_HELLO_DONE :
if (!ssl->options.resuming) {
while (ssl->options.clientState < CLIENT_FINISHED_COMPLETE)
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
ssl->options.acceptState = ACCEPT_SECOND_REPLY_DONE;
WOLFSSL_MSG("accept state ACCEPT_SECOND_REPLY_DONE");
FALL_THROUGH;
case ACCEPT_SECOND_REPLY_DONE :
#ifndef NO_CERTS
/* SERVER: When not resuming and verifying peer but no certificate
* received and not failing when not received then peer auth good.
*/
if (!ssl->options.resuming && ssl->options.verifyPeer &&
!ssl->options.havePeerCert && !ssl->options.failNoCert) {
ssl->options.peerAuthGood = 1;
}
#endif /* !NO_CERTS */
#ifdef WOLFSSL_NO_CLIENT_AUTH
if (!ssl->options.resuming) {
ssl->options.peerAuthGood = 1;
}
#endif
#ifdef HAVE_SESSION_TICKET
if (ssl->options.createTicket && !ssl->options.noTicketTls12) {
if ( (ssl->error = SendTicket(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_MSG("Thought we need ticket but failed");
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* HAVE_SESSION_TICKET */
ssl->options.acceptState = TICKET_SENT;
WOLFSSL_MSG("accept state TICKET_SENT");
FALL_THROUGH;
case TICKET_SENT:
/* SERVER: Fail-safe for CLient Authentication. */
if (!ssl->options.peerAuthGood) {
WOLFSSL_MSG("Client authentication did not happen");
return WOLFSSL_FATAL_ERROR;
}
if ( (ssl->error = SendChangeCipher(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.acceptState = CHANGE_CIPHER_SENT;
WOLFSSL_MSG("accept state CHANGE_CIPHER_SENT");
FALL_THROUGH;
case CHANGE_CIPHER_SENT :
if ( (ssl->error = SendFinished(ssl)) != 0) {
wolfssl_local_MaybeCheckAlertOnErr(ssl, ssl->error);
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
ssl->options.acceptState = ACCEPT_FINISHED_DONE;
WOLFSSL_MSG("accept state ACCEPT_FINISHED_DONE");
FALL_THROUGH;
case ACCEPT_FINISHED_DONE :
if (ssl->options.resuming) {
while (ssl->options.clientState < CLIENT_FINISHED_COMPLETE) {
if ( (ssl->error = ProcessReply(ssl)) < 0) {
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
}
ssl->options.acceptState = ACCEPT_THIRD_REPLY_DONE;
WOLFSSL_MSG("accept state ACCEPT_THIRD_REPLY_DONE");
FALL_THROUGH;
case ACCEPT_THIRD_REPLY_DONE :
#ifndef NO_HANDSHAKE_DONE_CB
if (ssl->hsDoneCb) {
int cbret = ssl->hsDoneCb(ssl, ssl->hsDoneCtx);
if (cbret < 0) {
ssl->error = cbret;
WOLFSSL_MSG("HandShake Done Cb don't continue error");
return WOLFSSL_FATAL_ERROR;
}
}
#endif /* NO_HANDSHAKE_DONE_CB */
if (!ssl->options.dtls) {
if (!ssl->options.keepResources) {
FreeHandshakeResources(ssl);
}
}
#ifdef WOLFSSL_DTLS
else {
ssl->options.dtlsHsRetain = 1;
}
#endif /* WOLFSSL_DTLS */
#if defined(WOLFSSL_ASYNC_CRYPT) && defined(HAVE_SECURE_RENEGOTIATION)
/* This may be necessary in async so that we don't try to
* renegotiate again */
if (ssl->secure_renegotiation &&
ssl->secure_renegotiation->startScr) {
ssl->secure_renegotiation->startScr = 0;
}
#endif /* WOLFSSL_ASYNC_CRYPT && HAVE_SECURE_RENEGOTIATION */
#if defined(WOLFSSL_ASYNC_IO) && !defined(WOLFSSL_ASYNC_CRYPT)
/* Free the remaining async context if not using it for crypto */
FreeAsyncCtx(ssl, 1);
#endif
#if defined(WOLFSSL_SESSION_EXPORT) && defined(WOLFSSL_DTLS)
if (ssl->dtls_export) {
if ((ssl->error = wolfSSL_send_session(ssl)) != 0) {
WOLFSSL_MSG("Export DTLS session error");
WOLFSSL_ERROR(ssl->error);
return WOLFSSL_FATAL_ERROR;
}
}
#endif
ssl->error = 0; /* clear the error */
WOLFSSL_LEAVE("wolfSSL_accept", WOLFSSL_SUCCESS);
return WOLFSSL_SUCCESS;
default:
WOLFSSL_MSG("Unknown accept state ERROR");
return WOLFSSL_FATAL_ERROR;
}
#endif /* !WOLFSSL_NO_TLS12 */
}
#endif /* !NO_WOLFSSL_SERVER && !NO_TLS */
/* end server only parts */
#if defined(WOLFSSL_DTLS) && !defined(NO_WOLFSSL_SERVER)
struct chGoodDisableReadCbCtx {
ClientHelloGoodCb userCb;
void* userCtx;
};
static int chGoodDisableReadCB(WOLFSSL* ssl, void* ctx)
{
struct chGoodDisableReadCbCtx* cb = (struct chGoodDisableReadCbCtx*)ctx;
int ret = 0;
if (cb->userCb != NULL)
ret = cb->userCb(ssl, cb->userCtx);
if (ret >= 0)
wolfSSL_SSLDisableRead(ssl);
return ret;
}
/**
* Statelessly listen for a connection
* @param ssl The ssl object to use for listening to connections
* @return WOLFSSL_SUCCESS - ClientHello containing a valid cookie was received
* The connection can be continued with wolfSSL_accept
* WOLFSSL_FAILURE - The I/O layer returned WANT_READ. This is either
* because there is no data to read and we are using
* non-blocking sockets or we sent a cookie request
* and we are waiting for a reply. The user should
* call wolfDTLS_accept_stateless again after data
* becomes available in the I/O layer.
* WOLFSSL_FATAL_ERROR - A fatal error occurred. The ssl object should
* be free'd and allocated again to continue.
*/
int wolfDTLS_accept_stateless(WOLFSSL* ssl)
{
byte disableRead;
int ret = WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR);
struct chGoodDisableReadCbCtx cb;
WOLFSSL_ENTER("wolfDTLS_SetChGoodCb");
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
/* Save this to restore it later */
disableRead = (byte)ssl->options.disableRead;
cb.userCb = ssl->chGoodCb;
cb.userCtx = ssl->chGoodCtx;
/* Register our own callback so that we can disable reading */
if (wolfDTLS_SetChGoodCb(ssl, chGoodDisableReadCB, &cb) != WOLFSSL_SUCCESS)
return WOLFSSL_FATAL_ERROR;
ssl->options.returnOnGoodCh = 1;
ret = wolfSSL_accept(ssl);
ssl->options.returnOnGoodCh = 0;
/* restore user options */
ssl->options.disableRead = disableRead;
(void)wolfDTLS_SetChGoodCb(ssl, cb.userCb, cb.userCtx);
if (ret == WOLFSSL_SUCCESS) {
WOLFSSL_MSG("should not happen. maybe the user called "
"wolfDTLS_accept_stateless instead of wolfSSL_accept");
}
else if (ssl->error == WC_NO_ERR_TRACE(WANT_READ) ||
ssl->error == WC_NO_ERR_TRACE(WANT_WRITE)) {
ssl->error = 0;
if (ssl->options.dtlsStateful)
ret = WOLFSSL_SUCCESS;
else
ret = WOLFSSL_FAILURE;
}
else {
ret = WOLFSSL_FATAL_ERROR;
}
return ret;
}
/* WC_NO_INLINE: wolfDTLS_accept_stateless passes the address of a stack-local
* context here; the restore call before return clears it again. Preventing
* inlining hides that cross-frame assignment from GCC's -Wdangling-pointer
* analysis, which otherwise flags a false positive on GCC 14+. */
WC_NO_INLINE
int wolfDTLS_SetChGoodCb(WOLFSSL* ssl, ClientHelloGoodCb cb, void* user_ctx)
{
WOLFSSL_ENTER("wolfDTLS_SetChGoodCb");
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->chGoodCb = cb;
ssl->chGoodCtx = user_ctx;
return WOLFSSL_SUCCESS;
}
#endif
#ifndef NO_HANDSHAKE_DONE_CB
int wolfSSL_SetHsDoneCb(WOLFSSL* ssl, HandShakeDoneCb cb, void* user_ctx)
{
WOLFSSL_ENTER("wolfSSL_SetHsDoneCb");
if (ssl == NULL)
return BAD_FUNC_ARG;
ssl->hsDoneCb = cb;
ssl->hsDoneCtx = user_ctx;
return WOLFSSL_SUCCESS;
}
#endif /* NO_HANDSHAKE_DONE_CB */
WOLFSSL_ABI
int wolfSSL_Cleanup(void)
{
int ret = WOLFSSL_SUCCESS; /* Only the first error will be returned */
int release = 0;
#if !defined(NO_SESSION_CACHE)
int i;
int j;
#endif
WOLFSSL_ENTER("wolfSSL_Cleanup");
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (inits_count_mutex_valid == 1) {
#endif
if (wc_LockMutex(&inits_count_mutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex count");
return BAD_MUTEX_E;
}
#ifndef WOLFSSL_MUTEX_INITIALIZER
}
#endif
if (initRefCount > 0) {
initRefCount = initRefCount - 1;
if (initRefCount == 0)
release = 1;
}
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (inits_count_mutex_valid == 1) {
#endif
wc_UnLockMutex(&inits_count_mutex);
#ifndef WOLFSSL_MUTEX_INITIALIZER
}
#endif
if (!release)
return ret;
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
wolfSSL_crypto_policy_disable();
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
#ifdef OPENSSL_EXTRA
wolfSSL_BN_free_one();
#endif
#ifndef NO_SESSION_CACHE
#ifdef ENABLE_SESSION_CACHE_ROW_LOCK
for (i = 0; i < SESSION_ROWS; ++i) {
if ((SessionCache[i].lock_valid == 1) &&
(wc_FreeRwLock(&SessionCache[i].row_lock) != 0)) {
if (ret == WOLFSSL_SUCCESS)
ret = BAD_MUTEX_E;
}
SessionCache[i].lock_valid = 0;
}
#else
if ((session_lock_valid == 1) && (wc_FreeRwLock(&session_lock) != 0)) {
if (ret == WOLFSSL_SUCCESS)
ret = BAD_MUTEX_E;
}
session_lock_valid = 0;
#endif
for (i = 0; i < SESSION_ROWS; i++) {
for (j = 0; j < SESSIONS_PER_ROW; j++) {
#ifdef SESSION_CACHE_DYNAMIC_MEM
if (SessionCache[i].Sessions[j]) {
EvictSessionFromCache(SessionCache[i].Sessions[j]);
XFREE(SessionCache[i].Sessions[j], SessionCache[i].heap,
DYNAMIC_TYPE_SESSION);
SessionCache[i].Sessions[j] = NULL;
}
#else
EvictSessionFromCache(&SessionCache[i].Sessions[j]);
#endif
}
}
#ifndef NO_CLIENT_CACHE
#ifndef WOLFSSL_MUTEX_INITIALIZER
if ((clisession_mutex_valid == 1) &&
(wc_FreeMutex(&clisession_mutex) != 0)) {
if (ret == WOLFSSL_SUCCESS)
ret = BAD_MUTEX_E;
}
clisession_mutex_valid = 0;
#endif
#endif
#endif /* !NO_SESSION_CACHE */
#if !defined(WOLFSSL_MUTEX_INITIALIZER) && \
!WOLFSSL_CLEANUP_THREADSAFE_BY_ATOMIC_OPS
if ((inits_count_mutex_valid == 1) &&
(wc_FreeMutex(&inits_count_mutex) != 0)) {
if (ret == WOLFSSL_SUCCESS)
ret = BAD_MUTEX_E;
}
inits_count_mutex_valid = 0;
#endif
#ifdef OPENSSL_EXTRA
wolfSSL_RAND_Cleanup();
#endif
if (wolfCrypt_Cleanup() != 0) {
WOLFSSL_MSG("Error with wolfCrypt_Cleanup call");
if (ret == WOLFSSL_SUCCESS)
ret = WC_CLEANUP_E;
}
#if FIPS_VERSION_GE(5,1)
if (wolfCrypt_SetPrivateKeyReadEnable_fips(0, WC_KEYTYPE_ALL) < 0) {
if (ret == WOLFSSL_SUCCESS)
ret = WC_CLEANUP_E;
}
#endif
#ifdef HAVE_GLOBAL_RNG
#ifndef WOLFSSL_MUTEX_INITIALIZER
if ((globalRNGMutex_valid == 1) && (wc_FreeMutex(&globalRNGMutex) != 0)) {
if (ret == WOLFSSL_SUCCESS)
ret = BAD_MUTEX_E;
}
globalRNGMutex_valid = 0;
#endif /* !WOLFSSL_MUTEX_INITIALIZER */
#if defined(OPENSSL_EXTRA) && defined(HAVE_HASHDRBG)
wolfSSL_FIPS_drbg_free(gDrbgDefCtx);
gDrbgDefCtx = NULL;
#endif
#endif
#ifdef HAVE_EX_DATA_CRYPTO
crypto_ex_cb_free(crypto_ex_cb_ctx_session);
crypto_ex_cb_ctx_session = NULL;
#endif
#ifdef WOLFSSL_MEM_FAIL_COUNT
wc_MemFailCount_Free();
#endif
return ret;
}
/* Returns 1 if name is a syntactically valid DNS FQDN per RFC 952/1123.
*
* Rules enforced:
* - Total effective length (excluding optional trailing dot) in [1, 253]
* - Each label is 1-63 octets of [a-zA-Z0-9-], with _ allowed in all but
* the last label.
* - No label starts or ends with '-'
* - At least two labels (single-label names are not "fully qualified")
* - Final label (TLD) contains at least one letter (rejects all-numeric
* strings that could be confused with IPv4 literals, and matches the
* ICANN constraint that TLDs are alphabetic)
* - Optional trailing dot is accepted (absolute FQDN form)
* - Internationalized names are valid in their ACE/punycode (xn--) form
*/
int wolfssl_local_IsValidFQDN(const char* name, word32 nameSz)
{
word32 i;
int labelLen = 0;
int labelCount = 0;
int curLabelHasAlpha = 0;
int curLabelHasUnderscore = 0;
if (name == NULL || nameSz == 0)
return 0;
/* Strip a single optional trailing dot before measuring. "example.com."
* is the absolute form of the same FQDN.
*/
if (name[nameSz - 1] == '.')
--nameSz;
if (nameSz < 1 || nameSz > 253)
return 0;
for (i = 0; i < nameSz; i++) {
byte c = (byte)name[i];
if (c == '.') {
if (labelLen == 0 || name[i - 1] == '-')
return 0;
++labelCount;
labelLen = 0;
curLabelHasAlpha = 0;
curLabelHasUnderscore = 0;
continue;
}
if (++labelLen > 63)
return 0;
if (c == '-') {
if (labelLen == 1)
return 0;
}
else if (((c | 0x20) >= 'a') && ((c | 0x20) <= 'z')) {
curLabelHasAlpha = 1;
}
else if (c == '_') {
curLabelHasUnderscore = 1;
}
else if ((c < '0') || (c > '9')) {
return 0;
}
}
/* Final label (no trailing dot in the effective range to close it) */
if ((labelLen == 0) || (name[nameSz - 1] == '-') || curLabelHasUnderscore)
return 0;
++labelCount;
return ((labelCount > 1) && curLabelHasAlpha);
}
/* call before SSL_connect, if verifying will add name check to
date check and signature check */
WOLFSSL_ABI
int wolfSSL_check_domain_name(WOLFSSL* ssl, const char* dn)
{
size_t dn_len;
WOLFSSL_ENTER("wolfSSL_check_domain_name");
if (ssl == NULL || dn == NULL) {
WOLFSSL_MSG("Bad function argument: NULL");
return WOLFSSL_FAILURE;
}
dn_len = XSTRLEN(dn);
if ((! wolfssl_local_IsValidFQDN(dn, (word32)dn_len)) &&
(XSTRCMP(dn, "localhost") != 0))
{
WOLFSSL_MSG("Bad function argument: fails wolfssl_local_IsValidFQDN");
return WOLFSSL_FAILURE;
}
if (ssl->buffers.domainName.buffer)
XFREE(ssl->buffers.domainName.buffer, ssl->heap, DYNAMIC_TYPE_DOMAIN);
ssl->buffers.domainName.length = (word32)XSTRLEN(dn);
ssl->buffers.domainName.buffer = (byte*)XMALLOC(
ssl->buffers.domainName.length + 1, ssl->heap, DYNAMIC_TYPE_DOMAIN);
if (ssl->buffers.domainName.buffer) {
unsigned char* domainName = ssl->buffers.domainName.buffer;
XMEMCPY(domainName, dn, ssl->buffers.domainName.length);
domainName[ssl->buffers.domainName.length] = '\0';
return WOLFSSL_SUCCESS;
}
else {
ssl->error = MEMORY_ERROR;
return WOLFSSL_FAILURE;
}
}
/* call before SSL_connect, if verifying will add IP SAN check to
date check and signature check */
WOLFSSL_ABI
int wolfSSL_check_ip_address(WOLFSSL* ssl, const char* ipaddr)
{
WOLFSSL_ENTER("wolfSSL_check_ip_address");
if (ssl == NULL || ipaddr == NULL) {
WOLFSSL_MSG("Bad function argument: NULL");
return WOLFSSL_FAILURE;
}
if (ssl->buffers.ipasc.buffer != NULL) {
XFREE(ssl->buffers.ipasc.buffer, ssl->heap, DYNAMIC_TYPE_DOMAIN);
ssl->buffers.ipasc.buffer = NULL;
ssl->buffers.ipasc.length = 0;
}
ssl->buffers.ipasc.length = (word32)XSTRLEN(ipaddr);
ssl->buffers.ipasc.buffer = (byte*)XMALLOC(ssl->buffers.ipasc.length + 1,
ssl->heap, DYNAMIC_TYPE_DOMAIN);
if (ssl->buffers.ipasc.buffer == NULL) {
ssl->error = MEMORY_ERROR;
return WOLFSSL_FAILURE;
}
XMEMCPY(ssl->buffers.ipasc.buffer, ipaddr, ssl->buffers.ipasc.length);
ssl->buffers.ipasc.buffer[ssl->buffers.ipasc.length] = '\0';
#ifdef OPENSSL_EXTRA
if (ssl->param == NULL) {
return WOLFSSL_FAILURE;
}
if (wolfSSL_X509_VERIFY_PARAM_set1_ip_asc(ssl->param, ipaddr) !=
WOLFSSL_SUCCESS) {
return WOLFSSL_FAILURE;
}
#endif
return WOLFSSL_SUCCESS;
}
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
const char *wolfSSL_get0_peername(WOLFSSL *ssl) {
if (ssl == NULL) {
return NULL;
}
if (ssl->buffers.domainName.buffer)
return (const char *)ssl->buffers.domainName.buffer;
else if (ssl->session && ssl->session->peer)
return ssl->session->peer->subjectCN;
#ifdef KEEP_PEER_CERT
else if (ssl->peerCert.subjectCN[0])
return ssl->peerCert.subjectCN;
#endif
else {
ssl->error = NO_PEER_CERT;
return NULL;
}
}
#endif /* SESSION_CERTS && OPENSSL_EXTRA */
/* turn on wolfSSL zlib compression
returns WOLFSSL_SUCCESS for success, else error (not built in)
*/
int wolfSSL_set_compression(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_set_compression");
(void)ssl;
#ifdef HAVE_LIBZ
ssl->options.usingCompression = 1;
return WOLFSSL_SUCCESS;
#else
return NOT_COMPILED_IN;
#endif
}
#ifndef USE_WINDOWS_API
#if !defined(NO_WRITEV) && !defined(NO_TLS)
/* simulate writev semantics, doesn't actually do block at a time though
because of SSL_write behavior and because front adds may be small */
int wolfSSL_writev(WOLFSSL* ssl, const struct iovec* iov, int iovcnt)
{
#ifdef WOLFSSL_SMALL_STACK
byte staticBuffer[1]; /* force heap usage */
#else
byte staticBuffer[FILE_BUFFER_SIZE];
#endif
byte* myBuffer = staticBuffer;
int dynamic = 0;
size_t sending = 0;
size_t idx = 0;
int i;
int ret;
WOLFSSL_ENTER("wolfSSL_writev");
for (i = 0; i < iovcnt; i++)
if (! WC_SAFE_SUM_UNSIGNED(size_t, sending, iov[i].iov_len,
sending))
return BUFFER_E;
if (sending > sizeof(staticBuffer)) {
myBuffer = (byte*)XMALLOC(sending, ssl->heap,
DYNAMIC_TYPE_WRITEV);
if (!myBuffer)
return MEMORY_ERROR;
dynamic = 1;
}
for (i = 0; i < iovcnt; i++) {
XMEMCPY(&myBuffer[idx], iov[i].iov_base, iov[i].iov_len);
idx += (int)iov[i].iov_len;
}
/* myBuffer may not be initialized fully, but the span up to the
* sending length will be.
*/
PRAGMA_GCC_DIAG_PUSH
PRAGMA_GCC("GCC diagnostic ignored \"-Wmaybe-uninitialized\"")
ret = wolfSSL_write_internal(ssl, myBuffer, sending);
PRAGMA_GCC_DIAG_POP
if (dynamic)
XFREE(myBuffer, ssl->heap, DYNAMIC_TYPE_WRITEV);
return ret;
}
#endif
#endif
#ifdef WOLFSSL_CALLBACKS
typedef struct itimerval Itimerval;
/* don't keep calling simple functions while setting up timer and signals
if no inlining these are the next best */
#define AddTimes(a, b, c) \
do { \
(c).tv_sec = (a).tv_sec + (b).tv_sec; \
(c).tv_usec = (a).tv_usec + (b).tv_usec;\
if ((c).tv_usec >= 1000000) { \
(c).tv_sec++; \
(c).tv_usec -= 1000000; \
} \
} while (0)
#define SubtractTimes(a, b, c) \
do { \
(c).tv_sec = (a).tv_sec - (b).tv_sec; \
(c).tv_usec = (a).tv_usec - (b).tv_usec;\
if ((c).tv_usec < 0) { \
(c).tv_sec--; \
(c).tv_usec += 1000000; \
} \
} while (0)
#define CmpTimes(a, b, cmp) \
(((a).tv_sec == (b).tv_sec) ? \
((a).tv_usec cmp (b).tv_usec) : \
((a).tv_sec cmp (b).tv_sec)) \
/* do nothing handler */
static void myHandler(int signo)
{
(void)signo;
return;
}
static int wolfSSL_ex_wrapper(WOLFSSL* ssl, HandShakeCallBack hsCb,
TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR);
int oldTimerOn = 0; /* was timer already on */
WOLFSSL_TIMEVAL startTime;
WOLFSSL_TIMEVAL endTime;
WOLFSSL_TIMEVAL totalTime;
Itimerval myTimeout;
Itimerval oldTimeout; /* if old timer adjust from total time to reset */
struct sigaction act, oact;
#define ERR_OUT(x) { ssl->hsInfoOn = 0; ssl->toInfoOn = 0; return x; }
if (hsCb) {
ssl->hsInfoOn = 1;
InitHandShakeInfo(&ssl->handShakeInfo, ssl);
}
if (toCb) {
ssl->toInfoOn = 1;
InitTimeoutInfo(&ssl->timeoutInfo);
if (gettimeofday(&startTime, 0) < 0)
ERR_OUT(GETTIME_ERROR);
/* use setitimer to simulate getitimer, init 0 myTimeout */
myTimeout.it_interval.tv_sec = 0;
myTimeout.it_interval.tv_usec = 0;
myTimeout.it_value.tv_sec = 0;
myTimeout.it_value.tv_usec = 0;
if (setitimer(ITIMER_REAL, &myTimeout, &oldTimeout) < 0)
ERR_OUT(SETITIMER_ERROR);
if (oldTimeout.it_value.tv_sec || oldTimeout.it_value.tv_usec) {
oldTimerOn = 1;
/* is old timer going to expire before ours */
if (CmpTimes(oldTimeout.it_value, timeout, <)) {
timeout.tv_sec = oldTimeout.it_value.tv_sec;
timeout.tv_usec = oldTimeout.it_value.tv_usec;
}
}
myTimeout.it_value.tv_sec = timeout.tv_sec;
myTimeout.it_value.tv_usec = timeout.tv_usec;
/* set up signal handler, don't restart socket send/recv */
act.sa_handler = myHandler;
sigemptyset(&act.sa_mask);
act.sa_flags = 0;
#ifdef SA_INTERRUPT
act.sa_flags |= SA_INTERRUPT;
#endif
if (sigaction(SIGALRM, &act, &oact) < 0)
ERR_OUT(SIGACT_ERROR);
if (setitimer(ITIMER_REAL, &myTimeout, 0) < 0)
ERR_OUT(SETITIMER_ERROR);
}
/* do main work */
#ifndef NO_WOLFSSL_CLIENT
if (ssl->options.side == WOLFSSL_CLIENT_END)
ret = wolfSSL_connect(ssl);
#endif
#ifndef NO_WOLFSSL_SERVER
if (ssl->options.side == WOLFSSL_SERVER_END)
ret = wolfSSL_accept(ssl);
#endif
/* do callbacks */
if (toCb) {
if (oldTimerOn) {
if (gettimeofday(&endTime, 0) < 0)
ERR_OUT(SYSLIB_FAILED_E);
SubtractTimes(endTime, startTime, totalTime);
/* adjust old timer for elapsed time */
if (CmpTimes(totalTime, oldTimeout.it_value, <))
SubtractTimes(oldTimeout.it_value, totalTime,
oldTimeout.it_value);
else {
/* reset value to interval, may be off */
oldTimeout.it_value.tv_sec = oldTimeout.it_interval.tv_sec;
oldTimeout.it_value.tv_usec =oldTimeout.it_interval.tv_usec;
}
/* keep iter the same whether there or not */
}
/* restore old handler */
if (sigaction(SIGALRM, &oact, 0) < 0)
ret = SIGACT_ERROR; /* more pressing error, stomp */
else
/* use old settings which may turn off (expired or not there) */
if (setitimer(ITIMER_REAL, &oldTimeout, 0) < 0)
ret = SETITIMER_ERROR;
/* if we had a timeout call callback */
if (ssl->timeoutInfo.timeoutName[0]) {
ssl->timeoutInfo.timeoutValue.tv_sec = timeout.tv_sec;
ssl->timeoutInfo.timeoutValue.tv_usec = timeout.tv_usec;
(toCb)(&ssl->timeoutInfo);
}
ssl->toInfoOn = 0;
}
/* clean up buffers allocated by AddPacketInfo */
FreeTimeoutInfo(&ssl->timeoutInfo, ssl->heap);
if (hsCb) {
FinishHandShakeInfo(&ssl->handShakeInfo);
(hsCb)(&ssl->handShakeInfo);
ssl->hsInfoOn = 0;
}
return ret;
}
#ifndef NO_WOLFSSL_CLIENT
int wolfSSL_connect_ex(WOLFSSL* ssl, HandShakeCallBack hsCb,
TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
{
WOLFSSL_ENTER("wolfSSL_connect_ex");
return wolfSSL_ex_wrapper(ssl, hsCb, toCb, timeout);
}
#endif
#ifndef NO_WOLFSSL_SERVER
int wolfSSL_accept_ex(WOLFSSL* ssl, HandShakeCallBack hsCb,
TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
{
WOLFSSL_ENTER("wolfSSL_accept_ex");
return wolfSSL_ex_wrapper(ssl, hsCb, toCb, timeout);
}
#endif
#endif /* WOLFSSL_CALLBACKS */
#ifndef NO_PSK
void wolfSSL_CTX_set_psk_client_callback(WOLFSSL_CTX* ctx,
wc_psk_client_callback cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_psk_client_callback");
if (ctx == NULL)
return;
ctx->havePSK = 1;
ctx->client_psk_cb = cb;
}
void wolfSSL_set_psk_client_callback(WOLFSSL* ssl,wc_psk_client_callback cb)
{
byte haveRSA = 1;
int keySz = 0;
WOLFSSL_ENTER("wolfSSL_set_psk_client_callback");
if (ssl == NULL)
return;
ssl->options.havePSK = 1;
ssl->options.client_psk_cb = cb;
#ifdef NO_RSA
haveRSA = 0;
#endif
#ifndef NO_CERTS
keySz = ssl->buffers.keySz;
#endif
if (AllocateSuites(ssl) != 0)
return;
InitSuites(ssl->suites, ssl->version, keySz, haveRSA, TRUE,
ssl->options.haveDH, ssl->options.haveECDSAsig,
ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
ssl->options.useAnon, TRUE, TRUE, TRUE, TRUE, ssl->options.side);
}
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_CERT_WITH_EXTERN_PSK)
int wolfSSL_CTX_set_cert_with_extern_psk(WOLFSSL_CTX* ctx, int state)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_cert_with_extern_psk");
if (ctx == NULL)
return WOLFSSL_FAILURE;
ctx->certWithExternPsk = (byte)(state != 0);
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_cert_with_extern_psk(WOLFSSL* ssl, int state)
{
WOLFSSL_ENTER("wolfSSL_set_cert_with_extern_psk");
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->options.certWithExternPsk = (word16)(state != 0);
return WOLFSSL_SUCCESS;
}
#endif
#ifdef OPENSSL_EXTRA
/**
* set call back function for psk session use
* @param ssl a pointer to WOLFSSL structure
* @param cb a function pointer to wc_psk_use_session_cb
* @return none
*/
void wolfSSL_set_psk_use_session_callback(WOLFSSL* ssl,
wc_psk_use_session_cb_func cb)
{
WOLFSSL_ENTER("wolfSSL_set_psk_use_session_callback");
if (ssl != NULL) {
ssl->options.havePSK = 1;
ssl->options.session_psk_cb = cb;
}
WOLFSSL_LEAVE("wolfSSL_set_psk_use_session_callback", WOLFSSL_SUCCESS);
}
#endif
void wolfSSL_CTX_set_psk_server_callback(WOLFSSL_CTX* ctx,
wc_psk_server_callback cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_psk_server_callback");
if (ctx == NULL)
return;
ctx->havePSK = 1;
ctx->server_psk_cb = cb;
}
void wolfSSL_set_psk_server_callback(WOLFSSL* ssl,wc_psk_server_callback cb)
{
byte haveRSA = 1;
int keySz = 0;
WOLFSSL_ENTER("wolfSSL_set_psk_server_callback");
if (ssl == NULL)
return;
ssl->options.havePSK = 1;
ssl->options.server_psk_cb = cb;
#ifdef NO_RSA
haveRSA = 0;
#endif
#ifndef NO_CERTS
keySz = ssl->buffers.keySz;
#endif
if (AllocateSuites(ssl) != 0)
return;
InitSuites(ssl->suites, ssl->version, keySz, haveRSA, TRUE,
ssl->options.haveDH, ssl->options.haveECDSAsig,
ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
ssl->options.useAnon, TRUE, TRUE, TRUE, TRUE, ssl->options.side);
}
const char* wolfSSL_get_psk_identity_hint(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_psk_identity_hint");
if (ssl == NULL || ssl->arrays == NULL)
return NULL;
return ssl->arrays->server_hint;
}
const char* wolfSSL_get_psk_identity(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_psk_identity");
if (ssl == NULL || ssl->arrays == NULL)
return NULL;
return ssl->arrays->client_identity;
}
int wolfSSL_CTX_use_psk_identity_hint(WOLFSSL_CTX* ctx, const char* hint)
{
WOLFSSL_ENTER("wolfSSL_CTX_use_psk_identity_hint");
if (hint == 0)
ctx->server_hint[0] = '\0';
else {
/* Qt does not call CTX_set_*_psk_callbacks where havePSK is set */
#ifdef WOLFSSL_QT
ctx->havePSK=1;
#endif
XSTRNCPY(ctx->server_hint, hint, MAX_PSK_ID_LEN);
ctx->server_hint[MAX_PSK_ID_LEN] = '\0'; /* null term */
}
return WOLFSSL_SUCCESS;
}
int wolfSSL_use_psk_identity_hint(WOLFSSL* ssl, const char* hint)
{
WOLFSSL_ENTER("wolfSSL_use_psk_identity_hint");
if (ssl == NULL || ssl->arrays == NULL)
return WOLFSSL_FAILURE;
if (hint == 0)
ssl->arrays->server_hint[0] = 0;
else {
XSTRNCPY(ssl->arrays->server_hint, hint,
sizeof(ssl->arrays->server_hint)-1);
ssl->arrays->server_hint[sizeof(ssl->arrays->server_hint)-1] = '\0';
}
return WOLFSSL_SUCCESS;
}
void* wolfSSL_get_psk_callback_ctx(WOLFSSL* ssl)
{
return ssl ? ssl->options.psk_ctx : NULL;
}
void* wolfSSL_CTX_get_psk_callback_ctx(WOLFSSL_CTX* ctx)
{
return ctx ? ctx->psk_ctx : NULL;
}
int wolfSSL_set_psk_callback_ctx(WOLFSSL* ssl, void* psk_ctx)
{
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->options.psk_ctx = psk_ctx;
return WOLFSSL_SUCCESS;
}
int wolfSSL_CTX_set_psk_callback_ctx(WOLFSSL_CTX* ctx, void* psk_ctx)
{
if (ctx == NULL)
return WOLFSSL_FAILURE;
ctx->psk_ctx = psk_ctx;
return WOLFSSL_SUCCESS;
}
#endif /* NO_PSK */
#ifdef HAVE_ANON
int wolfSSL_CTX_allow_anon_cipher(WOLFSSL_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_CTX_allow_anon_cipher");
if (ctx == NULL)
return WOLFSSL_FAILURE;
ctx->useAnon = 1;
return WOLFSSL_SUCCESS;
}
#endif /* HAVE_ANON */
#ifdef OPENSSL_EXTRA
int wolfSSL_add_all_algorithms(void)
{
WOLFSSL_ENTER("wolfSSL_add_all_algorithms");
if (initRefCount != 0 || wolfSSL_Init() == WOLFSSL_SUCCESS)
return WOLFSSL_SUCCESS;
else
return WOLFSSL_FATAL_ERROR;
}
int wolfSSL_OpenSSL_add_all_algorithms_noconf(void)
{
WOLFSSL_ENTER("wolfSSL_OpenSSL_add_all_algorithms_noconf");
if (wolfSSL_add_all_algorithms() ==
WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR))
{
return WOLFSSL_FATAL_ERROR;
}
return WOLFSSL_SUCCESS;
}
int wolfSSL_OpenSSL_add_all_algorithms_conf(void)
{
WOLFSSL_ENTER("wolfSSL_OpenSSL_add_all_algorithms_conf");
/* This function is currently the same as
wolfSSL_OpenSSL_add_all_algorithms_noconf since we do not employ
the use of a wolfssl.cnf type configuration file and is only used for
OpenSSL compatibility. */
if (wolfSSL_add_all_algorithms() ==
WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR))
{
return WOLFSSL_FATAL_ERROR;
}
return WOLFSSL_SUCCESS;
}
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL) || \
defined(WOLFSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
void wolfSSL_CTX_set_quiet_shutdown(WOLFSSL_CTX* ctx, int mode)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_quiet_shutdown");
if (mode)
ctx->quietShutdown = 1;
}
void wolfSSL_set_quiet_shutdown(WOLFSSL* ssl, int mode)
{
WOLFSSL_ENTER("wolfSSL_set_quiet_shutdown");
if (mode)
ssl->options.quietShutdown = 1;
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL ||
WOLFSSL_EXTRA || WOLFSSL_WPAS_SMALL */
#ifdef OPENSSL_EXTRA
#ifndef NO_BIO
static void ssl_set_bio(WOLFSSL* ssl, WOLFSSL_BIO* rd, WOLFSSL_BIO* wr, int flags)
{
WOLFSSL_ENTER("wolfSSL_set_bio");
if (ssl == NULL) {
WOLFSSL_MSG("Bad argument, ssl was NULL");
return;
}
/* free any existing WOLFSSL_BIOs in use but don't free those in
* a chain */
if ((flags & WOLFSSL_BIO_FLAG_READ) && (ssl->biord != NULL)) {
if ((flags & WOLFSSL_BIO_FLAG_WRITE) && (ssl->biord != ssl->biowr)) {
if (ssl->biowr != NULL && ssl->biowr->prev != NULL)
wolfSSL_BIO_free(ssl->biowr);
ssl->biowr = NULL;
}
if (ssl->biord->prev != NULL)
wolfSSL_BIO_free(ssl->biord);
ssl->biord = NULL;
}
else if ((flags & WOLFSSL_BIO_FLAG_WRITE) && (ssl->biowr != NULL)) {
if (ssl->biowr->prev != NULL)
wolfSSL_BIO_free(ssl->biowr);
ssl->biowr = NULL;
}
/* set flag obviously */
if (rd && !(rd->flags & WOLFSSL_BIO_FLAG_READ))
rd->flags |= WOLFSSL_BIO_FLAG_READ;
if (wr && !(wr->flags & WOLFSSL_BIO_FLAG_WRITE))
wr->flags |= WOLFSSL_BIO_FLAG_WRITE;
if (flags & WOLFSSL_BIO_FLAG_READ)
ssl->biord = rd;
if (flags & WOLFSSL_BIO_FLAG_WRITE)
ssl->biowr = wr;
/* set SSL to use BIO callbacks instead */
if ((flags & WOLFSSL_BIO_FLAG_READ) &&
(((ssl->cbioFlag & WOLFSSL_CBIO_RECV) == 0)))
{
ssl->CBIORecv = SslBioReceive;
}
if ((flags & WOLFSSL_BIO_FLAG_WRITE) &&
(((ssl->cbioFlag & WOLFSSL_CBIO_SEND) == 0)))
{
ssl->CBIOSend = SslBioSend;
}
/* User programs should always retry reading from these BIOs */
if (rd) {
/* User writes to rd */
wolfSSL_BIO_set_retry_write(rd);
}
if (wr) {
/* User reads from wr */
wolfSSL_BIO_set_retry_read(wr);
}
}
void wolfSSL_set_bio(WOLFSSL* ssl, WOLFSSL_BIO* rd, WOLFSSL_BIO* wr)
{
ssl_set_bio(ssl, rd, wr, WOLFSSL_BIO_FLAG_READ | WOLFSSL_BIO_FLAG_WRITE);
}
void wolfSSL_set_rbio(WOLFSSL* ssl, WOLFSSL_BIO* rd)
{
ssl_set_bio(ssl, rd, NULL, WOLFSSL_BIO_FLAG_READ);
}
void wolfSSL_set_wbio(WOLFSSL* ssl, WOLFSSL_BIO* wr)
{
ssl_set_bio(ssl, NULL, wr, WOLFSSL_BIO_FLAG_WRITE);
}
#endif /* !NO_BIO */
#endif /* OPENSSL_EXTRA */
#ifdef WOLFSSL_CERT_SETUP_CB
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* registers client cert callback, called during handshake if server
requests client auth but user has not loaded client cert/key */
void wolfSSL_CTX_set_client_cert_cb(WOLFSSL_CTX *ctx, client_cert_cb cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_client_cert_cb");
if (ctx != NULL) {
ctx->CBClientCert = cb;
}
}
#endif
void wolfSSL_CTX_set_cert_cb(WOLFSSL_CTX* ctx,
CertSetupCallback cb, void *arg)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_cert_cb");
if (ctx == NULL)
return;
ctx->certSetupCb = cb;
ctx->certSetupCbArg = arg;
}
int wolfSSL_get_client_suites_sigalgs(const WOLFSSL* ssl,
const byte** suites, word16* suiteSz,
const byte** hashSigAlgo, word16* hashSigAlgoSz)
{
WOLFSSL_ENTER("wolfSSL_get_client_suites_sigalgs");
if (suites != NULL)
*suites = NULL;
if (suiteSz != NULL)
*suiteSz = 0;
if (hashSigAlgo != NULL)
*hashSigAlgo = NULL;
if (hashSigAlgoSz != NULL)
*hashSigAlgoSz = 0;
if (ssl != NULL && ssl->clSuites != NULL) {
if (suites != NULL && suiteSz != NULL) {
*suites = ssl->clSuites->suites;
*suiteSz = ssl->clSuites->suiteSz;
}
if (hashSigAlgo != NULL && hashSigAlgoSz != NULL) {
*hashSigAlgo = ssl->clSuites->hashSigAlgo;
*hashSigAlgoSz = ssl->clSuites->hashSigAlgoSz;
}
return WOLFSSL_SUCCESS;
}
return WOLFSSL_FAILURE;
}
#ifndef NO_TLS
WOLFSSL_CIPHERSUITE_INFO wolfSSL_get_ciphersuite_info(byte first,
byte second)
{
WOLFSSL_CIPHERSUITE_INFO info;
info.rsaAuth = (byte)(CipherRequires(first, second, REQUIRES_RSA) ||
CipherRequires(first, second, REQUIRES_RSA_SIG));
info.eccAuth = (byte)(CipherRequires(first, second, REQUIRES_ECC) ||
/* Static ECC ciphers may require RSA for authentication */
(CipherRequires(first, second, REQUIRES_ECC_STATIC) &&
!CipherRequires(first, second, REQUIRES_RSA_SIG)));
info.eccStatic =
(byte)CipherRequires(first, second, REQUIRES_ECC_STATIC);
info.psk = (byte)CipherRequires(first, second, REQUIRES_PSK);
return info;
}
#endif
/**
* @param first First byte of the hash and signature algorithm
* @param second Second byte of the hash and signature algorithm
* @param hashAlgo The enum wc_HashType of the MAC algorithm
* @param sigAlgo The enum Key_Sum of the authentication algorithm
*/
int wolfSSL_get_sigalg_info(byte first, byte second,
int* hashAlgo, int* sigAlgo)
{
byte input[2];
byte hashType;
byte sigType;
if (hashAlgo == NULL || sigAlgo == NULL)
return BAD_FUNC_ARG;
input[0] = first;
input[1] = second;
DecodeSigAlg(input, &hashType, &sigType);
/* cast so that compiler reminds us of unimplemented values */
switch ((enum SignatureAlgorithm)sigType) {
case anonymous_sa_algo:
*sigAlgo = ANONk;
break;
case rsa_sa_algo:
*sigAlgo = RSAk;
break;
case dsa_sa_algo:
*sigAlgo = DSAk;
break;
case ecc_dsa_sa_algo:
case ecc_brainpool_sa_algo:
*sigAlgo = ECDSAk;
break;
case rsa_pss_sa_algo:
*sigAlgo = RSAPSSk;
break;
case ed25519_sa_algo:
*sigAlgo = ED25519k;
break;
case rsa_pss_pss_algo:
*sigAlgo = RSAPSSk;
break;
case ed448_sa_algo:
*sigAlgo = ED448k;
break;
case falcon_level1_sa_algo:
*sigAlgo = FALCON_LEVEL1k;
break;
case falcon_level5_sa_algo:
*sigAlgo = FALCON_LEVEL5k;
break;
case mldsa_44_sa_algo:
*sigAlgo = ML_DSA_44k;
break;
case mldsa_65_sa_algo:
*sigAlgo = ML_DSA_65k;
break;
case mldsa_87_sa_algo:
*sigAlgo = ML_DSA_87k;
break;
case sm2_sa_algo:
*sigAlgo = SM2k;
break;
case invalid_sa_algo:
case any_sa_algo:
default:
*hashAlgo = WC_HASH_TYPE_NONE;
*sigAlgo = 0;
return BAD_FUNC_ARG;
}
/* cast so that compiler reminds us of unimplemented values */
switch((enum wc_MACAlgorithm)hashType) {
case no_mac:
case rmd_mac: /* Don't have a RIPEMD type in wc_HashType */
*hashAlgo = WC_HASH_TYPE_NONE;
break;
case md5_mac:
*hashAlgo = WC_HASH_TYPE_MD5;
break;
case sha_mac:
*hashAlgo = WC_HASH_TYPE_SHA;
break;
case sha224_mac:
*hashAlgo = WC_HASH_TYPE_SHA224;
break;
case sha256_mac:
*hashAlgo = WC_HASH_TYPE_SHA256;
break;
case sha384_mac:
*hashAlgo = WC_HASH_TYPE_SHA384;
break;
case sha512_mac:
*hashAlgo = WC_HASH_TYPE_SHA512;
break;
case blake2b_mac:
*hashAlgo = WC_HASH_TYPE_BLAKE2B;
break;
case sm3_mac:
#ifdef WOLFSSL_SM3
*hashAlgo = WC_HASH_TYPE_SM3;
#else
*hashAlgo = WC_HASH_TYPE_NONE;
#endif
break;
default:
*hashAlgo = WC_HASH_TYPE_NONE;
*sigAlgo = 0;
return BAD_FUNC_ARG;
}
return 0;
}
/**
* Internal wrapper for calling certSetupCb
* @param ssl The SSL/TLS Object
* @return 0 on success
*/
int CertSetupCbWrapper(WOLFSSL* ssl)
{
int ret = 0;
if (ssl->ctx->certSetupCb != NULL) {
WOLFSSL_MSG("Calling user cert setup callback");
ret = ssl->ctx->certSetupCb(ssl, ssl->ctx->certSetupCbArg);
if (ret == 1) {
WOLFSSL_MSG("User cert callback returned success");
ret = 0;
}
else if (ret == 0) {
SendAlert(ssl, alert_fatal, internal_error);
ret = CLIENT_CERT_CB_ERROR;
}
else if (ret < 0) {
ret = WOLFSSL_ERROR_WANT_X509_LOOKUP;
}
else {
WOLFSSL_MSG("Unexpected user callback return");
ret = CLIENT_CERT_CB_ERROR;
}
}
return ret;
}
#endif /* WOLFSSL_CERT_SETUP_CB */
#ifdef OPENSSL_EXTRA
#if defined(WOLFCRYPT_HAVE_SRP) && !defined(NO_SHA256) \
&& !defined(WC_NO_RNG)
static const byte srp_N[] = {
0xEE, 0xAF, 0x0A, 0xB9, 0xAD, 0xB3, 0x8D, 0xD6, 0x9C, 0x33, 0xF8,
0x0A, 0xFA, 0x8F, 0xC5, 0xE8, 0x60, 0x72, 0x61, 0x87, 0x75, 0xFF,
0x3C, 0x0B, 0x9E, 0xA2, 0x31, 0x4C, 0x9C, 0x25, 0x65, 0x76, 0xD6,
0x74, 0xDF, 0x74, 0x96, 0xEA, 0x81, 0xD3, 0x38, 0x3B, 0x48, 0x13,
0xD6, 0x92, 0xC6, 0xE0, 0xE0, 0xD5, 0xD8, 0xE2, 0x50, 0xB9, 0x8B,
0xE4, 0x8E, 0x49, 0x5C, 0x1D, 0x60, 0x89, 0xDA, 0xD1, 0x5D, 0xC7,
0xD7, 0xB4, 0x61, 0x54, 0xD6, 0xB6, 0xCE, 0x8E, 0xF4, 0xAD, 0x69,
0xB1, 0x5D, 0x49, 0x82, 0x55, 0x9B, 0x29, 0x7B, 0xCF, 0x18, 0x85,
0xC5, 0x29, 0xF5, 0x66, 0x66, 0x0E, 0x57, 0xEC, 0x68, 0xED, 0xBC,
0x3C, 0x05, 0x72, 0x6C, 0xC0, 0x2F, 0xD4, 0xCB, 0xF4, 0x97, 0x6E,
0xAA, 0x9A, 0xFD, 0x51, 0x38, 0xFE, 0x83, 0x76, 0x43, 0x5B, 0x9F,
0xC6, 0x1D, 0x2F, 0xC0, 0xEB, 0x06, 0xE3
};
static const byte srp_g[] = {
0x02
};
int wolfSSL_CTX_set_srp_username(WOLFSSL_CTX* ctx, char* username)
{
int r = 0;
SrpSide srp_side = SRP_CLIENT_SIDE;
WOLFSSL_ENTER("wolfSSL_CTX_set_srp_username");
if (ctx == NULL || ctx->srp == NULL || username==NULL)
return WOLFSSL_FAILURE;
if (ctx->method->side == WOLFSSL_SERVER_END){
srp_side = SRP_SERVER_SIDE;
} else if (ctx->method->side == WOLFSSL_CLIENT_END){
srp_side = SRP_CLIENT_SIDE;
} else {
WOLFSSL_MSG("Init CTX failed");
return WOLFSSL_FAILURE;
}
if (wc_SrpInit(ctx->srp, SRP_TYPE_SHA256, srp_side) < 0) {
WOLFSSL_MSG("Init SRP CTX failed");
XFREE(ctx->srp, ctx->heap, DYNAMIC_TYPE_SRP);
ctx->srp = NULL;
return WOLFSSL_FAILURE;
}
r = wc_SrpSetUsername(ctx->srp, (const byte*)username,
(word32)XSTRLEN(username));
if (r < 0) {
WOLFSSL_MSG("fail to set srp username.");
return WOLFSSL_FAILURE;
}
/* if wolfSSL_CTX_set_srp_password has already been called, */
/* use saved password here */
if (ctx->srp_password != NULL) {
if (ctx->srp->user == NULL)
return WOLFSSL_FAILURE;
return wolfSSL_CTX_set_srp_password(ctx, (char*)ctx->srp_password);
}
return WOLFSSL_SUCCESS;
}
int wolfSSL_CTX_set_srp_password(WOLFSSL_CTX* ctx, char* password)
{
int r;
byte salt[SRP_SALT_SIZE];
WOLFSSL_ENTER("wolfSSL_CTX_set_srp_password");
if (ctx == NULL || ctx->srp == NULL || password == NULL)
return WOLFSSL_FAILURE;
if (ctx->srp->user != NULL) {
WC_RNG rng;
if (wc_InitRng(&rng) < 0) {
WOLFSSL_MSG("wc_InitRng failed");
return WOLFSSL_FAILURE;
}
XMEMSET(salt, 0, sizeof(salt)/sizeof(salt[0]));
r = wc_RNG_GenerateBlock(&rng, salt, sizeof(salt)/sizeof(salt[0]));
wc_FreeRng(&rng);
if (r < 0) {
WOLFSSL_MSG("wc_RNG_GenerateBlock failed");
return WOLFSSL_FAILURE;
}
if (wc_SrpSetParams(ctx->srp, srp_N, sizeof(srp_N)/sizeof(srp_N[0]),
srp_g, sizeof(srp_g)/sizeof(srp_g[0]),
salt, sizeof(salt)/sizeof(salt[0])) < 0){
WOLFSSL_MSG("wc_SrpSetParam failed");
return WOLFSSL_FAILURE;
}
r = wc_SrpSetPassword(ctx->srp, (const byte*)password,
(word32)XSTRLEN(password));
if (r < 0) {
WOLFSSL_MSG("wc_SrpSetPassword failed.");
return WOLFSSL_FAILURE;
}
XFREE(ctx->srp_password, NULL, DYNAMIC_TYPE_SRP);
ctx->srp_password = NULL;
} else {
/* save password for wolfSSL_set_srp_username */
XFREE(ctx->srp_password, ctx->heap, DYNAMIC_TYPE_SRP);
ctx->srp_password = (byte*)XMALLOC(XSTRLEN(password) + 1, ctx->heap,
DYNAMIC_TYPE_SRP);
if (ctx->srp_password == NULL){
WOLFSSL_MSG("memory allocation error");
return WOLFSSL_FAILURE;
}
XMEMCPY(ctx->srp_password, password, XSTRLEN(password) + 1);
}
return WOLFSSL_SUCCESS;
}
/**
* The modulus passed to wc_SrpSetParams in ssl.c is constant so check
* that the requested strength is less than or equal to the size of the
* static modulus size.
* @param ctx Not used
* @param strength Minimum number of bits for the modulus
* @return 1 if strength is less than or equal to static modulus
* 0 if strength is greater than static modulus
*/
int wolfSSL_CTX_set_srp_strength(WOLFSSL_CTX *ctx, int strength)
{
(void)ctx;
WOLFSSL_ENTER("wolfSSL_CTX_set_srp_strength");
if (strength > (int)(sizeof(srp_N)*8)) {
WOLFSSL_MSG("Bad Parameter");
return WOLFSSL_FAILURE;
}
return WOLFSSL_SUCCESS;
}
char* wolfSSL_get_srp_username(WOLFSSL *ssl)
{
if (ssl && ssl->ctx && ssl->ctx->srp) {
return (char*) ssl->ctx->srp->user;
}
return NULL;
}
#endif /* WOLFCRYPT_HAVE_SRP && !NO_SHA256 && !WC_NO_RNG */
/* keyblock size in bytes or -1 */
int wolfSSL_get_keyblock_size(WOLFSSL* ssl)
{
if (ssl == NULL)
return WOLFSSL_FATAL_ERROR;
return 2 * (ssl->specs.key_size + ssl->specs.iv_size +
ssl->specs.hash_size);
}
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EXTRA) || \
defined(WOLFSSL_WPAS_SMALL)
/* store keys returns WOLFSSL_SUCCESS or -1 on error */
int wolfSSL_get_keys(WOLFSSL* ssl, unsigned char** ms, unsigned int* msLen,
unsigned char** sr, unsigned int* srLen,
unsigned char** cr, unsigned int* crLen)
{
if (ssl == NULL || ssl->arrays == NULL)
return WOLFSSL_FATAL_ERROR;
*ms = ssl->arrays->masterSecret;
*sr = ssl->arrays->serverRandom;
*cr = ssl->arrays->clientRandom;
*msLen = SECRET_LEN;
*srLen = RAN_LEN;
*crLen = RAN_LEN;
return WOLFSSL_SUCCESS;
}
void wolfSSL_set_accept_state(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_set_accept_state");
if (ssl == NULL)
return;
if (ssl->options.side == WOLFSSL_CLIENT_END) {
#ifdef HAVE_ECC
WC_DECLARE_VAR(key, ecc_key, 1, 0);
word32 idx = 0;
#ifdef WOLFSSL_SMALL_STACK
key = (ecc_key*)XMALLOC(sizeof(ecc_key), ssl->heap,
DYNAMIC_TYPE_ECC);
if (key == NULL) {
WOLFSSL_MSG("Error allocating memory for ecc_key");
}
#endif
if (ssl->options.haveStaticECC && ssl->buffers.key != NULL) {
if (wc_ecc_init(key) >= 0) {
if (wc_EccPrivateKeyDecode(ssl->buffers.key->buffer, &idx,
key, ssl->buffers.key->length) != 0) {
ssl->options.haveECDSAsig = 0;
ssl->options.haveECC = 0;
ssl->options.haveStaticECC = 0;
}
wc_ecc_free(key);
}
}
WC_FREE_VAR_EX(key, ssl->heap, DYNAMIC_TYPE_ECC);
#endif
#ifndef NO_DH
if (!ssl->options.haveDH && ssl->ctx->haveDH) {
ssl->buffers.serverDH_P = ssl->ctx->serverDH_P;
ssl->buffers.serverDH_G = ssl->ctx->serverDH_G;
ssl->options.haveDH = 1;
}
#endif
}
if (InitSSL_Side(ssl, WOLFSSL_SERVER_END) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Error initializing server side");
}
}
#endif /* OPENSSL_EXTRA || WOLFSSL_EXTRA || WOLFSSL_WPAS_SMALL */
/* return true if connection established */
/* this works for TLS and DTLS */
int wolfSSL_is_init_finished(const WOLFSSL* ssl)
{
if (ssl == NULL)
return 0;
#if defined(WOLFSSL_DTLS13) && !defined(NO_WOLFSSL_CLIENT)
if (ssl->options.side == WOLFSSL_CLIENT_END && ssl->options.dtls
&& IsAtLeastTLSv1_3(ssl->version)) {
return ssl->options.serverState == SERVER_FINISHED_ACKED;
}
#endif /* WOLFSSL_DTLS13 && !NO_WOLFSSL_CLIENT */
/* Can't use ssl->options.connectState and ssl->options.acceptState
* because they differ in meaning for TLS <=1.2 and 1.3 */
if (ssl->options.handShakeState == HANDSHAKE_DONE)
return 1;
return 0;
}
#ifdef OPENSSL_EXTRA
void wolfSSL_CTX_set_tmp_rsa_callback(WOLFSSL_CTX* ctx,
WOLFSSL_RSA*(*f)(WOLFSSL*, int, int))
{
/* wolfSSL verifies all these internally */
(void)ctx;
(void)f;
}
void wolfSSL_set_shutdown(WOLFSSL* ssl, int opt)
{
WOLFSSL_ENTER("wolfSSL_set_shutdown");
if(ssl==NULL) {
WOLFSSL_MSG("Shutdown not set. ssl is null");
return;
}
ssl->options.sentNotify = (opt&WOLFSSL_SENT_SHUTDOWN) > 0;
ssl->options.closeNotify = (opt&WOLFSSL_RECEIVED_SHUTDOWN) > 0;
}
#endif
long wolfSSL_CTX_get_options(WOLFSSL_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_CTX_get_options");
WOLFSSL_MSG("wolfSSL options are set through API calls and macros");
if(ctx == NULL)
return BAD_FUNC_ARG;
return (long)ctx->mask;
}
/* forward declaration */
static long wolf_set_options(long old_op, long op);
long wolfSSL_CTX_set_options(WOLFSSL_CTX* ctx, long opt)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_options");
if (ctx == NULL)
return BAD_FUNC_ARG;
ctx->mask = (unsigned long)wolf_set_options((long)ctx->mask, opt);
#if defined(HAVE_SESSION_TICKET) && (defined(OPENSSL_EXTRA) \
|| defined(HAVE_WEBSERVER) || defined(WOLFSSL_WPAS_SMALL))
if ((ctx->mask & WOLFSSL_OP_NO_TICKET) == WOLFSSL_OP_NO_TICKET) {
ctx->noTicketTls12 = 1;
}
/* This code is here for documentation purpose. You must not turn off
* session tickets with the WOLFSSL_OP_NO_TICKET option for TLSv1.3.
* Because we need to support both stateful and stateless tickets.
#ifdef WOLFSSL_TLS13
if ((ctx->mask & WOLFSSL_OP_NO_TICKET) == WOLFSSL_OP_NO_TICKET) {
ctx->noTicketTls13 = 1;
}
#endif
*/
#endif
return (long)ctx->mask;
}
long wolfSSL_CTX_clear_options(WOLFSSL_CTX* ctx, long opt)
{
WOLFSSL_ENTER("wolfSSL_CTX_clear_options");
if(ctx == NULL)
return BAD_FUNC_ARG;
ctx->mask &= (unsigned long)~opt;
return (long)ctx->mask;
}
#ifdef OPENSSL_EXTRA
int wolfSSL_set_rfd(WOLFSSL* ssl, int rfd)
{
WOLFSSL_ENTER("wolfSSL_set_rfd");
ssl->rfd = rfd; /* not used directly to allow IO callbacks */
ssl->IOCB_ReadCtx = &ssl->rfd;
#ifdef WOLFSSL_DTLS
if (ssl->options.dtls) {
ssl->IOCB_ReadCtx = &ssl->buffers.dtlsCtx;
ssl->buffers.dtlsCtx.rfd = rfd;
}
#endif
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_wfd(WOLFSSL* ssl, int wfd)
{
WOLFSSL_ENTER("wolfSSL_set_wfd");
ssl->wfd = wfd; /* not used directly to allow IO callbacks */
ssl->IOCB_WriteCtx = &ssl->wfd;
return WOLFSSL_SUCCESS;
}
#endif /* OPENSSL_EXTRA */
#ifdef WOLFSSL_ENCRYPTED_KEYS
void wolfSSL_CTX_set_default_passwd_cb_userdata(WOLFSSL_CTX* ctx,
void* userdata)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_default_passwd_cb_userdata");
if (ctx)
ctx->passwd_userdata = userdata;
}
void wolfSSL_CTX_set_default_passwd_cb(WOLFSSL_CTX* ctx, wc_pem_password_cb*
cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_default_passwd_cb");
if (ctx)
ctx->passwd_cb = cb;
}
wc_pem_password_cb* wolfSSL_CTX_get_default_passwd_cb(WOLFSSL_CTX *ctx)
{
if (ctx == NULL || ctx->passwd_cb == NULL) {
return NULL;
}
return ctx->passwd_cb;
}
void* wolfSSL_CTX_get_default_passwd_cb_userdata(WOLFSSL_CTX *ctx)
{
if (ctx == NULL) {
return NULL;
}
return ctx->passwd_userdata;
}
#endif /* WOLFSSL_ENCRYPTED_KEYS */
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER) || defined(HAVE_MEMCACHED)
unsigned long wolfSSL_ERR_get_error(void)
{
WOLFSSL_ENTER("wolfSSL_ERR_get_error");
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
return (unsigned long)wc_GetErrorNodeErr();
#else
return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
}
#endif
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
int wolfSSL_num_locks(void)
{
return 0;
}
void wolfSSL_set_locking_callback(mutex_cb* f)
{
WOLFSSL_ENTER("wolfSSL_set_locking_callback");
if (wc_SetMutexCb(f) != 0) {
WOLFSSL_MSG("Error when setting mutex call back");
}
}
mutex_cb* wolfSSL_get_locking_callback(void)
{
WOLFSSL_ENTER("wolfSSL_get_locking_callback");
return wc_GetMutexCb();
}
typedef unsigned long (idCb)(void);
static idCb* inner_idCb = NULL;
unsigned long wolfSSL_thread_id(void)
{
if (inner_idCb != NULL) {
return inner_idCb();
}
else {
return 0;
}
}
void wolfSSL_set_id_callback(unsigned long (*f)(void))
{
inner_idCb = f;
}
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
#ifndef NO_BIO
/* print out and clear all errors */
void wolfSSL_ERR_print_errors(WOLFSSL_BIO* bio)
{
const char* file = NULL;
const char* reason = NULL;
int ret;
int line = 0;
char buf[WOLFSSL_MAX_ERROR_SZ * 2];
WOLFSSL_ENTER("wolfSSL_ERR_print_errors");
if (bio == NULL) {
WOLFSSL_MSG("BIO passed in was null");
return;
}
do {
ret = wc_PeekErrorNode(0, &file, &reason, &line);
if (ret >= 0) {
const char* r = wolfSSL_ERR_reason_error_string(
(unsigned long)(0 - ret));
if (XSNPRINTF(buf, sizeof(buf),
"error:%d:wolfSSL library:%s:%s:%d\n",
ret, r, file, line)
>= (int)sizeof(buf))
{
WOLFSSL_MSG("Buffer overrun formatting error message");
}
wolfSSL_BIO_write(bio, buf, (int)XSTRLEN(buf));
wc_RemoveErrorNode(0);
}
} while (ret >= 0);
if (wolfSSL_BIO_write(bio, "", 1) != 1) {
WOLFSSL_MSG("Issue writing final string terminator");
}
}
#endif /* !NO_BIO */
#endif /* WOLFSSL_HAVE_ERROR_QUEUE */
#endif /* OPENSSL_EXTRA || HAVE_WEBSERVER */
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
defined(HAVE_SECRET_CALLBACK)
#if !defined(NO_WOLFSSL_SERVER)
/* Return the amount of random bytes copied over or error case.
* ssl : ssl struct after handshake
* out : buffer to hold random bytes
* outSz : either 0 (return max buffer sz) or size of out buffer
*/
size_t wolfSSL_get_server_random(const WOLFSSL *ssl, unsigned char *out,
size_t outSz)
{
size_t size;
/* return max size of buffer */
if (outSz == 0) {
return RAN_LEN;
}
if (ssl == NULL || out == NULL) {
return 0;
}
if (ssl->arrays == NULL) {
WOLFSSL_MSG("Arrays struct not saved after handshake");
return 0;
}
if (outSz > RAN_LEN) {
size = RAN_LEN;
}
else {
size = outSz;
}
XMEMCPY(out, ssl->arrays->serverRandom, size);
return size;
}
#endif /* !NO_WOLFSSL_SERVER */
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL || HAVE_SECRET_CALLBACK */
#ifdef OPENSSL_EXTRA
#if !defined(NO_WOLFSSL_SERVER)
/* Used to get the peer ephemeral public key sent during the connection
* NOTE: currently wolfSSL_KeepHandshakeResources(WOLFSSL* ssl) must be called
* before the ephemeral key is stored.
* return WOLFSSL_SUCCESS on success */
int wolfSSL_get_peer_tmp_key(const WOLFSSL* ssl, WOLFSSL_EVP_PKEY** pkey)
{
WOLFSSL_EVP_PKEY* ret = NULL;
WOLFSSL_ENTER("wolfSSL_get_server_tmp_key");
if (ssl == NULL || pkey == NULL) {
WOLFSSL_MSG("Bad argument passed in");
return WOLFSSL_FAILURE;
}
#ifdef HAVE_ECC
if (ssl->peerEccKey != NULL) {
unsigned char* der;
const unsigned char* pt;
unsigned int derSz = 0;
int sz;
PRIVATE_KEY_UNLOCK();
if (wc_ecc_export_x963(ssl->peerEccKey, NULL, &derSz)
!= WC_NO_ERR_TRACE(LENGTH_ONLY_E))
{
WOLFSSL_MSG("get ecc der size failed");
PRIVATE_KEY_LOCK();
return WOLFSSL_FAILURE;
}
PRIVATE_KEY_LOCK();
derSz += MAX_SEQ_SZ + (2 * MAX_ALGO_SZ) + MAX_SEQ_SZ + TRAILING_ZERO;
der = (unsigned char*)XMALLOC(derSz, ssl->heap, DYNAMIC_TYPE_KEY);
if (der == NULL) {
WOLFSSL_MSG("Memory error");
return WOLFSSL_FAILURE;
}
if ((sz = wc_EccPublicKeyToDer(ssl->peerEccKey, der, derSz, 1)) <= 0) {
WOLFSSL_MSG("get ecc der failed");
XFREE(der, ssl->heap, DYNAMIC_TYPE_KEY);
return WOLFSSL_FAILURE;
}
pt = der; /* in case pointer gets advanced */
ret = wolfSSL_d2i_PUBKEY(NULL, &pt, sz);
XFREE(der, ssl->heap, DYNAMIC_TYPE_KEY);
}
#endif
*pkey = ret;
#ifdef HAVE_ECC
if (ret != NULL)
return WOLFSSL_SUCCESS;
else
#endif
return WOLFSSL_FAILURE;
}
#endif /* !NO_WOLFSSL_SERVER */
/**
* This function checks if any compiled in protocol versions are
* left enabled after calls to set_min or set_max API.
* @param major The SSL/TLS major version
* @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
* protocol versions are left enabled.
*/
static int CheckSslMethodVersion(byte major, unsigned long options)
{
int sanityConfirmed = 0;
(void)options;
switch (major) {
#ifndef NO_TLS
case SSLv3_MAJOR:
#ifdef WOLFSSL_ALLOW_SSLV3
if (!(options & WOLFSSL_OP_NO_SSLv3)) {
sanityConfirmed = 1;
}
#endif
#ifndef NO_OLD_TLS
if (!(options & WOLFSSL_OP_NO_TLSv1))
sanityConfirmed = 1;
if (!(options & WOLFSSL_OP_NO_TLSv1_1))
sanityConfirmed = 1;
#endif
#ifndef WOLFSSL_NO_TLS12
if (!(options & WOLFSSL_OP_NO_TLSv1_2))
sanityConfirmed = 1;
#endif
#ifdef WOLFSSL_TLS13
if (!(options & WOLFSSL_OP_NO_TLSv1_3))
sanityConfirmed = 1;
#endif
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS_MAJOR:
sanityConfirmed = 1;
break;
#endif
default:
WOLFSSL_MSG("Invalid major version");
return WOLFSSL_FAILURE;
}
if (!sanityConfirmed) {
WOLFSSL_MSG("All compiled in TLS versions disabled");
return WOLFSSL_FAILURE;
}
return WOLFSSL_SUCCESS;
}
/**
* protoVerTbl holds (D)TLS version numbers in ascending order.
* Except DTLS versions, the newer version is located in the latter part of
* the table. This table is referred by wolfSSL_CTX_set_min_proto_version and
* wolfSSL_CTX_set_max_proto_version.
*/
static const int protoVerTbl[] = {
SSL3_VERSION,
TLS1_VERSION,
TLS1_1_VERSION,
TLS1_2_VERSION,
TLS1_3_VERSION,
DTLS1_VERSION,
DTLS1_2_VERSION
};
/* number of protocol versions listed in protoVerTbl */
#define NUMBER_OF_PROTOCOLS (sizeof(protoVerTbl)/sizeof(int))
/**
* wolfSSL_CTX_set_min_proto_version attempts to set the minimum protocol
* version to use by SSL objects created from this WOLFSSL_CTX.
* This API guarantees that a version of SSL/TLS lower than specified
* here will not be allowed. If the version specified is not compiled in
* then this API sets the lowest compiled in protocol version.
* This API also accept 0 as version, to set the minimum version automatically.
* CheckSslMethodVersion() is called to check if any remaining protocol versions
* are enabled.
* @param ctx The wolfSSL CONTEXT factory for spawning SSL/TLS objects
* @param version Any of the following
* * 0
* * SSL3_VERSION
* * TLS1_VERSION
* * TLS1_1_VERSION
* * TLS1_2_VERSION
* * TLS1_3_VERSION
* * DTLS1_VERSION
* * DTLS1_2_VERSION
* @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
* protocol versions are left enabled.
*/
static int Set_CTX_min_proto_version(WOLFSSL_CTX* ctx, int version)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_min_proto_version_ex");
if (ctx == NULL) {
return WOLFSSL_FAILURE;
}
switch (version) {
#ifndef NO_TLS
case SSL3_VERSION:
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
ctx->minDowngrade = SSLv3_MINOR;
break;
#endif
case TLS1_VERSION:
#ifdef WOLFSSL_ALLOW_TLSV10
ctx->minDowngrade = TLSv1_MINOR;
break;
#endif
case TLS1_1_VERSION:
#ifndef NO_OLD_TLS
ctx->minDowngrade = TLSv1_1_MINOR;
break;
#endif
case TLS1_2_VERSION:
#ifndef WOLFSSL_NO_TLS12
ctx->minDowngrade = TLSv1_2_MINOR;
break;
#endif
case TLS1_3_VERSION:
#ifdef WOLFSSL_TLS13
ctx->minDowngrade = TLSv1_3_MINOR;
break;
#endif
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
#ifndef NO_OLD_TLS
ctx->minDowngrade = DTLS_MINOR;
break;
#endif
case DTLS1_2_VERSION:
ctx->minDowngrade = DTLSv1_2_MINOR;
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
switch (version) {
#ifndef NO_TLS
case TLS1_3_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_2);
FALL_THROUGH;
case TLS1_2_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_1);
FALL_THROUGH;
case TLS1_1_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1);
FALL_THROUGH;
case TLS1_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_SSLv3);
break;
case SSL3_VERSION:
case SSL2_VERSION:
/* Nothing to do here */
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
case DTLS1_2_VERSION:
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
return CheckSslMethodVersion(ctx->method->version.major, ctx->mask);
}
/* Sets the min protocol version allowed with WOLFSSL_CTX
* returns WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_min_proto_version(WOLFSSL_CTX* ctx, int version)
{
int ret;
int proto = 0;
int maxProto = 0;
int i;
int idx = 0;
WOLFSSL_ENTER("wolfSSL_CTX_set_min_proto_version");
if (ctx == NULL) {
return WOLFSSL_FAILURE;
}
if (version != 0) {
proto = version;
ctx->minProto = 0; /* turn min proto flag off */
for (i = 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
if (protoVerTbl[i] == version) {
break;
}
}
}
else {
/* when 0 is specified as version, try to find out the min version */
for (i = 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
ret = Set_CTX_min_proto_version(ctx, protoVerTbl[i]);
if (ret == WOLFSSL_SUCCESS) {
proto = protoVerTbl[i];
ctx->minProto = 1; /* turn min proto flag on */
break;
}
}
}
/* check case where max > min , if so then clear the NO_* options
* i is the index into the table for proto version used, see if the max
* proto version index found is smaller */
maxProto = wolfSSL_CTX_get_max_proto_version(ctx);
for (idx = 0; (unsigned)idx < NUMBER_OF_PROTOCOLS; idx++) {
if (protoVerTbl[idx] == maxProto) {
break;
}
}
if (idx < i) {
wolfSSL_CTX_clear_options(ctx, WOLFSSL_OP_NO_TLSv1 |
WOLFSSL_OP_NO_TLSv1_1 | WOLFSSL_OP_NO_TLSv1_2 |
WOLFSSL_OP_NO_TLSv1_3);
}
ret = Set_CTX_min_proto_version(ctx, proto);
return ret;
}
/**
* wolfSSL_CTX_set_max_proto_version attempts to set the maximum protocol
* version to use by SSL objects created from this WOLFSSL_CTX.
* This API guarantees that a version of SSL/TLS higher than specified
* here will not be allowed. If the version specified is not compiled in
* then this API sets the highest compiled in protocol version.
* This API also accept 0 as version, to set the maximum version automatically.
* CheckSslMethodVersion() is called to check if any remaining protocol versions
* are enabled.
* @param ctx The wolfSSL CONTEXT factory for spawning SSL/TLS objects
* @param ver Any of the following
* * 0
* * SSL3_VERSION
* * TLS1_VERSION
* * TLS1_1_VERSION
* * TLS1_2_VERSION
* * TLS1_3_VERSION
* * DTLS1_VERSION
* * DTLS1_2_VERSION
* @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
* protocol versions are left enabled.
*/
static int Set_CTX_max_proto_version(WOLFSSL_CTX* ctx, int ver)
{
int ret;
WOLFSSL_ENTER("Set_CTX_max_proto_version");
if (!ctx || !ctx->method) {
WOLFSSL_MSG("Bad parameter");
return WOLFSSL_FAILURE;
}
switch (ver) {
#ifndef NO_TLS
#ifndef NO_OLD_TLS
case SSL2_VERSION:
WOLFSSL_MSG("wolfSSL does not support SSLv2");
return WOLFSSL_FAILURE;
#endif
case SSL3_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1);
FALL_THROUGH;
case TLS1_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_1);
FALL_THROUGH;
case TLS1_1_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_2);
FALL_THROUGH;
case TLS1_2_VERSION:
wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_3);
FALL_THROUGH;
case TLS1_3_VERSION:
/* Nothing to do here */
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
case DTLS1_2_VERSION:
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
ret = CheckSslMethodVersion(ctx->method->version.major, ctx->mask);
if (ret == WOLFSSL_SUCCESS) {
/* Check the major */
switch (ver) {
#ifndef NO_TLS
case SSL3_VERSION:
case TLS1_VERSION:
case TLS1_1_VERSION:
case TLS1_2_VERSION:
case TLS1_3_VERSION:
if (ctx->method->version.major != SSLv3_MAJOR) {
WOLFSSL_MSG("Mismatched protocol version");
return WOLFSSL_FAILURE;
}
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
case DTLS1_2_VERSION:
if (ctx->method->version.major != DTLS_MAJOR) {
WOLFSSL_MSG("Mismatched protocol version");
return WOLFSSL_FAILURE;
}
break;
#endif
}
/* Update the method */
switch (ver) {
#ifndef NO_TLS
case SSL3_VERSION:
ctx->method->version.minor = SSLv3_MINOR;
break;
case TLS1_VERSION:
ctx->method->version.minor = TLSv1_MINOR;
break;
case TLS1_1_VERSION:
ctx->method->version.minor = TLSv1_1_MINOR;
break;
case TLS1_2_VERSION:
ctx->method->version.minor = TLSv1_2_MINOR;
break;
case TLS1_3_VERSION:
ctx->method->version.minor = TLSv1_3_MINOR;
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
ctx->method->version.minor = DTLS_MINOR;
break;
case DTLS1_2_VERSION:
ctx->method->version.minor = DTLSv1_2_MINOR;
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
}
return ret;
}
/* Sets the max protocol version allowed with WOLFSSL_CTX
* returns WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_max_proto_version(WOLFSSL_CTX* ctx, int version)
{
int i;
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
int minProto;
WOLFSSL_ENTER("wolfSSL_CTX_set_max_proto_version");
if (ctx == NULL) {
return ret;
}
/* clear out flags and reset min protocol version */
minProto = wolfSSL_CTX_get_min_proto_version(ctx);
wolfSSL_CTX_clear_options(ctx,
WOLFSSL_OP_NO_TLSv1 | WOLFSSL_OP_NO_TLSv1_1 |
WOLFSSL_OP_NO_TLSv1_2 | WOLFSSL_OP_NO_TLSv1_3);
wolfSSL_CTX_set_min_proto_version(ctx, minProto);
if (version != 0) {
ctx->maxProto = 0; /* turn max proto flag off */
return Set_CTX_max_proto_version(ctx, version);
}
/* when 0 is specified as version, try to find out the min version from
* the bottom to top of the protoverTbl.
*/
for (i = NUMBER_OF_PROTOCOLS -1; i >= 0; i--) {
ret = Set_CTX_max_proto_version(ctx, protoVerTbl[i]);
if (ret == WOLFSSL_SUCCESS) {
ctx->maxProto = 1; /* turn max proto flag on */
break;
}
}
return ret;
}
static int Set_SSL_min_proto_version(WOLFSSL* ssl, int ver)
{
WOLFSSL_ENTER("Set_SSL_min_proto_version");
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
switch (ver) {
#ifndef NO_TLS
case SSL3_VERSION:
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
ssl->options.minDowngrade = SSLv3_MINOR;
break;
#endif
case TLS1_VERSION:
#ifdef WOLFSSL_ALLOW_TLSV10
ssl->options.minDowngrade = TLSv1_MINOR;
break;
#endif
case TLS1_1_VERSION:
#ifndef NO_OLD_TLS
ssl->options.minDowngrade = TLSv1_1_MINOR;
break;
#endif
case TLS1_2_VERSION:
#ifndef WOLFSSL_NO_TLS12
ssl->options.minDowngrade = TLSv1_2_MINOR;
break;
#endif
case TLS1_3_VERSION:
#ifdef WOLFSSL_TLS13
ssl->options.minDowngrade = TLSv1_3_MINOR;
break;
#endif
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
#ifndef NO_OLD_TLS
ssl->options.minDowngrade = DTLS_MINOR;
break;
#endif
case DTLS1_2_VERSION:
ssl->options.minDowngrade = DTLSv1_2_MINOR;
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
switch (ver) {
#ifndef NO_TLS
case TLS1_3_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_2;
FALL_THROUGH;
case TLS1_2_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_1;
FALL_THROUGH;
case TLS1_1_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1;
FALL_THROUGH;
case TLS1_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_SSLv3;
break;
case SSL3_VERSION:
case SSL2_VERSION:
/* Nothing to do here */
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
case DTLS1_2_VERSION:
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
return CheckSslMethodVersion(ssl->version.major, ssl->options.mask);
}
int wolfSSL_set_min_proto_version(WOLFSSL* ssl, int version)
{
int i;
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);;
WOLFSSL_ENTER("wolfSSL_set_min_proto_version");
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
if (version != 0) {
return Set_SSL_min_proto_version(ssl, version);
}
/* when 0 is specified as version, try to find out the min version */
for (i= 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
ret = Set_SSL_min_proto_version(ssl, protoVerTbl[i]);
if (ret == WOLFSSL_SUCCESS)
break;
}
return ret;
}
static int Set_SSL_max_proto_version(WOLFSSL* ssl, int ver)
{
WOLFSSL_ENTER("Set_SSL_max_proto_version");
if (!ssl) {
WOLFSSL_MSG("Bad parameter");
return WOLFSSL_FAILURE;
}
switch (ver) {
case SSL2_VERSION:
WOLFSSL_MSG("wolfSSL does not support SSLv2");
return WOLFSSL_FAILURE;
#ifndef NO_TLS
case SSL3_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1;
FALL_THROUGH;
case TLS1_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_1;
FALL_THROUGH;
case TLS1_1_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_2;
FALL_THROUGH;
case TLS1_2_VERSION:
ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_3;
FALL_THROUGH;
case TLS1_3_VERSION:
/* Nothing to do here */
break;
#endif
#ifdef WOLFSSL_DTLS
case DTLS1_VERSION:
case DTLS1_2_VERSION:
break;
#endif
default:
WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
return WOLFSSL_FAILURE;
}
return CheckSslMethodVersion(ssl->version.major, ssl->options.mask);
}
int wolfSSL_set_max_proto_version(WOLFSSL* ssl, int version)
{
int i;
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);;
WOLFSSL_ENTER("wolfSSL_set_max_proto_version");
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
if (version != 0) {
return Set_SSL_max_proto_version(ssl, version);
}
/* when 0 is specified as version, try to find out the min version from
* the bottom to top of the protoverTbl.
*/
for (i = NUMBER_OF_PROTOCOLS -1; i >= 0; i--) {
ret = Set_SSL_max_proto_version(ssl, protoVerTbl[i]);
if (ret == WOLFSSL_SUCCESS)
break;
}
return ret;
}
static int GetMinProtoVersion(int minDowngrade)
{
int ret;
switch (minDowngrade) {
#ifndef NO_OLD_TLS
#ifdef WOLFSSL_ALLOW_SSLV3
case SSLv3_MINOR:
ret = SSL3_VERSION;
break;
#endif
#ifdef WOLFSSL_ALLOW_TLSV10
case TLSv1_MINOR:
ret = TLS1_VERSION;
break;
#endif
case TLSv1_1_MINOR:
ret = TLS1_1_VERSION;
break;
#endif
#ifndef WOLFSSL_NO_TLS12
case TLSv1_2_MINOR:
ret = TLS1_2_VERSION;
break;
#endif
#ifdef WOLFSSL_TLS13
case TLSv1_3_MINOR:
ret = TLS1_3_VERSION;
break;
#endif
default:
ret = 0;
break;
}
return ret;
}
int wolfSSL_CTX_get_min_proto_version(WOLFSSL_CTX* ctx)
{
int ret = 0;
WOLFSSL_ENTER("wolfSSL_CTX_get_min_proto_version");
if (ctx != NULL) {
if (ctx->minProto) {
ret = 0;
}
else {
ret = GetMinProtoVersion(ctx->minDowngrade);
}
}
else {
ret = GetMinProtoVersion(WOLFSSL_MIN_DOWNGRADE);
}
WOLFSSL_LEAVE("wolfSSL_CTX_get_min_proto_version", ret);
return ret;
}
/* returns the maximum allowed protocol version given the 'options' used
* returns WOLFSSL_FATAL_ERROR on no match */
static int GetMaxProtoVersion(long options)
{
#ifndef NO_TLS
#ifdef WOLFSSL_TLS13
if (!(options & WOLFSSL_OP_NO_TLSv1_3))
return TLS1_3_VERSION;
#endif
#ifndef WOLFSSL_NO_TLS12
if (!(options & WOLFSSL_OP_NO_TLSv1_2))
return TLS1_2_VERSION;
#endif
#ifndef NO_OLD_TLS
if (!(options & WOLFSSL_OP_NO_TLSv1_1))
return TLS1_1_VERSION;
#ifdef WOLFSSL_ALLOW_TLSV10
if (!(options & WOLFSSL_OP_NO_TLSv1))
return TLS1_VERSION;
#endif
#ifdef WOLFSSL_ALLOW_SSLV3
if (!(options & WOLFSSL_OP_NO_SSLv3))
return SSL3_VERSION;
#endif
#endif
#else
(void)options;
#endif /* NO_TLS */
return WOLFSSL_FATAL_ERROR;
}
/* returns the maximum protocol version for 'ctx' */
int wolfSSL_CTX_get_max_proto_version(WOLFSSL_CTX* ctx)
{
int ret = 0;
long options = 0; /* default to nothing set */
WOLFSSL_ENTER("wolfSSL_CTX_get_max_proto_version");
if (ctx != NULL) {
options = wolfSSL_CTX_get_options(ctx);
}
if ((ctx != NULL) && ctx->maxProto) {
ret = 0;
}
else {
ret = GetMaxProtoVersion(options);
}
WOLFSSL_LEAVE("wolfSSL_CTX_get_max_proto_version", ret);
if (ret == WC_NO_ERR_TRACE(WOLFSSL_FATAL_ERROR)) {
WOLFSSL_MSG("Error getting max proto version");
ret = 0; /* setting ret to 0 to match compat return */
}
return ret;
}
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
defined(HAVE_SECRET_CALLBACK)
#if !defined(NO_WOLFSSL_CLIENT)
/* Return the amount of random bytes copied over or error case.
* ssl : ssl struct after handshake
* out : buffer to hold random bytes
* outSz : either 0 (return max buffer sz) or size of out buffer
*/
size_t wolfSSL_get_client_random(const WOLFSSL* ssl, unsigned char* out,
size_t outSz)
{
size_t size;
/* return max size of buffer */
if (outSz == 0) {
return RAN_LEN;
}
if (ssl == NULL || out == NULL) {
return 0;
}
if (ssl->arrays == NULL) {
WOLFSSL_MSG("Arrays struct not saved after handshake");
return 0;
}
if (outSz > RAN_LEN) {
size = RAN_LEN;
}
else {
size = outSz;
}
XMEMCPY(out, ssl->arrays->clientRandom, size);
return size;
}
#endif /* !NO_WOLFSSL_CLIENT */
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL || HAVE_SECRET_CALLBACK */
#ifdef OPENSSL_EXTRA
unsigned long wolfSSLeay(void)
{
#ifdef SSLEAY_VERSION_NUMBER
return SSLEAY_VERSION_NUMBER;
#else
return OPENSSL_VERSION_NUMBER;
#endif
}
unsigned long wolfSSL_OpenSSL_version_num(void)
{
return OPENSSL_VERSION_NUMBER;
}
const char* wolfSSLeay_version(int type)
{
(void)type;
#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
return wolfSSL_OpenSSL_version(type);
#else
return wolfSSL_OpenSSL_version();
#endif
}
#endif /* OPENSSL_EXTRA */
#ifdef OPENSSL_EXTRA
void wolfSSL_ERR_free_strings(void)
{
/* handled internally */
}
void wolfSSL_cleanup_all_ex_data(void)
{
/* nothing to do here */
}
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(DEBUG_WOLFSSL_VERBOSE) || \
defined(HAVE_CURL)
void wolfSSL_ERR_clear_error(void)
{
WOLFSSL_ENTER("wolfSSL_ERR_clear_error");
#if defined(OPENSSL_EXTRA) || defined(DEBUG_WOLFSSL_VERBOSE)
wc_ClearErrorNodes();
#endif
}
#endif
int wolfSSL_clear(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_clear");
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
if (!ssl->options.handShakeDone) {
/* Only reset the session if we didn't complete a handshake */
wolfSSL_FreeSession(ssl->ctx, ssl->session);
ssl->session = wolfSSL_NewSession(ssl->heap);
if (ssl->session == NULL) {
return WOLFSSL_FAILURE;
}
}
/* reset error */
ssl->error = 0;
/* reset option bits */
ssl->options.isClosed = 0;
ssl->options.connReset = 0;
ssl->options.sentNotify = 0;
ssl->options.closeNotify = 0;
ssl->options.sendVerify = 0;
ssl->options.serverState = NULL_STATE;
ssl->options.clientState = NULL_STATE;
ssl->options.connectState = CONNECT_BEGIN;
ssl->options.acceptState = ACCEPT_BEGIN;
ssl->options.handShakeState = NULL_STATE;
ssl->options.handShakeDone = 0;
ssl->recordSzOverhead = 0;
ssl->options.processReply = 0; /* doProcessInit */
ssl->options.havePeerVerify = 0;
ssl->options.havePeerCert = 0;
ssl->options.peerAuthGood = 0;
ssl->options.tls1_3 = 0;
ssl->options.haveSessionId = 0;
ssl->options.tls = 0;
ssl->options.tls1_1 = 0;
#ifdef WOLFSSL_TLS13
#ifdef WOLFSSL_SEND_HRR_COOKIE
ssl->options.hrrSentCookie = 0;
#endif
ssl->options.hrrSentKeyShare = 0;
#endif
#ifdef WOLFSSL_DTLS
ssl->options.dtlsStateful = 0;
#endif
#ifdef WOLFSSL_TLS13
#if defined(HAVE_SESSION_TICKET) || !defined(NO_PSK)
ssl->options.noPskDheKe = ssl->ctx->noPskDheKe;
#ifdef HAVE_SUPPORTED_CURVES
ssl->options.onlyPskDheKe = ssl->ctx->onlyPskDheKe;
#endif
#endif
#endif
#ifdef HAVE_SESSION_TICKET
#ifdef WOLFSSL_TLS13
ssl->options.ticketsSent = 0;
#endif
ssl->options.rejectTicket = 0;
#endif
#ifdef WOLFSSL_EARLY_DATA
ssl->earlyData = no_early_data;
ssl->earlyDataSz = 0;
#endif
#if defined(HAVE_TLS_EXTENSIONS) && !defined(NO_TLS)
TLSX_FreeAll(ssl->extensions, ssl->heap);
ssl->extensions = NULL;
#if defined(HAVE_SECURE_RENEGOTIATION) \
|| defined(HAVE_SERVER_RENEGOTIATION_INFO)
ssl->secure_renegotiation = NULL;
#endif
#endif
if (ssl->keys.encryptionOn) {
ForceZero(ssl->buffers.inputBuffer.buffer -
ssl->buffers.inputBuffer.offset,
ssl->buffers.inputBuffer.bufferSize);
#ifdef WOLFSSL_CHECK_MEM_ZERO
wc_MemZero_Check(ssl->buffers.inputBuffer.buffer -
ssl->buffers.inputBuffer.offset,
ssl->buffers.inputBuffer.bufferSize);
#endif
}
ssl->keys.encryptionOn = 0;
XMEMSET(&ssl->msgsReceived, 0, sizeof(ssl->msgsReceived));
/* Discard any partial handshake-message reassembly on reuse. */
XFREE(ssl->pendingMsg, ssl->heap, DYNAMIC_TYPE_ARRAYS);
ssl->pendingMsg = NULL;
ssl->pendingMsgSz = 0;
ssl->pendingMsgOffset = 0;
ssl->pendingMsgType = 0;
FreeCiphers(ssl);
InitCiphers(ssl);
InitCipherSpecs(&ssl->specs);
if (InitSSL_Suites(ssl) != WOLFSSL_SUCCESS)
return WOLFSSL_FAILURE;
if (InitHandshakeHashes(ssl) != 0)
return WOLFSSL_FAILURE;
#ifdef KEEP_PEER_CERT
FreeX509(&ssl->peerCert);
InitX509(&ssl->peerCert, 0, ssl->heap);
#endif
#ifdef WOLFSSL_QUIC
wolfSSL_quic_clear(ssl);
#endif
#ifdef HAVE_OCSP
#if defined(WOLFSSL_TLS13) && defined(HAVE_CERTIFICATE_STATUS_REQUEST)
ssl->response_idx = 0;
#endif
#endif
return WOLFSSL_SUCCESS;
}
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER) || defined(HAVE_MEMCACHED)
long wolfSSL_CTX_set_mode(WOLFSSL_CTX* ctx, long mode)
{
/* WOLFSSL_MODE_ACCEPT_MOVING_WRITE_BUFFER is wolfSSL default mode */
WOLFSSL_ENTER("wolfSSL_CTX_set_mode");
switch(mode) {
case WOLFSSL_MODE_ENABLE_PARTIAL_WRITE:
ctx->partialWrite = 1;
break;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
case SSL_MODE_RELEASE_BUFFERS:
WOLFSSL_MSG("SSL_MODE_RELEASE_BUFFERS not implemented.");
break;
#endif
case WOLFSSL_MODE_AUTO_RETRY:
ctx->autoRetry = 1;
break;
default:
WOLFSSL_MSG("Mode Not Implemented");
}
/* WOLFSSL_MODE_AUTO_RETRY
* Should not return WOLFSSL_FATAL_ERROR with renegotiation on read/write */
return mode;
}
long wolfSSL_CTX_clear_mode(WOLFSSL_CTX* ctx, long mode)
{
/* WOLFSSL_MODE_ACCEPT_MOVING_WRITE_BUFFER is wolfSSL default mode */
WOLFSSL_ENTER("wolfSSL_CTX_clear_mode");
switch(mode) {
case WOLFSSL_MODE_ENABLE_PARTIAL_WRITE:
ctx->partialWrite = 0;
break;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
case SSL_MODE_RELEASE_BUFFERS:
WOLFSSL_MSG("SSL_MODE_RELEASE_BUFFERS not implemented.");
break;
#endif
case WOLFSSL_MODE_AUTO_RETRY:
ctx->autoRetry = 0;
break;
default:
WOLFSSL_MSG("Mode Not Implemented");
}
/* WOLFSSL_MODE_AUTO_RETRY
* Should not return WOLFSSL_FATAL_ERROR with renegotiation on read/write */
return 0;
}
#endif
#ifdef OPENSSL_EXTRA
#ifndef NO_WOLFSSL_STUB
long wolfSSL_SSL_get_mode(WOLFSSL* ssl)
{
/* TODO: */
(void)ssl;
WOLFSSL_STUB("SSL_get_mode");
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_get_mode(WOLFSSL_CTX* ctx)
{
/* TODO: */
(void)ctx;
WOLFSSL_STUB("SSL_CTX_get_mode");
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
void wolfSSL_CTX_set_default_read_ahead(WOLFSSL_CTX* ctx, int m)
{
/* TODO: maybe? */
(void)ctx;
(void)m;
WOLFSSL_STUB("SSL_CTX_set_default_read_ahead");
}
#endif
/* returns the unsigned error value and increments the pointer into the
* error queue.
*
* file pointer to file name
* line gets set to line number of error when not NULL
*/
unsigned long wolfSSL_ERR_get_error_line(const char** file, int* line)
{
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
int ret = wc_PullErrorNode(file, NULL, line);
if (ret < 0) {
if (ret == WC_NO_ERR_TRACE(BAD_STATE_E))
return 0; /* no errors in queue */
WOLFSSL_MSG("Issue getting error node");
WOLFSSL_LEAVE("wolfSSL_ERR_get_error_line", ret);
ret = 0 - ret; /* return absolute value of error */
/* panic and try to clear out nodes */
wc_ClearErrorNodes();
}
return (unsigned long)ret;
#else
(void)file;
(void)line;
return 0;
#endif
}
#if (defined(DEBUG_WOLFSSL) || defined(OPENSSL_EXTRA)) && \
(!defined(_WIN32) && !defined(NO_ERROR_QUEUE))
static const char WOLFSSL_SYS_ACCEPT_T[] = "accept";
static const char WOLFSSL_SYS_BIND_T[] = "bind";
static const char WOLFSSL_SYS_CONNECT_T[] = "connect";
static const char WOLFSSL_SYS_FOPEN_T[] = "fopen";
static const char WOLFSSL_SYS_FREAD_T[] = "fread";
static const char WOLFSSL_SYS_GETADDRINFO_T[] = "getaddrinfo";
static const char WOLFSSL_SYS_GETSOCKOPT_T[] = "getsockopt";
static const char WOLFSSL_SYS_GETSOCKNAME_T[] = "getsockname";
static const char WOLFSSL_SYS_GETHOSTBYNAME_T[] = "gethostbyname";
static const char WOLFSSL_SYS_GETNAMEINFO_T[] = "getnameinfo";
static const char WOLFSSL_SYS_GETSERVBYNAME_T[] = "getservbyname";
static const char WOLFSSL_SYS_IOCTLSOCKET_T[] = "ioctlsocket";
static const char WOLFSSL_SYS_LISTEN_T[] = "listen";
static const char WOLFSSL_SYS_OPENDIR_T[] = "opendir";
static const char WOLFSSL_SYS_SETSOCKOPT_T[] = "setsockopt";
static const char WOLFSSL_SYS_SOCKET_T[] = "socket";
/* switch with int mapped to function name for compatibility */
static const char* wolfSSL_ERR_sys_func(int fun)
{
switch (fun) {
case WOLFSSL_SYS_ACCEPT: return WOLFSSL_SYS_ACCEPT_T;
case WOLFSSL_SYS_BIND: return WOLFSSL_SYS_BIND_T;
case WOLFSSL_SYS_CONNECT: return WOLFSSL_SYS_CONNECT_T;
case WOLFSSL_SYS_FOPEN: return WOLFSSL_SYS_FOPEN_T;
case WOLFSSL_SYS_FREAD: return WOLFSSL_SYS_FREAD_T;
case WOLFSSL_SYS_GETADDRINFO: return WOLFSSL_SYS_GETADDRINFO_T;
case WOLFSSL_SYS_GETSOCKOPT: return WOLFSSL_SYS_GETSOCKOPT_T;
case WOLFSSL_SYS_GETSOCKNAME: return WOLFSSL_SYS_GETSOCKNAME_T;
case WOLFSSL_SYS_GETHOSTBYNAME: return WOLFSSL_SYS_GETHOSTBYNAME_T;
case WOLFSSL_SYS_GETNAMEINFO: return WOLFSSL_SYS_GETNAMEINFO_T;
case WOLFSSL_SYS_GETSERVBYNAME: return WOLFSSL_SYS_GETSERVBYNAME_T;
case WOLFSSL_SYS_IOCTLSOCKET: return WOLFSSL_SYS_IOCTLSOCKET_T;
case WOLFSSL_SYS_LISTEN: return WOLFSSL_SYS_LISTEN_T;
case WOLFSSL_SYS_OPENDIR: return WOLFSSL_SYS_OPENDIR_T;
case WOLFSSL_SYS_SETSOCKOPT: return WOLFSSL_SYS_SETSOCKOPT_T;
case WOLFSSL_SYS_SOCKET: return WOLFSSL_SYS_SOCKET_T;
default:
return "NULL";
}
}
#endif /* DEBUG_WOLFSSL */
void wolfSSL_ERR_put_error(int lib, int fun, int err, const char* file,
int line)
{
WOLFSSL_ENTER("wolfSSL_ERR_put_error");
#if !defined(DEBUG_WOLFSSL) && !defined(OPENSSL_EXTRA)
(void)fun;
(void)err;
(void)file;
(void)line;
WOLFSSL_MSG("Not compiled in debug mode");
#elif defined(OPENSSL_EXTRA) && \
(defined(_WIN32) || defined(NO_ERROR_QUEUE))
(void)fun;
(void)file;
(void)line;
WOLFSSL_ERROR(err);
#else
WOLFSSL_ERROR_LINE(err, wolfSSL_ERR_sys_func(fun), (unsigned int)line,
file, NULL);
#endif
(void)lib;
}
/* Similar to wolfSSL_ERR_get_error_line but takes in a flags argument for
* more flexibility.
*
* file output pointer to file where error happened
* line output to line number of error
* data output data. Is a string if WOLFSSL_ERR_TXT_STRING flag is used
* flags output format of output
*
* Returns the error value or 0 if no errors are in the queue
*/
unsigned long wolfSSL_ERR_get_error_line_data(const char** file, int* line,
const char** data, int *flags)
{
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
int ret;
WOLFSSL_ENTER("wolfSSL_ERR_get_error_line_data");
if (flags != NULL)
*flags = WOLFSSL_ERR_TXT_STRING; /* Clear the flags */
ret = wc_PullErrorNode(file, data, line);
if (ret < 0) {
if (ret == WC_NO_ERR_TRACE(BAD_STATE_E))
return 0; /* no errors in queue */
WOLFSSL_MSG("Error with pulling error node!");
WOLFSSL_LEAVE("wolfSSL_ERR_get_error_line_data", ret);
ret = 0 - ret; /* return absolute value of error */
/* panic and try to clear out nodes */
wc_ClearErrorNodes();
}
return (unsigned long)ret;
#else
WOLFSSL_ENTER("wolfSSL_ERR_get_error_line_data");
WOLFSSL_MSG("Error queue turned off, can not get error line");
(void)file;
(void)line;
(void)data;
(void)flags;
return 0;
#endif
}
#endif /* OPENSSL_EXTRA */
#ifdef SESSION_CERTS
/* Decode the X509 DER encoded certificate into a WOLFSSL_X509 object.
*
* x509 WOLFSSL_X509 object to decode into.
* in X509 DER data.
* len Length of the X509 DER data.
* returns the new certificate on success, otherwise NULL.
*/
static int DecodeToX509(WOLFSSL_X509* x509, const byte* in, int len)
{
int ret;
WC_DECLARE_VAR(cert, DecodedCert, 1, 0);
if (x509 == NULL || in == NULL || len <= 0)
return BAD_FUNC_ARG;
WC_ALLOC_VAR_EX(cert, DecodedCert, 1, NULL, DYNAMIC_TYPE_DCERT,
return MEMORY_E);
/* Create a DecodedCert object and copy fields into WOLFSSL_X509 object.
*/
InitDecodedCert(cert, (byte*)in, (word32)len, NULL);
if ((ret = ParseCertRelative(cert, CERT_TYPE, 0, NULL, NULL)) == 0) {
/* Check if x509 was not previously initialized by wolfSSL_X509_new() */
if (x509->dynamicMemory != TRUE)
InitX509(x509, 0, NULL);
ret = CopyDecodedToX509(x509, cert);
}
FreeDecodedCert(cert);
WC_FREE_VAR_EX(cert, NULL, DYNAMIC_TYPE_DCERT);
return ret;
}
#endif /* SESSION_CERTS */
#ifdef KEEP_PEER_CERT
WOLFSSL_ABI
WOLFSSL_X509* wolfSSL_get_peer_certificate(WOLFSSL* ssl)
{
WOLFSSL_X509* ret = NULL;
WOLFSSL_ENTER("wolfSSL_get_peer_certificate");
if (ssl != NULL) {
if (ssl->peerCert.issuer.sz)
ret = wolfSSL_X509_dup(&ssl->peerCert);
#ifdef SESSION_CERTS
else if (ssl->session->chain.count > 0) {
if (DecodeToX509(&ssl->peerCert,
ssl->session->chain.certs[0].buffer,
ssl->session->chain.certs[0].length) == 0) {
ret = wolfSSL_X509_dup(&ssl->peerCert);
}
}
#endif
}
WOLFSSL_LEAVE("wolfSSL_get_peer_certificate", ret != NULL);
return ret;
}
#endif /* KEEP_PEER_CERT */
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
/* Return stack of peer certs.
* Caller does not need to free return. The stack is Free'd when WOLFSSL* ssl
* is.
*/
WOLF_STACK_OF(WOLFSSL_X509)* wolfSSL_get_peer_cert_chain(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_peer_cert_chain");
if (ssl == NULL)
return NULL;
/* Try to populate if NULL or empty */
if (ssl->peerCertChain == NULL ||
wolfSSL_sk_X509_num(ssl->peerCertChain) == 0) {
wolfSSL_set_peer_cert_chain((WOLFSSL*) ssl);
}
return ssl->peerCertChain;
}
static int x509GetIssuerFromCM(WOLFSSL_X509 **issuer, WOLFSSL_CERT_MANAGER* cm,
WOLFSSL_X509 *x);
/**
* Recursively push the issuer CA chain onto the stack
* @param cm The cert manager that is queried for the issuer
* @param x This cert's issuer will be queried in cm
* @param sk The issuer is pushed onto this stack
* @return 0 on success or no issuer found
* WOLFSSL_FATAL_ERROR on a fatal error
*/
static int PushCAx509Chain(WOLFSSL_CERT_MANAGER* cm,
WOLFSSL_X509 *x, WOLFSSL_STACK* sk)
{
int i;
for (i = 0; i < MAX_CHAIN_DEPTH; i++) {
WOLFSSL_X509* issuer = NULL;
if (x509GetIssuerFromCM(&issuer, cm, x) != WOLFSSL_SUCCESS)
break;
if (wolfSSL_sk_X509_push(sk, issuer) <= 0) {
wolfSSL_X509_free(issuer);
issuer = NULL;
return WOLFSSL_FATAL_ERROR;
}
x = issuer;
}
return 0;
}
/* Builds up and creates a stack of peer certificates for ssl->peerCertChain
or ssl->verifiedChain based off of the ssl session chain. Attempts to place
CA certificates at the bottom of the stack for a verified chain. Returns
stack of WOLFSSL_X509 certs or NULL on failure */
static WOLF_STACK_OF(WOLFSSL_X509)* CreatePeerCertChain(const WOLFSSL* ssl,
int verifiedFlag)
{
WOLFSSL_STACK* sk;
WOLFSSL_X509* x509;
int i = 0;
int err;
WOLFSSL_ENTER("wolfSSL_set_peer_cert_chain");
if ((ssl == NULL) || (ssl->session->chain.count == 0))
return NULL;
sk = wolfSSL_sk_X509_new_null();
for (i = 0; i < ssl->session->chain.count; i++) {
x509 = wolfSSL_X509_new_ex(ssl->heap);
if (x509 == NULL) {
WOLFSSL_MSG("Error Creating X509");
wolfSSL_sk_X509_pop_free(sk, NULL);
return NULL;
}
err = DecodeToX509(x509, ssl->session->chain.certs[i].buffer,
ssl->session->chain.certs[i].length);
if (err == 0 && wolfSSL_sk_X509_push(sk, x509) <= 0)
err = WOLFSSL_FATAL_ERROR;
if (err == 0 && i == ssl->session->chain.count-1 && verifiedFlag) {
/* On the last element in the verified chain try to add the CA chain
* if we have one for this cert */
SSL_CM_WARNING(ssl);
err = PushCAx509Chain(SSL_CM(ssl), x509, sk);
}
if (err != 0) {
WOLFSSL_MSG("Error decoding cert");
wolfSSL_X509_free(x509);
x509 = NULL;
wolfSSL_sk_X509_pop_free(sk, NULL);
return NULL;
}
}
if (sk == NULL) {
WOLFSSL_MSG("Null session chain");
}
return sk;
}
/* Builds up and creates a stack of peer certificates for ssl->peerCertChain
returns the stack on success and NULL on failure */
WOLF_STACK_OF(WOLFSSL_X509)* wolfSSL_set_peer_cert_chain(WOLFSSL* ssl)
{
WOLFSSL_STACK* sk;
WOLFSSL_ENTER("wolfSSL_set_peer_cert_chain");
if ((ssl == NULL) || (ssl->session->chain.count == 0))
return NULL;
sk = CreatePeerCertChain(ssl, 0);
if (sk != NULL) {
if (ssl->options.side == WOLFSSL_SERVER_END) {
if (ssl->session->peer)
wolfSSL_X509_free(ssl->session->peer);
ssl->session->peer = wolfSSL_sk_X509_shift(sk);
ssl->session->peerVerifyRet = ssl->peerVerifyRet;
}
if (ssl->peerCertChain != NULL)
wolfSSL_sk_X509_pop_free(ssl->peerCertChain, NULL);
/* This is Free'd when ssl is Free'd */
ssl->peerCertChain = sk;
}
return sk;
}
#ifdef KEEP_PEER_CERT
/**
* Implemented in a similar way that ngx_ssl_ocsp_validate does it when
* SSL_get0_verified_chain is not available.
* @param ssl WOLFSSL object to extract certs from
* @return Stack of verified certs
*/
WOLF_STACK_OF(WOLFSSL_X509) *wolfSSL_get0_verified_chain(const WOLFSSL *ssl)
{
WOLF_STACK_OF(WOLFSSL_X509)* chain = NULL;
WOLFSSL_X509_STORE_CTX* storeCtx = NULL;
WOLFSSL_X509* peerCert = NULL;
WOLFSSL_ENTER("wolfSSL_get0_verified_chain");
if (ssl == NULL || ssl->ctx == NULL) {
WOLFSSL_MSG("Bad parameter");
return NULL;
}
peerCert = wolfSSL_get_peer_certificate((WOLFSSL*)ssl);
if (peerCert == NULL) {
WOLFSSL_MSG("wolfSSL_get_peer_certificate error");
return NULL;
}
/* wolfSSL_get_peer_certificate returns a copy. We want the internal
* member so that we don't have to worry about free'ing it. We call
* wolfSSL_get_peer_certificate so that we don't have to worry about
* setting up the internal pointer. */
wolfSSL_X509_free(peerCert);
peerCert = (WOLFSSL_X509*)&ssl->peerCert;
chain = CreatePeerCertChain((WOLFSSL*)ssl, 1);
if (chain == NULL) {
WOLFSSL_MSG("wolfSSL_get_peer_cert_chain error");
return NULL;
}
if (ssl->verifiedChain != NULL) {
wolfSSL_sk_X509_pop_free(ssl->verifiedChain, NULL);
}
((WOLFSSL*)ssl)->verifiedChain = chain;
storeCtx = wolfSSL_X509_STORE_CTX_new();
if (storeCtx == NULL) {
WOLFSSL_MSG("wolfSSL_X509_STORE_CTX_new error");
return NULL;
}
if (wolfSSL_X509_STORE_CTX_init(storeCtx, SSL_STORE(ssl),
peerCert, chain) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("wolfSSL_X509_STORE_CTX_init error");
wolfSSL_X509_STORE_CTX_free(storeCtx);
return NULL;
}
if (wolfSSL_X509_verify_cert(storeCtx) <= 0) {
WOLFSSL_MSG("wolfSSL_X509_verify_cert error");
wolfSSL_X509_STORE_CTX_free(storeCtx);
return NULL;
}
wolfSSL_X509_STORE_CTX_free(storeCtx);
return chain;
}
#endif /* KEEP_PEER_CERT */
#endif /* SESSION_CERTS && OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
void wolfSSL_set_connect_state(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_set_connect_state");
if (ssl == NULL) {
WOLFSSL_MSG("WOLFSSL struct pointer passed in was null");
return;
}
#ifndef NO_DH
/* client creates its own DH parameters on handshake */
if (ssl->buffers.serverDH_P.buffer && ssl->buffers.weOwnDH) {
XFREE(ssl->buffers.serverDH_P.buffer, ssl->heap,
DYNAMIC_TYPE_PUBLIC_KEY);
}
ssl->buffers.serverDH_P.buffer = NULL;
if (ssl->buffers.serverDH_G.buffer && ssl->buffers.weOwnDH) {
XFREE(ssl->buffers.serverDH_G.buffer, ssl->heap,
DYNAMIC_TYPE_PUBLIC_KEY);
}
ssl->buffers.serverDH_G.buffer = NULL;
#endif
if (InitSSL_Side(ssl, WOLFSSL_CLIENT_END) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Error initializing client side");
}
}
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */
int wolfSSL_get_shutdown(const WOLFSSL* ssl)
{
int isShutdown = 0;
WOLFSSL_ENTER("wolfSSL_get_shutdown");
if (ssl) {
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
if (ssl->options.shutdownDone) {
/* The SSL object was possibly cleared with wolfSSL_clear after
* a successful shutdown. Simulate a response for a full
* bidirectional shutdown. */
isShutdown = WOLFSSL_SENT_SHUTDOWN | WOLFSSL_RECEIVED_SHUTDOWN;
}
else
#endif
{
/* in OpenSSL, WOLFSSL_SENT_SHUTDOWN = 1, when closeNotifySent *
* WOLFSSL_RECEIVED_SHUTDOWN = 2, from close notify or fatal err */
if (ssl->options.sentNotify)
isShutdown |= WOLFSSL_SENT_SHUTDOWN;
if (ssl->options.closeNotify||ssl->options.connReset)
isShutdown |= WOLFSSL_RECEIVED_SHUTDOWN;
}
}
WOLFSSL_LEAVE("wolfSSL_get_shutdown", isShutdown);
return isShutdown;
}
int wolfSSL_session_reused(WOLFSSL* ssl)
{
int resuming = 0;
WOLFSSL_ENTER("wolfSSL_session_reused");
if (ssl) {
#ifndef HAVE_SECURE_RENEGOTIATION
resuming = ssl->options.resuming;
#else
resuming = ssl->options.resuming || ssl->options.resumed;
#endif
}
WOLFSSL_LEAVE("wolfSSL_session_reused", resuming);
return resuming;
}
/* helper function that takes in a protocol version struct and returns string */
static const char* wolfSSL_internal_get_version(const ProtocolVersion* version)
{
WOLFSSL_ENTER("wolfSSL_get_version");
if (version == NULL) {
return "Bad arg";
}
if (version->major == SSLv3_MAJOR) {
switch (version->minor) {
case SSLv3_MINOR :
return "SSLv3";
case TLSv1_MINOR :
return "TLSv1";
case TLSv1_1_MINOR :
return "TLSv1.1";
case TLSv1_2_MINOR :
return "TLSv1.2";
case TLSv1_3_MINOR :
return "TLSv1.3";
default:
return "unknown";
}
}
#ifdef WOLFSSL_DTLS
else if (version->major == DTLS_MAJOR) {
switch (version->minor) {
case DTLS_MINOR :
return "DTLS";
case DTLSv1_2_MINOR :
return "DTLSv1.2";
case DTLSv1_3_MINOR :
return "DTLSv1.3";
default:
return "unknown";
}
}
#endif /* WOLFSSL_DTLS */
return "unknown";
}
const char* wolfSSL_get_version(const WOLFSSL* ssl)
{
if (ssl == NULL) {
WOLFSSL_MSG("Bad argument");
return "unknown";
}
return wolfSSL_internal_get_version(&ssl->version);
}
/* current library version */
const char* wolfSSL_lib_version(void)
{
return LIBWOLFSSL_VERSION_STRING;
}
#ifdef OPENSSL_EXTRA
#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
const char* wolfSSL_OpenSSL_version(int a)
{
(void)a;
return "wolfSSL " LIBWOLFSSL_VERSION_STRING;
}
#else
const char* wolfSSL_OpenSSL_version(void)
{
return "wolfSSL " LIBWOLFSSL_VERSION_STRING;
}
#endif /* WOLFSSL_QT */
#endif
/* current library version in hex */
word32 wolfSSL_lib_version_hex(void)
{
return LIBWOLFSSL_VERSION_HEX;
}
int wolfSSL_get_current_cipher_suite(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_current_cipher_suite");
if (ssl)
return (ssl->options.cipherSuite0 << 8) | ssl->options.cipherSuite;
return 0;
}
WOLFSSL_CIPHER* wolfSSL_get_current_cipher(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_current_cipher");
if (ssl) {
ssl->cipher.cipherSuite0 = ssl->options.cipherSuite0;
ssl->cipher.cipherSuite = ssl->options.cipherSuite;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
ssl->cipher.bits = ssl->specs.key_size * 8;
#endif
return &ssl->cipher;
}
else
return NULL;
}
const char* wolfSSL_CIPHER_get_name(const WOLFSSL_CIPHER* cipher)
{
WOLFSSL_ENTER("wolfSSL_CIPHER_get_name");
if (cipher == NULL) {
return NULL;
}
#if !defined(WOLFSSL_CIPHER_INTERNALNAME) && !defined(NO_ERROR_STRINGS) && \
!defined(WOLFSSL_QT)
return GetCipherNameIana(cipher->cipherSuite0, cipher->cipherSuite);
#else
return wolfSSL_get_cipher_name_from_suite(cipher->cipherSuite0,
cipher->cipherSuite);
#endif
}
const char* wolfSSL_CIPHER_get_version(const WOLFSSL_CIPHER* cipher)
{
WOLFSSL_ENTER("wolfSSL_CIPHER_get_version");
if (cipher == NULL || cipher->ssl == NULL) {
return NULL;
}
return wolfSSL_get_version(cipher->ssl);
}
const char* wolfSSL_get_cipher(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_cipher");
return wolfSSL_CIPHER_get_name(wolfSSL_get_current_cipher(ssl));
}
/* gets cipher name in the format DHE-RSA-... rather then TLS_DHE... */
const char* wolfSSL_get_cipher_name(WOLFSSL* ssl)
{
/* get access to cipher_name_idx in internal.c */
return wolfSSL_get_cipher_name_internal(ssl);
}
const char* wolfSSL_get_cipher_name_from_suite(byte cipherSuite0,
byte cipherSuite)
{
return GetCipherNameInternal(cipherSuite0, cipherSuite);
}
const char* wolfSSL_get_cipher_name_iana_from_suite(byte cipherSuite0,
byte cipherSuite)
{
return GetCipherNameIana(cipherSuite0, cipherSuite);
}
int wolfSSL_get_cipher_suite_from_name(const char* name, byte* cipherSuite0,
byte* cipherSuite, int *flags) {
if ((name == NULL) ||
(cipherSuite0 == NULL) ||
(cipherSuite == NULL) ||
(flags == NULL))
return BAD_FUNC_ARG;
return GetCipherSuiteFromName(name, cipherSuite0, cipherSuite, NULL, NULL,
flags);
}
word32 wolfSSL_CIPHER_get_id(const WOLFSSL_CIPHER* cipher)
{
word16 cipher_id = 0;
WOLFSSL_ENTER("wolfSSL_CIPHER_get_id");
if (cipher && cipher->ssl) {
cipher_id = (word16)(cipher->ssl->options.cipherSuite0 << 8) |
cipher->ssl->options.cipherSuite;
}
return cipher_id;
}
const WOLFSSL_CIPHER* wolfSSL_get_cipher_by_value(word16 value)
{
const WOLFSSL_CIPHER* cipher = NULL;
byte cipherSuite0, cipherSuite;
WOLFSSL_ENTER("wolfSSL_get_cipher_by_value");
/* extract cipher id information */
cipherSuite = (value & 0xFF);
cipherSuite0 = ((value >> 8) & 0xFF);
/* TODO: lookup by cipherSuite0 / cipherSuite */
(void)cipherSuite0;
(void)cipherSuite;
return cipher;
}
#if defined(HAVE_ECC) || defined(HAVE_CURVE25519) || defined(HAVE_CURVE448) || \
!defined(NO_DH) || (defined(WOLFSSL_TLS13) && defined(WOLFSSL_HAVE_MLKEM))
#ifdef HAVE_FFDHE
static const char* wolfssl_ffdhe_name(word16 group)
{
const char* str = NULL;
switch (group) {
case WOLFSSL_FFDHE_2048:
str = "FFDHE_2048";
break;
case WOLFSSL_FFDHE_3072:
str = "FFDHE_3072";
break;
case WOLFSSL_FFDHE_4096:
str = "FFDHE_4096";
break;
case WOLFSSL_FFDHE_6144:
str = "FFDHE_6144";
break;
case WOLFSSL_FFDHE_8192:
str = "FFDHE_8192";
break;
default:
break;
}
return str;
}
#endif
/* Return the name of the curve used for key exchange as a printable string.
*
* ssl The SSL/TLS object.
* returns NULL if ECDH was not used, otherwise the name as a string.
*/
const char* wolfSSL_get_curve_name(WOLFSSL* ssl)
{
const char* cName = NULL;
WOLFSSL_ENTER("wolfSSL_get_curve_name");
if (ssl == NULL)
return NULL;
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_HAVE_MLKEM)
/* Check for post-quantum groups. Return now because we do not want the ECC
* check to override this result in the case of a hybrid. */
if (IsAtLeastTLSv1_3(ssl->version)) {
switch (ssl->namedGroup) {
#ifndef WOLFSSL_NO_ML_KEM
#ifndef WOLFSSL_NO_ML_KEM_512
case WOLFSSL_ML_KEM_512:
return "ML_KEM_512";
#ifdef WOLFSSL_EXTRA_PQC_HYBRIDS
#ifdef WOLFSSL_ML_KEM_USE_OLD_IDS
case WOLFSSL_P256_ML_KEM_512_OLD:
return "P256_ML_KEM_512_OLD";
#endif /* WOLFSSL_ML_KEM_USE_OLD_IDS */
case WOLFSSL_SECP256R1MLKEM512:
return "SecP256r1MLKEM512";
#ifdef HAVE_CURVE25519
case WOLFSSL_X25519MLKEM512:
return "X25519MLKEM512";
#endif /* HAVE_CURVE25519 */
#endif /* WOLFSSL_EXTRA_PQC_HYBRIDS */
#endif /* WOLFSSL_NO_ML_KEM_512 */
#ifndef WOLFSSL_NO_ML_KEM_768
case WOLFSSL_ML_KEM_768:
return "ML_KEM_768";
#ifdef WOLFSSL_PQC_HYBRIDS
case WOLFSSL_SECP256R1MLKEM768:
return "SecP256r1MLKEM768";
#ifdef HAVE_CURVE25519
case WOLFSSL_X25519MLKEM768:
return "X25519MLKEM768";
#endif
#endif /* WOLFSSL_PQC_HYBRIDS */
#ifdef WOLFSSL_EXTRA_PQC_HYBRIDS
#ifdef WOLFSSL_ML_KEM_USE_OLD_IDS
case WOLFSSL_P384_ML_KEM_768_OLD:
return "P384_ML_KEM_768_OLD";
#endif /* WOLFSSL_ML_KEM_USE_OLD_IDS */
case WOLFSSL_SECP384R1MLKEM768:
return "SecP384r1MLKEM768";
#ifdef HAVE_CURVE448
case WOLFSSL_X448MLKEM768:
return "X448MLKEM768";
#endif /* HAVE_CURVE448 */
#endif /* WOLFSSL_EXTRA_PQC_HYBRIDS */
#endif /* WOLFSSL_NO_ML_KEM_768 */
#ifndef WOLFSSL_NO_ML_KEM_1024
case WOLFSSL_ML_KEM_1024:
return "ML_KEM_1024";
#ifdef WOLFSSL_PQC_HYBRIDS
case WOLFSSL_SECP384R1MLKEM1024:
return "SecP384r1MLKEM1024";
#endif /* WOLFSSL_PQC_HYBRIDS */
#ifdef WOLFSSL_EXTRA_PQC_HYBRIDS
#ifdef WOLFSSL_ML_KEM_USE_OLD_IDS
case WOLFSSL_P521_ML_KEM_1024_OLD:
return "P521_ML_KEM_1024_OLD";
#endif /* WOLFSSL_ML_KEM_USE_OLD_IDS */
case WOLFSSL_SECP521R1MLKEM1024:
return "SecP521r1MLKEM1024";
#endif /* WOLFSSL_EXTRA_PQC_HYBRIDS */
#endif /* WOLFSSL_NO_ML_KEM_1024 */
#endif /* WOLFSSL_NO_ML_KEM */
#ifdef WOLFSSL_MLKEM_KYBER
#ifndef WOLFSSL_NO_KYBER512
case WOLFSSL_KYBER_LEVEL1:
return "KYBER_LEVEL1";
case WOLFSSL_P256_KYBER_LEVEL1:
return "P256_KYBER_LEVEL1";
#ifdef HAVE_CURVE25519
case WOLFSSL_X25519_KYBER_LEVEL1:
return "X25519_KYBER_LEVEL1";
#endif
#endif
#ifndef WOLFSSL_NO_KYBER768
case WOLFSSL_KYBER_LEVEL3:
return "KYBER_LEVEL3";
case WOLFSSL_P384_KYBER_LEVEL3:
return "P384_KYBER_LEVEL3";
case WOLFSSL_P256_KYBER_LEVEL3:
return "P256_KYBER_LEVEL3";
#ifdef HAVE_CURVE25519
case WOLFSSL_X25519_KYBER_LEVEL3:
return "X25519_KYBER_LEVEL3";
#endif
#ifdef HAVE_CURVE448
case WOLFSSL_X448_KYBER_LEVEL3:
return "X448_KYBER_LEVEL3";
#endif
#endif
#ifndef WOLFSSL_NO_KYBER1024
case WOLFSSL_KYBER_LEVEL5:
return "KYBER_LEVEL5";
case WOLFSSL_P521_KYBER_LEVEL5:
return "P521_KYBER_LEVEL5";
#endif
#endif /* WOLFSSL_MLKEM_KYBER */
}
}
#endif /* WOLFSSL_TLS13 && WOLFSSL_HAVE_MLKEM */
#ifdef HAVE_FFDHE
if (ssl->namedGroup != 0) {
cName = wolfssl_ffdhe_name(ssl->namedGroup);
}
#endif
#ifdef HAVE_CURVE25519
if (ssl->ecdhCurveOID == ECC_X25519_OID && cName == NULL) {
cName = "X25519";
}
#endif
#ifdef HAVE_CURVE448
if (ssl->ecdhCurveOID == ECC_X448_OID && cName == NULL) {
cName = "X448";
}
#endif
#ifdef HAVE_ECC
if (ssl->ecdhCurveOID != 0 && cName == NULL) {
cName = wc_ecc_get_name(wc_ecc_get_oid(ssl->ecdhCurveOID, NULL,
NULL));
}
#endif
return cName;
}
#endif
#ifdef OPENSSL_EXTRA
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
/* return authentication NID corresponding to cipher suite
* @param cipher a pointer to WOLFSSL_CIPHER
* return NID if found, WC_NID_undef if not found
*/
int wolfSSL_CIPHER_get_auth_nid(const WOLFSSL_CIPHER* cipher)
{
static const struct authnid {
const char* alg_name;
const int nid;
} authnid_tbl[] = {
{"RSA", WC_NID_auth_rsa},
{"PSK", WC_NID_auth_psk},
{"SRP", WC_NID_auth_srp},
{"ECDSA", WC_NID_auth_ecdsa},
{"None", WC_NID_auth_null},
{NULL, WC_NID_undef}
};
const char* authStr;
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
if (GetCipherSegment(cipher, n) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WC_NID_undef;
}
authStr = GetCipherAuthStr(n);
if (authStr != NULL) {
const struct authnid* sa;
for(sa = authnid_tbl; sa->alg_name != NULL; sa++) {
if (XSTRCMP(sa->alg_name, authStr) == 0) {
return sa->nid;
}
}
}
return WC_NID_undef;
}
/* return cipher NID corresponding to cipher suite
* @param cipher a pointer to WOLFSSL_CIPHER
* return NID if found, WC_NID_undef if not found
*/
int wolfSSL_CIPHER_get_cipher_nid(const WOLFSSL_CIPHER* cipher)
{
static const struct ciphernid {
const char* alg_name;
const int nid;
} ciphernid_tbl[] = {
{"AESGCM(256)", WC_NID_aes_256_gcm},
{"AESGCM(128)", WC_NID_aes_128_gcm},
{"AESCCM(128)", WC_NID_aes_128_ccm},
{"AES(128)", WC_NID_aes_128_cbc},
{"AES(256)", WC_NID_aes_256_cbc},
{"CAMELLIA(256)", WC_NID_camellia_256_cbc},
{"CAMELLIA(128)", WC_NID_camellia_128_cbc},
{"RC4", WC_NID_rc4},
{"3DES", WC_NID_des_ede3_cbc},
{"CHACHA20/POLY1305(256)", WC_NID_chacha20_poly1305},
{"None", WC_NID_undef},
{NULL, WC_NID_undef}
};
const char* encStr;
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
WOLFSSL_ENTER("wolfSSL_CIPHER_get_cipher_nid");
if (GetCipherSegment(cipher, n) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WC_NID_undef;
}
encStr = GetCipherEncStr(n);
if (encStr != NULL) {
const struct ciphernid* c;
for(c = ciphernid_tbl; c->alg_name != NULL; c++) {
if (XSTRCMP(c->alg_name, encStr) == 0) {
return c->nid;
}
}
}
return WC_NID_undef;
}
/* return digest NID corresponding to cipher suite
* @param cipher a pointer to WOLFSSL_CIPHER
* return NID if found, WC_NID_undef if not found
*/
int wolfSSL_CIPHER_get_digest_nid(const WOLFSSL_CIPHER* cipher)
{
static const struct macnid {
const char* alg_name;
const int nid;
} macnid_tbl[] = {
{"SHA1", WC_NID_sha1},
{"SHA256", WC_NID_sha256},
{"SHA384", WC_NID_sha384},
{NULL, WC_NID_undef}
};
const char* name;
const char* macStr;
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
(void)name;
WOLFSSL_ENTER("wolfSSL_CIPHER_get_digest_nid");
if ((name = GetCipherSegment(cipher, n)) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WC_NID_undef;
}
/* in MD5 case, NID will be WC_NID_md5 */
if (XSTRSTR(name, "MD5") != NULL) {
return WC_NID_md5;
}
macStr = GetCipherMacStr(n);
if (macStr != NULL) {
const struct macnid* mc;
for(mc = macnid_tbl; mc->alg_name != NULL; mc++) {
if (XSTRCMP(mc->alg_name, macStr) == 0) {
return mc->nid;
}
}
}
return WC_NID_undef;
}
/* return key exchange NID corresponding to cipher suite
* @param cipher a pointer to WOLFSSL_CIPHER
* return NID if found, WC_NID_undef if not found
*/
int wolfSSL_CIPHER_get_kx_nid(const WOLFSSL_CIPHER* cipher)
{
static const struct kxnid {
const char* name;
const int nid;
} kxnid_table[] = {
{"ECDHEPSK", WC_NID_kx_ecdhe_psk},
{"ECDH", WC_NID_kx_ecdhe},
{"DHEPSK", WC_NID_kx_dhe_psk},
{"DH", WC_NID_kx_dhe},
{"RSAPSK", WC_NID_kx_rsa_psk},
{"SRP", WC_NID_kx_srp},
{"EDH", WC_NID_kx_dhe},
{"PSK", WC_NID_kx_psk},
{"RSA", WC_NID_kx_rsa},
{NULL, WC_NID_undef}
};
const char* keaStr;
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
WOLFSSL_ENTER("wolfSSL_CIPHER_get_kx_nid");
if (GetCipherSegment(cipher, n) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WC_NID_undef;
}
/* in TLS 1.3 case, NID will be WC_NID_kx_any */
if (XSTRCMP(n[0], "TLS13") == 0) {
return WC_NID_kx_any;
}
keaStr = GetCipherKeaStr(n);
if (keaStr != NULL) {
const struct kxnid* k;
for(k = kxnid_table; k->name != NULL; k++) {
if (XSTRCMP(k->name, keaStr) == 0) {
return k->nid;
}
}
}
return WC_NID_undef;
}
/* check if cipher suite is AEAD
* @param cipher a pointer to WOLFSSL_CIPHER
* return 1 if cipher is AEAD, 0 otherwise
*/
int wolfSSL_CIPHER_is_aead(const WOLFSSL_CIPHER* cipher)
{
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
WOLFSSL_ENTER("wolfSSL_CIPHER_is_aead");
if (GetCipherSegment(cipher, n) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WC_NID_undef;
}
return IsCipherAEAD(n);
}
/* Creates cipher->description based on cipher->offset
* cipher->offset is set in wolfSSL_get_ciphers_compat when it is added
* to a stack of ciphers.
* @param [in] cipher: A cipher from a stack of ciphers.
* return WOLFSSL_SUCCESS if cipher->description is set, else WOLFSSL_FAILURE
*/
int wolfSSL_sk_CIPHER_description(WOLFSSL_CIPHER* cipher)
{
int strLen;
unsigned long offset;
char* dp;
const char* name;
const char *keaStr, *authStr, *encStr, *macStr, *protocol;
char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
int len = MAX_DESCRIPTION_SZ-1;
const CipherSuiteInfo* cipher_names;
ProtocolVersion pv;
WOLFSSL_ENTER("wolfSSL_sk_CIPHER_description");
if (cipher == NULL)
return WOLFSSL_FAILURE;
dp = cipher->description;
if (dp == NULL)
return WOLFSSL_FAILURE;
cipher_names = GetCipherNames();
offset = cipher->offset;
if (offset >= (unsigned long)GetCipherNamesSize())
return WOLFSSL_FAILURE;
pv.major = cipher_names[offset].major;
pv.minor = cipher_names[offset].minor;
protocol = wolfSSL_internal_get_version(&pv);
if ((name = GetCipherSegment(cipher, n)) == NULL) {
WOLFSSL_MSG("no suitable cipher name found");
return WOLFSSL_FAILURE;
}
/* keaStr */
keaStr = GetCipherKeaStr(n);
/* authStr */
authStr = GetCipherAuthStr(n);
/* encStr */
encStr = GetCipherEncStr(n);
if ((cipher->bits = SetCipherBits(encStr)) ==
WC_NO_ERR_TRACE(WOLFSSL_FAILURE))
{
WOLFSSL_MSG("Cipher Bits Not Set.");
}
/* macStr */
macStr = GetCipherMacStr(n);
/* Build up the string by copying onto the end. */
XSTRNCPY(dp, name, (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, " ", (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, protocol, (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, " Kx=", (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, keaStr, (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, " Au=", (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, authStr, (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, " Enc=", (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, encStr, (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += strLen;
XSTRNCPY(dp, " Mac=", (size_t)len);
dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
len -= strLen; dp += (size_t)strLen;
XSTRNCPY(dp, macStr, (size_t)len);
dp[len-1] = '\0';
return WOLFSSL_SUCCESS;
}
#endif /* OPENSSL_ALL || WOLFSSL_QT */
static WC_INLINE const char* wolfssl_kea_to_string(int kea)
{
const char* keaStr;
switch (kea) {
case no_kea:
keaStr = "None";
break;
#ifndef NO_RSA
case rsa_kea:
keaStr = "RSA";
break;
#endif
#ifndef NO_DH
case diffie_hellman_kea:
keaStr = "DHE";
break;
#endif
case fortezza_kea:
keaStr = "FZ";
break;
#ifndef NO_PSK
case psk_kea:
keaStr = "PSK";
break;
#ifndef NO_DH
case dhe_psk_kea:
keaStr = "DHEPSK";
break;
#endif
#ifdef HAVE_ECC
case ecdhe_psk_kea:
keaStr = "ECDHEPSK";
break;
#endif
#endif
#ifdef HAVE_ECC
case ecc_diffie_hellman_kea:
keaStr = "ECDHE";
break;
case ecc_static_diffie_hellman_kea:
keaStr = "ECDH";
break;
#endif
case any_kea:
keaStr = "any";
break;
default:
keaStr = "unknown";
break;
}
return keaStr;
}
static WC_INLINE const char* wolfssl_sigalg_to_string(int sig_algo)
{
const char* authStr;
switch (sig_algo) {
case anonymous_sa_algo:
authStr = "None";
break;
#ifndef NO_RSA
case rsa_sa_algo:
authStr = "RSA";
break;
#ifdef WC_RSA_PSS
case rsa_pss_sa_algo:
authStr = "RSA-PSS";
break;
#endif
#endif
#ifndef NO_DSA
case dsa_sa_algo:
authStr = "DSA";
break;
#endif
#ifdef HAVE_ECC
case ecc_dsa_sa_algo:
authStr = "ECDSA";
break;
#endif
#ifdef WOLFSSL_SM2
case sm2_sa_algo:
authStr = "SM2";
break;
#endif
#ifdef HAVE_ED25519
case ed25519_sa_algo:
authStr = "Ed25519";
break;
#endif
#ifdef HAVE_ED448
case ed448_sa_algo:
authStr = "Ed448";
break;
#endif
case any_sa_algo:
authStr = "any";
break;
default:
authStr = "unknown";
break;
}
return authStr;
}
static WC_INLINE const char* wolfssl_cipher_to_string(int cipher, int key_size)
{
const char* encStr;
(void)key_size;
switch (cipher) {
case wolfssl_cipher_null:
encStr = "None";
break;
#ifndef NO_RC4
case wolfssl_rc4:
encStr = "RC4(128)";
break;
#endif
#ifndef NO_DES3
case wolfssl_triple_des:
encStr = "3DES(168)";
break;
#endif
#ifndef NO_AES
case wolfssl_aes:
if (key_size == AES_128_KEY_SIZE)
encStr = "AES(128)";
else if (key_size == AES_256_KEY_SIZE)
encStr = "AES(256)";
else
encStr = "AES(?)";
break;
#ifdef HAVE_AESGCM
case wolfssl_aes_gcm:
if (key_size == AES_128_KEY_SIZE)
encStr = "AESGCM(128)";
else if (key_size == AES_256_KEY_SIZE)
encStr = "AESGCM(256)";
else
encStr = "AESGCM(?)";
break;
#endif
#ifdef HAVE_AESCCM
case wolfssl_aes_ccm:
if (key_size == AES_128_KEY_SIZE)
encStr = "AESCCM(128)";
else if (key_size == AES_256_KEY_SIZE)
encStr = "AESCCM(256)";
else
encStr = "AESCCM(?)";
break;
#endif
#endif
#ifdef HAVE_CHACHA
case wolfssl_chacha:
encStr = "CHACHA20/POLY1305(256)";
break;
#endif
#ifdef HAVE_ARIA
case wolfssl_aria_gcm:
if (key_size == ARIA_128_KEY_SIZE)
encStr = "Aria(128)";
else if (key_size == ARIA_192_KEY_SIZE)
encStr = "Aria(192)";
else if (key_size == ARIA_256_KEY_SIZE)
encStr = "Aria(256)";
else
encStr = "Aria(?)";
break;
#endif
#ifdef HAVE_CAMELLIA
case wolfssl_camellia:
if (key_size == CAMELLIA_128_KEY_SIZE)
encStr = "Camellia(128)";
else if (key_size == CAMELLIA_256_KEY_SIZE)
encStr = "Camellia(256)";
else
encStr = "Camellia(?)";
break;
#endif
default:
encStr = "unknown";
break;
}
return encStr;
}
static WC_INLINE const char* wolfssl_mac_to_string(int mac)
{
const char* macStr;
switch (mac) {
case no_mac:
macStr = "None";
break;
#ifndef NO_MD5
case md5_mac:
macStr = "MD5";
break;
#endif
#ifndef NO_SHA
case sha_mac:
macStr = "SHA1";
break;
#endif
#ifdef WOLFSSL_SHA224
case sha224_mac:
macStr = "SHA224";
break;
#endif
#ifndef NO_SHA256
case sha256_mac:
macStr = "SHA256";
break;
#endif
#ifdef WOLFSSL_SHA384
case sha384_mac:
macStr = "SHA384";
break;
#endif
#ifdef WOLFSSL_SHA512
case sha512_mac:
macStr = "SHA512";
break;
#endif
default:
macStr = "unknown";
break;
}
return macStr;
}
char* wolfSSL_CIPHER_description(const WOLFSSL_CIPHER* cipher, char* in,
int len)
{
char *ret = in;
const char *keaStr, *authStr, *encStr, *macStr;
size_t strLen;
WOLFSSL_ENTER("wolfSSL_CIPHER_description");
if (cipher == NULL || in == NULL)
return NULL;
#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
/* if cipher is in the stack from wolfSSL_get_ciphers_compat then
* Return the description based on cipher_names[cipher->offset]
*/
if (cipher->in_stack == TRUE) {
wolfSSL_sk_CIPHER_description((WOLFSSL_CIPHER*)cipher);
XSTRNCPY(in,cipher->description,(size_t)len);
return ret;
}
#endif
/* Get the cipher description based on the SSL session cipher */
keaStr = wolfssl_kea_to_string(cipher->ssl->specs.kea);
authStr = wolfssl_sigalg_to_string(cipher->ssl->specs.sig_algo);
encStr = wolfssl_cipher_to_string(cipher->ssl->specs.bulk_cipher_algorithm,
cipher->ssl->specs.key_size);
if (cipher->ssl->specs.cipher_type == aead)
macStr = "AEAD";
else
macStr = wolfssl_mac_to_string(cipher->ssl->specs.mac_algorithm);
/* Build up the string by copying onto the end. */
XSTRNCPY(in, wolfSSL_CIPHER_get_name(cipher), (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, " ", (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, wolfSSL_get_version(cipher->ssl), (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, " Kx=", (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, keaStr, (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, " Au=", (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, authStr, (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, " Enc=", (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, encStr, (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, " Mac=", (size_t)len);
in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
XSTRNCPY(in, macStr, (size_t)len);
in[len-1] = '\0';
return ret;
}
int wolfSSL_OCSP_parse_url(const char* url, char** host, char** port,
char** path, int* ssl)
{
const char* u;
const char* upath; /* path in u */
const char* uport; /* port in u */
const char* hostEnd;
WOLFSSL_ENTER("OCSP_parse_url");
if (url == NULL || host == NULL || port == NULL || path == NULL ||
ssl == NULL) {
return WOLFSSL_FAILURE;
}
u = url;
*host = NULL;
*port = NULL;
*path = NULL;
*ssl = 0;
if (*(u++) != 'h') goto err;
if (*(u++) != 't') goto err;
if (*(u++) != 't') goto err;
if (*(u++) != 'p') goto err;
if (*u == 's') {
*ssl = 1;
u++;
*port = CopyString("443", -1, NULL, DYNAMIC_TYPE_OPENSSL);
}
else if (*u == ':') {
*ssl = 0;
*port = CopyString("80", -1, NULL, DYNAMIC_TYPE_OPENSSL);
}
else
goto err;
if (*port == NULL)
goto err;
if (*(u++) != ':') goto err;
if (*(u++) != '/') goto err;
if (*(u++) != '/') goto err;
/* Look for path */
upath = XSTRSTR(u, "/");
*path = CopyString(upath == NULL ? "/" : upath, -1, NULL,
DYNAMIC_TYPE_OPENSSL);
/* Look for port */
uport = XSTRSTR(u, ":");
if (uport != NULL) {
if (*(++uport) == '\0')
goto err;
/* port must be before path */
if (upath != NULL && uport >= upath)
goto err;
XFREE(*port, NULL, DYNAMIC_TYPE_OPENSSL);
if (upath)
*port = CopyString(uport, (int)(upath - uport), NULL,
DYNAMIC_TYPE_OPENSSL);
else
*port = CopyString(uport, -1, NULL, DYNAMIC_TYPE_OPENSSL);
if (*port == NULL)
goto err;
hostEnd = uport - 1;
}
else
hostEnd = upath;
if (hostEnd)
*host = CopyString(u, (int)(hostEnd - u), NULL, DYNAMIC_TYPE_OPENSSL);
else
*host = CopyString(u, -1, NULL, DYNAMIC_TYPE_OPENSSL);
if (*host == NULL)
goto err;
return WOLFSSL_SUCCESS;
err:
XFREE(*host, NULL, DYNAMIC_TYPE_OPENSSL);
*host = NULL;
XFREE(*port, NULL, DYNAMIC_TYPE_OPENSSL);
*port = NULL;
XFREE(*path, NULL, DYNAMIC_TYPE_OPENSSL);
*path = NULL;
return WOLFSSL_FAILURE;
}
#ifndef NO_WOLFSSL_STUB
WOLFSSL_COMP_METHOD* wolfSSL_COMP_zlib(void)
{
WOLFSSL_STUB("COMP_zlib");
return 0;
}
WOLFSSL_COMP_METHOD* wolfSSL_COMP_rle(void)
{
WOLFSSL_STUB("COMP_rle");
return 0;
}
int wolfSSL_COMP_add_compression_method(int method, void* data)
{
(void)method;
(void)data;
WOLFSSL_STUB("COMP_add_compression_method");
return 0;
}
const WOLFSSL_COMP_METHOD* wolfSSL_get_current_compression(const WOLFSSL *ssl) {
(void)ssl;
return NULL;
}
const WOLFSSL_COMP_METHOD* wolfSSL_get_current_expansion(const WOLFSSL *ssl) {
(void)ssl;
return NULL;
}
const char* wolfSSL_COMP_get_name(const WOLFSSL_COMP_METHOD *comp)
{
static const char ret[] = "not supported";
(void)comp;
WOLFSSL_STUB("wolfSSL_COMP_get_name");
return ret;
}
#endif
/* wolfSSL_set_dynlock_create_callback
* CRYPTO_set_dynlock_create_callback has been deprecated since openSSL 1.0.1.
* This function exists for compatibility purposes because wolfSSL satisfies
* thread safety without relying on the callback.
*/
void wolfSSL_set_dynlock_create_callback(WOLFSSL_dynlock_value* (*f)(
const char*, int))
{
WOLFSSL_STUB("CRYPTO_set_dynlock_create_callback");
(void)f;
}
/* wolfSSL_set_dynlock_lock_callback
* CRYPTO_set_dynlock_lock_callback has been deprecated since openSSL 1.0.1.
* This function exists for compatibility purposes because wolfSSL satisfies
* thread safety without relying on the callback.
*/
void wolfSSL_set_dynlock_lock_callback(
void (*f)(int, WOLFSSL_dynlock_value*, const char*, int))
{
WOLFSSL_STUB("CRYPTO_set_set_dynlock_lock_callback");
(void)f;
}
/* wolfSSL_set_dynlock_destroy_callback
* CRYPTO_set_dynlock_destroy_callback has been deprecated since openSSL 1.0.1.
* This function exists for compatibility purposes because wolfSSL satisfies
* thread safety without relying on the callback.
*/
void wolfSSL_set_dynlock_destroy_callback(
void (*f)(WOLFSSL_dynlock_value*, const char*, int))
{
WOLFSSL_STUB("CRYPTO_set_set_dynlock_destroy_callback");
(void)f;
}
/* Sets the DNS hostname to name.
* Hostname is cleared if name is NULL or empty. */
int wolfSSL_set1_host(WOLFSSL * ssl, const char* name)
{
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
return wolfSSL_X509_VERIFY_PARAM_set1_host(ssl->param, name, 0);
}
/******************************************************************************
* wolfSSL_CTX_set1_param - set a pointer to the SSL verification parameters
*
* RETURNS:
* WOLFSSL_SUCCESS on success, otherwise returns WOLFSSL_FAILURE
* Note: Returns WOLFSSL_SUCCESS, in case either parameter is NULL,
* same as openssl.
*/
int wolfSSL_CTX_set1_param(WOLFSSL_CTX* ctx, WOLFSSL_X509_VERIFY_PARAM *vpm)
{
if (ctx == NULL || vpm == NULL)
return WOLFSSL_SUCCESS;
return wolfSSL_X509_VERIFY_PARAM_set1(ctx->param, vpm);
}
/******************************************************************************
* wolfSSL_CTX/_get0_param - return a pointer to the SSL verification parameters
*
* RETURNS:
* returns pointer to the SSL verification parameters on success,
* otherwise returns NULL
*/
WOLFSSL_X509_VERIFY_PARAM* wolfSSL_CTX_get0_param(WOLFSSL_CTX* ctx)
{
if (ctx == NULL) {
return NULL;
}
return ctx->param;
}
WOLFSSL_X509_VERIFY_PARAM* wolfSSL_get0_param(WOLFSSL* ssl)
{
if (ssl == NULL) {
return NULL;
}
return ssl->param;
}
#endif /* OPENSSL_EXTRA */
#ifdef OPENSSL_EXTRA
/* Sets a function callback that will send information about the state of all
* WOLFSSL objects that have been created by the WOLFSSL_CTX structure passed
* in.
*
* ctx WOLFSSL_CTX structure to set callback function in
* f callback function to use
*/
void wolfSSL_CTX_set_info_callback(WOLFSSL_CTX* ctx,
void (*f)(const WOLFSSL* ssl, int type, int val))
{
WOLFSSL_ENTER("wolfSSL_CTX_set_info_callback");
if (ctx == NULL) {
WOLFSSL_MSG("Bad function argument");
}
else {
ctx->CBIS = f;
}
}
void wolfSSL_set_info_callback(WOLFSSL* ssl,
void (*f)(const WOLFSSL* ssl, int type, int val))
{
WOLFSSL_ENTER("wolfSSL_set_info_callback");
if (ssl == NULL) {
WOLFSSL_MSG("Bad function argument");
}
else {
ssl->CBIS = f;
}
}
unsigned long wolfSSL_ERR_peek_error(void)
{
WOLFSSL_ENTER("wolfSSL_ERR_peek_error");
return wolfSSL_ERR_peek_error_line_data(NULL, NULL, NULL, NULL);
}
#ifdef WOLFSSL_DEBUG_TRACE_ERROR_CODES_H
#include <wolfssl/debug-untrace-error-codes.h>
#endif
int wolfSSL_ERR_GET_LIB(unsigned long err)
{
unsigned long value;
value = (err & 0xFFFFFFL);
switch (value) {
case -PARSE_ERROR:
return WOLFSSL_ERR_LIB_SSL;
case -ASN_NO_PEM_HEADER:
case -WOLFSSL_PEM_R_NO_START_LINE_E:
case -WOLFSSL_PEM_R_PROBLEMS_GETTING_PASSWORD_E:
case -WOLFSSL_PEM_R_BAD_PASSWORD_READ_E:
case -WOLFSSL_PEM_R_BAD_DECRYPT_E:
return WOLFSSL_ERR_LIB_PEM;
case -WOLFSSL_EVP_R_BAD_DECRYPT_E:
case -WOLFSSL_EVP_R_BN_DECODE_ERROR:
case -WOLFSSL_EVP_R_DECODE_ERROR:
case -WOLFSSL_EVP_R_PRIVATE_KEY_DECODE_ERROR:
return WOLFSSL_ERR_LIB_EVP;
case -WOLFSSL_ASN1_R_HEADER_TOO_LONG_E:
return WOLFSSL_ERR_LIB_ASN1;
default:
return 0;
}
}
#ifdef WOLFSSL_DEBUG_TRACE_ERROR_CODES
#include <wolfssl/debug-trace-error-codes.h>
#endif
/* This function is to find global error values that are the same through out
* all library version. With wolfSSL having only one set of error codes the
* return value is pretty straight forward. The only thing needed is all wolfSSL
* error values are typically negative.
*
* Returns the error reason
*/
int wolfSSL_ERR_GET_REASON(unsigned long err)
{
int ret = (int)err;
WOLFSSL_ENTER("wolfSSL_ERR_GET_REASON");
#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)
/* Nginx looks for this error to know to stop parsing certificates.
* Same for HAProxy. */
if ((err == (unsigned long)((ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE)) ||
((err & 0xFFFFFFL) == (unsigned long)(-WC_NO_ERR_TRACE(ASN_NO_PEM_HEADER))) ||
((err & 0xFFFL) == (unsigned long)PEM_R_NO_START_LINE))
return PEM_R_NO_START_LINE;
if (err == (unsigned long)((ERR_LIB_SSL << 24) | -SSL_R_HTTP_REQUEST))
return SSL_R_HTTP_REQUEST;
#endif
#if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
if (err == (unsigned long)((ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG))
return ASN1_R_HEADER_TOO_LONG;
#endif
/* check if error value is in range of wolfCrypt or wolfSSL errors */
ret = 0 - ret; /* setting as negative value */
if ((ret <= WC_SPAN1_FIRST_E && ret >= WC_SPAN1_LAST_E) ||
(ret <= WC_SPAN2_FIRST_E && ret >= WC_SPAN2_LAST_E) ||
(ret <= WOLFSSL_FIRST_E && ret >= WOLFSSL_LAST_E))
{
return ret;
}
else {
WOLFSSL_MSG("Not in range of typical error values");
ret = (int)err;
}
return ret;
}
#ifndef NO_TLS
/* returns a string that describes the alert
*
* alertID the alert value to look up
*/
const char* wolfSSL_alert_type_string_long(int alertID)
{
WOLFSSL_ENTER("wolfSSL_alert_type_string_long");
return AlertTypeToString(alertID);
}
const char* wolfSSL_alert_type_string(int alertID)
{
WOLFSSL_ENTER("wolfSSL_alert_type_string");
switch (alertID) {
case alert_warning:
return "W";
case alert_fatal:
return "F";
default:
return "U";
}
}
const char* wolfSSL_alert_desc_string_long(int alertID)
{
WOLFSSL_ENTER("wolfSSL_alert_desc_string_long");
return AlertTypeToString(alertID);
}
const char* wolfSSL_alert_desc_string(int alertID)
{
WOLFSSL_ENTER("wolfSSL_alert_desc_string");
switch (alertID) {
case close_notify:
return "CN";
case unexpected_message:
return "UM";
case bad_record_mac:
return "BM";
case record_overflow:
return "RO";
case decompression_failure:
return "DF";
case handshake_failure:
return "HF";
case no_certificate:
return "NC";
case bad_certificate:
return "BC";
case unsupported_certificate:
return "UC";
case certificate_revoked:
return "CR";
case certificate_expired:
return "CE";
case certificate_unknown:
return "CU";
case illegal_parameter:
return "IP";
case unknown_ca:
return "CA";
case access_denied:
return "AD";
case decode_error:
return "DE";
case decrypt_error:
return "DC";
case wolfssl_alert_protocol_version:
return "PV";
case insufficient_security:
return "IS";
case internal_error:
return "IE";
case inappropriate_fallback:
return "IF";
case user_canceled:
return "US";
case no_renegotiation:
return "NR";
case missing_extension:
return "ME";
case unsupported_extension:
return "UE";
case unrecognized_name:
return "UN";
case bad_certificate_status_response:
return "BR";
case unknown_psk_identity:
return "UP";
case certificate_required:
return "CQ";
case no_application_protocol:
return "AP";
default:
return "UK";
}
}
#endif /* !NO_TLS */
#define STATE_STRINGS_PROTO(s) \
{ \
{"SSLv3 " s, \
"SSLv3 " s, \
"SSLv3 " s}, \
{"TLSv1 " s, \
"TLSv1 " s, \
"TLSv1 " s}, \
{"TLSv1_1 " s, \
"TLSv1_1 " s, \
"TLSv1_1 " s}, \
{"TLSv1_2 " s, \
"TLSv1_2 " s, \
"TLSv1_2 " s}, \
{"TLSv1_3 " s, \
"TLSv1_3 " s, \
"TLSv1_3 " s}, \
{"DTLSv1 " s, \
"DTLSv1 " s, \
"DTLSv1 " s}, \
{"DTLSv1_2 " s, \
"DTLSv1_2 " s, \
"DTLSv1_2 " s}, \
{"DTLSv1_3 " s, \
"DTLSv1_3 " s, \
"DTLSv1_3 " s}, \
}
#define STATE_STRINGS_PROTO_RW(s) \
{ \
{"SSLv3 read " s, \
"SSLv3 write " s, \
"SSLv3 " s}, \
{"TLSv1 read " s, \
"TLSv1 write " s, \
"TLSv1 " s}, \
{"TLSv1_1 read " s, \
"TLSv1_1 write " s, \
"TLSv1_1 " s}, \
{"TLSv1_2 read " s, \
"TLSv1_2 write " s, \
"TLSv1_2 " s}, \
{"TLSv1_3 read " s, \
"TLSv1_3 write " s, \
"TLSv1_3 " s}, \
{"DTLSv1 read " s, \
"DTLSv1 write " s, \
"DTLSv1 " s}, \
{"DTLSv1_2 read " s, \
"DTLSv1_2 write " s, \
"DTLSv1_2 " s}, \
{"DTLSv1_3 read " s, \
"DTLSv1_3 write " s, \
"DTLSv1_3 " s}, \
}
/* Gets the current state of the WOLFSSL structure
*
* ssl WOLFSSL structure to get state of
*
* Returns a human readable string of the WOLFSSL structure state
*/
const char* wolfSSL_state_string_long(const WOLFSSL* ssl)
{
static const char* OUTPUT_STR[24][8][3] = {
STATE_STRINGS_PROTO("Initialization"),
STATE_STRINGS_PROTO_RW("Server Hello Request"),
STATE_STRINGS_PROTO_RW("Server Hello Verify Request"),
STATE_STRINGS_PROTO_RW("Server Hello Retry Request"),
STATE_STRINGS_PROTO_RW("Server Hello"),
STATE_STRINGS_PROTO_RW("Server Certificate Status"),
STATE_STRINGS_PROTO_RW("Server Encrypted Extensions"),
STATE_STRINGS_PROTO_RW("Server Session Ticket"),
STATE_STRINGS_PROTO_RW("Server Certificate Request"),
STATE_STRINGS_PROTO_RW("Server Cert"),
STATE_STRINGS_PROTO_RW("Server Key Exchange"),
STATE_STRINGS_PROTO_RW("Server Hello Done"),
STATE_STRINGS_PROTO_RW("Server Change CipherSpec"),
STATE_STRINGS_PROTO_RW("Server Finished"),
STATE_STRINGS_PROTO_RW("server Key Update"),
STATE_STRINGS_PROTO_RW("Client Hello"),
STATE_STRINGS_PROTO_RW("Client Key Exchange"),
STATE_STRINGS_PROTO_RW("Client Cert"),
STATE_STRINGS_PROTO_RW("Client Change CipherSpec"),
STATE_STRINGS_PROTO_RW("Client Certificate Verify"),
STATE_STRINGS_PROTO_RW("Client End Of Early Data"),
STATE_STRINGS_PROTO_RW("Client Finished"),
STATE_STRINGS_PROTO_RW("Client Key Update"),
STATE_STRINGS_PROTO("Handshake Done"),
};
enum ProtocolVer {
SSL_V3 = 0,
TLS_V1,
TLS_V1_1,
TLS_V1_2,
TLS_V1_3,
DTLS_V1,
DTLS_V1_2,
DTLS_V1_3,
UNKNOWN = 100
};
enum IOMode {
SS_READ = 0,
SS_WRITE,
SS_NEITHER
};
enum SslState {
ss_null_state = 0,
ss_server_hellorequest,
ss_server_helloverify,
ss_server_helloretryrequest,
ss_server_hello,
ss_server_certificatestatus,
ss_server_encryptedextensions,
ss_server_sessionticket,
ss_server_certrequest,
ss_server_cert,
ss_server_keyexchange,
ss_server_hellodone,
ss_server_changecipherspec,
ss_server_finished,
ss_server_keyupdate,
ss_client_hello,
ss_client_keyexchange,
ss_client_cert,
ss_client_changecipherspec,
ss_client_certverify,
ss_client_endofearlydata,
ss_client_finished,
ss_client_keyupdate,
ss_handshake_done
};
int protocol = 0;
int cbmode = 0;
int state = 0;
WOLFSSL_ENTER("wolfSSL_state_string_long");
if (ssl == NULL) {
WOLFSSL_MSG("Null argument passed in");
return NULL;
}
/* Get state of callback */
if (ssl->cbmode == WOLFSSL_CB_MODE_WRITE) {
cbmode = SS_WRITE;
}
else if (ssl->cbmode == WOLFSSL_CB_MODE_READ) {
cbmode = SS_READ;
}
else {
cbmode = SS_NEITHER;
}
/* Get protocol version */
switch (ssl->version.major) {
case SSLv3_MAJOR:
switch (ssl->version.minor) {
case SSLv3_MINOR:
protocol = SSL_V3;
break;
case TLSv1_MINOR:
protocol = TLS_V1;
break;
case TLSv1_1_MINOR:
protocol = TLS_V1_1;
break;
case TLSv1_2_MINOR:
protocol = TLS_V1_2;
break;
case TLSv1_3_MINOR:
protocol = TLS_V1_3;
break;
default:
protocol = UNKNOWN;
}
break;
case DTLS_MAJOR:
switch (ssl->version.minor) {
case DTLS_MINOR:
protocol = DTLS_V1;
break;
case DTLSv1_2_MINOR:
protocol = DTLS_V1_2;
break;
case DTLSv1_3_MINOR:
protocol = DTLS_V1_3;
break;
default:
protocol = UNKNOWN;
}
break;
default:
protocol = UNKNOWN;
}
/* accept process */
if (ssl->cbmode == WOLFSSL_CB_MODE_READ) {
state = ssl->cbtype;
switch (state) {
case hello_request:
state = ss_server_hellorequest;
break;
case client_hello:
state = ss_client_hello;
break;
case server_hello:
state = ss_server_hello;
break;
case hello_verify_request:
state = ss_server_helloverify;
break;
case session_ticket:
state = ss_server_sessionticket;
break;
case end_of_early_data:
state = ss_client_endofearlydata;
break;
case hello_retry_request:
state = ss_server_helloretryrequest;
break;
case encrypted_extensions:
state = ss_server_encryptedextensions;
break;
case certificate:
if (ssl->options.side == WOLFSSL_SERVER_END)
state = ss_client_cert;
else if (ssl->options.side == WOLFSSL_CLIENT_END)
state = ss_server_cert;
else {
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
break;
case server_key_exchange:
state = ss_server_keyexchange;
break;
case certificate_request:
state = ss_server_certrequest;
break;
case server_hello_done:
state = ss_server_hellodone;
break;
case certificate_verify:
state = ss_client_certverify;
break;
case client_key_exchange:
state = ss_client_keyexchange;
break;
case finished:
if (ssl->options.side == WOLFSSL_SERVER_END)
state = ss_client_finished;
else if (ssl->options.side == WOLFSSL_CLIENT_END)
state = ss_server_finished;
else {
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
break;
case certificate_status:
state = ss_server_certificatestatus;
break;
case key_update:
if (ssl->options.side == WOLFSSL_SERVER_END)
state = ss_client_keyupdate;
else if (ssl->options.side == WOLFSSL_CLIENT_END)
state = ss_server_keyupdate;
else {
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
break;
case change_cipher_hs:
if (ssl->options.side == WOLFSSL_SERVER_END)
state = ss_client_changecipherspec;
else if (ssl->options.side == WOLFSSL_CLIENT_END)
state = ss_server_changecipherspec;
else {
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
break;
default:
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
}
else {
/* Send process */
if (ssl->options.side == WOLFSSL_SERVER_END)
state = ssl->options.serverState;
else
state = ssl->options.clientState;
switch (state) {
case SERVER_HELLOVERIFYREQUEST_COMPLETE:
state = ss_server_helloverify;
break;
case SERVER_HELLO_RETRY_REQUEST_COMPLETE:
state = ss_server_helloretryrequest;
break;
case SERVER_HELLO_COMPLETE:
state = ss_server_hello;
break;
case SERVER_ENCRYPTED_EXTENSIONS_COMPLETE:
state = ss_server_encryptedextensions;
break;
case SERVER_CERT_COMPLETE:
state = ss_server_cert;
break;
case SERVER_KEYEXCHANGE_COMPLETE:
state = ss_server_keyexchange;
break;
case SERVER_HELLODONE_COMPLETE:
state = ss_server_hellodone;
break;
case SERVER_CHANGECIPHERSPEC_COMPLETE:
state = ss_server_changecipherspec;
break;
case SERVER_FINISHED_COMPLETE:
state = ss_server_finished;
break;
case CLIENT_HELLO_RETRY:
case CLIENT_HELLO_COMPLETE:
state = ss_client_hello;
break;
case CLIENT_KEYEXCHANGE_COMPLETE:
state = ss_client_keyexchange;
break;
case CLIENT_CHANGECIPHERSPEC_COMPLETE:
state = ss_client_changecipherspec;
break;
case CLIENT_FINISHED_COMPLETE:
state = ss_client_finished;
break;
case HANDSHAKE_DONE:
state = ss_handshake_done;
break;
default:
WOLFSSL_MSG("Unknown State");
state = ss_null_state;
}
}
if (protocol == UNKNOWN) {
WOLFSSL_MSG("Unknown protocol");
return "";
}
else {
return OUTPUT_STR[state][protocol][cbmode];
}
}
#endif /* OPENSSL_EXTRA */
static long wolf_set_options(long old_op, long op)
{
/* if SSL_OP_ALL then turn all bug workarounds on */
if ((op & WOLFSSL_OP_ALL) == WOLFSSL_OP_ALL) {
WOLFSSL_MSG("\tSSL_OP_ALL");
}
/* by default cookie exchange is on with DTLS */
if ((op & WOLFSSL_OP_COOKIE_EXCHANGE) == WOLFSSL_OP_COOKIE_EXCHANGE) {
WOLFSSL_MSG("\tSSL_OP_COOKIE_EXCHANGE : on by default");
}
if ((op & WOLFSSL_OP_NO_SSLv2) == WOLFSSL_OP_NO_SSLv2) {
WOLFSSL_MSG("\tWOLFSSL_OP_NO_SSLv2 : wolfSSL does not support SSLv2");
}
#ifdef SSL_OP_NO_TLSv1_3
if ((op & WOLFSSL_OP_NO_TLSv1_3) == WOLFSSL_OP_NO_TLSv1_3) {
WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_3");
}
#endif
if ((op & WOLFSSL_OP_NO_TLSv1_2) == WOLFSSL_OP_NO_TLSv1_2) {
WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_2");
}
if ((op & WOLFSSL_OP_NO_TLSv1_1) == WOLFSSL_OP_NO_TLSv1_1) {
WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_1");
}
if ((op & WOLFSSL_OP_NO_TLSv1) == WOLFSSL_OP_NO_TLSv1) {
WOLFSSL_MSG("\tSSL_OP_NO_TLSv1");
}
if ((op & WOLFSSL_OP_NO_SSLv3) == WOLFSSL_OP_NO_SSLv3) {
WOLFSSL_MSG("\tSSL_OP_NO_SSLv3");
}
if ((op & WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) ==
WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) {
WOLFSSL_MSG("\tWOLFSSL_OP_CIPHER_SERVER_PREFERENCE");
}
if ((op & WOLFSSL_OP_NO_COMPRESSION) == WOLFSSL_OP_NO_COMPRESSION) {
#ifdef HAVE_LIBZ
WOLFSSL_MSG("SSL_OP_NO_COMPRESSION");
#else
WOLFSSL_MSG("SSL_OP_NO_COMPRESSION: compression not compiled in");
#endif
}
return old_op | op;
}
static int FindHashSig(const Suites* suites, byte first, byte second)
{
word16 i;
if (suites == NULL || suites->hashSigAlgoSz == 0) {
WOLFSSL_MSG("Suites pointer error or suiteSz 0");
return SUITES_ERROR;
}
for (i = 0; i < suites->hashSigAlgoSz-1; i += 2) {
if (suites->hashSigAlgo[i] == first &&
suites->hashSigAlgo[i+1] == second )
return i;
}
return MATCH_SUITE_ERROR;
}
long wolfSSL_set_options(WOLFSSL* ssl, long op)
{
word16 haveRSA = 1;
word16 havePSK = 0;
int keySz = 0;
WOLFSSL_ENTER("wolfSSL_set_options");
if (ssl == NULL) {
return 0;
}
ssl->options.mask = (unsigned long)wolf_set_options((long)ssl->options.mask, op);
if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_3) == WOLFSSL_OP_NO_TLSv1_3) {
WOLFSSL_MSG("Disabling TLS 1.3");
if (ssl->version.minor == TLSv1_3_MINOR)
ssl->version.minor = TLSv1_2_MINOR;
}
if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_2) == WOLFSSL_OP_NO_TLSv1_2) {
WOLFSSL_MSG("Disabling TLS 1.2");
if (ssl->version.minor == TLSv1_2_MINOR)
ssl->version.minor = TLSv1_1_MINOR;
}
if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_1) == WOLFSSL_OP_NO_TLSv1_1) {
WOLFSSL_MSG("Disabling TLS 1.1");
if (ssl->version.minor == TLSv1_1_MINOR)
ssl->version.minor = TLSv1_MINOR;
}
if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1) == WOLFSSL_OP_NO_TLSv1) {
WOLFSSL_MSG("Disabling TLS 1.0");
if (ssl->version.minor == TLSv1_MINOR)
ssl->version.minor = SSLv3_MINOR;
}
if ((ssl->options.mask & WOLFSSL_OP_NO_COMPRESSION)
== WOLFSSL_OP_NO_COMPRESSION) {
#ifdef HAVE_LIBZ
ssl->options.usingCompression = 0;
#endif
}
#if defined(HAVE_SESSION_TICKET) && (defined(OPENSSL_EXTRA) \
|| defined(HAVE_WEBSERVER) || defined(WOLFSSL_WPAS_SMALL))
if ((ssl->options.mask & WOLFSSL_OP_NO_TICKET) == WOLFSSL_OP_NO_TICKET) {
ssl->options.noTicketTls12 = 1;
}
#endif
/* in the case of a version change the cipher suites should be reset */
#ifndef NO_PSK
havePSK = ssl->options.havePSK;
#endif
#ifdef NO_RSA
haveRSA = 0;
#endif
#ifndef NO_CERTS
keySz = ssl->buffers.keySz;
#endif
if (ssl->options.side != WOLFSSL_NEITHER_END) {
if (AllocateSuites(ssl) != 0)
return 0;
if (!ssl->suites->setSuites) {
/* Client side won't set DH params, so it needs haveDH set to TRUE. */
if (ssl->options.side == WOLFSSL_CLIENT_END)
InitSuites(ssl->suites, ssl->version, keySz, haveRSA,
havePSK, TRUE, ssl->options.haveECDSAsig,
ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
ssl->options.useAnon,
TRUE, TRUE, TRUE, TRUE, ssl->options.side);
else
InitSuites(ssl->suites, ssl->version, keySz, haveRSA,
havePSK, ssl->options.haveDH, ssl->options.haveECDSAsig,
ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
ssl->options.useAnon,
TRUE, TRUE, TRUE, TRUE, ssl->options.side);
}
else {
/* Only preserve overlapping suites */
Suites tmpSuites;
word16 in, out;
word16 haveECDSAsig, haveStaticECC;
#ifdef NO_RSA
haveECDSAsig = 1;
haveStaticECC = 1;
#else
haveECDSAsig = 0;
haveStaticECC = ssl->options.haveStaticECC;
#endif
XMEMSET(&tmpSuites, 0, sizeof(Suites));
/* Get all possible ciphers and sigalgs for the version. Following
* options limit the allowed ciphers so let's try to get as many as
* possible.
* - haveStaticECC turns off haveRSA
* - haveECDSAsig turns off haveRSAsig */
InitSuites(&tmpSuites, ssl->version, 0, 1, 1, 1, haveECDSAsig, 1, 1,
haveStaticECC, 1, 1, 1, 1, 1, ssl->options.side);
for (in = 0, out = 0; in < ssl->suites->suiteSz; in += SUITE_LEN) {
if (FindSuite(&tmpSuites, ssl->suites->suites[in],
ssl->suites->suites[in+1]) >= 0) {
ssl->suites->suites[out] = ssl->suites->suites[in];
ssl->suites->suites[out+1] = ssl->suites->suites[in+1];
out += SUITE_LEN;
}
}
ssl->suites->suiteSz = out;
for (in = 0, out = 0; in < ssl->suites->hashSigAlgoSz; in += 2) {
if (FindHashSig(&tmpSuites, ssl->suites->hashSigAlgo[in],
ssl->suites->hashSigAlgo[in+1]) >= 0) {
ssl->suites->hashSigAlgo[out] =
ssl->suites->hashSigAlgo[in];
ssl->suites->hashSigAlgo[out+1] =
ssl->suites->hashSigAlgo[in+1];
out += 2;
}
}
ssl->suites->hashSigAlgoSz = out;
}
}
return (long)ssl->options.mask;
}
long wolfSSL_get_options(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_options");
if(ssl == NULL)
return WOLFSSL_FAILURE;
return (long)ssl->options.mask;
}
#if defined(HAVE_SECURE_RENEGOTIATION) \
|| defined(HAVE_SERVER_RENEGOTIATION_INFO)
/* clears the counter for number of renegotiations done
* returns the current count before it is cleared */
long wolfSSL_clear_num_renegotiations(WOLFSSL *s)
{
long total;
WOLFSSL_ENTER("wolfSSL_clear_num_renegotiations");
if (s == NULL)
return 0;
total = s->secure_rene_count;
s->secure_rene_count = 0;
return total;
}
/* return the number of renegotiations since wolfSSL_new */
long wolfSSL_total_renegotiations(WOLFSSL *s)
{
WOLFSSL_ENTER("wolfSSL_total_renegotiations");
return wolfSSL_num_renegotiations(s);
}
/* return the number of renegotiations since wolfSSL_new */
long wolfSSL_num_renegotiations(WOLFSSL* s)
{
if (s == NULL) {
return 0;
}
return s->secure_rene_count;
}
/* Is there a renegotiation currently in progress? */
int wolfSSL_SSL_renegotiate_pending(WOLFSSL *s)
{
return s && s->options.handShakeDone &&
s->options.handShakeState != HANDSHAKE_DONE ? 1 : 0;
}
#endif /* HAVE_SECURE_RENEGOTIATION || HAVE_SERVER_RENEGOTIATION_INFO */
#ifdef OPENSSL_EXTRA
long wolfSSL_clear_options(WOLFSSL* ssl, long opt)
{
WOLFSSL_ENTER("wolfSSL_clear_options");
if(ssl == NULL)
return WOLFSSL_FAILURE;
ssl->options.mask &= (unsigned long)~opt;
return (long)ssl->options.mask;
}
#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
void WOLFSSL_CTX_set_tmp_dh_callback(WOLFSSL_CTX *ctx,
WOLFSSL_DH *(*dh) (WOLFSSL *ssl, int is_export, int keylength))
{
(void)ctx;
(void)dh;
WOLFSSL_STUB("WOLFSSL_CTX_set_tmp_dh_callback");
}
#endif
#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
WOLF_STACK_OF(WOLFSSL_COMP) *WOLFSSL_COMP_get_compression_methods(void)
{
WOLFSSL_STUB("WOLFSSL_COMP_get_compression_methods");
return NULL;
}
#endif
#if !defined(NETOS)
void wolfSSL_ERR_load_SSL_strings(void)
{
}
#endif
#endif /* OPENSSL_EXTRA */
#ifdef WOLFSSL_HAVE_TLS_UNIQUE
size_t wolfSSL_get_finished(const WOLFSSL *ssl, void *buf, size_t count)
{
byte len = 0;
byte const * src;
WOLFSSL_ENTER("wolfSSL_get_finished");
if (!ssl || !buf) {
WOLFSSL_MSG("Bad parameter");
return WOLFSSL_FAILURE;
}
if (ssl->options.side == WOLFSSL_SERVER_END) {
src = ssl->serverFinished;
len = ssl->serverFinished_len;
}
else {
src = ssl->clientFinished;
len = ssl->clientFinished_len;
}
if (count < len) {
WOLFSSL_MSG("Buffer too small");
return WOLFSSL_FAILURE;
}
XMEMCPY(buf, src, len);
return len;
}
size_t wolfSSL_get_peer_finished(const WOLFSSL *ssl, void *buf, size_t count)
{
byte len = 0;
byte const * src;
WOLFSSL_ENTER("wolfSSL_get_peer_finished");
if (!ssl || !buf) {
WOLFSSL_MSG("Bad parameter");
return WOLFSSL_FAILURE;
}
if (ssl->options.side == WOLFSSL_CLIENT_END) {
src = ssl->serverFinished;
len = ssl->serverFinished_len;
}
else {
src = ssl->clientFinished;
len = ssl->clientFinished_len;
}
if (count < len) {
WOLFSSL_MSG("Buffer too small");
return WOLFSSL_FAILURE;
}
XMEMCPY(buf, src, len);
return len;
}
#endif /* WOLFSSL_HAVE_TLS_UNIQUE */
#ifdef OPENSSL_EXTRA
#ifndef NO_WOLFSSL_STUB
/* shows the number of accepts attempted by CTX in it's lifetime */
long wolfSSL_CTX_sess_accept(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_accept");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
/* shows the number of connects attempted CTX in it's lifetime */
long wolfSSL_CTX_sess_connect(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_connect");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
/* shows the number of accepts completed by CTX in it's lifetime */
long wolfSSL_CTX_sess_accept_good(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_accept_good");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
/* shows the number of connects completed by CTX in it's lifetime */
long wolfSSL_CTX_sess_connect_good(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_connect_good");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
/* shows the number of renegotiation accepts attempted by CTX */
long wolfSSL_CTX_sess_accept_renegotiate(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_accept_renegotiate");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
/* shows the number of renegotiation accepts attempted by CTX */
long wolfSSL_CTX_sess_connect_renegotiate(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_connect_renegotiate");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_hits(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_hits");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_cb_hits(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_cb_hits");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_cache_full(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_cache_full");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_misses(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_misses");
(void)ctx;
return 0;
}
#endif
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_timeouts(WOLFSSL_CTX* ctx)
{
WOLFSSL_STUB("wolfSSL_CTX_sess_timeouts");
(void)ctx;
return 0;
}
#endif
int wolfSSL_get_read_ahead(const WOLFSSL* ssl)
{
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
return ssl->readAhead;
}
int wolfSSL_set_read_ahead(WOLFSSL* ssl, int v)
{
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
ssl->readAhead = (byte)v;
return WOLFSSL_SUCCESS;
}
int wolfSSL_CTX_get_read_ahead(WOLFSSL_CTX* ctx)
{
if (ctx == NULL) {
return WOLFSSL_FAILURE;
}
return ctx->readAhead;
}
int wolfSSL_CTX_set_read_ahead(WOLFSSL_CTX* ctx, int v)
{
if (ctx == NULL) {
return WOLFSSL_FAILURE;
}
ctx->readAhead = (byte)v;
return WOLFSSL_SUCCESS;
}
long wolfSSL_CTX_set_tlsext_opaque_prf_input_callback_arg(WOLFSSL_CTX* ctx,
void* arg)
{
if (ctx == NULL) {
return WOLFSSL_FAILURE;
}
ctx->userPRFArg = arg;
return WOLFSSL_SUCCESS;
}
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
const WOLFSSL_ObjectInfo wolfssl_object_info[] = {
#ifndef NO_CERTS
/* oidCertExtType */
{ WC_NID_basic_constraints, BASIC_CA_OID, oidCertExtType,
"basicConstraints", "X509v3 Basic Constraints"},
{ WC_NID_subject_alt_name, ALT_NAMES_OID, oidCertExtType, "subjectAltName",
"X509v3 Subject Alternative Name"},
{ WC_NID_crl_distribution_points, CRL_DIST_OID, oidCertExtType,
"crlDistributionPoints", "X509v3 CRL Distribution Points"},
{ WC_NID_info_access, AUTH_INFO_OID, oidCertExtType, "authorityInfoAccess",
"Authority Information Access"},
{ WC_NID_authority_key_identifier, AUTH_KEY_OID, oidCertExtType,
"authorityKeyIdentifier", "X509v3 Authority Key Identifier"},
{ WC_NID_subject_key_identifier, SUBJ_KEY_OID, oidCertExtType,
"subjectKeyIdentifier", "X509v3 Subject Key Identifier"},
{ WC_NID_key_usage, KEY_USAGE_OID, oidCertExtType, "keyUsage",
"X509v3 Key Usage"},
{ WC_NID_inhibit_any_policy, INHIBIT_ANY_OID, oidCertExtType,
"inhibitAnyPolicy", "X509v3 Inhibit Any Policy"},
{ WC_NID_ext_key_usage, EXT_KEY_USAGE_OID, oidCertExtType,
"extendedKeyUsage", "X509v3 Extended Key Usage"},
{ WC_NID_name_constraints, NAME_CONS_OID, oidCertExtType,
"nameConstraints", "X509v3 Name Constraints"},
{ WC_NID_certificate_policies, CERT_POLICY_OID, oidCertExtType,
"certificatePolicies", "X509v3 Certificate Policies"},
/* oidCertAuthInfoType */
{ WC_NID_ad_OCSP, AIA_OCSP_OID, oidCertAuthInfoType, "OCSP",
"OCSP"},
{ WC_NID_ad_ca_issuers, AIA_CA_ISSUER_OID, oidCertAuthInfoType,
"caIssuers", "CA Issuers"},
/* oidCertPolicyType */
{ WC_NID_any_policy, CP_ANY_OID, oidCertPolicyType, "anyPolicy",
"X509v3 Any Policy"},
/* oidCertAltNameType */
{ WC_NID_hw_name_oid, HW_NAME_OID, oidCertAltNameType, "Hardware name",""},
/* oidCertKeyUseType */
{ WC_NID_anyExtendedKeyUsage, EKU_ANY_OID, oidCertKeyUseType,
"anyExtendedKeyUsage", "Any Extended Key Usage"},
{ EKU_SERVER_AUTH_OID, EKU_SERVER_AUTH_OID, oidCertKeyUseType,
"serverAuth", "TLS Web Server Authentication"},
{ EKU_CLIENT_AUTH_OID, EKU_CLIENT_AUTH_OID, oidCertKeyUseType,
"clientAuth", "TLS Web Client Authentication"},
{ EKU_OCSP_SIGN_OID, EKU_OCSP_SIGN_OID, oidCertKeyUseType,
"OCSPSigning", "OCSP Signing"},
/* oidCertNameType */
{ WC_NID_commonName, WC_NAME_COMMON_NAME_OID, oidCertNameType,
"CN", "commonName"},
#if !defined(WOLFSSL_CERT_REQ)
{ WC_NID_surname, WC_NAME_SURNAME_OID, oidCertNameType, "SN", "surname"},
#endif
{ WC_NID_serialNumber, WC_NAME_SERIAL_NUMBER_OID, oidCertNameType,
"serialNumber", "serialNumber"},
{ WC_NID_userId, WC_NID_userId, oidCertNameType, "UID", "userid"},
{ WC_NID_countryName, WC_NAME_COUNTRY_NAME_OID, oidCertNameType,
"C", "countryName"},
{ WC_NID_localityName, WC_NAME_LOCALITY_NAME_OID, oidCertNameType,
"L", "localityName"},
{ WC_NID_stateOrProvinceName, WC_NAME_STATE_NAME_OID, oidCertNameType,
"ST", "stateOrProvinceName"},
{ WC_NID_streetAddress, WC_NAME_STREET_ADDRESS_OID, oidCertNameType,
"street", "streetAddress"},
{ WC_NID_organizationName, WC_NAME_ORGANIZATION_NAME_OID, oidCertNameType,
"O", "organizationName"},
{ WC_NID_organizationalUnitName, WC_NAME_ORGANIZATION_UNIT_NAME_OID,
oidCertNameType, "OU", "organizationalUnitName"},
{ WC_NID_title, WC_NAME_TITLE_OID, oidCertNameType, "title", "title"},
{ WC_NID_description, WC_NAME_DESCRIPTION_OID, oidCertNameType,
"description", "description"},
{ WC_NID_emailAddress, WC_NAME_EMAIL_ADDRESS_OID, oidCertNameType,
"emailAddress", "emailAddress"},
{ WC_NID_domainComponent, WC_NAME_DOMAIN_COMPONENT_OID, oidCertNameType,
"DC", "domainComponent"},
{ WC_NID_rfc822Mailbox, WC_NAME_RFC822_MAILBOX_OID, oidCertNameType,
"rfc822Mailbox", "rfc822Mailbox"},
{ WC_NID_favouriteDrink, WC_NAME_FAVOURITE_DRINK_OID, oidCertNameType,
"favouriteDrink", "favouriteDrink"},
{ WC_NID_businessCategory, WC_NAME_BUSINESS_CATEGORY_OID, oidCertNameType,
"businessCategory", "businessCategory"},
{ WC_NID_jurisdictionCountryName, WC_NAME_JURIS_COUNTRY_OID,
oidCertNameType, "jurisdictionC", "jurisdictionCountryName"},
{ WC_NID_jurisdictionStateOrProvinceName, WC_NAME_JURIS_STATE_PROV_OID,
oidCertNameType, "jurisdictionST", "jurisdictionStateOrProvinceName"},
{ WC_NID_postalCode, WC_NAME_POSTAL_CODE_OID, oidCertNameType, "postalCode",
"postalCode"},
{ WC_NID_userId, WC_NAME_USER_ID_OID, oidCertNameType, "UID", "userId"},
{ WC_NID_netscape_cert_type, NETSCAPE_CT_OID, oidCertNameType,
"nsCertType", "Netscape Cert Type"},
#if defined(WOLFSSL_CERT_REQ) || defined(WOLFSSL_CERT_NAME_ALL)
{ WC_NID_pkcs9_challengePassword, CHALLENGE_PASSWORD_OID,
oidCsrAttrType, "challengePassword", "challengePassword"},
{ WC_NID_pkcs9_contentType, PKCS9_CONTENT_TYPE_OID,
oidCsrAttrType, "contentType", "contentType" },
{ WC_NID_pkcs9_unstructuredName, UNSTRUCTURED_NAME_OID,
oidCsrAttrType, "unstructuredName", "unstructuredName" },
{ WC_NID_name, WC_NAME_NAME_OID, oidCsrAttrType, "name", "name" },
{ WC_NID_surname, SURNAME_OID,
oidCsrAttrType, "surname", "surname" },
{ WC_NID_givenName, WC_NAME_GIVEN_NAME_OID,
oidCsrAttrType, "givenName", "givenName" },
{ WC_NID_initials, WC_NAME_INITIALIS_OID,
oidCsrAttrType, "initials", "initials" },
{ WC_NID_dnQualifier, DNQUALIFIER_OID,
oidCsrAttrType, "dnQualifer", "dnQualifier" },
#endif
#endif
#ifdef OPENSSL_EXTRA /* OPENSSL_EXTRA_X509_SMALL only needs the above */
/* oidHashType */
#ifdef WOLFSSL_MD2
{ WC_NID_md2, MD2h, oidHashType, "MD2", "md2"},
#endif
#ifndef NO_MD4
{ WC_NID_md4, MD4h, oidHashType, "MD4", "md4"},
#endif
#ifndef NO_MD5
{ WC_NID_md5, MD5h, oidHashType, "MD5", "md5"},
#endif
#ifndef NO_SHA
{ WC_NID_sha1, SHAh, oidHashType, "SHA1", "sha1"},
#endif
#ifdef WOLFSSL_SHA224
{ WC_NID_sha224, SHA224h, oidHashType, "SHA224", "sha224"},
#endif
#ifndef NO_SHA256
{ WC_NID_sha256, SHA256h, oidHashType, "SHA256", "sha256"},
#endif
#ifdef WOLFSSL_SHA384
{ WC_NID_sha384, SHA384h, oidHashType, "SHA384", "sha384"},
#endif
#ifdef WOLFSSL_SHA512
{ WC_NID_sha512, SHA512h, oidHashType, "SHA512", "sha512"},
#endif
#ifdef WOLFSSL_SHA3
#ifndef WOLFSSL_NOSHA3_224
{ WC_NID_sha3_224, SHA3_224h, oidHashType, "SHA3-224", "sha3-224"},
#endif
#ifndef WOLFSSL_NOSHA3_256
{ WC_NID_sha3_256, SHA3_256h, oidHashType, "SHA3-256", "sha3-256"},
#endif
#ifndef WOLFSSL_NOSHA3_384
{ WC_NID_sha3_384, SHA3_384h, oidHashType, "SHA3-384", "sha3-384"},
#endif
#ifndef WOLFSSL_NOSHA3_512
{ WC_NID_sha3_512, SHA3_512h, oidHashType, "SHA3-512", "sha3-512"},
#endif
#endif /* WOLFSSL_SHA3 */
#ifdef WOLFSSL_SM3
{ WC_NID_sm3, SM3h, oidHashType, "SM3", "sm3"},
#endif
#ifdef WOLFSSL_SHAKE128
{ WC_NID_shake128, SHAKE128h, oidHashType, "SHAKE128", "shake128"},
#endif
#ifdef WOLFSSL_SHAKE256
{ WC_NID_shake256, SHAKE256h, oidHashType, "SHAKE256", "shake256"},
#endif
/* oidSigType */
#ifndef NO_DSA
#ifndef NO_SHA
{ WC_NID_dsaWithSHA1, CTC_SHAwDSA, oidSigType,
"DSA-SHA1", "dsaWithSHA1"},
{ WC_NID_dsa_with_SHA256, CTC_SHA256wDSA, oidSigType, "dsa_with_SHA256",
"dsa_with_SHA256"},
#endif
#endif /* NO_DSA */
#ifndef NO_RSA
#ifdef WOLFSSL_MD2
{ WC_NID_md2WithRSAEncryption, CTC_MD2wRSA, oidSigType, "RSA-MD2",
"md2WithRSAEncryption"},
#endif
#ifndef NO_MD5
{ WC_NID_md5WithRSAEncryption, CTC_MD5wRSA, oidSigType, "RSA-MD5",
"md5WithRSAEncryption"},
#endif
#ifndef NO_SHA
{ WC_NID_sha1WithRSAEncryption, CTC_SHAwRSA, oidSigType, "RSA-SHA1",
"sha1WithRSAEncryption"},
#endif
#ifdef WOLFSSL_SHA224
{ WC_NID_sha224WithRSAEncryption, CTC_SHA224wRSA, oidSigType,
"RSA-SHA224", "sha224WithRSAEncryption"},
#endif
#ifndef NO_SHA256
{ WC_NID_sha256WithRSAEncryption, CTC_SHA256wRSA, oidSigType,
"RSA-SHA256", "sha256WithRSAEncryption"},
#endif
#ifdef WOLFSSL_SHA384
{ WC_NID_sha384WithRSAEncryption, CTC_SHA384wRSA, oidSigType,
"RSA-SHA384", "sha384WithRSAEncryption"},
#endif
#ifdef WOLFSSL_SHA512
{ WC_NID_sha512WithRSAEncryption, CTC_SHA512wRSA, oidSigType,
"RSA-SHA512", "sha512WithRSAEncryption"},
#endif
#ifdef WOLFSSL_SHA3
#ifndef WOLFSSL_NOSHA3_224
{ WC_NID_RSA_SHA3_224, CTC_SHA3_224wRSA, oidSigType, "RSA-SHA3-224",
"sha3-224WithRSAEncryption"},
#endif
#ifndef WOLFSSL_NOSHA3_256
{ WC_NID_RSA_SHA3_256, CTC_SHA3_256wRSA, oidSigType, "RSA-SHA3-256",
"sha3-256WithRSAEncryption"},
#endif
#ifndef WOLFSSL_NOSHA3_384
{ WC_NID_RSA_SHA3_384, CTC_SHA3_384wRSA, oidSigType, "RSA-SHA3-384",
"sha3-384WithRSAEncryption"},
#endif
#ifndef WOLFSSL_NOSHA3_512
{ WC_NID_RSA_SHA3_512, CTC_SHA3_512wRSA, oidSigType, "RSA-SHA3-512",
"sha3-512WithRSAEncryption"},
#endif
#endif
#ifdef WC_RSA_PSS
{ WC_NID_rsassaPss, CTC_RSASSAPSS, oidSigType,
"RSASSA-PSS", "rsassaPss" },
#endif
#endif /* NO_RSA */
#ifdef HAVE_ECC
#ifndef NO_SHA
{ WC_NID_ecdsa_with_SHA1, CTC_SHAwECDSA, oidSigType, "ecdsa-with-SHA1",
"shaWithECDSA"},
#endif
#ifdef WOLFSSL_SHA224
{ WC_NID_ecdsa_with_SHA224, CTC_SHA224wECDSA, oidSigType,
"ecdsa-with-SHA224","sha224WithECDSA"},
#endif
#ifndef NO_SHA256
{ WC_NID_ecdsa_with_SHA256, CTC_SHA256wECDSA, oidSigType,
"ecdsa-with-SHA256","sha256WithECDSA"},
#endif
#ifdef WOLFSSL_SHA384
{ WC_NID_ecdsa_with_SHA384, CTC_SHA384wECDSA, oidSigType,
"ecdsa-with-SHA384","sha384WithECDSA"},
#endif
#ifdef WOLFSSL_SHA512
{ WC_NID_ecdsa_with_SHA512, CTC_SHA512wECDSA, oidSigType,
"ecdsa-with-SHA512","sha512WithECDSA"},
#endif
#ifdef WOLFSSL_SHA3
#ifndef WOLFSSL_NOSHA3_224
{ WC_NID_ecdsa_with_SHA3_224, CTC_SHA3_224wECDSA, oidSigType,
"id-ecdsa-with-SHA3-224", "ecdsa_with_SHA3-224"},
#endif
#ifndef WOLFSSL_NOSHA3_256
{ WC_NID_ecdsa_with_SHA3_256, CTC_SHA3_256wECDSA, oidSigType,
"id-ecdsa-with-SHA3-256", "ecdsa_with_SHA3-256"},
#endif
#ifndef WOLFSSL_NOSHA3_384
{ WC_NID_ecdsa_with_SHA3_384, CTC_SHA3_384wECDSA, oidSigType,
"id-ecdsa-with-SHA3-384", "ecdsa_with_SHA3-384"},
#endif
#ifndef WOLFSSL_NOSHA3_512
{ WC_NID_ecdsa_with_SHA3_512, CTC_SHA3_512wECDSA, oidSigType,
"id-ecdsa-with-SHA3-512", "ecdsa_with_SHA3-512"},
#endif
#endif
#endif /* HAVE_ECC */
/* oidKeyType */
#ifndef NO_DSA
{ WC_NID_dsa, DSAk, oidKeyType, "DSA", "dsaEncryption"},
#endif /* NO_DSA */
#ifndef NO_RSA
{ WC_NID_rsaEncryption, RSAk, oidKeyType, "rsaEncryption",
"rsaEncryption"},
#ifdef WC_RSA_PSS
{ WC_NID_rsassaPss, RSAPSSk, oidKeyType, "RSASSA-PSS", "rsassaPss"},
#endif
#endif /* NO_RSA */
#ifdef HAVE_ECC
{ WC_NID_X9_62_id_ecPublicKey, ECDSAk, oidKeyType, "id-ecPublicKey",
"id-ecPublicKey"},
#endif /* HAVE_ECC */
#ifndef NO_DH
{ WC_NID_dhKeyAgreement, DHk, oidKeyType, "dhKeyAgreement",
"dhKeyAgreement"},
#endif
#ifdef HAVE_ED448
{ WC_NID_ED448, ED448k, oidKeyType, "ED448", "ED448"},
#endif
#ifdef HAVE_ED25519
{ WC_NID_ED25519, ED25519k, oidKeyType, "ED25519", "ED25519"},
#endif
#ifdef HAVE_FALCON
{ CTC_FALCON_LEVEL1, FALCON_LEVEL1k, oidKeyType, "Falcon Level 1",
"Falcon Level 1"},
{ CTC_FALCON_LEVEL5, FALCON_LEVEL5k, oidKeyType, "Falcon Level 5",
"Falcon Level 5"},
#endif /* HAVE_FALCON */
#ifdef WOLFSSL_HAVE_MLDSA
#ifdef WOLFSSL_MLDSA_FIPS204_DRAFT
/* Pre-standardization (NIST PQC round 3) Dilithium OID labels.
* These coexist with the FIPS 204 "ML-DSA 44/65/87" entries below
* and are intentionally kept under the Dilithium name. */
{ CTC_DILITHIUM_LEVEL2, DILITHIUM_LEVEL2k, oidKeyType,
"Dilithium Level 2", "Dilithium Level 2"},
{ CTC_DILITHIUM_LEVEL3, DILITHIUM_LEVEL3k, oidKeyType,
"Dilithium Level 3", "Dilithium Level 3"},
{ CTC_DILITHIUM_LEVEL5, DILITHIUM_LEVEL5k, oidKeyType,
"Dilithium Level 5", "Dilithium Level 5"},
#endif /* WOLFSSL_MLDSA_FIPS204_DRAFT */
{ CTC_ML_DSA_44, ML_DSA_44k, oidKeyType,
"ML-DSA 44", "ML-DSA 44"},
{ CTC_ML_DSA_65, ML_DSA_65k, oidKeyType,
"ML-DSA 65", "ML-DSA 65"},
{ CTC_ML_DSA_87, ML_DSA_87k, oidKeyType,
"ML-DSA 87", "ML-DSA 87"},
#endif /* WOLFSSL_HAVE_MLDSA */
/* oidCurveType */
#ifdef HAVE_ECC
{ WC_NID_X9_62_prime192v1, ECC_SECP192R1_OID, oidCurveType,
"prime192v1", "prime192v1"},
{ WC_NID_X9_62_prime192v2, ECC_PRIME192V2_OID, oidCurveType,
"prime192v2", "prime192v2"},
{ WC_NID_X9_62_prime192v3, ECC_PRIME192V3_OID, oidCurveType,
"prime192v3", "prime192v3"},
{ WC_NID_X9_62_prime239v1, ECC_PRIME239V1_OID, oidCurveType,
"prime239v1", "prime239v1"},
{ WC_NID_X9_62_prime239v2, ECC_PRIME239V2_OID, oidCurveType,
"prime239v2", "prime239v2"},
{ WC_NID_X9_62_prime239v3, ECC_PRIME239V3_OID, oidCurveType,
"prime239v3", "prime239v3"},
{ WC_NID_X9_62_prime256v1, ECC_SECP256R1_OID, oidCurveType,
"prime256v1", "prime256v1"},
{ WC_NID_secp112r1, ECC_SECP112R1_OID, oidCurveType, "secp112r1",
"secp112r1"},
{ WC_NID_secp112r2, ECC_SECP112R2_OID, oidCurveType, "secp112r2",
"secp112r2"},
{ WC_NID_secp128r1, ECC_SECP128R1_OID, oidCurveType, "secp128r1",
"secp128r1"},
{ WC_NID_secp128r2, ECC_SECP128R2_OID, oidCurveType, "secp128r2",
"secp128r2"},
{ WC_NID_secp160r1, ECC_SECP160R1_OID, oidCurveType, "secp160r1",
"secp160r1"},
{ WC_NID_secp160r2, ECC_SECP160R2_OID, oidCurveType, "secp160r2",
"secp160r2"},
{ WC_NID_secp224r1, ECC_SECP224R1_OID, oidCurveType, "secp224r1",
"secp224r1"},
{ WC_NID_secp384r1, ECC_SECP384R1_OID, oidCurveType, "secp384r1",
"secp384r1"},
{ WC_NID_secp521r1, ECC_SECP521R1_OID, oidCurveType, "secp521r1",
"secp521r1"},
{ WC_NID_secp160k1, ECC_SECP160K1_OID, oidCurveType, "secp160k1",
"secp160k1"},
{ WC_NID_secp192k1, ECC_SECP192K1_OID, oidCurveType, "secp192k1",
"secp192k1"},
{ WC_NID_secp224k1, ECC_SECP224K1_OID, oidCurveType, "secp224k1",
"secp224k1"},
{ WC_NID_secp256k1, ECC_SECP256K1_OID, oidCurveType, "secp256k1",
"secp256k1"},
{ WC_NID_brainpoolP160r1, ECC_BRAINPOOLP160R1_OID, oidCurveType,
"brainpoolP160r1", "brainpoolP160r1"},
{ WC_NID_brainpoolP192r1, ECC_BRAINPOOLP192R1_OID, oidCurveType,
"brainpoolP192r1", "brainpoolP192r1"},
{ WC_NID_brainpoolP224r1, ECC_BRAINPOOLP224R1_OID, oidCurveType,
"brainpoolP224r1", "brainpoolP224r1"},
{ WC_NID_brainpoolP256r1, ECC_BRAINPOOLP256R1_OID, oidCurveType,
"brainpoolP256r1", "brainpoolP256r1"},
{ WC_NID_brainpoolP320r1, ECC_BRAINPOOLP320R1_OID, oidCurveType,
"brainpoolP320r1", "brainpoolP320r1"},
{ WC_NID_brainpoolP384r1, ECC_BRAINPOOLP384R1_OID, oidCurveType,
"brainpoolP384r1", "brainpoolP384r1"},
{ WC_NID_brainpoolP512r1, ECC_BRAINPOOLP512R1_OID, oidCurveType,
"brainpoolP512r1", "brainpoolP512r1"},
#ifdef WOLFSSL_SM2
{ WC_NID_sm2, ECC_SM2P256V1_OID, oidCurveType, "sm2", "sm2"},
#endif
#endif /* HAVE_ECC */
/* oidBlkType */
#ifdef WOLFSSL_AES_128
{ AES128CBCb, AES128CBCb, oidBlkType, "AES-128-CBC", "aes-128-cbc"},
#endif
#ifdef WOLFSSL_AES_192
{ AES192CBCb, AES192CBCb, oidBlkType, "AES-192-CBC", "aes-192-cbc"},
#endif
#ifdef WOLFSSL_AES_256
{ AES256CBCb, AES256CBCb, oidBlkType, "AES-256-CBC", "aes-256-cbc"},
#endif
#ifndef NO_DES3
{ WC_NID_des, DESb, oidBlkType, "DES-CBC", "des-cbc"},
{ WC_NID_des3, DES3b, oidBlkType, "DES-EDE3-CBC", "des-ede3-cbc"},
#endif /* !NO_DES3 */
#if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
{ WC_NID_chacha20_poly1305, WC_NID_chacha20_poly1305, oidBlkType,
"ChaCha20-Poly1305", "chacha20-poly1305"},
#endif
/* oidOcspType */
#ifdef HAVE_OCSP
{ WC_NID_id_pkix_OCSP_basic, OCSP_BASIC_OID, oidOcspType,
"basicOCSPResponse", "Basic OCSP Response"},
{ OCSP_NONCE_OID, OCSP_NONCE_OID, oidOcspType, "Nonce", "OCSP Nonce"},
#endif /* HAVE_OCSP */
#ifndef NO_PWDBASED
/* oidKdfType */
{ PBKDF2_OID, PBKDF2_OID, oidKdfType, "PBKDFv2", "PBKDF2"},
/* oidPBEType */
{ PBE_SHA1_RC4_128, PBE_SHA1_RC4_128, oidPBEType,
"PBE-SHA1-RC4-128", "pbeWithSHA1And128BitRC4"},
{ PBE_SHA1_DES, PBE_SHA1_DES, oidPBEType, "PBE-SHA1-DES",
"pbeWithSHA1AndDES-CBC"},
{ PBE_SHA1_DES3, PBE_SHA1_DES3, oidPBEType, "PBE-SHA1-3DES",
"pbeWithSHA1And3-KeyTripleDES-CBC"},
#endif
/* oidKeyWrapType */
#ifdef WOLFSSL_AES_128
{ AES128_WRAP, AES128_WRAP, oidKeyWrapType, "AES-128 wrap",
"aes128-wrap"},
#endif
#ifdef WOLFSSL_AES_192
{ AES192_WRAP, AES192_WRAP, oidKeyWrapType, "AES-192 wrap",
"aes192-wrap"},
#endif
#ifdef WOLFSSL_AES_256
{ AES256_WRAP, AES256_WRAP, oidKeyWrapType, "AES-256 wrap",
"aes256-wrap"},
#endif
#ifndef NO_PKCS7
#ifndef NO_DH
/* oidCmsKeyAgreeType */
#ifndef NO_SHA
{ dhSinglePass_stdDH_sha1kdf_scheme, dhSinglePass_stdDH_sha1kdf_scheme,
oidCmsKeyAgreeType, "dhSinglePass-stdDH-sha1kdf-scheme",
"dhSinglePass-stdDH-sha1kdf-scheme"},
#endif
#ifdef WOLFSSL_SHA224
{ dhSinglePass_stdDH_sha224kdf_scheme,
dhSinglePass_stdDH_sha224kdf_scheme, oidCmsKeyAgreeType,
"dhSinglePass-stdDH-sha224kdf-scheme",
"dhSinglePass-stdDH-sha224kdf-scheme"},
#endif
#ifndef NO_SHA256
{ dhSinglePass_stdDH_sha256kdf_scheme,
dhSinglePass_stdDH_sha256kdf_scheme, oidCmsKeyAgreeType,
"dhSinglePass-stdDH-sha256kdf-scheme",
"dhSinglePass-stdDH-sha256kdf-scheme"},
#endif
#ifdef WOLFSSL_SHA384
{ dhSinglePass_stdDH_sha384kdf_scheme,
dhSinglePass_stdDH_sha384kdf_scheme, oidCmsKeyAgreeType,
"dhSinglePass-stdDH-sha384kdf-scheme",
"dhSinglePass-stdDH-sha384kdf-scheme"},
#endif
#ifdef WOLFSSL_SHA512
{ dhSinglePass_stdDH_sha512kdf_scheme,
dhSinglePass_stdDH_sha512kdf_scheme, oidCmsKeyAgreeType,
"dhSinglePass-stdDH-sha512kdf-scheme",
"dhSinglePass-stdDH-sha512kdf-scheme"},
#endif
#endif
#endif
#if defined(WOLFSSL_APACHE_HTTPD)
/* "1.3.6.1.5.5.7.8.7" */
{ WC_NID_id_on_dnsSRV, WOLFSSL_DNS_SRV_SUM, oidCertNameType,
WOLFSSL_SN_DNS_SRV, WOLFSSL_LN_DNS_SRV },
/* "1.3.6.1.4.1.311.20.2.3" */
{ WC_NID_ms_upn, WOLFSSL_MS_UPN_SUM, oidCertExtType, WOLFSSL_SN_MS_UPN,
WOLFSSL_LN_MS_UPN },
/* "1.3.6.1.5.5.7.1.24" */
{ WC_NID_tlsfeature, WOLFSSL_TLS_FEATURE_SUM, oidTlsExtType,
WOLFSSL_SN_TLS_FEATURE, WOLFSSL_LN_TLS_FEATURE },
#endif
#endif /* OPENSSL_EXTRA */
};
#define WOLFSSL_OBJECT_INFO_SZ \
(sizeof(wolfssl_object_info) / sizeof(*wolfssl_object_info))
const size_t wolfssl_object_info_sz = WOLFSSL_OBJECT_INFO_SZ;
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* Free the dynamically allocated data.
*
* p Pointer to dynamically allocated memory.
*/
void wolfSSL_OPENSSL_free(void* p)
{
WOLFSSL_MSG("wolfSSL_OPENSSL_free");
XFREE(p, NULL, DYNAMIC_TYPE_OPENSSL);
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
#ifdef OPENSSL_EXTRA
void *wolfSSL_OPENSSL_malloc(size_t a)
{
return (void *)XMALLOC(a, NULL, DYNAMIC_TYPE_OPENSSL);
}
int wolfSSL_OPENSSL_hexchar2int(unsigned char c)
{
/* 'char' is unsigned on some platforms. */
return (int)(signed char)HexCharToByte((char)c);
}
unsigned char *wolfSSL_OPENSSL_hexstr2buf(const char *str, long *len)
{
unsigned char* targetBuf;
int srcDigitHigh = 0;
int srcDigitLow = 0;
size_t srcLen;
size_t srcIdx = 0;
long targetIdx = 0;
srcLen = XSTRLEN(str);
targetBuf = (unsigned char*)XMALLOC(srcLen / 2, NULL, DYNAMIC_TYPE_OPENSSL);
if (targetBuf == NULL) {
return NULL;
}
while (srcIdx < srcLen) {
if (str[srcIdx] == ':') {
srcIdx++;
continue;
}
srcDigitHigh = wolfSSL_OPENSSL_hexchar2int((unsigned char)str[srcIdx++]);
srcDigitLow = wolfSSL_OPENSSL_hexchar2int((unsigned char)str[srcIdx++]);
if (srcDigitHigh < 0 || srcDigitLow < 0) {
WOLFSSL_MSG("Invalid hex character.");
XFREE(targetBuf, NULL, DYNAMIC_TYPE_OPENSSL);
return NULL;
}
targetBuf[targetIdx++] = (unsigned char)((srcDigitHigh << 4) |
srcDigitLow );
}
if (len != NULL)
*len = targetIdx;
return targetBuf;
}
int wolfSSL_OPENSSL_init_ssl(word64 opts, const WOLFSSL_INIT_SETTINGS *settings)
{
(void)opts;
(void)settings;
return wolfSSL_library_init();
}
int wolfSSL_OPENSSL_init_crypto(word64 opts,
const WOLFSSL_INIT_SETTINGS* settings)
{
(void)opts;
(void)settings;
return wolfSSL_library_init();
}
#endif /* OPENSSL_EXTRA */
#ifdef HAVE_FUZZER
void wolfSSL_SetFuzzerCb(WOLFSSL* ssl, CallbackFuzzer cbf, void* fCtx)
{
if (ssl) {
ssl->fuzzerCb = cbf;
ssl->fuzzerCtx = fCtx;
}
}
#endif
#ifndef NO_CERTS
#ifdef HAVE_PK_CALLBACKS
/* callback for premaster secret generation */
void wolfSSL_CTX_SetGenPreMasterCb(WOLFSSL_CTX* ctx, CallbackGenPreMaster cb)
{
if (ctx)
ctx->GenPreMasterCb = cb;
}
/* Set premaster secret generation callback context */
void wolfSSL_SetGenPreMasterCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->GenPreMasterCtx = ctx;
}
/* Get premaster secret generation callback context */
void* wolfSSL_GetGenPreMasterCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->GenPreMasterCtx;
return NULL;
}
/* callback for master secret generation */
void wolfSSL_CTX_SetGenMasterSecretCb(WOLFSSL_CTX* ctx,
CallbackGenMasterSecret cb)
{
if (ctx)
ctx->GenMasterCb = cb;
}
/* Set master secret generation callback context */
void wolfSSL_SetGenMasterSecretCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->GenMasterCtx = ctx;
}
/* Get master secret generation callback context */
void* wolfSSL_GetGenMasterSecretCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->GenMasterCtx;
return NULL;
}
/* callback for extended master secret generation */
void wolfSSL_CTX_SetGenExtMasterSecretCb(WOLFSSL_CTX* ctx,
CallbackGenExtMasterSecret cb)
{
if (ctx)
ctx->GenExtMasterCb = cb;
}
/* Set extended master secret generation callback context */
void wolfSSL_SetGenExtMasterSecretCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->GenExtMasterCtx = ctx;
}
/* Get extended master secret generation callback context */
void* wolfSSL_GetGenExtMasterSecretCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->GenExtMasterCtx;
return NULL;
}
/* callback for session key generation */
void wolfSSL_CTX_SetGenSessionKeyCb(WOLFSSL_CTX* ctx, CallbackGenSessionKey cb)
{
if (ctx)
ctx->GenSessionKeyCb = cb;
}
/* Set session key generation callback context */
void wolfSSL_SetGenSessionKeyCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->GenSessionKeyCtx = ctx;
}
/* Get session key generation callback context */
void* wolfSSL_GetGenSessionKeyCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->GenSessionKeyCtx;
return NULL;
}
/* callback for setting encryption keys */
void wolfSSL_CTX_SetEncryptKeysCb(WOLFSSL_CTX* ctx, CallbackEncryptKeys cb)
{
if (ctx)
ctx->EncryptKeysCb = cb;
}
/* Set encryption keys callback context */
void wolfSSL_SetEncryptKeysCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->EncryptKeysCtx = ctx;
}
/* Get encryption keys callback context */
void* wolfSSL_GetEncryptKeysCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->EncryptKeysCtx;
return NULL;
}
/* callback for Tls finished */
/* the callback can be used to build TLS Finished message if enabled */
void wolfSSL_CTX_SetTlsFinishedCb(WOLFSSL_CTX* ctx, CallbackTlsFinished cb)
{
if (ctx)
ctx->TlsFinishedCb = cb;
}
/* Set Tls finished callback context */
void wolfSSL_SetTlsFinishedCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->TlsFinishedCtx = ctx;
}
/* Get Tls finished callback context */
void* wolfSSL_GetTlsFinishedCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->TlsFinishedCtx;
return NULL;
}
#if !defined(WOLFSSL_NO_TLS12) && !defined(WOLFSSL_AEAD_ONLY)
/* callback for verify data */
void wolfSSL_CTX_SetVerifyMacCb(WOLFSSL_CTX* ctx, CallbackVerifyMac cb)
{
if (ctx)
ctx->VerifyMacCb = cb;
}
/* Set set keys callback context */
void wolfSSL_SetVerifyMacCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->VerifyMacCtx = ctx;
}
/* Get set keys callback context */
void* wolfSSL_GetVerifyMacCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->VerifyMacCtx;
return NULL;
}
#endif /* !WOLFSSL_NO_TLS12 && !WOLFSSL_AEAD_ONLY */
void wolfSSL_CTX_SetHKDFExpandLabelCb(WOLFSSL_CTX* ctx,
CallbackHKDFExpandLabel cb)
{
if (ctx)
ctx->HKDFExpandLabelCb = cb;
}
#ifdef WOLFSSL_PUBLIC_ASN
void wolfSSL_CTX_SetProcessPeerCertCb(WOLFSSL_CTX* ctx,
CallbackProcessPeerCert cb)
{
if (ctx)
ctx->ProcessPeerCertCb = cb;
}
#endif /* WOLFSSL_PUBLIC_ASN */
void wolfSSL_CTX_SetProcessServerSigKexCb(WOLFSSL_CTX* ctx,
CallbackProcessServerSigKex cb)
{
if (ctx)
ctx->ProcessServerSigKexCb = cb;
}
void wolfSSL_CTX_SetPerformTlsRecordProcessingCb(WOLFSSL_CTX* ctx,
CallbackPerformTlsRecordProcessing cb)
{
if (ctx)
ctx->PerformTlsRecordProcessingCb = cb;
}
#endif /* HAVE_PK_CALLBACKS */
#endif /* NO_CERTS */
#if defined(HAVE_PK_CALLBACKS) && defined(HAVE_HKDF)
void wolfSSL_CTX_SetHKDFExtractCb(WOLFSSL_CTX* ctx, CallbackHKDFExtract cb)
{
if (ctx)
ctx->HkdfExtractCb = cb;
}
void wolfSSL_SetHKDFExtractCtx(WOLFSSL* ssl, void *ctx)
{
if (ssl)
ssl->HkdfExtractCtx = ctx;
}
void* wolfSSL_GetHKDFExtractCtx(WOLFSSL* ssl)
{
if (ssl)
return ssl->HkdfExtractCtx;
return NULL;
}
#endif /* HAVE_PK_CALLBACKS && HAVE_HKDF */
#ifdef WOLFSSL_HAVE_WOLFSCEP
/* Used by autoconf to see if wolfSCEP is available */
void wolfSSL_wolfSCEP(void) {}
#endif
#ifdef WOLFSSL_HAVE_CERT_SERVICE
/* Used by autoconf to see if cert service is available */
void wolfSSL_cert_service(void) {}
#endif
#if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) && \
!defined(WOLFCRYPT_ONLY)
/* NID variables are dependent on compatibility header files currently
*
* returns a pointer to a new WOLFSSL_ASN1_OBJECT struct on success and NULL
* on fail
*/
WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_nid2obj(int id)
{
return wolfSSL_OBJ_nid2obj_ex(id, NULL);
}
WOLFSSL_LOCAL WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_nid2obj_ex(int id,
WOLFSSL_ASN1_OBJECT* arg_obj)
{
word32 oidSz = 0;
int nid = 0;
const byte* oid;
word32 type = 0;
WOLFSSL_ASN1_OBJECT* obj = arg_obj;
byte objBuf[MAX_OID_SZ + MAX_LENGTH_SZ + 1]; /* +1 for object tag */
word32 objSz = 0;
const char* sName = NULL;
int i;
#ifdef WOLFSSL_DEBUG_OPENSSL
WOLFSSL_ENTER("wolfSSL_OBJ_nid2obj");
#endif
for (i = 0; i < (int)WOLFSSL_OBJECT_INFO_SZ; i++) {
if (wolfssl_object_info[i].nid == id) {
nid = id;
id = wolfssl_object_info[i].id;
sName = wolfssl_object_info[i].sName;
type = wolfssl_object_info[i].type;
break;
}
}
if (i == (int)WOLFSSL_OBJECT_INFO_SZ) {
WOLFSSL_MSG("NID not in table");
#ifdef WOLFSSL_QT
sName = NULL;
type = (word32)id;
#else
return NULL;
#endif
}
#ifdef HAVE_ECC
if (type == 0 && wc_ecc_get_oid((word32)id, &oid, &oidSz) > 0) {
type = oidCurveType;
}
#endif /* HAVE_ECC */
if (sName != NULL) {
if (XSTRLEN(sName) > WOLFSSL_MAX_SNAME - 1) {
WOLFSSL_MSG("Attempted short name is too large");
return NULL;
}
}
oid = OidFromId((word32)id, type, &oidSz);
/* set object ID to buffer */
if (obj == NULL){
obj = wolfSSL_ASN1_OBJECT_new();
if (obj == NULL) {
WOLFSSL_MSG("Issue creating WOLFSSL_ASN1_OBJECT struct");
return NULL;
}
}
obj->nid = nid;
obj->type = id;
obj->grp = (int)type;
obj->sName[0] = '\0';
if (sName != NULL) {
XMEMCPY(obj->sName, (char*)sName, XSTRLEN((char*)sName));
}
objBuf[0] = ASN_OBJECT_ID; objSz++;
objSz += SetLength(oidSz, objBuf + 1);
if (oidSz) {
XMEMCPY(objBuf + objSz, oid, oidSz);
objSz += oidSz;
}
if (obj->objSz == 0 || objSz != obj->objSz) {
obj->objSz = objSz;
if(((obj->dynamic & WOLFSSL_ASN1_DYNAMIC_DATA) != 0) ||
(obj->obj == NULL)) {
if (obj->obj != NULL)
XFREE((byte*)obj->obj, NULL, DYNAMIC_TYPE_ASN1);
obj->obj = (byte*)XMALLOC(obj->objSz, NULL, DYNAMIC_TYPE_ASN1);
if (obj->obj == NULL) {
wolfSSL_ASN1_OBJECT_free(obj);
return NULL;
}
obj->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA;
}
else {
obj->dynamic &= (unsigned char)~WOLFSSL_ASN1_DYNAMIC_DATA;
}
}
XMEMCPY((byte*)obj->obj, objBuf, obj->objSz);
(void)type;
return obj;
}
static const char* oid_translate_num_to_str(const char* oid)
{
const struct oid_dict {
const char* num;
const char* desc;
} oid_dict[] = {
{ "2.5.29.37.0", "Any Extended Key Usage" },
{ "1.3.6.1.5.5.7.3.1", "TLS Web Server Authentication" },
{ "1.3.6.1.5.5.7.3.2", "TLS Web Client Authentication" },
{ "1.3.6.1.5.5.7.3.3", "Code Signing" },
{ "1.3.6.1.5.5.7.3.4", "E-mail Protection" },
{ "1.3.6.1.5.5.7.3.8", "Time Stamping" },
{ "1.3.6.1.5.5.7.3.9", "OCSP Signing" },
{ NULL, NULL }
};
const struct oid_dict* idx;
for (idx = oid_dict; idx->num != NULL; idx++) {
if (!XSTRCMP(oid, idx->num)) {
return idx->desc;
}
}
return NULL;
}
static int wolfssl_obj2txt_numeric(char *buf, int bufLen,
const WOLFSSL_ASN1_OBJECT *a)
{
int bufSz;
int length;
word32 idx = 0;
byte tag;
if (GetASNTag(a->obj, &idx, &tag, a->objSz) != 0) {
return WOLFSSL_FAILURE;
}
if (tag != ASN_OBJECT_ID) {
WOLFSSL_MSG("Bad ASN1 Object");
return WOLFSSL_FAILURE;
}
if (GetLength((const byte*)a->obj, &idx, &length,
a->objSz) < 0 || length < 0) {
return ASN_PARSE_E;
}
if (bufLen < MAX_OID_STRING_SZ) {
bufSz = bufLen - 1;
}
else {
bufSz = MAX_OID_STRING_SZ;
}
if ((bufSz = DecodePolicyOID(buf, (word32)bufSz, a->obj + idx,
(word32)length)) <= 0) {
WOLFSSL_MSG("Error decoding OID");
return WOLFSSL_FAILURE;
}
buf[bufSz] = '\0';
return bufSz;
}
/* If no_name is one then use numerical form, otherwise short name.
*
* Returns the buffer size on success, WOLFSSL_FAILURE on error
*/
int wolfSSL_OBJ_obj2txt(char *buf, int bufLen, const WOLFSSL_ASN1_OBJECT *a,
int no_name)
{
int bufSz;
const char* desc;
const char* name;
WOLFSSL_ENTER("wolfSSL_OBJ_obj2txt");
if (buf == NULL || bufLen <= 1 || a == NULL) {
WOLFSSL_MSG("Bad input argument");
return WOLFSSL_FAILURE;
}
if (no_name == 1) {
return wolfssl_obj2txt_numeric(buf, bufLen, a);
}
/* return long name unless using x509small, then return short name */
#if defined(OPENSSL_EXTRA_X509_SMALL) && !defined(OPENSSL_EXTRA)
name = a->sName;
#else
name = wolfSSL_OBJ_nid2ln(wolfSSL_OBJ_obj2nid(a));
#endif
if (name == NULL) {
WOLFSSL_MSG("Name not found");
bufSz = 0;
}
else if (XSTRLEN(name) + 1 < (word32)bufLen - 1) {
bufSz = (int)XSTRLEN(name);
}
else {
bufSz = bufLen - 1;
}
if (bufSz) {
XMEMCPY(buf, name, (size_t)bufSz);
}
else if (a->type == WOLFSSL_GEN_DNS || a->type == WOLFSSL_GEN_EMAIL ||
a->type == WOLFSSL_GEN_URI) {
size_t objLen = XSTRLEN((const char*)a->obj);
if (objLen >= (size_t)bufLen) {
bufSz = bufLen - 1;
}
else {
bufSz = (int)objLen;
}
XMEMCPY(buf, a->obj, (size_t)bufSz);
}
else if ((bufSz = wolfssl_obj2txt_numeric(buf, bufLen, a)) > 0) {
if ((desc = oid_translate_num_to_str(buf))) {
bufSz = (int)XSTRLEN(desc);
bufSz = (int)min((word32)bufSz,(word32) bufLen - 1);
XMEMCPY(buf, desc, (size_t)bufSz);
}
}
else {
bufSz = 0;
}
buf[bufSz] = '\0';
return bufSz;
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_WPAS_SMALL)
/* Returns the long name that corresponds with an ASN1_OBJECT nid value.
* n : NID value of ASN1_OBJECT to search */
const char* wolfSSL_OBJ_nid2ln(int n)
{
const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
size_t i;
WOLFSSL_ENTER("wolfSSL_OBJ_nid2ln");
for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
if (obj_info->nid == n) {
return obj_info->lName;
}
}
WOLFSSL_MSG("NID not found in table");
return NULL;
}
#endif /* OPENSSL_EXTRA, HAVE_LIGHTY, WOLFSSL_MYSQL_COMPATIBLE, HAVE_STUNNEL,
WOLFSSL_NGINX, HAVE_POCO_LIB, WOLFSSL_HAPROXY, WOLFSSL_WPAS_SMALL */
#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
defined(WOLFSSL_HAPROXY)
/* Return the corresponding short name for the nid <n>.
* or NULL if short name can't be found.
*/
const char * wolfSSL_OBJ_nid2sn(int n) {
const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
size_t i;
WOLFSSL_ENTER("wolfSSL_OBJ_nid2sn");
if (n == WC_NID_md5) {
/* WC_NID_surname == WC_NID_md5 and WC_NID_surname comes before WC_NID_md5 in
* wolfssl_object_info. As a result, the loop below will incorrectly
* return "SN" instead of "MD5." WC_NID_surname isn't the true OpenSSL
* NID, but other functions rely on this table and modifying it to
* conform with OpenSSL's NIDs isn't trivial. */
return "MD5";
}
for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
if (obj_info->nid == n) {
return obj_info->sName;
}
}
WOLFSSL_MSG_EX("SN not found (nid:%d)",n);
return NULL;
}
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
int wolfSSL_OBJ_sn2nid(const char *sn) {
WOLFSSL_ENTER("wolfSSL_OBJ_sn2nid");
if (sn == NULL)
return WC_NID_undef;
return wc_OBJ_sn2nid(sn);
}
#endif
size_t wolfSSL_OBJ_length(const WOLFSSL_ASN1_OBJECT* o)
{
size_t ret = 0;
int err = 0;
word32 idx = 0;
int len = 0;
WOLFSSL_ENTER("wolfSSL_OBJ_length");
if (o == NULL || o->obj == NULL) {
WOLFSSL_MSG("Bad argument.");
err = 1;
}
if (err == 0 && GetASNObjectId(o->obj, &idx, &len, o->objSz)) {
WOLFSSL_MSG("Error parsing ASN.1 header.");
err = 1;
}
if (err == 0) {
ret = (size_t)len;
}
WOLFSSL_LEAVE("wolfSSL_OBJ_length", (int)ret);
return ret;
}
const unsigned char* wolfSSL_OBJ_get0_data(const WOLFSSL_ASN1_OBJECT* o)
{
const unsigned char* ret = NULL;
int err = 0;
word32 idx = 0;
int len = 0;
WOLFSSL_ENTER("wolfSSL_OBJ_get0_data");
if (o == NULL || o->obj == NULL) {
WOLFSSL_MSG("Bad argument.");
err = 1;
}
if (err == 0 && GetASNObjectId(o->obj, &idx, &len, o->objSz)) {
WOLFSSL_MSG("Error parsing ASN.1 header.");
err = 1;
}
if (err == 0) {
ret = o->obj + idx;
}
return ret;
}
/* Gets the NID value that corresponds with the ASN1 object.
*
* o ASN1 object to get NID of
*
* Return NID on success and a negative value on failure
*/
int wolfSSL_OBJ_obj2nid(const WOLFSSL_ASN1_OBJECT *o)
{
word32 oid = 0;
word32 idx = 0;
int ret;
#ifdef WOLFSSL_DEBUG_OPENSSL
WOLFSSL_ENTER("wolfSSL_OBJ_obj2nid");
#endif
if (o == NULL) {
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_QT
if (o->grp == oidCertExtType) {
/* If nid is an unknown extension, return WC_NID_undef */
if (wolfSSL_OBJ_nid2sn(o->nid) == NULL)
return WC_NID_undef;
}
#endif
if (o->nid > 0)
return o->nid;
if ((ret = GetObjectId(o->obj, &idx, &oid,
(word32)o->grp, o->objSz)) < 0) {
if (ret == WC_NO_ERR_TRACE(ASN_OBJECT_ID_E)) {
/* Put ASN object tag in front and try again */
int len = SetObjectId((int)o->objSz, NULL) + (int)o->objSz;
byte* buf = (byte*)XMALLOC((size_t)len, NULL,
DYNAMIC_TYPE_TMP_BUFFER);
if (!buf) {
WOLFSSL_MSG("malloc error");
return WOLFSSL_FATAL_ERROR;
}
idx = (word32)SetObjectId((int)o->objSz, buf);
XMEMCPY(buf + idx, o->obj, o->objSz);
idx = 0;
ret = GetObjectId(buf, &idx, &oid, (word32)o->grp, (word32)len);
XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
if (ret < 0) {
WOLFSSL_MSG("Issue getting OID of object");
return WOLFSSL_FATAL_ERROR;
}
}
else {
WOLFSSL_MSG("Issue getting OID of object");
return WOLFSSL_FATAL_ERROR;
}
}
return oid2nid(oid, o->grp);
}
/* Return the corresponding NID for the long name <ln>
* or WC_NID_undef if NID can't be found.
*/
int wolfSSL_OBJ_ln2nid(const char *ln)
{
const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
size_t lnlen;
WOLFSSL_ENTER("wolfSSL_OBJ_ln2nid");
if (ln && (lnlen = XSTRLEN(ln)) > 0) {
/* Accept input like "/commonName=" */
if (ln[0] == '/') {
ln++;
lnlen--;
}
if (lnlen) {
size_t i;
if (ln[lnlen-1] == '=') {
lnlen--;
}
for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
if (lnlen == XSTRLEN(obj_info->lName) &&
XSTRNCMP(ln, obj_info->lName, lnlen) == 0) {
return obj_info->nid;
}
}
}
}
return WC_NID_undef;
}
/* compares two objects, return 0 if equal */
int wolfSSL_OBJ_cmp(const WOLFSSL_ASN1_OBJECT* a,
const WOLFSSL_ASN1_OBJECT* b)
{
WOLFSSL_ENTER("wolfSSL_OBJ_cmp");
if (a && b && a->obj && b->obj) {
if (a->objSz == b->objSz) {
return XMEMCMP(a->obj, b->obj, a->objSz);
}
else if (a->type == EXT_KEY_USAGE_OID ||
b->type == EXT_KEY_USAGE_OID) {
/* Special case for EXT_KEY_USAGE_OID so that
* cmp will be treated as a substring search */
/* Used in libest to check for id-kp-cmcRA in
* EXT_KEY_USAGE extension */
unsigned int idx;
const byte* s; /* shorter */
unsigned int sLen;
const byte* l; /* longer */
unsigned int lLen;
if (a->objSz > b->objSz) {
s = b->obj; sLen = b->objSz;
l = a->obj; lLen = a->objSz;
}
else {
s = a->obj; sLen = a->objSz;
l = b->obj; lLen = b->objSz;
}
for (idx = 0; idx <= lLen - sLen; idx++) {
if (XMEMCMP(l + idx, s, sLen) == 0) {
/* Found substring */
return 0;
}
}
}
}
return WOLFSSL_FATAL_ERROR;
}
#endif /* OPENSSL_EXTRA, HAVE_LIGHTY, WOLFSSL_MYSQL_COMPATIBLE, HAVE_STUNNEL,
WOLFSSL_NGINX, HAVE_POCO_LIB, WOLFSSL_HAPROXY */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL) || \
defined(HAVE_LIGHTY) || defined(WOLFSSL_MYSQL_COMPATIBLE) || \
defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
defined(HAVE_POCO_LIB) || defined(WOLFSSL_HAPROXY)
/* Gets the NID value that is related to the OID string passed in. Example
* string would be "2.5.29.14" for subject key ID.
*
* returns NID value on success and WC_NID_undef on error
*/
int wolfSSL_OBJ_txt2nid(const char* s)
{
unsigned int i;
#ifdef WOLFSSL_CERT_EXT
int ret;
unsigned int sum = 0;
unsigned int outSz = MAX_OID_SZ;
unsigned char out[MAX_OID_SZ];
XMEMSET(out, 0, sizeof(out));
#endif
WOLFSSL_ENTER("wolfSSL_OBJ_txt2nid");
if (s == NULL) {
return WC_NID_undef;
}
#ifdef WOLFSSL_CERT_EXT
ret = EncodePolicyOID(out, &outSz, s, NULL);
if (ret == 0) {
/* sum OID */
sum = wc_oid_sum(out, outSz);
}
#endif /* WOLFSSL_CERT_EXT */
/* get the group that the OID's sum is in
* @TODO possible conflict with multiples */
for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++) {
int len;
#ifdef WOLFSSL_CERT_EXT
if (ret == 0) {
if (wolfssl_object_info[i].id == (int)sum) {
return wolfssl_object_info[i].nid;
}
}
#endif
/* try as a short name */
len = (int)XSTRLEN(s);
if ((int)XSTRLEN(wolfssl_object_info[i].sName) == len &&
XSTRNCMP(wolfssl_object_info[i].sName, s, (word32)len) == 0) {
return wolfssl_object_info[i].nid;
}
/* try as a long name */
if ((int)XSTRLEN(wolfssl_object_info[i].lName) == len &&
XSTRNCMP(wolfssl_object_info[i].lName, s, (word32)len) == 0) {
return wolfssl_object_info[i].nid;
}
}
return WC_NID_undef;
}
#endif
#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
defined(WOLFSSL_HAPROXY)
/* Creates new ASN1_OBJECT from short name, long name, or text
* representation of oid. If no_name is 0, then short name, long name, and
* numerical value of oid are interpreted. If no_name is 1, then only the
* numerical value of the oid is interpreted.
*
* Returns pointer to ASN1_OBJECT on success, or NULL on error.
*/
#if defined(WOLFSSL_CERT_EXT) && defined(WOLFSSL_CERT_GEN)
WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_txt2obj(const char* s, int no_name)
{
int i, ret;
int nid = WC_NID_undef;
unsigned int outSz = MAX_OID_SZ;
unsigned char out[MAX_OID_SZ];
WOLFSSL_ASN1_OBJECT* obj;
WOLFSSL_ENTER("wolfSSL_OBJ_txt2obj");
if (s == NULL)
return NULL;
/* If s is numerical value, try to sum oid */
ret = EncodePolicyOID(out, &outSz, s, NULL);
if (ret == 0 && outSz > 0) {
/* If numerical encode succeeded then just
* create object from that because sums are
* not unique and can cause confusion. */
obj = wolfSSL_ASN1_OBJECT_new();
if (obj == NULL) {
WOLFSSL_MSG("Issue creating WOLFSSL_ASN1_OBJECT struct");
return NULL;
}
obj->dynamic |= WOLFSSL_ASN1_DYNAMIC;
obj->obj = (byte*)XMALLOC(1 + MAX_LENGTH_SZ + outSz, NULL,
DYNAMIC_TYPE_ASN1);
if (obj->obj == NULL) {
wolfSSL_ASN1_OBJECT_free(obj);
return NULL;
}
obj->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA;
i = SetObjectId((int)outSz, (byte*)obj->obj);
XMEMCPY((byte*)obj->obj + i, out, outSz);
obj->objSz = (word32)i + outSz;
return obj;
}
/* TODO: update short names in wolfssl_object_info and check OID sums
are correct */
for (i = 0; i < (int)WOLFSSL_OBJECT_INFO_SZ; i++) {
/* Short name, long name, and numerical value are interpreted */
if (no_name == 0 &&
((XSTRCMP(s, wolfssl_object_info[i].sName) == 0) ||
(XSTRCMP(s, wolfssl_object_info[i].lName) == 0)))
{
nid = wolfssl_object_info[i].nid;
}
}
if (nid != WC_NID_undef)
return wolfSSL_OBJ_nid2obj(nid);
return NULL;
}
#endif
/* compatibility function. Its intended use is to remove OID's from an
* internal table that have been added with OBJ_create. wolfSSL manages its
* own internal OID values and does not currently support OBJ_create. */
void wolfSSL_OBJ_cleanup(void)
{
WOLFSSL_ENTER("wolfSSL_OBJ_cleanup");
}
#ifndef NO_WOLFSSL_STUB
int wolfSSL_OBJ_create(const char *oid, const char *sn, const char *ln)
{
(void)oid;
(void)sn;
(void)ln;
WOLFSSL_STUB("wolfSSL_OBJ_create");
return WOLFSSL_FAILURE;
}
#endif
void wolfSSL_set_verify_depth(WOLFSSL *ssl, int depth)
{
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
WOLFSSL_ENTER("wolfSSL_set_verify_depth");
ssl->options.verifyDepth = (byte)depth;
#endif
}
#endif /* OPENSSL_ALL || HAVE_LIGHTY || WOLFSSL_MYSQL_COMPATIBLE ||
HAVE_STUNNEL || WOLFSSL_NGINX || HAVE_POCO_LIB || WOLFSSL_HAPROXY */
#ifdef OPENSSL_EXTRA
/* wolfSSL uses negative values for error states. This function returns an
* unsigned type so the value returned is the absolute value of the error.
*/
unsigned long wolfSSL_ERR_peek_last_error_line(const char **file, int *line)
{
WOLFSSL_ENTER("wolfSSL_ERR_peek_last_error");
(void)line;
(void)file;
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
{
int ret;
if ((ret = wc_PeekErrorNode(-1, file, NULL, line)) < 0) {
WOLFSSL_MSG("Issue peeking at error node in queue");
return 0;
}
#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) \
|| defined(WOLFSSL_HAPROXY)
if (ret == -WC_NO_ERR_TRACE(ASN_NO_PEM_HEADER))
return (ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE;
#endif
#if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
if (ret == ASN1_R_HEADER_TOO_LONG) {
return (ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG;
}
#endif
return (unsigned long)ret;
}
#else
return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
}
#endif /* OPENSSL_EXTRA */
#ifdef HAVE_EX_DATA_CRYPTO
CRYPTO_EX_cb_ctx* crypto_ex_cb_ctx_session = NULL;
static int crypto_ex_cb_new(CRYPTO_EX_cb_ctx** dst, long ctx_l, void* ctx_ptr,
WOLFSSL_CRYPTO_EX_new* new_func, WOLFSSL_CRYPTO_EX_dup* dup_func,
WOLFSSL_CRYPTO_EX_free* free_func)
{
CRYPTO_EX_cb_ctx* new_ctx = (CRYPTO_EX_cb_ctx*)XMALLOC(
sizeof(CRYPTO_EX_cb_ctx), NULL, DYNAMIC_TYPE_OPENSSL);
if (new_ctx == NULL)
return WOLFSSL_FATAL_ERROR;
new_ctx->ctx_l = ctx_l;
new_ctx->ctx_ptr = ctx_ptr;
new_ctx->new_func = new_func;
new_ctx->free_func = free_func;
new_ctx->dup_func = dup_func;
new_ctx->next = NULL;
/* Push to end of list */
while (*dst != NULL)
dst = &(*dst)->next;
*dst = new_ctx;
return 0;
}
void crypto_ex_cb_free(CRYPTO_EX_cb_ctx* cb_ctx)
{
while (cb_ctx != NULL) {
CRYPTO_EX_cb_ctx* next = cb_ctx->next;
XFREE(cb_ctx, NULL, DYNAMIC_TYPE_OPENSSL);
cb_ctx = next;
}
}
void crypto_ex_cb_setup_new_data(void *new_obj, CRYPTO_EX_cb_ctx* cb_ctx,
WOLFSSL_CRYPTO_EX_DATA* ex_data)
{
int idx = 0;
for (; cb_ctx != NULL; idx++, cb_ctx = cb_ctx->next) {
if (cb_ctx->new_func != NULL)
cb_ctx->new_func(new_obj, NULL, ex_data, idx, cb_ctx->ctx_l,
cb_ctx->ctx_ptr);
}
}
int crypto_ex_cb_dup_data(const WOLFSSL_CRYPTO_EX_DATA *in,
WOLFSSL_CRYPTO_EX_DATA *out, CRYPTO_EX_cb_ctx* cb_ctx)
{
int idx = 0;
for (; cb_ctx != NULL; idx++, cb_ctx = cb_ctx->next) {
if (cb_ctx->dup_func != NULL) {
void* ptr = wolfSSL_CRYPTO_get_ex_data(in, idx);
if (!cb_ctx->dup_func(out, in,
&ptr, idx,
cb_ctx->ctx_l, cb_ctx->ctx_ptr)) {
return WOLFSSL_FAILURE;
}
wolfSSL_CRYPTO_set_ex_data(out, idx, ptr);
}
}
return WOLFSSL_SUCCESS;
}
void crypto_ex_cb_free_data(void *obj, CRYPTO_EX_cb_ctx* cb_ctx,
WOLFSSL_CRYPTO_EX_DATA* ex_data)
{
int idx = 0;
for (; cb_ctx != NULL; idx++, cb_ctx = cb_ctx->next) {
if (cb_ctx->free_func != NULL)
cb_ctx->free_func(obj, NULL, ex_data, idx, cb_ctx->ctx_l,
cb_ctx->ctx_ptr);
}
}
/**
* wolfssl_local_get_ex_new_index is a helper function for the following
* xx_get_ex_new_index functions:
* - wolfSSL_CRYPTO_get_ex_new_index
* - wolfSSL_CTX_get_ex_new_index
* - wolfSSL_get_ex_new_index
* Issues a unique index number for the specified class-index.
* Returns an index number greater or equal to zero on success,
* -1 on failure.
*/
int wolfssl_local_get_ex_new_index(int class_index, long ctx_l, void* ctx_ptr,
WOLFSSL_CRYPTO_EX_new* new_func, WOLFSSL_CRYPTO_EX_dup* dup_func,
WOLFSSL_CRYPTO_EX_free* free_func)
{
/* index counter for each class index*/
static int ctx_idx = 0;
static int ssl_idx = 0;
static int ssl_session_idx = 0;
static int x509_idx = 0;
int idx = -1;
switch(class_index) {
case WOLF_CRYPTO_EX_INDEX_SSL:
WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(ctx_l, ctx_ptr, new_func,
dup_func, free_func);
idx = ssl_idx++;
break;
case WOLF_CRYPTO_EX_INDEX_SSL_CTX:
WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(ctx_l, ctx_ptr, new_func,
dup_func, free_func);
idx = ctx_idx++;
break;
case WOLF_CRYPTO_EX_INDEX_X509:
WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(ctx_l, ctx_ptr, new_func,
dup_func, free_func);
idx = x509_idx++;
break;
case WOLF_CRYPTO_EX_INDEX_SSL_SESSION:
if (crypto_ex_cb_new(&crypto_ex_cb_ctx_session, ctx_l, ctx_ptr,
new_func, dup_func, free_func) != 0)
return WOLFSSL_FATAL_ERROR;
idx = ssl_session_idx++;
break;
/* following class indexes are not supoprted */
case WOLF_CRYPTO_EX_INDEX_X509_STORE:
case WOLF_CRYPTO_EX_INDEX_X509_STORE_CTX:
case WOLF_CRYPTO_EX_INDEX_DH:
case WOLF_CRYPTO_EX_INDEX_DSA:
case WOLF_CRYPTO_EX_INDEX_EC_KEY:
case WOLF_CRYPTO_EX_INDEX_RSA:
case WOLF_CRYPTO_EX_INDEX_ENGINE:
case WOLF_CRYPTO_EX_INDEX_UI:
case WOLF_CRYPTO_EX_INDEX_BIO:
case WOLF_CRYPTO_EX_INDEX_APP:
case WOLF_CRYPTO_EX_INDEX_UI_METHOD:
case WOLF_CRYPTO_EX_INDEX_DRBG:
default:
break;
}
if (idx >= MAX_EX_DATA)
return WOLFSSL_FATAL_ERROR;
return idx;
}
#endif /* HAVE_EX_DATA_CRYPTO */
#ifdef HAVE_EX_DATA_CRYPTO
int wolfSSL_CTX_get_ex_new_index(long idx, void* arg,
WOLFSSL_CRYPTO_EX_new* new_func,
WOLFSSL_CRYPTO_EX_dup* dup_func,
WOLFSSL_CRYPTO_EX_free* free_func)
{
WOLFSSL_ENTER("wolfSSL_CTX_get_ex_new_index");
return wolfssl_local_get_ex_new_index(WOLF_CRYPTO_EX_INDEX_SSL_CTX, idx,
arg, new_func, dup_func, free_func);
}
/* Return the index that can be used for the WOLFSSL structure to store
* application data.
*
*/
int wolfSSL_get_ex_new_index(long argValue, void* arg,
WOLFSSL_CRYPTO_EX_new* cb1, WOLFSSL_CRYPTO_EX_dup* cb2,
WOLFSSL_CRYPTO_EX_free* cb3)
{
WOLFSSL_ENTER("wolfSSL_get_ex_new_index");
return wolfssl_local_get_ex_new_index(WOLF_CRYPTO_EX_INDEX_SSL, argValue,
arg, cb1, cb2, cb3);
}
#endif /* HAVE_EX_DATA_CRYPTO */
#ifdef OPENSSL_EXTRA
void* wolfSSL_CTX_get_ex_data(const WOLFSSL_CTX* ctx, int idx)
{
WOLFSSL_ENTER("wolfSSL_CTX_get_ex_data");
#ifdef HAVE_EX_DATA
if (ctx != NULL) {
return wolfSSL_CRYPTO_get_ex_data(&ctx->ex_data, idx);
}
#else
(void)ctx;
(void)idx;
#endif
return NULL;
}
int wolfSSL_CTX_set_ex_data(WOLFSSL_CTX* ctx, int idx, void* data)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_ex_data");
#ifdef HAVE_EX_DATA
if (ctx != NULL) {
return wolfSSL_CRYPTO_set_ex_data(&ctx->ex_data, idx, data);
}
#else
(void)ctx;
(void)idx;
(void)data;
#endif
return WOLFSSL_FAILURE;
}
#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_CTX_set_ex_data_with_cleanup(
WOLFSSL_CTX* ctx,
int idx,
void* data,
wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_ex_data_with_cleanup");
if (ctx != NULL) {
return wolfSSL_CRYPTO_set_ex_data_with_cleanup(&ctx->ex_data, idx, data,
cleanup_routine);
}
return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* Returns char* to app data stored in ex[0].
*
* ssl WOLFSSL structure to get app data from
*/
void* wolfSSL_get_app_data(const WOLFSSL *ssl)
{
/* checkout exdata stuff... */
WOLFSSL_ENTER("wolfSSL_get_app_data");
return wolfSSL_get_ex_data(ssl, 0);
}
/* Set ex array 0 to have app data
*
* ssl WOLFSSL struct to set app data in
* arg data to be stored
*
* Returns WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on failure
*/
int wolfSSL_set_app_data(WOLFSSL *ssl, void* arg) {
WOLFSSL_ENTER("wolfSSL_set_app_data");
return wolfSSL_set_ex_data(ssl, 0, arg);
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
int wolfSSL_set_ex_data(WOLFSSL* ssl, int idx, void* data)
{
WOLFSSL_ENTER("wolfSSL_set_ex_data");
#ifdef HAVE_EX_DATA
if (ssl != NULL) {
return wolfSSL_CRYPTO_set_ex_data(&ssl->ex_data, idx, data);
}
#else
WOLFSSL_MSG("HAVE_EX_DATA macro is not defined");
(void)ssl;
(void)idx;
(void)data;
#endif
return WOLFSSL_FAILURE;
}
#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_set_ex_data_with_cleanup(
WOLFSSL* ssl,
int idx,
void* data,
wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
WOLFSSL_ENTER("wolfSSL_set_ex_data_with_cleanup");
if (ssl != NULL)
{
return wolfSSL_CRYPTO_set_ex_data_with_cleanup(&ssl->ex_data, idx, data,
cleanup_routine);
}
return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */
void* wolfSSL_get_ex_data(const WOLFSSL* ssl, int idx)
{
WOLFSSL_ENTER("wolfSSL_get_ex_data");
#ifdef HAVE_EX_DATA
if (ssl != NULL) {
return wolfSSL_CRYPTO_get_ex_data(&ssl->ex_data, idx);
}
#else
WOLFSSL_MSG("HAVE_EX_DATA macro is not defined");
(void)ssl;
(void)idx;
#endif
return 0;
}
#if defined(HAVE_LIGHTY) || defined(HAVE_STUNNEL) \
|| defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(OPENSSL_EXTRA)
/* returns the enum value associated with handshake state
*
* ssl the WOLFSSL structure to get state of
*/
int wolfSSL_get_state(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_state");
if (ssl == NULL) {
WOLFSSL_MSG("Null argument passed in");
return WOLFSSL_FAILURE;
}
return ssl->options.handShakeState;
}
#endif /* HAVE_LIGHTY || HAVE_STUNNEL || WOLFSSL_MYSQL_COMPATIBLE */
#ifdef OPENSSL_EXTRA
void wolfSSL_certs_clear(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_certs_clear");
if (ssl == NULL)
return;
/* ctx still owns certificate, certChain, key, dh, and cm */
if (ssl->buffers.weOwnCert) {
FreeDer(&ssl->buffers.certificate);
ssl->buffers.weOwnCert = 0;
}
ssl->buffers.certificate = NULL;
if (ssl->buffers.weOwnCertChain) {
FreeDer(&ssl->buffers.certChain);
ssl->buffers.weOwnCertChain = 0;
}
ssl->buffers.certChain = NULL;
#ifdef WOLFSSL_TLS13
ssl->buffers.certChainCnt = 0;
#endif
if (ssl->buffers.weOwnKey) {
FreeDer(&ssl->buffers.key);
#ifdef WOLFSSL_BLIND_PRIVATE_KEY
FreeDer(&ssl->buffers.keyMask);
#endif
ssl->buffers.weOwnKey = 0;
}
ssl->buffers.key = NULL;
#ifdef WOLFSSL_BLIND_PRIVATE_KEY
ssl->buffers.keyMask = NULL;
#endif
ssl->buffers.keyType = 0;
ssl->buffers.keyId = 0;
ssl->buffers.keyLabel = 0;
ssl->buffers.keySz = 0;
ssl->buffers.keyDevId = 0;
#ifdef WOLFSSL_DUAL_ALG_CERTS
if (ssl->buffers.weOwnAltKey) {
FreeDer(&ssl->buffers.altKey);
#ifdef WOLFSSL_BLIND_PRIVATE_KEY
FreeDer(&ssl->buffers.altKeyMask);
#endif
ssl->buffers.weOwnAltKey = 0;
}
ssl->buffers.altKey = NULL;
#ifdef WOLFSSL_BLIND_PRIVATE_KEY
ssl->buffers.altKeyMask = NULL;
#endif
#endif /* WOLFSSL_DUAL_ALG_CERTS */
}
#endif
#if defined(OPENSSL_ALL) || defined(WOLFSSL_ASIO) || defined(WOLFSSL_HAPROXY) \
|| defined(WOLFSSL_NGINX) || defined(WOLFSSL_QT)
long wolfSSL_ctrl(WOLFSSL* ssl, int cmd, long opt, void* pt)
{
WOLFSSL_ENTER("wolfSSL_ctrl");
if (ssl == NULL)
return BAD_FUNC_ARG;
switch (cmd) {
#if defined(WOLFSSL_NGINX) || defined(WOLFSSL_QT) || \
defined(OPENSSL_ALL)
#ifdef HAVE_SNI
case SSL_CTRL_SET_TLSEXT_HOSTNAME:
WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TLSEXT_HOSTNAME.");
if (pt == NULL) {
WOLFSSL_MSG("Passed in NULL Host Name.");
break;
}
return wolfSSL_set_tlsext_host_name(ssl, (const char*) pt);
#endif /* HAVE_SNI */
#endif /* WOLFSSL_NGINX || WOLFSSL_QT || OPENSSL_ALL */
default:
WOLFSSL_MSG("Case not implemented.");
}
(void)opt;
(void)pt;
return WOLFSSL_FAILURE;
}
long wolfSSL_CTX_ctrl(WOLFSSL_CTX* ctx, int cmd, long opt, void* pt)
{
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
long ctrl_opt;
#endif
long ret = WOLFSSL_SUCCESS;
WOLFSSL_ENTER("wolfSSL_CTX_ctrl");
if (ctx == NULL)
return WOLFSSL_FAILURE;
switch (cmd) {
case SSL_CTRL_CHAIN:
#ifdef SESSION_CERTS
{
/*
* We don't care about opt here because a copy of the certificate is
* stored anyway so increasing the reference counter is not necessary.
* Just check to make sure that it is set to one of the correct values.
*/
WOLF_STACK_OF(WOLFSSL_X509)* sk = (WOLF_STACK_OF(WOLFSSL_X509)*) pt;
WOLFSSL_X509* x509;
int i;
if (opt != 0 && opt != 1) {
ret = WOLFSSL_FAILURE;
break;
}
/* Clear certificate chain */
FreeDer(&ctx->certChain);
if (sk) {
for (i = 0; i < wolfSSL_sk_X509_num(sk); i++) {
x509 = wolfSSL_sk_X509_value(sk, i);
/* Prevent wolfSSL_CTX_add_extra_chain_cert from freeing cert */
if (wolfSSL_X509_up_ref(x509) != 1) {
WOLFSSL_MSG("Error increasing reference count");
continue;
}
if (wolfSSL_CTX_add_extra_chain_cert(ctx, x509) !=
WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Error adding certificate to context");
/* Decrease reference count on failure */
wolfSSL_X509_free(x509);
x509 = NULL;
}
}
}
/* Free previous chain */
wolfSSL_sk_X509_pop_free(ctx->x509Chain, NULL);
ctx->x509Chain = sk;
if (sk && opt == 1) {
/* up all refs when opt == 1 */
for (i = 0; i < wolfSSL_sk_X509_num(sk); i++) {
x509 = wolfSSL_sk_X509_value(sk, i);
if (wolfSSL_X509_up_ref(x509) != 1) {
WOLFSSL_MSG("Error increasing reference count");
continue;
}
}
}
}
#else
WOLFSSL_MSG("Session certificates not compiled in");
ret = WOLFSSL_FAILURE;
#endif
break;
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
case SSL_CTRL_OPTIONS:
WOLFSSL_MSG("Entering Case: SSL_CTRL_OPTIONS.");
ctrl_opt = wolfSSL_CTX_set_options(ctx, opt);
#ifdef WOLFSSL_QT
/* Set whether to use client or server cipher preference */
if ((ctrl_opt & WOLFSSL_OP_CIPHER_SERVER_PREFERENCE)
== WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) {
WOLFSSL_MSG("Using Server's Cipher Preference.");
ctx->useClientOrder = 0;
} else {
WOLFSSL_MSG("Using Client's Cipher Preference.");
ctx->useClientOrder = 1;
}
#endif /* WOLFSSL_QT */
return ctrl_opt;
#endif /* OPENSSL_EXTRA || HAVE_WEBSERVER */
case SSL_CTRL_EXTRA_CHAIN_CERT:
WOLFSSL_MSG("Entering Case: SSL_CTRL_EXTRA_CHAIN_CERT.");
if (pt == NULL) {
WOLFSSL_MSG("Passed in x509 pointer NULL.");
ret = WOLFSSL_FAILURE;
break;
}
return wolfSSL_CTX_add_extra_chain_cert(ctx, (WOLFSSL_X509*)pt);
#ifndef NO_DH
case SSL_CTRL_SET_TMP_DH:
WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TMP_DH.");
if (pt == NULL) {
WOLFSSL_MSG("Passed in DH pointer NULL.");
ret = WOLFSSL_FAILURE;
break;
}
return wolfSSL_CTX_set_tmp_dh(ctx, (WOLFSSL_DH*)pt);
#endif
#ifdef HAVE_ECC
case SSL_CTRL_SET_TMP_ECDH:
WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TMP_ECDH.");
if (pt == NULL) {
WOLFSSL_MSG("Passed in ECDH pointer NULL.");
ret = WOLFSSL_FAILURE;
break;
}
return wolfSSL_SSL_CTX_set_tmp_ecdh(ctx, (WOLFSSL_EC_KEY*)pt);
#endif
case SSL_CTRL_MODE:
wolfSSL_CTX_set_mode(ctx,opt);
break;
case SSL_CTRL_SET_MIN_PROTO_VERSION:
WOLFSSL_MSG("set min proto version");
return wolfSSL_CTX_set_min_proto_version(ctx, (int)opt);
case SSL_CTRL_SET_MAX_PROTO_VERSION:
WOLFSSL_MSG("set max proto version");
return wolfSSL_CTX_set_max_proto_version(ctx, (int)opt);
case SSL_CTRL_GET_MIN_PROTO_VERSION:
WOLFSSL_MSG("get min proto version");
return wolfSSL_CTX_get_min_proto_version(ctx);
case SSL_CTRL_GET_MAX_PROTO_VERSION:
WOLFSSL_MSG("get max proto version");
return wolfSSL_CTX_get_max_proto_version(ctx);
default:
WOLFSSL_MSG("CTX_ctrl cmd not implemented");
ret = WOLFSSL_FAILURE;
break;
}
(void)ctx;
(void)cmd;
(void)opt;
(void)pt;
WOLFSSL_LEAVE("wolfSSL_CTX_ctrl", (int)ret);
return ret;
}
#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_callback_ctrl(WOLFSSL_CTX* ctx, int cmd, void (*fp)(void))
{
(void) ctx;
(void) cmd;
(void) fp;
WOLFSSL_STUB("wolfSSL_CTX_callback_ctrl");
return WOLFSSL_FAILURE;
}
#endif /* NO_WOLFSSL_STUB */
#endif /* OPENSSL_ALL || WOLFSSL_ASIO || WOLFSSL_HAPROXY || WOLFSSL_QT */
/* stunnel compatibility functions*/
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && \
(defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
defined(HAVE_LIGHTY) || defined(WOLFSSL_HAPROXY) || \
defined(WOLFSSL_OPENSSH)))
void wolfSSL_ERR_remove_thread_state(void* pid)
{
(void) pid;
return;
}
#ifndef NO_FILESYSTEM
/***TBD ***/
void wolfSSL_print_all_errors_fp(XFILE fp)
{
(void)fp;
}
#endif /* !NO_FILESYSTEM */
#endif /* OPENSSL_ALL || OPENSSL_EXTRA || HAVE_STUNNEL || WOLFSSL_NGINX ||
HAVE_LIGHTY || WOLFSSL_HAPROXY || WOLFSSL_OPENSSH */
/* Note: This is a huge section of API's - through
* wolfSSL_X509_OBJECT_get0_X509_CRL */
#if defined(OPENSSL_ALL) || defined(OPENSSL_EXTRA)
#if defined(USE_WOLFSSL_MEMORY) && !defined(WOLFSSL_DEBUG_MEMORY) && \
!defined(WOLFSSL_STATIC_MEMORY)
static wolfSSL_OSSL_Malloc_cb ossl_malloc = NULL;
static wolfSSL_OSSL_Free_cb ossl_free = NULL;
static wolfSSL_OSSL_Realloc_cb ossl_realloc = NULL;
static void* OSSL_Malloc(size_t size)
{
if (ossl_malloc != NULL)
return ossl_malloc(size, NULL, 0);
else
return NULL;
}
static void OSSL_Free(void *ptr)
{
if (ossl_free != NULL)
ossl_free(ptr, NULL, 0);
}
static void* OSSL_Realloc(void *ptr, size_t size)
{
if (ossl_realloc != NULL)
return ossl_realloc(ptr, size, NULL, 0);
else
return NULL;
}
#endif /* USE_WOLFSSL_MEMORY && !WOLFSSL_DEBUG_MEMORY &&
* !WOLFSSL_STATIC_MEMORY */
int wolfSSL_CRYPTO_set_mem_functions(
wolfSSL_OSSL_Malloc_cb m,
wolfSSL_OSSL_Realloc_cb r,
wolfSSL_OSSL_Free_cb f)
{
#if defined(USE_WOLFSSL_MEMORY) && !defined(WOLFSSL_STATIC_MEMORY)
#ifdef WOLFSSL_DEBUG_MEMORY
WOLFSSL_MSG("mem functions will receive function name instead of "
"file name");
if (wolfSSL_SetAllocators((wolfSSL_Malloc_cb)m, (wolfSSL_Free_cb)f,
(wolfSSL_Realloc_cb)r) == 0)
return WOLFSSL_SUCCESS;
#else
WOLFSSL_MSG("wolfSSL was compiled without WOLFSSL_DEBUG_MEMORY mem "
"functions will receive a NULL file name and 0 for the "
"line number.");
if (wolfSSL_SetAllocators((wolfSSL_Malloc_cb)OSSL_Malloc,
(wolfSSL_Free_cb)OSSL_Free, (wolfSSL_Realloc_cb)OSSL_Realloc) == 0) {
ossl_malloc = m;
ossl_free = f;
ossl_realloc = r;
return WOLFSSL_SUCCESS;
}
#endif
else
return WOLFSSL_FAILURE;
#else
(void)m;
(void)r;
(void)f;
WOLFSSL_MSG("wolfSSL allocator callback functions not compiled in");
return WOLFSSL_FAILURE;
#endif
}
int wolfSSL_ERR_load_ERR_strings(void)
{
return WOLFSSL_SUCCESS;
}
void wolfSSL_ERR_load_crypto_strings(void)
{
WOLFSSL_ENTER("wolfSSL_ERR_load_crypto_strings");
/* Do nothing */
return;
}
int wolfSSL_FIPS_mode(void)
{
#ifdef HAVE_FIPS
return 1;
#else
return 0;
#endif
}
int wolfSSL_FIPS_mode_set(int r)
{
#ifdef HAVE_FIPS
if (r == 0) {
WOLFSSL_MSG("Cannot disable FIPS at runtime.");
return WOLFSSL_FAILURE;
}
return WOLFSSL_SUCCESS;
#else
if (r == 0) {
return WOLFSSL_SUCCESS;
}
WOLFSSL_MSG("Cannot enable FIPS. This isn't the wolfSSL FIPS code.");
return WOLFSSL_FAILURE;
#endif
}
int wolfSSL_CIPHER_get_bits(const WOLFSSL_CIPHER *c, int *alg_bits)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
WOLFSSL_ENTER("wolfSSL_CIPHER_get_bits");
#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
(void)alg_bits;
if (c!= NULL)
ret = c->bits;
#else
if (c != NULL && c->ssl != NULL) {
ret = 8 * c->ssl->specs.key_size;
if (alg_bits != NULL) {
*alg_bits = ret;
}
}
#endif
return ret;
}
WOLFSSL_CTX* wolfSSL_set_SSL_CTX(WOLFSSL* ssl, WOLFSSL_CTX* ctx)
{
int ret;
/* This method requires some explanation. Its sibling is
* int SetSSL_CTX(WOLFSSL* ssl, WOLFSSL_CTX* ctx, int writeDup)
* which re-inits the WOLFSSL* with all settings in the new CTX.
* That one is the right one to use *before* a handshake is started.
*
* This method was added by OpenSSL to be used *during* the handshake, e.g.
* when a server inspects the SNI in a ClientHello callback and
* decides which set of certificates to use.
*
* Since, at the time the SNI callback is run, some decisions on
* Extensions or the ServerHello might already have been taken, this
* method is very restricted in what it does:
* - changing the server certificate(s)
* - changing the server id for session handling
* and everything else in WOLFSSL* needs to remain untouched.
*
* SECURITY: swapping ssl->ctx switches cm-resolved settings (CA store,
* CRL, OCSP) to the new CTX but leaves ssl-cached ones (verify mode and
* callback, minDowngrade, key-size minimums, suites, version bounds)
* pinned to the original. SNI callbacks must re-apply those ssl-level
* settings explicitly; CRL/OCSP isolation requires an SSL-local store.
*/
WOLFSSL_ENTER("wolfSSL_set_SSL_CTX");
if (ssl == NULL || ctx == NULL)
return NULL;
if (ssl->ctx == ctx)
return ssl->ctx;
if (ctx->suites == NULL) {
/* suites */
if (AllocateCtxSuites(ctx) != 0)
return NULL;
InitSSL_CTX_Suites(ctx);
}
wolfSSL_RefWithMutexInc(&ctx->ref, &ret);
#ifdef WOLFSSL_REFCNT_ERROR_RETURN
if (ret != 0) {
/* can only fail on serious stuff, like mutex not working
* or ctx refcount out of whack. */
return NULL;
}
#else
(void)ret;
#endif
if (ssl->ctx != NULL)
wolfSSL_CTX_free(ssl->ctx);
ssl->ctx = ctx;
#ifndef NO_CERTS
#ifdef WOLFSSL_COPY_CERT
/* If WOLFSSL_COPY_CERT defined, always make new copy of cert from ctx */
if (ctx->certificate != NULL) {
if (ssl->buffers.certificate != NULL) {
FreeDer(&ssl->buffers.certificate);
ssl->buffers.certificate = NULL;
}
ret = AllocCopyDer(&ssl->buffers.certificate, ctx->certificate->buffer,
ctx->certificate->length, ctx->certificate->type,
ctx->certificate->heap);
if (ret != 0) {
ssl->buffers.weOwnCert = 0;
return NULL;
}
ssl->buffers.weOwnCert = 1;
}
if (ctx->certChain != NULL) {
if (ssl->buffers.certChain != NULL) {
FreeDer(&ssl->buffers.certChain);
ssl->buffers.certChain = NULL;
}
ret = AllocCopyDer(&ssl->buffers.certChain, ctx->certChain->buffer,
ctx->certChain->length, ctx->certChain->type,
ctx->certChain->heap);
if (ret != 0) {
ssl->buffers.weOwnCertChain = 0;
return NULL;
}
ssl->buffers.weOwnCertChain = 1;
}
#else
/* ctx owns certificate, certChain and key */
ssl->buffers.certificate = ctx->certificate;
ssl->buffers.certChain = ctx->certChain;
#endif
#ifdef WOLFSSL_TLS13
ssl->buffers.certChainCnt = ctx->certChainCnt;
#endif
#ifndef WOLFSSL_BLIND_PRIVATE_KEY
#ifdef WOLFSSL_COPY_KEY
if (ssl->buffers.key != NULL && ssl->buffers.weOwnKey) {
FreeDer(&ssl->buffers.key);
}
if (ctx->privateKey != NULL) {
ret = AllocCopyDer(&ssl->buffers.key, ctx->privateKey->buffer,
ctx->privateKey->length, ctx->privateKey->type,
ctx->privateKey->heap);
if (ret != 0) {
ssl->buffers.weOwnKey = 0;
return NULL;
}
ssl->buffers.weOwnKey = 1;
}
else {
ssl->buffers.key = ctx->privateKey;
}
#else
ssl->buffers.key = ctx->privateKey;
#endif
#else
if (ctx->privateKey != NULL) {
if (ssl->buffers.key != NULL && ssl->buffers.weOwnKey) {
FreeDer(&ssl->buffers.key);
}
ret = AllocCopyDer(&ssl->buffers.key, ctx->privateKey->buffer,
ctx->privateKey->length, ctx->privateKey->type,
ctx->privateKey->heap);
if (ret != 0) {
return NULL;
}
/* Blind the private key for the SSL with new random mask. */
wolfssl_priv_der_blind_toggle(ssl->buffers.key, ctx->privateKeyMask);
ret = wolfssl_priv_der_blind(ssl->rng, ssl->buffers.key,
&ssl->buffers.keyMask);
if (ret != 0) {
return NULL;
}
}
#endif
ssl->buffers.keyType = ctx->privateKeyType;
ssl->buffers.keyId = ctx->privateKeyId;
ssl->buffers.keyLabel = ctx->privateKeyLabel;
ssl->buffers.keySz = ctx->privateKeySz;
ssl->buffers.keyDevId = ctx->privateKeyDevId;
/* flags indicating what certs/keys are available */
ssl->options.haveRSA = ctx->haveRSA;
ssl->options.haveDH = ctx->haveDH;
ssl->options.haveECDSAsig = ctx->haveECDSAsig;
ssl->options.haveECC = ctx->haveECC;
ssl->options.haveStaticECC = ctx->haveStaticECC;
ssl->options.haveFalconSig = ctx->haveFalconSig;
ssl->options.haveMlDsaSig = ctx->haveMlDsaSig;
#ifdef WOLFSSL_DUAL_ALG_CERTS
#ifndef WOLFSSL_BLIND_PRIVATE_KEY
ssl->buffers.altKey = ctx->altPrivateKey;
#else
if (ctx->altPrivateKey != NULL) {
ret = AllocCopyDer(&ssl->buffers.altKey, ctx->altPrivateKey->buffer,
ctx->altPrivateKey->length, ctx->altPrivateKey->type,
ctx->altPrivateKey->heap);
if (ret != 0) {
return NULL;
}
/* Blind the private key for the SSL with new random mask. */
wolfssl_priv_der_blind_toggle(ssl->buffers.altKey,
ctx->altPrivateKeyMask);
ret = wolfssl_priv_der_blind(ssl->rng, ssl->buffers.altKey,
&ssl->buffers.altKeyMask);
if (ret != 0) {
return NULL;
}
}
#endif
ssl->buffers.altKeySz = ctx->altPrivateKeySz;
ssl->buffers.altKeyType = ctx->altPrivateKeyType;
#endif /* WOLFSSL_DUAL_ALG_CERTS */
#endif
#ifdef WOLFSSL_SESSION_ID_CTX
/* copy over application session context ID */
ssl->sessionCtxSz = ctx->sessionCtxSz;
XMEMCPY(ssl->sessionCtx, ctx->sessionCtx, ctx->sessionCtxSz);
#endif
return ssl->ctx;
}
#ifndef NO_BIO
void wolfSSL_ERR_load_BIO_strings(void) {
WOLFSSL_ENTER("wolfSSL_ERR_load_BIO_strings");
/* do nothing */
}
#endif
#ifndef NO_WOLFSSL_STUB
/* Set THREADID callback, return 1 on success, 0 on error */
int wolfSSL_THREADID_set_callback(
void(*threadid_func)(WOLFSSL_CRYPTO_THREADID*))
{
WOLFSSL_ENTER("wolfSSL_THREADID_set_callback");
WOLFSSL_STUB("CRYPTO_THREADID_set_callback");
(void)threadid_func;
return 1;
}
#endif
#ifndef NO_WOLFSSL_STUB
void wolfSSL_THREADID_set_numeric(void* id, unsigned long val)
{
WOLFSSL_ENTER("wolfSSL_THREADID_set_numeric");
WOLFSSL_STUB("CRYPTO_THREADID_set_numeric");
(void)id;
(void)val;
return;
}
#endif
#endif /* OPENSSL_ALL || OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA)
int wolfSSL_CRYPTO_memcmp(const void *a, const void *b, size_t size)
{
int ret = 0;
int chunk;
const byte* pa = (const byte*)a;
const byte* pb = (const byte*)b;
if (!a || !b)
return -1;
/* ConstantCompare takes an int length. Compare in chunks of at most
* INT_MAX so a size that does not fit in an int is not narrowed into a
* negative or truncated length, which could wrongly report equality. */
while (size > 0) {
chunk = (size > (size_t)INT_MAX) ? INT_MAX : (int)size;
ret |= ConstantCompare(pa, pb, chunk);
pa += chunk;
pb += chunk;
size -= (size_t)chunk;
}
return ret;
}
unsigned long wolfSSL_ERR_peek_last_error(void)
{
WOLFSSL_ENTER("wolfSSL_ERR_peek_last_error");
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
{
int ret;
if ((ret = wc_PeekErrorNode(-1, NULL, NULL, NULL)) < 0) {
WOLFSSL_MSG("Issue peeking at error node in queue");
return 0;
}
if (ret == -WC_NO_ERR_TRACE(ASN_NO_PEM_HEADER))
return (WOLFSSL_ERR_LIB_PEM << 24) | -WC_NO_ERR_TRACE(WOLFSSL_PEM_R_NO_START_LINE_E);
#if defined(WOLFSSL_PYTHON)
if (ret == ASN1_R_HEADER_TOO_LONG)
return (WOLFSSL_ERR_LIB_ASN1 << 24) | -WC_NO_ERR_TRACE(WOLFSSL_ASN1_R_HEADER_TOO_LONG_E);
#endif
return (unsigned long)ret;
}
#else
return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
}
#endif /* OPENSSL_EXTRA */
int wolfSSL_version(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_version");
if (ssl->version.major == SSLv3_MAJOR) {
switch (ssl->version.minor) {
case SSLv3_MINOR :
return SSL3_VERSION;
case TLSv1_MINOR :
return TLS1_VERSION;
case TLSv1_1_MINOR :
return TLS1_1_VERSION;
case TLSv1_2_MINOR :
return TLS1_2_VERSION;
case TLSv1_3_MINOR :
return TLS1_3_VERSION;
default:
return WOLFSSL_FAILURE;
}
}
else if (ssl->version.major == DTLS_MAJOR) {
switch (ssl->version.minor) {
case DTLS_MINOR :
return DTLS1_VERSION;
case DTLSv1_2_MINOR :
return DTLS1_2_VERSION;
case DTLSv1_3_MINOR:
return DTLS1_3_VERSION;
default:
return WOLFSSL_FAILURE;
}
}
return WOLFSSL_FAILURE;
}
WOLFSSL_CTX* wolfSSL_get_SSL_CTX(const WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_SSL_CTX");
return ssl->ctx;
}
#ifdef WOLFSSL_JNI
int wolfSSL_set_jobject(WOLFSSL* ssl, void* objPtr)
{
WOLFSSL_ENTER("wolfSSL_set_jobject");
if (ssl != NULL)
{
ssl->jObjectRef = objPtr;
return WOLFSSL_SUCCESS;
}
return WOLFSSL_FAILURE;
}
void* wolfSSL_get_jobject(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_jobject");
if (ssl != NULL)
return ssl->jObjectRef;
return NULL;
}
#endif /* WOLFSSL_JNI */
#ifdef WOLFSSL_ASYNC_CRYPT
int wolfSSL_CTX_AsyncPoll(WOLFSSL_CTX* ctx, WOLF_EVENT** events, int maxEvents,
WOLF_EVENT_FLAG flags, int* eventCount)
{
if (ctx == NULL) {
return BAD_FUNC_ARG;
}
return wolfAsync_EventQueuePoll(&ctx->event_queue, NULL,
events, maxEvents, flags, eventCount);
}
int wolfSSL_AsyncPoll(WOLFSSL* ssl, WOLF_EVENT_FLAG flags)
{
int ret, eventCount = 0;
WOLF_EVENT* events[1];
if (ssl == NULL) {
return BAD_FUNC_ARG;
}
ret = wolfAsync_EventQueuePoll(&ssl->ctx->event_queue, ssl,
events, sizeof(events)/sizeof(events[0]), flags, &eventCount);
if (ret == 0) {
ret = eventCount;
}
return ret;
}
#endif /* WOLFSSL_ASYNC_CRYPT */
#ifdef OPENSSL_EXTRA
static int peek_ignore_err(int err)
{
switch(err) {
case -WC_NO_ERR_TRACE(WANT_READ):
case -WC_NO_ERR_TRACE(WANT_WRITE):
case -WC_NO_ERR_TRACE(ZERO_RETURN):
case -WOLFSSL_ERROR_ZERO_RETURN:
case -WC_NO_ERR_TRACE(SOCKET_PEER_CLOSED_E):
case -WC_NO_ERR_TRACE(SOCKET_ERROR_E):
return 1;
default:
return 0;
}
}
unsigned long wolfSSL_ERR_peek_error_line_data(const char **file, int *line,
const char **data, int *flags)
{
unsigned long err;
WOLFSSL_ENTER("wolfSSL_ERR_peek_error_line_data");
err = wc_PeekErrorNodeLineData(file, line, data, flags, peek_ignore_err);
if (err == -WC_NO_ERR_TRACE(ASN_NO_PEM_HEADER))
return (WOLFSSL_ERR_LIB_PEM << 24) | -WC_NO_ERR_TRACE(WOLFSSL_PEM_R_NO_START_LINE_E);
#ifdef OPENSSL_ALL
/* PARSE_ERROR is returned if an HTTP request is detected. */
else if (err == -WC_NO_ERR_TRACE(PARSE_ERROR))
return (WOLFSSL_ERR_LIB_SSL << 24) | -WC_NO_ERR_TRACE(PARSE_ERROR) /* SSL_R_HTTP_REQUEST */;
#endif
#if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
else if (err == ASN1_R_HEADER_TOO_LONG)
return (WOLFSSL_ERR_LIB_ASN1 << 24) | -WC_NO_ERR_TRACE(WOLFSSL_ASN1_R_HEADER_TOO_LONG_E);
#endif
return err;
}
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL) || \
defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)
#if !defined(WOLFSSL_USER_IO)
/* converts an IPv6 or IPv4 address into an octet string for use with rfc3280
* example input would be "127.0.0.1" and the returned value would be 7F000001
*/
WOLFSSL_ASN1_STRING* wolfSSL_a2i_IPADDRESS(const char* ipa)
{
int ipaSz = WOLFSSL_IP4_ADDR_LEN;
char buf[WOLFSSL_IP6_ADDR_LEN + 1]; /* plus 1 for terminator */
int af = WOLFSSL_IP4;
WOLFSSL_ASN1_STRING *ret = NULL;
if (ipa == NULL)
return NULL;
if (XSTRSTR(ipa, ":") != NULL) {
af = WOLFSSL_IP6;
ipaSz = WOLFSSL_IP6_ADDR_LEN;
}
buf[WOLFSSL_IP6_ADDR_LEN] = '\0';
#ifdef FREESCALE_MQX
if (XINET_PTON(af, ipa, (void*)buf, sizeof(buf)) != RTCS_OK) {
#else
if (XINET_PTON(af, ipa, (void*)buf) != 1) {
#endif
WOLFSSL_MSG("Error parsing IP address");
return NULL;
}
ret = wolfSSL_ASN1_STRING_new();
if (ret != NULL) {
if (wolfSSL_ASN1_STRING_set(ret, buf, ipaSz) != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Error setting the string");
wolfSSL_ASN1_STRING_free(ret);
ret = NULL;
}
}
return ret;
}
#endif /* !WOLFSSL_USER_IO */
/* Is the specified cipher suite a fake one used an an extension proxy? */
static WC_INLINE int SCSV_Check(byte suite0, byte suite)
{
(void)suite0;
(void)suite;
#ifdef HAVE_RENEGOTIATION_INDICATION
if (suite0 == CIPHER_BYTE && suite == TLS_EMPTY_RENEGOTIATION_INFO_SCSV)
return 1;
#endif
return 0;
}
static WC_INLINE int sslCipherMinMaxCheck(const WOLFSSL *ssl, byte suite0,
byte suite)
{
const CipherSuiteInfo* cipher_names = GetCipherNames();
int cipherSz = GetCipherNamesSize();
int i;
for (i = 0; i < cipherSz; i++)
if (cipher_names[i].cipherSuite0 == suite0 &&
cipher_names[i].cipherSuite == suite)
break;
if (i == cipherSz)
return 1;
/* Check min version */
if (cipher_names[i].minor < ssl->options.minDowngrade) {
if (ssl->options.minDowngrade <= TLSv1_2_MINOR &&
cipher_names[i].minor >= TLSv1_MINOR)
/* 1.0 ciphersuites are in general available in 1.1 and
* 1.1 ciphersuites are in general available in 1.2 */
return 0;
return 1;
}
/* Check max version */
switch (cipher_names[i].minor) {
case SSLv3_MINOR :
return ssl->options.mask & WOLFSSL_OP_NO_SSLv3;
case TLSv1_MINOR :
return ssl->options.mask & WOLFSSL_OP_NO_TLSv1;
case TLSv1_1_MINOR :
return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_1;
case TLSv1_2_MINOR :
return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_2;
case TLSv1_3_MINOR :
return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_3;
default:
WOLFSSL_MSG("Unrecognized minor version");
return 1;
}
}
/* returns a pointer to internal cipher suite list. Should not be free'd by
* caller.
*/
WOLF_STACK_OF(WOLFSSL_CIPHER) *wolfSSL_get_ciphers_compat(const WOLFSSL *ssl)
{
const Suites* suites;
#if defined(OPENSSL_ALL)
const CipherSuiteInfo* cipher_names = GetCipherNames();
int cipherSz = GetCipherNamesSize();
#endif
WOLFSSL_ENTER("wolfSSL_get_ciphers_compat");
if (ssl == NULL)
return NULL;
suites = WOLFSSL_SUITES(ssl);
if (suites == NULL)
return NULL;
/* check if stack needs populated */
if (ssl->suitesStack == NULL) {
int i;
((WOLFSSL*)ssl)->suitesStack =
wolfssl_sk_new_type_ex(STACK_TYPE_CIPHER, ssl->heap);
if (ssl->suitesStack == NULL)
return NULL;
/* higher priority of cipher suite will be on top of stack */
#if defined(OPENSSL_ALL)
for (i = suites->suiteSz - 2; i >=0; i-=2)
#else
for (i = 0; i < suites->suiteSz; i+=2)
#endif
{
struct WOLFSSL_CIPHER cipher;
/* A couple of suites are placeholders for special options,
* skip those. */
if (SCSV_Check(suites->suites[i], suites->suites[i+1])
|| sslCipherMinMaxCheck(ssl, suites->suites[i],
suites->suites[i+1])) {
continue;
}
XMEMSET(&cipher, 0, sizeof(cipher));
cipher.cipherSuite0 = suites->suites[i];
cipher.cipherSuite = suites->suites[i+1];
cipher.ssl = ssl;
#if defined(OPENSSL_ALL)
cipher.in_stack = 1;
{
int j;
for (j = 0; j < cipherSz; j++) {
if (cipher_names[j].cipherSuite0 == cipher.cipherSuite0 &&
cipher_names[j].cipherSuite == cipher.cipherSuite) {
cipher.offset = (unsigned long)j;
break;
}
}
}
#endif
if (wolfSSL_sk_insert(ssl->suitesStack, &cipher, 0) <= 0) {
WOLFSSL_MSG("Error inserting cipher onto stack");
wolfSSL_sk_CIPHER_free(ssl->suitesStack);
((WOLFSSL*)ssl)->suitesStack = NULL;
break;
}
}
/* If no ciphers were added, free empty stack and return NULL */
if (ssl->suitesStack != NULL && wolfSSL_sk_num(ssl->suitesStack) == 0) {
wolfSSL_sk_CIPHER_free(ssl->suitesStack);
((WOLFSSL*)ssl)->suitesStack = NULL;
}
}
return ssl->suitesStack;
}
#endif /* OPENSSL_EXTRA || OPENSSL_ALL || WOLFSSL_NGINX || WOLFSSL_HAPROXY */
#ifdef OPENSSL_ALL
/* returned pointer is to an internal element in WOLFSSL struct and should not
* be free'd. It gets free'd when the WOLFSSL struct is free'd. */
WOLF_STACK_OF(WOLFSSL_CIPHER)* wolfSSL_get_client_ciphers(WOLFSSL* ssl)
{
WOLF_STACK_OF(WOLFSSL_CIPHER)* ret = NULL;
const CipherSuiteInfo* cipher_names = GetCipherNames();
int cipherSz = GetCipherNamesSize();
const Suites* suites;
WOLFSSL_ENTER("wolfSSL_get_client_ciphers");
if (ssl == NULL) {
return NULL;
}
/* return NULL if is client side */
if (wolfSSL_is_server(ssl) == 0) {
return NULL;
}
suites = ssl->clSuites;
if (suites == NULL) {
WOLFSSL_MSG("No client suites stored");
}
else if (ssl->clSuitesStack != NULL) {
ret = ssl->clSuitesStack;
}
else { /* generate cipher suites stack if not already done */
int i;
int j;
ret = wolfSSL_sk_new_node(ssl->heap);
if (ret != NULL) {
ret->type = STACK_TYPE_CIPHER;
/* higher priority of cipher suite will be on top of stack */
for (i = suites->suiteSz - 2; i >= 0; i -= 2) {
WOLFSSL_CIPHER cipher;
/* A couple of suites are placeholders for special options,
* skip those. */
if (SCSV_Check(suites->suites[i], suites->suites[i+1])
|| sslCipherMinMaxCheck(ssl, suites->suites[i],
suites->suites[i+1])) {
continue;
}
cipher.cipherSuite0 = suites->suites[i];
cipher.cipherSuite = suites->suites[i+1];
cipher.ssl = ssl;
for (j = 0; j < cipherSz; j++) {
if (cipher_names[j].cipherSuite0 ==
cipher.cipherSuite0 &&
cipher_names[j].cipherSuite ==
cipher.cipherSuite) {
cipher.offset = (unsigned long)j;
break;
}
}
/* in_stack is checked in wolfSSL_CIPHER_description */
cipher.in_stack = 1;
if (wolfSSL_sk_CIPHER_push(ret, &cipher) <= 0) {
WOLFSSL_MSG("Error pushing client cipher onto stack");
wolfSSL_sk_CIPHER_free(ret);
ret = NULL;
break;
}
}
}
ssl->clSuitesStack = ret;
}
return ret;
}
#endif /* OPENSSL_ALL */
#if defined(OPENSSL_EXTRA) || defined(HAVE_SECRET_CALLBACK)
long wolfSSL_SSL_CTX_get_timeout(const WOLFSSL_CTX *ctx)
{
WOLFSSL_ENTER("wolfSSL_SSL_CTX_get_timeout");
if (ctx == NULL)
return 0;
return ctx->timeout;
}
/* returns the time in seconds of the current timeout */
long wolfSSL_get_timeout(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_get_timeout");
if (ssl == NULL)
return 0;
return ssl->timeout;
}
#endif
#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) \
|| defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY)
#ifndef NO_BIO
WOLFSSL_BIO *wolfSSL_SSL_get_rbio(const WOLFSSL *s)
{
WOLFSSL_ENTER("wolfSSL_SSL_get_rbio");
/* Nginx sets the buffer size if the read BIO is different to write BIO.
* The setting buffer size doesn't do anything so return NULL for both.
*/
if (s == NULL)
return NULL;
return s->biord;
}
WOLFSSL_BIO *wolfSSL_SSL_get_wbio(const WOLFSSL *s)
{
WOLFSSL_ENTER("wolfSSL_SSL_get_wbio");
(void)s;
/* Nginx sets the buffer size if the read BIO is different to write BIO.
* The setting buffer size doesn't do anything so return NULL for both.
*/
if (s == NULL)
return NULL;
return s->biowr;
}
#endif /* !NO_BIO */
#ifndef NO_TLS
int wolfSSL_SSL_do_handshake_internal(WOLFSSL *s)
{
WOLFSSL_ENTER("wolfSSL_SSL_do_handshake_internal");
if (s == NULL)
return WOLFSSL_FAILURE;
if (s->options.side == WOLFSSL_CLIENT_END) {
#ifndef NO_WOLFSSL_CLIENT
return wolfSSL_connect(s);
#else
WOLFSSL_MSG("Client not compiled in");
return WOLFSSL_FAILURE;
#endif
}
#ifndef NO_WOLFSSL_SERVER
return wolfSSL_accept(s);
#else
WOLFSSL_MSG("Server not compiled in");
return WOLFSSL_FAILURE;
#endif
}
int wolfSSL_SSL_do_handshake(WOLFSSL *s)
{
WOLFSSL_ENTER("wolfSSL_SSL_do_handshake");
#ifdef WOLFSSL_QUIC
if (WOLFSSL_IS_QUIC(s)) {
return wolfSSL_quic_do_handshake(s);
}
#endif
return wolfSSL_SSL_do_handshake_internal(s);
}
#endif /* !NO_TLS */
#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
int wolfSSL_SSL_in_init(const WOLFSSL *ssl)
#else
int wolfSSL_SSL_in_init(WOLFSSL *ssl)
#endif
{
WOLFSSL_ENTER("wolfSSL_SSL_in_init");
return !wolfSSL_is_init_finished(ssl);
}
int wolfSSL_SSL_in_before(const WOLFSSL *ssl)
{
WOLFSSL_ENTER("wolfSSL_SSL_in_before");
if (ssl == NULL)
return WOLFSSL_FAILURE;
return ssl->options.handShakeState == NULL_STATE;
}
int wolfSSL_SSL_in_connect_init(WOLFSSL* ssl)
{
WOLFSSL_ENTER("wolfSSL_SSL_in_connect_init");
if (ssl == NULL)
return WOLFSSL_FAILURE;
if (ssl->options.side == WOLFSSL_CLIENT_END) {
return ssl->options.connectState > CONNECT_BEGIN &&
ssl->options.connectState < SECOND_REPLY_DONE;
}
return ssl->options.acceptState > ACCEPT_BEGIN &&
ssl->options.acceptState < ACCEPT_THIRD_REPLY_DONE;
}
#endif /* OPENSSL_ALL || WOLFSSL_NGINX || WOLFSSL_HAPROXY ||
OPENSSL_EXTRA || HAVE_LIGHTY */
#if defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) || \
defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
void wolfSSL_WOLFSSL_STRING_free(WOLFSSL_STRING s)
{
WOLFSSL_ENTER("wolfSSL_WOLFSSL_STRING_free");
XFREE(s, NULL, DYNAMIC_TYPE_OPENSSL);
}
#endif /* WOLFSSL_NGINX || WOLFSSL_HAPROXY || OPENSSL_EXTRA || OPENSSL_ALL */
#if defined(OPENSSL_EXTRA) || defined(HAVE_CURL)
#if (defined(HAVE_ECC) || \
defined(HAVE_CURVE25519) || defined(HAVE_CURVE448))
#define CURVE_NAME(c) XSTR_SIZEOF((c)), (c)
const WOLF_EC_NIST_NAME kNistCurves[] = {
#ifdef HAVE_ECC
{CURVE_NAME("P-160"), WC_NID_secp160r1, WOLFSSL_ECC_SECP160R1},
{CURVE_NAME("P-160-2"), WC_NID_secp160r2, WOLFSSL_ECC_SECP160R2},
{CURVE_NAME("P-192"), WC_NID_X9_62_prime192v1, WOLFSSL_ECC_SECP192R1},
{CURVE_NAME("P-224"), WC_NID_secp224r1, WOLFSSL_ECC_SECP224R1},
{CURVE_NAME("P-256"), WC_NID_X9_62_prime256v1, WOLFSSL_ECC_SECP256R1},
{CURVE_NAME("P-384"), WC_NID_secp384r1, WOLFSSL_ECC_SECP384R1},
{CURVE_NAME("P-521"), WC_NID_secp521r1, WOLFSSL_ECC_SECP521R1},
{CURVE_NAME("K-160"), WC_NID_secp160k1, WOLFSSL_ECC_SECP160K1},
{CURVE_NAME("K-192"), WC_NID_secp192k1, WOLFSSL_ECC_SECP192K1},
{CURVE_NAME("K-224"), WC_NID_secp224k1, WOLFSSL_ECC_SECP224K1},
{CURVE_NAME("K-256"), WC_NID_secp256k1, WOLFSSL_ECC_SECP256K1},
{CURVE_NAME("B-256"), WC_NID_brainpoolP256r1,
WOLFSSL_ECC_BRAINPOOLP256R1},
{CURVE_NAME("B-384"), WC_NID_brainpoolP384r1,
WOLFSSL_ECC_BRAINPOOLP384R1},
{CURVE_NAME("B-512"), WC_NID_brainpoolP512r1,
WOLFSSL_ECC_BRAINPOOLP512R1},
#endif
#ifdef HAVE_CURVE25519
{CURVE_NAME("X25519"), WC_NID_X25519, WOLFSSL_ECC_X25519},
#endif
#ifdef HAVE_CURVE448
{CURVE_NAME("X448"), WC_NID_X448, WOLFSSL_ECC_X448},
#endif
#ifdef WOLFSSL_HAVE_MLKEM
#ifndef WOLFSSL_NO_ML_KEM
{CURVE_NAME("ML_KEM_512"), WOLFSSL_ML_KEM_512, WOLFSSL_ML_KEM_512},
{CURVE_NAME("ML_KEM_768"), WOLFSSL_ML_KEM_768, WOLFSSL_ML_KEM_768},
{CURVE_NAME("ML_KEM_1024"), WOLFSSL_ML_KEM_1024, WOLFSSL_ML_KEM_1024},
/* Aliases accepting the OpenSSL/IANA spelling without underscores. */
{CURVE_NAME("MLKEM512"), WOLFSSL_ML_KEM_512, WOLFSSL_ML_KEM_512},
{CURVE_NAME("MLKEM768"), WOLFSSL_ML_KEM_768, WOLFSSL_ML_KEM_768},
{CURVE_NAME("MLKEM1024"), WOLFSSL_ML_KEM_1024, WOLFSSL_ML_KEM_1024},
#if defined(HAVE_ECC)
#ifdef WOLFSSL_PQC_HYBRIDS
{CURVE_NAME("SecP256r1MLKEM768"), WOLFSSL_SECP256R1MLKEM768,
WOLFSSL_SECP256R1MLKEM768},
{CURVE_NAME("SecP384r1MLKEM1024"), WOLFSSL_SECP384R1MLKEM1024,
WOLFSSL_SECP384R1MLKEM1024},
{CURVE_NAME("X25519MLKEM768"), WOLFSSL_X25519MLKEM768,
WOLFSSL_X25519MLKEM768},
#endif /* WOLFSSL_PQC_HYBRIDS */
#ifdef WOLFSSL_EXTRA_PQC_HYBRIDS
{CURVE_NAME("SecP256r1MLKEM512"), WOLFSSL_SECP256R1MLKEM512,
WOLFSSL_SECP256R1MLKEM512},
{CURVE_NAME("SecP384r1MLKEM768"), WOLFSSL_SECP384R1MLKEM768,
WOLFSSL_SECP384R1MLKEM768},
{CURVE_NAME("SecP521r1MLKEM1024"), WOLFSSL_SECP521R1MLKEM1024,
WOLFSSL_SECP521R1MLKEM1024},
{CURVE_NAME("X25519MLKEM512"), WOLFSSL_X25519MLKEM512,
WOLFSSL_X25519MLKEM512},
{CURVE_NAME("X448MLKEM768"), WOLFSSL_X448MLKEM768,
WOLFSSL_X448MLKEM768},
#endif /* WOLFSSL_EXTRA_PQC_HYBRIDS */
#endif
#endif /* !WOLFSSL_NO_ML_KEM */
#ifdef WOLFSSL_MLKEM_KYBER
{CURVE_NAME("KYBER_LEVEL1"), WOLFSSL_KYBER_LEVEL1, WOLFSSL_KYBER_LEVEL1},
{CURVE_NAME("KYBER_LEVEL3"), WOLFSSL_KYBER_LEVEL3, WOLFSSL_KYBER_LEVEL3},
{CURVE_NAME("KYBER_LEVEL5"), WOLFSSL_KYBER_LEVEL5, WOLFSSL_KYBER_LEVEL5},
#if defined(HAVE_ECC)
{CURVE_NAME("P256_KYBER_LEVEL1"), WOLFSSL_P256_KYBER_LEVEL1,
WOLFSSL_P256_KYBER_LEVEL1},
{CURVE_NAME("P384_KYBER_LEVEL3"), WOLFSSL_P384_KYBER_LEVEL3,
WOLFSSL_P384_KYBER_LEVEL3},
{CURVE_NAME("P256_KYBER_LEVEL3"), WOLFSSL_P256_KYBER_LEVEL3,
WOLFSSL_P256_KYBER_LEVEL3},
{CURVE_NAME("P521_KYBER_LEVEL5"), WOLFSSL_P521_KYBER_LEVEL5,
WOLFSSL_P521_KYBER_LEVEL5},
{CURVE_NAME("X25519_KYBER_LEVEL1"), WOLFSSL_X25519_KYBER_LEVEL1,
WOLFSSL_X25519_KYBER_LEVEL1},
{CURVE_NAME("X448_KYBER_LEVEL3"), WOLFSSL_X448_KYBER_LEVEL3,
WOLFSSL_X448_KYBER_LEVEL3},
{CURVE_NAME("X25519_KYBER_LEVEL3"), WOLFSSL_X25519_KYBER_LEVEL3,
WOLFSSL_X25519_KYBER_LEVEL3},
#endif
#endif /* WOLFSSL_MLKEM_KYBER */
#endif /* WOLFSSL_HAVE_MLKEM */
#ifdef WOLFSSL_SM2
{CURVE_NAME("SM2"), WC_NID_sm2, WOLFSSL_ECC_SM2P256V1},
#endif
#ifdef HAVE_ECC
/* Alternative curve names */
{CURVE_NAME("prime256v1"), WC_NID_X9_62_prime256v1, WOLFSSL_ECC_SECP256R1},
{CURVE_NAME("secp256r1"), WC_NID_X9_62_prime256v1, WOLFSSL_ECC_SECP256R1},
{CURVE_NAME("secp384r1"), WC_NID_secp384r1, WOLFSSL_ECC_SECP384R1},
{CURVE_NAME("secp521r1"), WC_NID_secp521r1, WOLFSSL_ECC_SECP521R1},
#endif
#ifdef WOLFSSL_SM2
{CURVE_NAME("sm2p256v1"), WC_NID_sm2, WOLFSSL_ECC_SM2P256V1},
#endif
{0, NULL, 0, 0},
};
int set_curves_list(WOLFSSL* ssl, WOLFSSL_CTX *ctx, const char* names,
byte curves_only)
{
int idx, start = 0, len, i, ret = WOLFSSL_FAILURE;
word16 curve;
word32 disabled;
char name[MAX_CURVE_NAME_SZ];
byte groups_len = 0;
#ifdef WOLFSSL_SMALL_STACK
void *heap = ssl? ssl->heap : ctx ? ctx->heap : NULL;
int *groups;
#else
int groups[WOLFSSL_MAX_GROUP_COUNT];
#endif
const WOLF_EC_NIST_NAME* nist_name;
WC_ALLOC_VAR_EX(groups, int, WOLFSSL_MAX_GROUP_COUNT, heap,
DYNAMIC_TYPE_TMP_BUFFER,
{
ret=MEMORY_E;
goto leave;
});
for (idx = 1; names[idx-1] != '\0'; idx++) {
if (names[idx] != ':' && names[idx] != '\0')
continue;
len = idx - start;
if (len > MAX_CURVE_NAME_SZ - 1)
goto leave;
XMEMCPY(name, names + start, (size_t)len);
name[len] = 0;
curve = WOLFSSL_NAMED_GROUP_INVALID;
for (nist_name = kNistCurves; nist_name->name != NULL; nist_name++) {
if (len == nist_name->name_len &&
XSTRNCASECMP(name, nist_name->name, (size_t)len) == 0) {
curve = nist_name->curve;
break;
}
}
if (curve == WOLFSSL_NAMED_GROUP_INVALID) {
#if !defined(HAVE_FIPS) && !defined(HAVE_SELFTEST) && defined(HAVE_ECC)
int nret;
const ecc_set_type *eccSet;
nret = wc_ecc_get_curve_idx_from_name(name);
if (nret < 0) {
WOLFSSL_MSG("Could not find name in set");
goto leave;
}
eccSet = wc_ecc_get_curve_params(nret);
if (eccSet == NULL) {
WOLFSSL_MSG("NULL set returned");
goto leave;
}
curve = GetCurveByOID((int)eccSet->oidSum);
#else
WOLFSSL_MSG("API not present to search farther using name");
goto leave;
#endif
}
if ((curves_only && curve >= WOLFSSL_ECC_MAX_AVAIL) ||
curve == WOLFSSL_NAMED_GROUP_INVALID) {
WOLFSSL_MSG("curve value is not supported");
goto leave;
}
for (i = 0; i < groups_len; ++i) {
if (groups[i] == curve) {
/* silently drop duplicates */
break;
}
}
if (i >= groups_len) {
if (groups_len >= WOLFSSL_MAX_GROUP_COUNT) {
WOLFSSL_MSG_EX("setting %d or more supported "
"curves is not permitted", groups_len);
goto leave;
}
groups[groups_len++] = (int)curve;
}
start = idx + 1;
}
/* Disable all curves so that only the ones the user wants are enabled. */
disabled = 0xFFFFFFFFUL;
for (i = 0; i < groups_len; ++i) {
/* Switch the bit to off and therefore is enabled. */
curve = (word16)groups[i];
if (curve >= 64) {
WC_DO_NOTHING;
}
else if (curve >= 32) {
/* 0 is for invalid and 1-14 aren't used otherwise. */
disabled &= ~(1U << (curve - 32));
}
else {
disabled &= ~(1U << curve);
}
#if defined(HAVE_SUPPORTED_CURVES) && !defined(NO_TLS)
#if !defined(WOLFSSL_OLD_SET_CURVES_LIST)
/* using the wolfSSL API to set the groups, this will populate
* (ssl|ctx)->groups and reset any TLSX_SUPPORTED_GROUPS.
* The order in (ssl|ctx)->groups will then be respected
* when TLSX_KEY_SHARE needs to be established */
if ((ssl && wolfSSL_set_groups(ssl, groups, groups_len)
!= WOLFSSL_SUCCESS)
|| (ctx && wolfSSL_CTX_set_groups(ctx, groups, groups_len)
!= WOLFSSL_SUCCESS)) {
WOLFSSL_MSG("Unable to set supported curve");
goto leave;
}
#elif !defined(NO_WOLFSSL_CLIENT)
/* set the supported curve so client TLS extension contains only the
* desired curves */
if ((ssl && wolfSSL_UseSupportedCurve(ssl, curve) != WOLFSSL_SUCCESS)
|| (ctx && wolfSSL_CTX_UseSupportedCurve(ctx, curve)
!= WOLFSSL_SUCCESS)) {
WOLFSSL_MSG("Unable to set supported curve");
goto leave;
}
#endif
#endif /* HAVE_SUPPORTED_CURVES && !NO_TLS */
}
if (ssl != NULL)
ssl->disabledCurves = disabled;
else if (ctx != NULL)
ctx->disabledCurves = disabled;
ret = WOLFSSL_SUCCESS;
leave:
#ifdef WOLFSSL_SMALL_STACK
if (groups)
XFREE((void*)groups, heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
return ret;
}
#endif /* (HAVE_ECC || HAVE_CURVE25519 || HAVE_CURVE448) */
#endif /* OPENSSL_EXTRA || HAVE_CURL */
#ifdef OPENSSL_EXTRA
/* Sets a callback for when sending and receiving protocol messages.
* This callback is copied to all WOLFSSL objects created from the ctx.
*
* ctx WOLFSSL_CTX structure to set callback in
* cb callback to use
*
* return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE with error case
*/
int wolfSSL_CTX_set_msg_callback(WOLFSSL_CTX *ctx, SSL_Msg_Cb cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_msg_callback");
if (ctx == NULL) {
WOLFSSL_MSG("Null ctx passed in");
return WOLFSSL_FAILURE;
}
ctx->protoMsgCb = cb;
return WOLFSSL_SUCCESS;
}
/* Sets a callback for when sending and receiving protocol messages.
*
* ssl WOLFSSL structure to set callback in
* cb callback to use
*
* return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE with error case
*/
int wolfSSL_set_msg_callback(WOLFSSL *ssl, SSL_Msg_Cb cb)
{
WOLFSSL_ENTER("wolfSSL_set_msg_callback");
if (ssl == NULL) {
return WOLFSSL_FAILURE;
}
if (cb != NULL) {
ssl->toInfoOn = 1;
}
ssl->protoMsgCb = cb;
return WOLFSSL_SUCCESS;
}
/* set the user argument to pass to the msg callback when called
* return WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_msg_callback_arg(WOLFSSL_CTX *ctx, void* arg)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_msg_callback_arg");
if (ctx == NULL) {
WOLFSSL_MSG("Null WOLFSSL_CTX passed in");
return WOLFSSL_FAILURE;
}
ctx->protoMsgCtx = arg;
return WOLFSSL_SUCCESS;
}
int wolfSSL_set_msg_callback_arg(WOLFSSL *ssl, void* arg)
{
WOLFSSL_ENTER("wolfSSL_set_msg_callback_arg");
if (ssl == NULL)
return WOLFSSL_FAILURE;
ssl->protoMsgCtx = arg;
return WOLFSSL_SUCCESS;
}
void *wolfSSL_OPENSSL_memdup(const void *data, size_t siz, const char* file,
int line)
{
void *ret;
(void)file;
(void)line;
if (data == NULL || siz >= INT_MAX)
return NULL;
ret = wolfSSL_OPENSSL_malloc(siz);
if (ret == NULL) {
return NULL;
}
return XMEMCPY(ret, data, siz);
}
void wolfSSL_OPENSSL_cleanse(void *ptr, size_t len)
{
if (ptr)
ForceZero(ptr, (word32)len);
}
#endif /* OPENSSL_EXTRA */
#define WOLFSSL_SSL_API_EXT_INCLUDED
#include "src/ssl_api_ext.c"
#if defined(OPENSSL_EXTRA)
#ifndef NO_BIO
#define WOLFSSL_BIO_INCLUDED
#include "src/bio.c"
#endif
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
word32 nid2oid(int nid, int grp)
{
/* get OID type */
switch (grp) {
/* oidHashType */
case oidHashType:
switch (nid) {
#ifdef WOLFSSL_MD2
case WC_NID_md2:
return MD2h;
#endif
#ifndef NO_MD5
case WC_NID_md5:
return MD5h;
#endif
#ifndef NO_SHA
case WC_NID_sha1:
return SHAh;
#endif
case WC_NID_sha224:
return SHA224h;
#ifndef NO_SHA256
case WC_NID_sha256:
return SHA256h;
#endif
#ifdef WOLFSSL_SHA384
case WC_NID_sha384:
return SHA384h;
#endif
#ifdef WOLFSSL_SHA512
case WC_NID_sha512:
return SHA512h;
#endif
#ifndef WOLFSSL_NOSHA3_224
case WC_NID_sha3_224:
return SHA3_224h;
#endif
#ifndef WOLFSSL_NOSHA3_256
case WC_NID_sha3_256:
return SHA3_256h;
#endif
#ifndef WOLFSSL_NOSHA3_384
case WC_NID_sha3_384:
return SHA3_384h;
#endif
#ifndef WOLFSSL_NOSHA3_512
case WC_NID_sha3_512:
return SHA3_512h;
#endif
}
break;
/* oidSigType */
case oidSigType:
switch (nid) {
#ifndef NO_DSA
case WC_NID_dsaWithSHA1:
return CTC_SHAwDSA;
case WC_NID_dsa_with_SHA256:
return CTC_SHA256wDSA;
#endif /* NO_DSA */
#ifndef NO_RSA
case WC_NID_md2WithRSAEncryption:
return CTC_MD2wRSA;
case WC_NID_md5WithRSAEncryption:
return CTC_MD5wRSA;
case WC_NID_sha1WithRSAEncryption:
return CTC_SHAwRSA;
case WC_NID_sha224WithRSAEncryption:
return CTC_SHA224wRSA;
case WC_NID_sha256WithRSAEncryption:
return CTC_SHA256wRSA;
case WC_NID_sha384WithRSAEncryption:
return CTC_SHA384wRSA;
case WC_NID_sha512WithRSAEncryption:
return CTC_SHA512wRSA;
#ifdef WOLFSSL_SHA3
case WC_NID_RSA_SHA3_224:
return CTC_SHA3_224wRSA;
case WC_NID_RSA_SHA3_256:
return CTC_SHA3_256wRSA;
case WC_NID_RSA_SHA3_384:
return CTC_SHA3_384wRSA;
case WC_NID_RSA_SHA3_512:
return CTC_SHA3_512wRSA;
#endif
#endif /* NO_RSA */
#ifdef HAVE_ECC
case WC_NID_ecdsa_with_SHA1:
return CTC_SHAwECDSA;
case WC_NID_ecdsa_with_SHA224:
return CTC_SHA224wECDSA;
case WC_NID_ecdsa_with_SHA256:
return CTC_SHA256wECDSA;
case WC_NID_ecdsa_with_SHA384:
return CTC_SHA384wECDSA;
case WC_NID_ecdsa_with_SHA512:
return CTC_SHA512wECDSA;
#ifdef WOLFSSL_SHA3
case WC_NID_ecdsa_with_SHA3_224:
return CTC_SHA3_224wECDSA;
case WC_NID_ecdsa_with_SHA3_256:
return CTC_SHA3_256wECDSA;
case WC_NID_ecdsa_with_SHA3_384:
return CTC_SHA3_384wECDSA;
case WC_NID_ecdsa_with_SHA3_512:
return CTC_SHA3_512wECDSA;
#endif
#endif /* HAVE_ECC */
#ifdef HAVE_ED25519
case WC_NID_ED25519:
return CTC_ED25519;
#endif /* HAVE_ED25519 */
#ifdef HAVE_ED448
case WC_NID_ED448:
return CTC_ED448;
#endif /* HAVE_ED448 */
}
break;
/* oidKeyType */
case oidKeyType:
switch (nid) {
#ifndef NO_DSA
case WC_NID_dsa:
return DSAk;
#endif /* NO_DSA */
#ifndef NO_RSA
case WC_NID_rsaEncryption:
return RSAk;
#endif /* NO_RSA */
#ifdef HAVE_ECC
case WC_NID_X9_62_id_ecPublicKey:
return ECDSAk;
#endif /* HAVE_ECC */
#ifdef HAVE_ED25519
case WC_NID_ED25519:
return ED25519k;
#endif /* HAVE_ED25519 */
#ifdef HAVE_ED448
case WC_NID_ED448:
return ED448k;
#endif /* HAVE_ED448 */
}
break;
#ifdef HAVE_ECC
case oidCurveType:
switch (nid) {
case WC_NID_X9_62_prime192v1:
return ECC_SECP192R1_OID;
case WC_NID_X9_62_prime192v2:
return ECC_PRIME192V2_OID;
case WC_NID_X9_62_prime192v3:
return ECC_PRIME192V3_OID;
case WC_NID_X9_62_prime239v1:
return ECC_PRIME239V1_OID;
case WC_NID_X9_62_prime239v2:
return ECC_PRIME239V2_OID;
case WC_NID_X9_62_prime239v3:
return ECC_PRIME239V3_OID;
case WC_NID_X9_62_prime256v1:
return ECC_SECP256R1_OID;
case WC_NID_secp112r1:
return ECC_SECP112R1_OID;
case WC_NID_secp112r2:
return ECC_SECP112R2_OID;
case WC_NID_secp128r1:
return ECC_SECP128R1_OID;
case WC_NID_secp128r2:
return ECC_SECP128R2_OID;
case WC_NID_secp160r1:
return ECC_SECP160R1_OID;
case WC_NID_secp160r2:
return ECC_SECP160R2_OID;
case WC_NID_secp224r1:
return ECC_SECP224R1_OID;
case WC_NID_secp384r1:
return ECC_SECP384R1_OID;
case WC_NID_secp521r1:
return ECC_SECP521R1_OID;
case WC_NID_secp160k1:
return ECC_SECP160K1_OID;
case WC_NID_secp192k1:
return ECC_SECP192K1_OID;
case WC_NID_secp224k1:
return ECC_SECP224K1_OID;
case WC_NID_secp256k1:
return ECC_SECP256K1_OID;
case WC_NID_brainpoolP160r1:
return ECC_BRAINPOOLP160R1_OID;
case WC_NID_brainpoolP192r1:
return ECC_BRAINPOOLP192R1_OID;
case WC_NID_brainpoolP224r1:
return ECC_BRAINPOOLP224R1_OID;
case WC_NID_brainpoolP256r1:
return ECC_BRAINPOOLP256R1_OID;
case WC_NID_brainpoolP320r1:
return ECC_BRAINPOOLP320R1_OID;
case WC_NID_brainpoolP384r1:
return ECC_BRAINPOOLP384R1_OID;
case WC_NID_brainpoolP512r1:
return ECC_BRAINPOOLP512R1_OID;
}
break;
#endif /* HAVE_ECC */
/* oidBlkType */
case oidBlkType:
switch (nid) {
#ifdef WOLFSSL_AES_128
case AES128CBCb:
return AES128CBCb;
#endif
#ifdef WOLFSSL_AES_192
case AES192CBCb:
return AES192CBCb;
#endif
#ifdef WOLFSSL_AES_256
case AES256CBCb:
return AES256CBCb;
#endif
#ifndef NO_DES3
case WC_NID_des:
return DESb;
case WC_NID_des3:
return DES3b;
#endif
}
break;
#ifdef HAVE_OCSP
case oidOcspType:
switch (nid) {
case WC_NID_id_pkix_OCSP_basic:
return OCSP_BASIC_OID;
case OCSP_NONCE_OID:
return OCSP_NONCE_OID;
}
break;
#endif /* HAVE_OCSP */
/* oidCertExtType */
case oidCertExtType:
switch (nid) {
case WC_NID_basic_constraints:
return BASIC_CA_OID;
case WC_NID_subject_alt_name:
return ALT_NAMES_OID;
case WC_NID_crl_distribution_points:
return CRL_DIST_OID;
case WC_NID_info_access:
return AUTH_INFO_OID;
case WC_NID_authority_key_identifier:
return AUTH_KEY_OID;
case WC_NID_subject_key_identifier:
return SUBJ_KEY_OID;
case WC_NID_inhibit_any_policy:
return INHIBIT_ANY_OID;
case WC_NID_key_usage:
return KEY_USAGE_OID;
case WC_NID_name_constraints:
return NAME_CONS_OID;
case WC_NID_certificate_policies:
return CERT_POLICY_OID;
case WC_NID_ext_key_usage:
return EXT_KEY_USAGE_OID;
}
break;
/* oidCertAuthInfoType */
case oidCertAuthInfoType:
switch (nid) {
case WC_NID_ad_OCSP:
return AIA_OCSP_OID;
case WC_NID_ad_ca_issuers:
return AIA_CA_ISSUER_OID;
}
break;
/* oidCertPolicyType */
case oidCertPolicyType:
switch (nid) {
case WC_NID_any_policy:
return CP_ANY_OID;
}
break;
/* oidCertAltNameType */
case oidCertAltNameType:
switch (nid) {
case WC_NID_hw_name_oid:
return HW_NAME_OID;
}
break;
/* oidCertKeyUseType */
case oidCertKeyUseType:
switch (nid) {
case WC_NID_anyExtendedKeyUsage:
return EKU_ANY_OID;
case EKU_SERVER_AUTH_OID:
return EKU_SERVER_AUTH_OID;
case EKU_CLIENT_AUTH_OID:
return EKU_CLIENT_AUTH_OID;
case EKU_OCSP_SIGN_OID:
return EKU_OCSP_SIGN_OID;
}
break;
/* oidKdfType */
case oidKdfType:
switch (nid) {
case PBKDF2_OID:
return PBKDF2_OID;
}
break;
/* oidPBEType */
case oidPBEType:
switch (nid) {
case PBE_SHA1_RC4_128:
return PBE_SHA1_RC4_128;
case PBE_SHA1_DES:
return PBE_SHA1_DES;
case PBE_SHA1_DES3:
return PBE_SHA1_DES3;
}
break;
/* oidKeyWrapType */
case oidKeyWrapType:
switch (nid) {
#ifdef WOLFSSL_AES_128
case AES128_WRAP:
return AES128_WRAP;
#endif
#ifdef WOLFSSL_AES_192
case AES192_WRAP:
return AES192_WRAP;
#endif
#ifdef WOLFSSL_AES_256
case AES256_WRAP:
return AES256_WRAP;
#endif
}
break;
/* oidCmsKeyAgreeType */
case oidCmsKeyAgreeType:
switch (nid) {
#ifndef NO_SHA
case dhSinglePass_stdDH_sha1kdf_scheme:
return dhSinglePass_stdDH_sha1kdf_scheme;
#endif
#ifdef WOLFSSL_SHA224
case dhSinglePass_stdDH_sha224kdf_scheme:
return dhSinglePass_stdDH_sha224kdf_scheme;
#endif
#ifndef NO_SHA256
case dhSinglePass_stdDH_sha256kdf_scheme:
return dhSinglePass_stdDH_sha256kdf_scheme;
#endif
#ifdef WOLFSSL_SHA384
case dhSinglePass_stdDH_sha384kdf_scheme:
return dhSinglePass_stdDH_sha384kdf_scheme;
#endif
#ifdef WOLFSSL_SHA512
case dhSinglePass_stdDH_sha512kdf_scheme:
return dhSinglePass_stdDH_sha512kdf_scheme;
#endif
}
break;
/* oidCmsKeyAgreeType */
#ifdef WOLFSSL_CERT_REQ
case oidCsrAttrType:
switch (nid) {
case WC_NID_pkcs9_contentType:
return PKCS9_CONTENT_TYPE_OID;
case WC_NID_pkcs9_challengePassword:
return CHALLENGE_PASSWORD_OID;
case WC_NID_serialNumber:
return SERIAL_NUMBER_OID;
case WC_NID_userId:
return USER_ID_OID;
case WC_NID_surname:
return SURNAME_OID;
}
break;
#endif
default:
WOLFSSL_MSG("NID not in table");
/* MSVC warns without the cast */
return (word32)-1;
}
/* MSVC warns without the cast */
return (word32)-1;
}
int oid2nid(word32 oid, int grp)
{
size_t i;
/* get OID type */
switch (grp) {
/* oidHashType */
case oidHashType:
switch (oid) {
#ifdef WOLFSSL_MD2
case MD2h:
return WC_NID_md2;
#endif
#ifndef NO_MD5
case MD5h:
return WC_NID_md5;
#endif
#ifndef NO_SHA
case SHAh:
return WC_NID_sha1;
#endif
case SHA224h:
return WC_NID_sha224;
#ifndef NO_SHA256
case SHA256h:
return WC_NID_sha256;
#endif
#ifdef WOLFSSL_SHA384
case SHA384h:
return WC_NID_sha384;
#endif
#ifdef WOLFSSL_SHA512
case SHA512h:
return WC_NID_sha512;
#endif
}
break;
/* oidSigType */
case oidSigType:
switch (oid) {
#ifndef NO_DSA
case CTC_SHAwDSA:
return WC_NID_dsaWithSHA1;
case CTC_SHA256wDSA:
return WC_NID_dsa_with_SHA256;
#endif /* NO_DSA */
#ifndef NO_RSA
case CTC_MD2wRSA:
return WC_NID_md2WithRSAEncryption;
case CTC_MD5wRSA:
return WC_NID_md5WithRSAEncryption;
case CTC_SHAwRSA:
return WC_NID_sha1WithRSAEncryption;
case CTC_SHA224wRSA:
return WC_NID_sha224WithRSAEncryption;
case CTC_SHA256wRSA:
return WC_NID_sha256WithRSAEncryption;
case CTC_SHA384wRSA:
return WC_NID_sha384WithRSAEncryption;
case CTC_SHA512wRSA:
return WC_NID_sha512WithRSAEncryption;
#ifdef WOLFSSL_SHA3
case CTC_SHA3_224wRSA:
return WC_NID_RSA_SHA3_224;
case CTC_SHA3_256wRSA:
return WC_NID_RSA_SHA3_256;
case CTC_SHA3_384wRSA:
return WC_NID_RSA_SHA3_384;
case CTC_SHA3_512wRSA:
return WC_NID_RSA_SHA3_512;
#endif
#ifdef WC_RSA_PSS
case CTC_RSASSAPSS:
return WC_NID_rsassaPss;
#endif
#endif /* NO_RSA */
#ifdef HAVE_ECC
case CTC_SHAwECDSA:
return WC_NID_ecdsa_with_SHA1;
case CTC_SHA224wECDSA:
return WC_NID_ecdsa_with_SHA224;
case CTC_SHA256wECDSA:
return WC_NID_ecdsa_with_SHA256;
case CTC_SHA384wECDSA:
return WC_NID_ecdsa_with_SHA384;
case CTC_SHA512wECDSA:
return WC_NID_ecdsa_with_SHA512;
#ifdef WOLFSSL_SHA3
case CTC_SHA3_224wECDSA:
return WC_NID_ecdsa_with_SHA3_224;
case CTC_SHA3_256wECDSA:
return WC_NID_ecdsa_with_SHA3_256;
case CTC_SHA3_384wECDSA:
return WC_NID_ecdsa_with_SHA3_384;
case CTC_SHA3_512wECDSA:
return WC_NID_ecdsa_with_SHA3_512;
#endif
#endif /* HAVE_ECC */
#ifdef HAVE_ED25519
case CTC_ED25519:
return WC_NID_ED25519;
#endif /* HAVE_ED25519 */
#ifdef HAVE_ED448
case CTC_ED448:
return WC_NID_ED448;
#endif /* HAVE_ED448 */
}
break;
/* oidKeyType */
case oidKeyType:
switch (oid) {
#ifndef NO_DSA
case DSAk:
return WC_NID_dsa;
#endif /* NO_DSA */
#ifndef NO_RSA
case RSAk:
return WC_NID_rsaEncryption;
#ifdef WC_RSA_PSS
case RSAPSSk:
return WC_NID_rsassaPss;
#endif
#endif /* NO_RSA */
#ifdef HAVE_ECC
case ECDSAk:
return WC_NID_X9_62_id_ecPublicKey;
#endif /* HAVE_ECC */
#ifdef HAVE_ED25519
case ED25519k:
return WC_NID_ED25519;
#endif /* HAVE_ED25519 */
#ifdef HAVE_ED448
case ED448k:
return WC_NID_ED448;
#endif /* HAVE_ED448 */
}
break;
#ifdef HAVE_ECC
case oidCurveType:
switch (oid) {
case ECC_SECP192R1_OID:
return WC_NID_X9_62_prime192v1;
case ECC_PRIME192V2_OID:
return WC_NID_X9_62_prime192v2;
case ECC_PRIME192V3_OID:
return WC_NID_X9_62_prime192v3;
case ECC_PRIME239V1_OID:
return WC_NID_X9_62_prime239v1;
case ECC_PRIME239V2_OID:
return WC_NID_X9_62_prime239v2;
case ECC_PRIME239V3_OID:
return WC_NID_X9_62_prime239v3;
case ECC_SECP256R1_OID:
return WC_NID_X9_62_prime256v1;
case ECC_SECP112R1_OID:
return WC_NID_secp112r1;
case ECC_SECP112R2_OID:
return WC_NID_secp112r2;
case ECC_SECP128R1_OID:
return WC_NID_secp128r1;
case ECC_SECP128R2_OID:
return WC_NID_secp128r2;
case ECC_SECP160R1_OID:
return WC_NID_secp160r1;
case ECC_SECP160R2_OID:
return WC_NID_secp160r2;
case ECC_SECP224R1_OID:
return WC_NID_secp224r1;
case ECC_SECP384R1_OID:
return WC_NID_secp384r1;
case ECC_SECP521R1_OID:
return WC_NID_secp521r1;
case ECC_SECP160K1_OID:
return WC_NID_secp160k1;
case ECC_SECP192K1_OID:
return WC_NID_secp192k1;
case ECC_SECP224K1_OID:
return WC_NID_secp224k1;
case ECC_SECP256K1_OID:
return WC_NID_secp256k1;
case ECC_BRAINPOOLP160R1_OID:
return WC_NID_brainpoolP160r1;
case ECC_BRAINPOOLP192R1_OID:
return WC_NID_brainpoolP192r1;
case ECC_BRAINPOOLP224R1_OID:
return WC_NID_brainpoolP224r1;
case ECC_BRAINPOOLP256R1_OID:
return WC_NID_brainpoolP256r1;
case ECC_BRAINPOOLP320R1_OID:
return WC_NID_brainpoolP320r1;
case ECC_BRAINPOOLP384R1_OID:
return WC_NID_brainpoolP384r1;
case ECC_BRAINPOOLP512R1_OID:
return WC_NID_brainpoolP512r1;
}
break;
#endif /* HAVE_ECC */
/* oidBlkType */
case oidBlkType:
switch (oid) {
#ifdef WOLFSSL_AES_128
case AES128CBCb:
return AES128CBCb;
#endif
#ifdef WOLFSSL_AES_192
case AES192CBCb:
return AES192CBCb;
#endif
#ifdef WOLFSSL_AES_256
case AES256CBCb:
return AES256CBCb;
#endif
#ifndef NO_DES3
case DESb:
return WC_NID_des;
case DES3b:
return WC_NID_des3;
#endif
}
break;
#ifdef HAVE_OCSP
case oidOcspType:
switch (oid) {
case OCSP_BASIC_OID:
return WC_NID_id_pkix_OCSP_basic;
case OCSP_NONCE_OID:
return OCSP_NONCE_OID;
}
break;
#endif /* HAVE_OCSP */
/* oidCertExtType */
case oidCertExtType:
switch (oid) {
case BASIC_CA_OID:
return WC_NID_basic_constraints;
case ALT_NAMES_OID:
return WC_NID_subject_alt_name;
case CRL_DIST_OID:
return WC_NID_crl_distribution_points;
case AUTH_INFO_OID:
return WC_NID_info_access;
case AUTH_KEY_OID:
return WC_NID_authority_key_identifier;
case SUBJ_KEY_OID:
return WC_NID_subject_key_identifier;
case INHIBIT_ANY_OID:
return WC_NID_inhibit_any_policy;
case KEY_USAGE_OID:
return WC_NID_key_usage;
case NAME_CONS_OID:
return WC_NID_name_constraints;
case CERT_POLICY_OID:
return WC_NID_certificate_policies;
case EXT_KEY_USAGE_OID:
return WC_NID_ext_key_usage;
}
break;
/* oidCertAuthInfoType */
case oidCertAuthInfoType:
switch (oid) {
case AIA_OCSP_OID:
return WC_NID_ad_OCSP;
case AIA_CA_ISSUER_OID:
return WC_NID_ad_ca_issuers;
}
break;
/* oidCertPolicyType */
case oidCertPolicyType:
switch (oid) {
case CP_ANY_OID:
return WC_NID_any_policy;
}
break;
/* oidCertAltNameType */
case oidCertAltNameType:
switch (oid) {
case HW_NAME_OID:
return WC_NID_hw_name_oid;
}
break;
/* oidCertKeyUseType */
case oidCertKeyUseType:
switch (oid) {
case EKU_ANY_OID:
return WC_NID_anyExtendedKeyUsage;
case EKU_SERVER_AUTH_OID:
return EKU_SERVER_AUTH_OID;
case EKU_CLIENT_AUTH_OID:
return EKU_CLIENT_AUTH_OID;
case EKU_OCSP_SIGN_OID:
return EKU_OCSP_SIGN_OID;
}
break;
/* oidKdfType */
case oidKdfType:
switch (oid) {
case PBKDF2_OID:
return PBKDF2_OID;
}
break;
/* oidPBEType */
case oidPBEType:
switch (oid) {
case PBE_SHA1_RC4_128:
return PBE_SHA1_RC4_128;
case PBE_SHA1_DES:
return PBE_SHA1_DES;
case PBE_SHA1_DES3:
return PBE_SHA1_DES3;
}
break;
/* oidKeyWrapType */
case oidKeyWrapType:
switch (oid) {
#ifdef WOLFSSL_AES_128
case AES128_WRAP:
return AES128_WRAP;
#endif
#ifdef WOLFSSL_AES_192
case AES192_WRAP:
return AES192_WRAP;
#endif
#ifdef WOLFSSL_AES_256
case AES256_WRAP:
return AES256_WRAP;
#endif
}
break;
/* oidCmsKeyAgreeType */
case oidCmsKeyAgreeType:
switch (oid) {
#ifndef NO_SHA
case dhSinglePass_stdDH_sha1kdf_scheme:
return dhSinglePass_stdDH_sha1kdf_scheme;
#endif
#ifdef WOLFSSL_SHA224
case dhSinglePass_stdDH_sha224kdf_scheme:
return dhSinglePass_stdDH_sha224kdf_scheme;
#endif
#ifndef NO_SHA256
case dhSinglePass_stdDH_sha256kdf_scheme:
return dhSinglePass_stdDH_sha256kdf_scheme;
#endif
#ifdef WOLFSSL_SHA384
case dhSinglePass_stdDH_sha384kdf_scheme:
return dhSinglePass_stdDH_sha384kdf_scheme;
#endif
#ifdef WOLFSSL_SHA512
case dhSinglePass_stdDH_sha512kdf_scheme:
return dhSinglePass_stdDH_sha512kdf_scheme;
#endif
}
break;
#ifdef WOLFSSL_CERT_REQ
case oidCsrAttrType:
switch (oid) {
case PKCS9_CONTENT_TYPE_OID:
return WC_NID_pkcs9_contentType;
case CHALLENGE_PASSWORD_OID:
return WC_NID_pkcs9_challengePassword;
case SERIAL_NUMBER_OID:
return WC_NID_serialNumber;
case USER_ID_OID:
return WC_NID_userId;
}
break;
#endif
default:
WOLFSSL_MSG("OID not in table");
}
/* If not found in above switch then try the table */
for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++) {
if (wolfssl_object_info[i].id == (int)oid) {
return wolfssl_object_info[i].nid;
}
}
return WOLFSSL_FATAL_ERROR;
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */
#if defined(OPENSSL_EXTRA)
/* frees all nodes in the current threads error queue
*
* id thread id. ERR_remove_state is depreciated and id is ignored. The
* current threads queue will be free'd.
*/
void wolfSSL_ERR_remove_state(unsigned long id)
{
WOLFSSL_ENTER("wolfSSL_ERR_remove_state");
(void)id;
if (wc_ERR_remove_state() != 0) {
WOLFSSL_MSG("Error with removing the state");
}
}
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA)
/* wolfSSL_THREADID_current is provided as a compat API with
* CRYPTO_THREADID_current to register current thread id into given id object.
* However, CRYPTO_THREADID_current API has been deprecated and no longer
* exists in the OpenSSL 1.0.0 or later.This API only works as a stub
* like as existing wolfSSL_THREADID_set_numeric.
*/
void wolfSSL_THREADID_current(WOLFSSL_CRYPTO_THREADID* id)
{
(void)id;
return;
}
/* wolfSSL_THREADID_hash is provided as a compatible API with
* CRYPTO_THREADID_hash which returns a hash value calculated from the
* specified thread id. However, CRYPTO_THREADID_hash API has been
* deprecated and no longer exists in the OpenSSL 1.0.0 or later.
* This API only works as a stub to returns 0. This behavior is
* equivalent to the latest OpenSSL CRYPTO_THREADID_hash.
*/
unsigned long wolfSSL_THREADID_hash(const WOLFSSL_CRYPTO_THREADID* id)
{
(void)id;
return 0UL;
}
/**
* Set security level (wolfSSL doesn't support setting the security level).
*
* The security level can only be set through a system wide crypto-policy
* with wolfSSL_crypto_policy_enable().
*
* @param ctx a pointer to WOLFSSL_CTX structure
* @param level security level
*/
void wolfSSL_CTX_set_security_level(WOLFSSL_CTX* ctx, int level)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_security_level");
(void)ctx;
(void)level;
}
int wolfSSL_CTX_get_security_level(const WOLFSSL_CTX * ctx)
{
WOLFSSL_ENTER("wolfSSL_CTX_get_security_level");
#if defined(WOLFSSL_SYS_CRYPTO_POLICY)
if (ctx == NULL) {
return BAD_FUNC_ARG;
}
return ctx->secLevel;
#else
(void)ctx;
return 0;
#endif /* WOLFSSL_SYS_CRYPTO_POLICY */
}
#if defined(OPENSSL_EXTRA) && defined(HAVE_SECRET_CALLBACK)
/*
* This API accepts a user callback which puts key-log records into
* a KEY LOGFILE. The callback is stored into a CTX and propagated to
* each SSL object on its creation timing.
*/
void wolfSSL_CTX_set_keylog_callback(WOLFSSL_CTX* ctx,
wolfSSL_CTX_keylog_cb_func cb)
{
WOLFSSL_ENTER("wolfSSL_CTX_set_keylog_callback");
/* stores the callback into WOLFSSL_CTX */
if (ctx != NULL) {
ctx->keyLogCb = cb;
}
}
wolfSSL_CTX_keylog_cb_func wolfSSL_CTX_get_keylog_callback(
const WOLFSSL_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_CTX_get_keylog_callback");
if (ctx != NULL)
return ctx->keyLogCb;
return NULL;
}
#endif /* OPENSSL_EXTRA && HAVE_SECRET_CALLBACK */
#endif /* OPENSSL_EXTRA */
#ifdef WOLFSSL_THREADED_CRYPT
int wolfSSL_AsyncEncryptReady(WOLFSSL* ssl, int idx)
{
ThreadCrypt* encrypt;
if (ssl == NULL) {
return 0;
}
encrypt = &ssl->buffers.encrypt[idx];
return (encrypt->avail == 0) && (encrypt->done == 0);
}
int wolfSSL_AsyncEncryptStop(WOLFSSL* ssl, int idx)
{
ThreadCrypt* encrypt;
if (ssl == NULL) {
return 1;
}
encrypt = &ssl->buffers.encrypt[idx];
return encrypt->stop;
}
int wolfSSL_AsyncEncrypt(WOLFSSL* ssl, int idx)
{
int ret = WC_NO_ERR_TRACE(NOT_COMPILED_IN);
ThreadCrypt* encrypt = &ssl->buffers.encrypt[idx];
if (ssl->specs.bulk_cipher_algorithm == wolfssl_aes_gcm) {
unsigned char* out = encrypt->buffer.buffer + encrypt->offset;
unsigned char* input = encrypt->buffer.buffer + encrypt->offset;
word32 encSz = encrypt->buffer.length - encrypt->offset;
ret =
#if !defined(NO_GCM_ENCRYPT_EXTRA) && \
((!defined(HAVE_FIPS) && !defined(HAVE_SELFTEST)) || \
(defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION >= 2)))
wc_AesGcmEncrypt_ex
#else
wc_AesGcmEncrypt
#endif
(encrypt->encrypt.aes,
out + AESGCM_EXP_IV_SZ, input + AESGCM_EXP_IV_SZ,
encSz - AESGCM_EXP_IV_SZ - ssl->specs.aead_mac_size,
encrypt->nonce, AESGCM_NONCE_SZ,
out + encSz - ssl->specs.aead_mac_size,
ssl->specs.aead_mac_size,
encrypt->additional, AEAD_AUTH_DATA_SZ);
#if !defined(NO_PUBLIC_GCM_SET_IV) && \
((!defined(HAVE_FIPS) && !defined(HAVE_SELFTEST)) || \
(defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION >= 2)))
XMEMCPY(out, encrypt->nonce + AESGCM_IMP_IV_SZ, AESGCM_EXP_IV_SZ);
#endif
encrypt->done = 1;
}
return ret;
}
int wolfSSL_AsyncEncryptSetSignal(WOLFSSL* ssl, int idx,
WOLFSSL_THREAD_SIGNAL signal, void* ctx)
{
int ret = 0;
if (ssl == NULL) {
ret = BAD_FUNC_ARG;
}
else {
ssl->buffers.encrypt[idx].signal = signal;
ssl->buffers.encrypt[idx].signalCtx = ctx;
}
return ret;
}
#endif
#ifndef NO_CERT
#define WOLFSSL_X509_INCLUDED
#include "src/x509.c"
#endif
/*******************************************************************************
* START OF standard C library wrapping APIs
******************************************************************************/
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && \
(defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
defined(HAVE_LIGHTY) || defined(WOLFSSL_HAPROXY) || \
defined(WOLFSSL_OPENSSH)))
#ifndef NO_WOLFSSL_STUB
int wolfSSL_CRYPTO_set_mem_ex_functions(void *(*m) (size_t, const char *, int),
void *(*r) (void *, size_t, const char *,
int), void (*f) (void *))
{
(void) m;
(void) r;
(void) f;
WOLFSSL_ENTER("wolfSSL_CRYPTO_set_mem_ex_functions");
WOLFSSL_STUB("CRYPTO_set_mem_ex_functions");
return WOLFSSL_FAILURE;
}
#endif
#endif
#if defined(OPENSSL_EXTRA)
/**
* free allocated memory resource
* @param str a pointer to resource to be freed
* @param file dummy argument
* @param line dummy argument
*/
void wolfSSL_CRYPTO_free(void *str, const char *file, int line)
{
(void)file;
(void)line;
XFREE(str, 0, DYNAMIC_TYPE_TMP_BUFFER);
}
/**
* allocate memory with size of num
* @param num size of memory allocation to be malloced
* @param file dummy argument
* @param line dummy argument
* @return a pointer to allocated memory on succssesful, otherwise NULL
*/
void *wolfSSL_CRYPTO_malloc(size_t num, const char *file, int line)
{
(void)file;
(void)line;
return XMALLOC(num, 0, DYNAMIC_TYPE_TMP_BUFFER);
}
#endif
/*******************************************************************************
* END OF standard C library wrapping APIs
******************************************************************************/
/*******************************************************************************
* START OF EX_DATA APIs
******************************************************************************/
#ifdef HAVE_EX_DATA
void wolfSSL_CRYPTO_cleanup_all_ex_data(void)
{
WOLFSSL_ENTER("wolfSSL_CRYPTO_cleanup_all_ex_data");
}
void* wolfSSL_CRYPTO_get_ex_data(const WOLFSSL_CRYPTO_EX_DATA* ex_data, int idx)
{
WOLFSSL_ENTER("wolfSSL_CRYPTO_get_ex_data");
#ifdef MAX_EX_DATA
if (ex_data && idx < MAX_EX_DATA && idx >= 0) {
return ex_data->ex_data[idx];
}
#else
(void)ex_data;
(void)idx;
#endif
return NULL;
}
int wolfSSL_CRYPTO_set_ex_data(WOLFSSL_CRYPTO_EX_DATA* ex_data, int idx,
void *data)
{
WOLFSSL_ENTER("wolfSSL_CRYPTO_set_ex_data");
#ifdef MAX_EX_DATA
if (ex_data && idx < MAX_EX_DATA && idx >= 0) {
#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
if (ex_data->ex_data_cleanup_routines[idx]) {
/* call cleanup then remove cleanup callback,
* since different value is being set */
if (ex_data->ex_data[idx])
ex_data->ex_data_cleanup_routines[idx](ex_data->ex_data[idx]);
ex_data->ex_data_cleanup_routines[idx] = NULL;
}
#endif
ex_data->ex_data[idx] = data;
return WOLFSSL_SUCCESS;
}
#else
(void)ex_data;
(void)idx;
(void)data;
#endif
return WOLFSSL_FAILURE;
}
#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_CRYPTO_set_ex_data_with_cleanup(
WOLFSSL_CRYPTO_EX_DATA* ex_data,
int idx,
void *data,
wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
WOLFSSL_ENTER("wolfSSL_CRYPTO_set_ex_data_with_cleanup");
if (ex_data && idx < MAX_EX_DATA && idx >= 0) {
if (ex_data->ex_data_cleanup_routines[idx] && ex_data->ex_data[idx])
ex_data->ex_data_cleanup_routines[idx](ex_data->ex_data[idx]);
ex_data->ex_data[idx] = data;
ex_data->ex_data_cleanup_routines[idx] = cleanup_routine;
return WOLFSSL_SUCCESS;
}
return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */
#endif /* HAVE_EX_DATA */
#ifdef HAVE_EX_DATA_CRYPTO
/**
* Issues unique index for the class specified by class_index.
* Other parameter except class_index are ignored.
* Currently, following class_index are accepted:
* - WOLF_CRYPTO_EX_INDEX_SSL
* - WOLF_CRYPTO_EX_INDEX_SSL_CTX
* - WOLF_CRYPTO_EX_INDEX_X509
* @param class_index index one of CRYPTO_EX_INDEX_xxx
* @param argp parameters to be saved
* @param argl parameters to be saved
* @param new_func a pointer to WOLFSSL_CRYPTO_EX_new
* @param dup_func a pointer to WOLFSSL_CRYPTO_EX_dup
* @param free_func a pointer to WOLFSSL_CRYPTO_EX_free
* @return index value grater or equal to zero on success, -1 on failure.
*/
int wolfSSL_CRYPTO_get_ex_new_index(int class_index, long argl, void *argp,
WOLFSSL_CRYPTO_EX_new* new_func,
WOLFSSL_CRYPTO_EX_dup* dup_func,
WOLFSSL_CRYPTO_EX_free* free_func)
{
WOLFSSL_ENTER("wolfSSL_CRYPTO_get_ex_new_index");
return wolfssl_local_get_ex_new_index(class_index, argl, argp, new_func,
dup_func, free_func);
}
#endif /* HAVE_EX_DATA_CRYPTO */
/*******************************************************************************
* END OF EX_DATA APIs
******************************************************************************/
/*******************************************************************************
* START OF BUF_MEM API
******************************************************************************/
#if defined(OPENSSL_EXTRA)
/* Begin functions for openssl/buffer.h */
WOLFSSL_BUF_MEM* wolfSSL_BUF_MEM_new(void)
{
WOLFSSL_BUF_MEM* buf;
buf = (WOLFSSL_BUF_MEM*)XMALLOC(sizeof(WOLFSSL_BUF_MEM), NULL,
DYNAMIC_TYPE_OPENSSL);
if (buf) {
XMEMSET(buf, 0, sizeof(WOLFSSL_BUF_MEM));
}
return buf;
}
/* non-compat API returns length of buffer on success */
int wolfSSL_BUF_MEM_grow_ex(WOLFSSL_BUF_MEM* buf, size_t len,
char zeroFill)
{
int len_int = (int)len;
int mx;
char* tmp;
/* verify provided arguments */
if (buf == NULL || len_int < 0) {
return 0; /* BAD_FUNC_ARG; */
}
/* check to see if fits in existing length */
if (buf->length > len) {
buf->length = len;
return len_int;
}
/* check to see if fits in max buffer */
if (buf->max >= len) {
if (buf->data != NULL && zeroFill) {
XMEMSET(&buf->data[buf->length], 0, len - buf->length);
}
buf->length = len;
return len_int;
}
/* expand size, to handle growth */
mx = (len_int + 3) / 3 * 4;
#ifdef WOLFSSL_NO_REALLOC
tmp = (char*)XMALLOC(mx, NULL, DYNAMIC_TYPE_OPENSSL);
if (tmp != NULL && buf->data != NULL) {
XMEMCPY(tmp, buf->data, len_int);
XFREE(buf->data, NULL, DYNAMIC_TYPE_OPENSSL);
buf->data = NULL;
}
#else
/* use realloc */
tmp = (char*)XREALLOC(buf->data, mx, NULL, DYNAMIC_TYPE_OPENSSL);
#endif
if (tmp == NULL) {
return 0; /* ERR_R_MALLOC_FAILURE; */
}
buf->data = tmp;
buf->max = (size_t)mx;
if (zeroFill)
XMEMSET(&buf->data[buf->length], 0, len - buf->length);
buf->length = len;
return len_int;
}
/* returns length of buffer on success */
int wolfSSL_BUF_MEM_grow(WOLFSSL_BUF_MEM* buf, size_t len)
{
return wolfSSL_BUF_MEM_grow_ex(buf, len, 1);
}
/* non-compat API returns length of buffer on success */
int wolfSSL_BUF_MEM_resize(WOLFSSL_BUF_MEM* buf, size_t len)
{
char* tmp;
int mx;
/* verify provided arguments */
if (buf == NULL || len == 0 || (int)len <= 0) {
return 0; /* BAD_FUNC_ARG; */
}
if (len == buf->length)
return (int)len;
if (len > buf->length)
return wolfSSL_BUF_MEM_grow_ex(buf, len, 0);
/* expand size, to handle growth */
mx = ((int)len + 3) / 3 * 4;
/* We want to shrink the internal buffer */
#ifdef WOLFSSL_NO_REALLOC
tmp = (char*)XMALLOC(mx, NULL, DYNAMIC_TYPE_OPENSSL);
if (tmp != NULL && buf->data != NULL)
{
XMEMCPY(tmp, buf->data, len);
XFREE(buf->data,NULL,DYNAMIC_TYPE_OPENSSL);
buf->data = NULL;
}
#else
tmp = (char*)XREALLOC(buf->data, mx, NULL, DYNAMIC_TYPE_OPENSSL);
#endif
if (tmp == NULL)
return 0;
buf->data = tmp;
buf->length = len;
buf->max = (size_t)mx;
return (int)len;
}
void wolfSSL_BUF_MEM_free(WOLFSSL_BUF_MEM* buf)
{
if (buf) {
XFREE(buf->data, NULL, DYNAMIC_TYPE_OPENSSL);
buf->data = NULL;
buf->max = 0;
buf->length = 0;
XFREE(buf, NULL, DYNAMIC_TYPE_OPENSSL);
}
}
/* End Functions for openssl/buffer.h */
#endif /* OPENSSL_EXTRA */
/*******************************************************************************
* END OF BUF_MEM API
******************************************************************************/
#define WOLFSSL_CONF_INCLUDED
#include <src/conf.c>
/*******************************************************************************
* START OF RAND API
******************************************************************************/
#if defined(OPENSSL_EXTRA) && !defined(WOLFSSL_NO_OPENSSL_RAND_CB)
static int wolfSSL_RAND_InitMutex(void)
{
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (gRandMethodsInit == 0) {
if (wc_InitMutex(&gRandMethodMutex) != 0) {
WOLFSSL_MSG("Bad Init Mutex rand methods");
return BAD_MUTEX_E;
}
gRandMethodsInit = 1;
}
#endif
return 0;
}
#endif
#ifdef OPENSSL_EXTRA
#if defined(HAVE_GETPID) && !defined(WOLFSSL_NO_GETPID) && \
((defined(HAVE_FIPS) && FIPS_VERSION3_LE(6,0,0)) || defined(HAVE_SELFTEST))
/* In older FIPS bundles add check for reseed here since it does not exist in
* the older random.c certified files. */
static pid_t currentRandPid = 0;
#endif
/* Checks if the global RNG has been created. If not then one is created.
*
* Returns WOLFSSL_SUCCESS when no error is encountered.
*/
int wolfSSL_RAND_Init(void)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
#ifdef HAVE_GLOBAL_RNG
if (wc_LockMutex(&globalRNGMutex) == 0) {
if (initGlobalRNG == 0) {
ret = wc_InitRng(&globalRNG);
if (ret == 0) {
#if defined(HAVE_GETPID) && !defined(WOLFSSL_NO_GETPID) && \
((defined(HAVE_FIPS) && FIPS_VERSION3_LE(6,0,0)) || \
defined(HAVE_SELFTEST))
currentRandPid = getpid();
#endif
initGlobalRNG = 1;
ret = WOLFSSL_SUCCESS;
}
}
else {
/* GlobalRNG is already initialized */
ret = WOLFSSL_SUCCESS;
}
wc_UnLockMutex(&globalRNGMutex);
}
#endif
return ret;
}
/* WOLFSSL_SUCCESS on ok */
int wolfSSL_RAND_seed(const void* seed, int len)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->seed) {
int ret = gRandMethods->seed(seed, len);
wc_UnLockMutex(&gRandMethodMutex);
return ret;
}
wc_UnLockMutex(&gRandMethodMutex);
}
#else
(void)seed;
(void)len;
#endif
/* Make sure global shared RNG (globalRNG) is initialized */
return wolfSSL_RAND_Init();
}
/* Returns the path for reading seed data from.
* Uses the env variable $RANDFILE first if set, if not then used $HOME/.rnd
*
* Note uses stdlib by default unless XGETENV macro is overwritten
*
* fname buffer to hold path
* len length of fname buffer
*
* Returns a pointer to fname on success and NULL on failure
*/
const char* wolfSSL_RAND_file_name(char* fname, unsigned long len)
{
#if !defined(NO_FILESYSTEM) && defined(XGETENV) && !defined(NO_GETENV)
char* rt;
WOLFSSL_ENTER("wolfSSL_RAND_file_name");
if (fname == NULL) {
return NULL;
}
XMEMSET(fname, 0, len);
/* // NOLINTBEGIN(concurrency-mt-unsafe) */
if ((rt = XGETENV("RANDFILE")) != NULL) {
if (len > XSTRLEN(rt)) {
XMEMCPY(fname, rt, XSTRLEN(rt));
}
else {
WOLFSSL_MSG("RANDFILE too large for buffer");
rt = NULL;
}
}
/* // NOLINTEND(concurrency-mt-unsafe) */
/* $RANDFILE was not set or is too large, check $HOME */
if (rt == NULL) {
const char ap[] = "/.rnd";
WOLFSSL_MSG("Environment variable RANDFILE not set");
/* // NOLINTBEGIN(concurrency-mt-unsafe) */
if ((rt = XGETENV("HOME")) == NULL) {
#ifdef XALTHOMEVARNAME
if ((rt = XGETENV(XALTHOMEVARNAME)) == NULL) {
WOLFSSL_MSG("Environment variable HOME and " XALTHOMEVARNAME
" not set");
return NULL;
}
#else
WOLFSSL_MSG("Environment variable HOME not set");
return NULL;
#endif
}
/* // NOLINTEND(concurrency-mt-unsafe) */
if (len > XSTRLEN(rt) + XSTRLEN(ap)) {
fname[0] = '\0';
XSTRNCAT(fname, rt, len);
XSTRNCAT(fname, ap, len - XSTRLEN(rt));
return fname;
}
else {
WOLFSSL_MSG("Path too large for buffer");
return NULL;
}
}
return fname;
#else
WOLFSSL_ENTER("wolfSSL_RAND_file_name");
WOLFSSL_MSG("RAND_file_name requires filesystem and getenv support, "
"not compiled in");
(void)fname;
(void)len;
return NULL;
#endif
}
/* Writes 1024 bytes from the RNG to the given file name.
*
* fname name of file to write to
*
* Returns the number of bytes written
*/
int wolfSSL_RAND_write_file(const char* fname)
{
int bytes = 0;
WOLFSSL_ENTER("wolfSSL_RAND_write_file");
if (fname == NULL) {
return WOLFSSL_FAILURE;
}
#ifndef NO_FILESYSTEM
{
#ifndef WOLFSSL_SMALL_STACK
unsigned char buf[1024];
#else
unsigned char* buf = (unsigned char *)XMALLOC(1024, NULL,
DYNAMIC_TYPE_TMP_BUFFER);
if (buf == NULL) {
WOLFSSL_MSG("malloc failed");
return WOLFSSL_FAILURE;
}
#endif
bytes = 1024; /* default size of buf */
if (initGlobalRNG == 0 && wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("No RNG to use");
WC_FREE_VAR_EX(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return 0;
}
if (wc_RNG_GenerateBlock(&globalRNG, buf, (word32)bytes) != 0) {
WOLFSSL_MSG("Error generating random buffer");
bytes = 0;
}
else {
XFILE f;
#ifdef WOLFSSL_CHECK_MEM_ZERO
wc_MemZero_Add("wolfSSL_RAND_write_file buf", buf, bytes);
#endif
f = XFOPEN(fname, "wb");
if (f == XBADFILE) {
WOLFSSL_MSG("Error opening the file");
bytes = 0;
}
else {
size_t bytes_written = XFWRITE(buf, 1, (size_t)bytes, f);
bytes = (int)bytes_written;
XFCLOSE(f);
}
}
ForceZero(buf, (word32)bytes);
#ifdef WOLFSSL_SMALL_STACK
XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#elif defined(WOLFSSL_CHECK_MEM_ZERO)
wc_MemZero_Check(buf, sizeof(buf));
#endif
}
#endif
return bytes;
}
#ifndef FREERTOS_TCP
/* These constant values are protocol values made by egd */
#if defined(USE_WOLFSSL_IO) && !defined(USE_WINDOWS_API) && \
!defined(HAVE_FIPS) && defined(HAVE_HASHDRBG) && !defined(NETOS) && \
defined(HAVE_SYS_UN_H)
#define WOLFSSL_EGD_NBLOCK 0x01
#include <sys/un.h>
#endif
/* This collects entropy from the path nm and seeds the global PRNG with it.
*
* nm is the file path to the egd server
*
* Returns the number of bytes read.
*/
int wolfSSL_RAND_egd(const char* nm)
{
#ifdef WOLFSSL_EGD_NBLOCK
struct sockaddr_un rem;
int fd;
int ret = WOLFSSL_SUCCESS;
word32 bytes = 0;
word32 idx = 0;
#ifndef WOLFSSL_SMALL_STACK
unsigned char buf[256];
#else
unsigned char* buf;
buf = (unsigned char*)XMALLOC(256, NULL, DYNAMIC_TYPE_TMP_BUFFER);
if (buf == NULL) {
WOLFSSL_MSG("Not enough memory");
return WOLFSSL_FATAL_ERROR;
}
#endif
XMEMSET(&rem, 0, sizeof(struct sockaddr_un));
if (nm == NULL) {
WC_FREE_VAR_EX(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return WOLFSSL_FATAL_ERROR;
}
fd = wc_socket_cloexec(AF_UNIX, SOCK_STREAM, 0);
if (fd < 0) {
WOLFSSL_MSG("Error creating socket");
WC_FREE_VAR_EX(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
return WOLFSSL_FATAL_ERROR;
}
rem.sun_family = AF_UNIX;
XSTRNCPY(rem.sun_path, nm, sizeof(rem.sun_path) - 1);
rem.sun_path[sizeof(rem.sun_path)-1] = '\0';
/* connect to egd server */
if (connect(fd, (struct sockaddr*)&rem, sizeof(struct sockaddr_un)) == -1) {
WOLFSSL_MSG("error connecting to egd server");
ret = WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_CHECK_MEM_ZERO
if (ret == WOLFSSL_SUCCESS) {
wc_MemZero_Add("wolfSSL_RAND_egd buf", buf, 256);
}
#endif
while (ret == WOLFSSL_SUCCESS && bytes < 255 && idx + 2 < 256) {
buf[idx] = WOLFSSL_EGD_NBLOCK;
buf[idx + 1] = 255 - bytes; /* request 255 bytes from server */
ret = (int)write(fd, buf + idx, 2);
if (ret != 2) {
if (errno == EAGAIN) {
ret = WOLFSSL_SUCCESS;
continue;
}
WOLFSSL_MSG("error requesting entropy from egd server");
ret = WOLFSSL_FATAL_ERROR;
break;
}
/* attempting to read */
buf[idx] = 0;
ret = (int)read(fd, buf + idx, 256 - bytes);
if (ret == 0) {
WOLFSSL_MSG("error reading entropy from egd server");
ret = WOLFSSL_FATAL_ERROR;
break;
}
if (ret > 0 && buf[idx] > 0) {
bytes += buf[idx]; /* egd stores amount sent in first byte */
if (bytes + idx > 255 || buf[idx] > ret) {
WOLFSSL_MSG("Buffer error");
ret = WOLFSSL_FATAL_ERROR;
break;
}
XMEMMOVE(buf + idx, buf + idx + 1, buf[idx]);
idx = bytes;
ret = WOLFSSL_SUCCESS;
if (bytes >= 255) {
break;
}
}
else {
if (errno == EAGAIN || errno == EINTR) {
WOLFSSL_MSG("EGD would read");
ret = WOLFSSL_SUCCESS; /* try again */
}
else if (buf[idx] == 0) {
/* if egd returned 0 then there is no more entropy to be had.
Do not try more reads. */
ret = WOLFSSL_SUCCESS;
break;
}
else {
WOLFSSL_MSG("Error with read");
ret = WOLFSSL_FATAL_ERROR;
}
}
}
if (bytes > 0 && ret == WOLFSSL_SUCCESS) {
/* call to check global RNG is created */
if (wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Error with initializing global RNG structure");
ret = WOLFSSL_FATAL_ERROR;
}
else if (wc_RNG_DRBG_Reseed(&globalRNG, (const byte*) buf, bytes)
!= 0) {
WOLFSSL_MSG("Error with reseeding DRBG structure");
ret = WOLFSSL_FATAL_ERROR;
}
#ifdef SHOW_SECRETS
else { /* print out entropy found only when no error occurred */
word32 i;
printf("EGD Entropy = ");
for (i = 0; i < bytes; i++) {
printf("%02X", buf[i]);
}
printf("\n");
}
#endif
}
ForceZero(buf, bytes);
#ifdef WOLFSSL_SMALL_STACK
XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#elif defined(WOLFSSL_CHECK_MEM_ZERO)
wc_MemZero_Check(buf, 256);
#endif
close(fd);
if (ret == WOLFSSL_SUCCESS) {
return (int)bytes;
}
else {
return ret;
}
#else
WOLFSSL_MSG("Type of socket needed is not available");
WOLFSSL_MSG("\tor using mode where DRBG API is not available");
(void)nm;
return WOLFSSL_FATAL_ERROR;
#endif /* WOLFSSL_EGD_NBLOCK */
}
#endif /* !FREERTOS_TCP */
void wolfSSL_RAND_Cleanup(void)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->cleanup)
gRandMethods->cleanup();
wc_UnLockMutex(&gRandMethodMutex);
}
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (wc_FreeMutex(&gRandMethodMutex) == 0)
gRandMethodsInit = 0;
#endif
#endif
#ifdef HAVE_GLOBAL_RNG
if (wc_LockMutex(&globalRNGMutex) == 0) {
if (initGlobalRNG) {
wc_FreeRng(&globalRNG);
initGlobalRNG = 0;
}
wc_UnLockMutex(&globalRNGMutex);
}
#endif
}
/* returns WOLFSSL_SUCCESS if the bytes generated are valid otherwise
* WOLFSSL_FAILURE */
int wolfSSL_RAND_pseudo_bytes(unsigned char* buf, int num)
{
int ret;
int hash;
byte secret[DRBG_SEED_LEN]; /* secret length arbitrarily chosen */
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->pseudorand) {
ret = gRandMethods->pseudorand(buf, num);
wc_UnLockMutex(&gRandMethodMutex);
return ret;
}
wc_UnLockMutex(&gRandMethodMutex);
}
#endif
#ifdef WOLFSSL_HAVE_PRF
#ifndef NO_SHA256
hash = WC_SHA256;
#elif defined(WOLFSSL_SHA384)
hash = WC_SHA384;
#elif !defined(NO_SHA)
hash = WC_SHA;
#elif !defined(NO_MD5)
hash = WC_MD5;
#endif
/* get secret value from source of entropy */
ret = wolfSSL_RAND_bytes(secret, DRBG_SEED_LEN);
/* uses input buffer to seed for pseudo random number generation, each
* thread will potentially have different results this way */
if (ret == WOLFSSL_SUCCESS) {
PRIVATE_KEY_UNLOCK();
ret = wc_PRF(buf, num, secret, DRBG_SEED_LEN, (const byte*)buf, num,
hash, NULL, INVALID_DEVID);
PRIVATE_KEY_LOCK();
ret = (ret == 0) ? WOLFSSL_SUCCESS: WOLFSSL_FAILURE;
}
#else
/* fall back to just doing wolfSSL_RAND_bytes if PRF not avialbale */
ret = wolfSSL_RAND_bytes(buf, num);
(void)hash;
(void)secret;
#endif
return ret;
}
/* returns WOLFSSL_SUCCESS (1) if the bytes generated are valid otherwise 0
* on failure */
int wolfSSL_RAND_bytes(unsigned char* buf, int num)
{
int ret = 0;
WC_RNG* rng = NULL;
WC_DECLARE_VAR(tmpRNG, WC_RNG, 1, 0);
int initTmpRng = 0;
#ifdef HAVE_GLOBAL_RNG
int used_global = 0;
#endif
WOLFSSL_ENTER("wolfSSL_RAND_bytes");
/* sanity check */
if (buf == NULL || num < 0)
/* return code compliant with OpenSSL */
return 0;
/* if a RAND callback has been set try and use it */
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->bytes) {
ret = gRandMethods->bytes(buf, num);
wc_UnLockMutex(&gRandMethodMutex);
return ret;
}
wc_UnLockMutex(&gRandMethodMutex);
}
#endif
#ifdef HAVE_GLOBAL_RNG
if (initGlobalRNG) {
if (wc_LockMutex(&globalRNGMutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex rng");
return ret;
}
/* the above access to initGlobalRNG is racey -- recheck it now that we
* have the lock.
*/
if (initGlobalRNG) {
#if defined(HAVE_GETPID) && !defined(WOLFSSL_NO_GETPID) && \
((defined(HAVE_FIPS) && FIPS_VERSION3_LE(6,0,0)) || \
defined(HAVE_SELFTEST))
pid_t p;
p = getpid();
if (p != currentRandPid) {
wc_UnLockMutex(&globalRNGMutex);
if (wolfSSL_RAND_poll() != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("Issue with check pid and reseed");
ret = WOLFSSL_FAILURE;
}
/* reclaim lock after wolfSSL_RAND_poll */
if (wc_LockMutex(&globalRNGMutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex rng");
return ret;
}
currentRandPid = p;
}
#endif
rng = &globalRNG;
used_global = 1;
}
else {
wc_UnLockMutex(&globalRNGMutex);
}
}
if (used_global == 0)
#endif
{
WC_ALLOC_VAR_EX(tmpRNG, WC_RNG, 1, NULL, DYNAMIC_TYPE_RNG,
return ret);
if (wc_InitRng(tmpRNG) == 0) {
rng = tmpRNG;
initTmpRng = 1;
}
}
if (rng) {
/* handles size greater than RNG_MAX_BLOCK_LEN */
int blockCount = num / RNG_MAX_BLOCK_LEN;
while (blockCount--) {
ret = wc_RNG_GenerateBlock(rng, buf, RNG_MAX_BLOCK_LEN);
if (ret != 0) {
WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
break;
}
num -= RNG_MAX_BLOCK_LEN;
buf += RNG_MAX_BLOCK_LEN;
}
if (ret == 0 && num)
ret = wc_RNG_GenerateBlock(rng, buf, (word32)num);
if (ret != 0)
WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
else
ret = WOLFSSL_SUCCESS;
}
#ifdef HAVE_GLOBAL_RNG
if (used_global == 1)
wc_UnLockMutex(&globalRNGMutex);
#endif
if (initTmpRng)
wc_FreeRng(tmpRNG);
WC_FREE_VAR_EX(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
return ret;
}
int wolfSSL_RAND_poll(void)
{
byte entropy[16];
int ret = 0;
word32 entropy_sz = 16;
WOLFSSL_ENTER("wolfSSL_RAND_poll");
if (initGlobalRNG == 0){
WOLFSSL_MSG("Global RNG no Init");
return WOLFSSL_FAILURE;
}
ret = wc_GenerateSeed(&globalRNG.seed, entropy, entropy_sz);
if (ret != 0) {
WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
ret = WOLFSSL_FAILURE;
}
else {
#ifdef HAVE_HASHDRBG
if (wc_LockMutex(&globalRNGMutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex rng");
return ret;
}
ret = wc_RNG_DRBG_Reseed(&globalRNG, entropy, entropy_sz);
if (ret != 0) {
WOLFSSL_MSG("Error reseeding DRBG");
ret = WOLFSSL_FAILURE;
}
else {
ret = WOLFSSL_SUCCESS;
}
wc_UnLockMutex(&globalRNGMutex);
#elif defined(HAVE_INTEL_RDRAND)
WOLFSSL_MSG("Not polling with RAND_poll, RDRAND used without "
"HAVE_HASHDRBG");
ret = WOLFSSL_SUCCESS;
#else
WOLFSSL_MSG("RAND_poll called with HAVE_HASHDRBG not set");
ret = WOLFSSL_FAILURE;
#endif
}
return ret;
}
/* If a valid struct is provided with function pointers, will override
RAND_seed, bytes, cleanup, add, pseudo_bytes and status. If a NULL
pointer is passed in, it will cancel any previous function overrides.
Returns WOLFSSL_SUCCESS on success, WOLFSSL_FAILURE on failure. */
int wolfSSL_RAND_set_rand_method(const WOLFSSL_RAND_METHOD *methods)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 &&
wc_LockMutex(&gRandMethodMutex) == 0) {
gRandMethods = methods;
wc_UnLockMutex(&gRandMethodMutex);
return WOLFSSL_SUCCESS;
}
#else
(void)methods;
#endif
return WOLFSSL_FAILURE;
}
/* Returns WOLFSSL_SUCCESS if the RNG has been seeded with enough data */
int wolfSSL_RAND_status(void)
{
int ret = WOLFSSL_SUCCESS;
int useGlobalRng = 1;
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 &&
wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->status) {
ret = gRandMethods->status();
useGlobalRng = 0;
}
wc_UnLockMutex(&gRandMethodMutex);
}
else {
ret = WOLFSSL_FAILURE;
useGlobalRng = 0;
}
#endif
/* Drive the global RNG so init / DRBG state failures (mutex
* acquisition, reseed required, corrupted state) surface to the
* caller. DRBG output is deterministic between reseeds, so this
* does not directly probe the entropy source. */
#ifdef HAVE_GLOBAL_RNG
if (useGlobalRng) {
if (wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
ret = WOLFSSL_FAILURE;
}
else if (wc_LockMutex(&globalRNGMutex) != 0) {
ret = WOLFSSL_FAILURE;
}
else {
byte b = 0;
int genRet = wc_RNG_GenerateBlock(&globalRNG, &b, 1);
wc_UnLockMutex(&globalRNGMutex);
ForceZero(&b, 1);
if (genRet != 0)
ret = WOLFSSL_FAILURE;
}
}
#endif
(void)useGlobalRng;
return ret;
}
void wolfSSL_RAND_add(const void* add, int len, double entropy)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
if (wolfSSL_RAND_InitMutex() == 0 &&
wc_LockMutex(&gRandMethodMutex) == 0) {
if (gRandMethods && gRandMethods->add) {
/* callback has return code, but RAND_add does not */
(void)gRandMethods->add(add, len, entropy);
}
wc_UnLockMutex(&gRandMethodMutex);
}
#else
/* wolfSSL seeds/adds internally, use explicit RNG if you want
to take control */
(void)add;
(void)len;
(void)entropy;
#endif
}
#ifndef NO_WOLFSSL_STUB
void wolfSSL_RAND_screen(void)
{
WOLFSSL_STUB("RAND_screen");
}
#endif
#ifndef WOLFSSL_RAND_LOAD_FILE_BUF_SZ
#define WOLFSSL_RAND_LOAD_FILE_BUF_SZ 256
#endif
#ifndef WOLFSSL_RAND_LOAD_FILE_MAX_BYTES
#define WOLFSSL_RAND_LOAD_FILE_MAX_BYTES (1L << 20)
#endif
int wolfSSL_RAND_load_file(const char* fname, long len)
{
#if !defined(NO_FILESYSTEM) && defined(HAVE_HASHDRBG)
XFILE f;
long maxBytes;
long readSoFar = 0;
int ret = 0;
#ifndef WOLFSSL_SMALL_STACK
unsigned char buf[WOLFSSL_RAND_LOAD_FILE_BUF_SZ];
#else
unsigned char* buf;
#endif
WOLFSSL_ENTER("wolfSSL_RAND_load_file");
if (fname == NULL)
return WOLFSSL_FATAL_ERROR;
/* OpenSSL semantics: RAND_load_file(file, -1) reads up to an
* implementation-defined maximum. WOLFSSL_RAND_LOAD_FILE_MAX_BYTES
* caps the read so callers passing -1 to ingest a seed file aren't
* silently truncated at a small default. */
maxBytes = (len < 0) ? WOLFSSL_RAND_LOAD_FILE_MAX_BYTES : len;
if (maxBytes == 0)
return 0;
f = XFOPEN(fname, "rb");
if (f == XBADFILE) {
WOLFSSL_MSG("RAND_load_file: cannot open file");
return WOLFSSL_FATAL_ERROR;
}
#ifdef WOLFSSL_SMALL_STACK
buf = (unsigned char*)XMALLOC(WOLFSSL_RAND_LOAD_FILE_BUF_SZ, NULL,
DYNAMIC_TYPE_TMP_BUFFER);
if (buf == NULL) {
XFCLOSE(f);
return WOLFSSL_FATAL_ERROR;
}
#endif
#ifdef WOLFSSL_CHECK_MEM_ZERO
wc_MemZero_Add("wolfSSL_RAND_load_file buf", buf,
WOLFSSL_RAND_LOAD_FILE_BUF_SZ);
#endif
if (initGlobalRNG == 0 && wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
WOLFSSL_MSG("RAND_load_file: global RNG not available");
ret = WOLFSSL_FATAL_ERROR;
goto cleanup;
}
while (readSoFar < maxBytes) {
size_t toRead = (size_t)((maxBytes - readSoFar) <
WOLFSSL_RAND_LOAD_FILE_BUF_SZ
? (maxBytes - readSoFar) : WOLFSSL_RAND_LOAD_FILE_BUF_SZ);
size_t n = XFREAD(buf, 1, toRead, f);
if (n == 0)
break;
if (wc_LockMutex(&globalRNGMutex) != 0) {
ret = WOLFSSL_FATAL_ERROR;
break;
}
if (wc_RNG_DRBG_Reseed(&globalRNG, buf, (word32)n) != 0) {
wc_UnLockMutex(&globalRNGMutex);
WOLFSSL_MSG("RAND_load_file: DRBG reseed failed");
ret = WOLFSSL_FATAL_ERROR;
break;
}
wc_UnLockMutex(&globalRNGMutex);
readSoFar += (long)n;
}
cleanup:
XFCLOSE(f);
ForceZero(buf, WOLFSSL_RAND_LOAD_FILE_BUF_SZ);
#ifdef WOLFSSL_SMALL_STACK
XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#elif defined(WOLFSSL_CHECK_MEM_ZERO)
wc_MemZero_Check(buf, WOLFSSL_RAND_LOAD_FILE_BUF_SZ);
#endif
if (ret < 0)
return WOLFSSL_FATAL_ERROR;
return (int)readSoFar;
#else
/* Without HAVE_HASHDRBG / filesystem support there is no way to feed
* external entropy to the wolfCrypt RNG; return success so callers
* in those configurations are not broken. */
(void)fname;
if (len == -1)
return 1024;
return (int)len;
#endif
}
#endif /* OPENSSL_EXTRA */
/*******************************************************************************
* END OF RAND API
******************************************************************************/
/*******************************************************************************
* START OF EVP_CIPHER API
******************************************************************************/
#ifdef OPENSSL_EXTRA
/* store for external read of iv, WOLFSSL_SUCCESS on success */
int wolfSSL_StoreExternalIV(WOLFSSL_EVP_CIPHER_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_StoreExternalIV");
if (ctx == NULL) {
WOLFSSL_MSG("Bad function argument");
return WOLFSSL_FATAL_ERROR;
}
switch (ctx->cipherType) {
#ifndef NO_AES
#if defined(HAVE_AES_CBC) || defined(WOLFSSL_AES_DIRECT)
case WC_AES_128_CBC_TYPE :
case WC_AES_192_CBC_TYPE :
case WC_AES_256_CBC_TYPE :
WOLFSSL_MSG("AES CBC");
XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
break;
#endif
#ifdef HAVE_AESGCM
case WC_AES_128_GCM_TYPE :
case WC_AES_192_GCM_TYPE :
case WC_AES_256_GCM_TYPE :
WOLFSSL_MSG("AES GCM");
XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
break;
#endif /* HAVE_AESGCM */
#ifdef HAVE_AESCCM
case WC_AES_128_CCM_TYPE :
case WC_AES_192_CCM_TYPE :
case WC_AES_256_CCM_TYPE :
WOLFSSL_MSG("AES CCM");
XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
break;
#endif /* HAVE_AESCCM */
#ifdef HAVE_AES_ECB
case WC_AES_128_ECB_TYPE :
case WC_AES_192_ECB_TYPE :
case WC_AES_256_ECB_TYPE :
WOLFSSL_MSG("AES ECB");
break;
#endif
#ifdef WOLFSSL_AES_COUNTER
case WC_AES_128_CTR_TYPE :
case WC_AES_192_CTR_TYPE :
case WC_AES_256_CTR_TYPE :
WOLFSSL_MSG("AES CTR");
XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, WC_AES_BLOCK_SIZE);
break;
#endif /* WOLFSSL_AES_COUNTER */
#ifdef WOLFSSL_AES_CFB
#if !defined(HAVE_SELFTEST) && !defined(HAVE_FIPS)
case WC_AES_128_CFB1_TYPE:
case WC_AES_192_CFB1_TYPE:
case WC_AES_256_CFB1_TYPE:
WOLFSSL_MSG("AES CFB1");
break;
case WC_AES_128_CFB8_TYPE:
case WC_AES_192_CFB8_TYPE:
case WC_AES_256_CFB8_TYPE:
WOLFSSL_MSG("AES CFB8");
break;
#endif /* !HAVE_SELFTEST && !HAVE_FIPS */
case WC_AES_128_CFB128_TYPE:
case WC_AES_192_CFB128_TYPE:
case WC_AES_256_CFB128_TYPE:
WOLFSSL_MSG("AES CFB128");
break;
#endif /* WOLFSSL_AES_CFB */
#if defined(WOLFSSL_AES_OFB)
case WC_AES_128_OFB_TYPE:
case WC_AES_192_OFB_TYPE:
case WC_AES_256_OFB_TYPE:
WOLFSSL_MSG("AES OFB");
break;
#endif /* WOLFSSL_AES_OFB */
#ifdef WOLFSSL_AES_XTS
case WC_AES_128_XTS_TYPE:
case WC_AES_256_XTS_TYPE:
WOLFSSL_MSG("AES XTS");
break;
#endif /* WOLFSSL_AES_XTS */
#endif /* NO_AES */
#ifdef HAVE_ARIA
case WC_ARIA_128_GCM_TYPE :
case WC_ARIA_192_GCM_TYPE :
case WC_ARIA_256_GCM_TYPE :
WOLFSSL_MSG("ARIA GCM");
XMEMCPY(ctx->iv, &ctx->cipher.aria.nonce, ARIA_BLOCK_SIZE);
break;
#endif /* HAVE_ARIA */
#ifndef NO_DES3
case WC_DES_CBC_TYPE :
WOLFSSL_MSG("DES CBC");
XMEMCPY(ctx->iv, &ctx->cipher.des.reg, DES_BLOCK_SIZE);
break;
case WC_DES_EDE3_CBC_TYPE :
WOLFSSL_MSG("DES EDE3 CBC");
XMEMCPY(ctx->iv, &ctx->cipher.des3.reg, DES_BLOCK_SIZE);
break;
#endif
#ifdef WOLFSSL_DES_ECB
case WC_DES_ECB_TYPE :
WOLFSSL_MSG("DES ECB");
break;
case WC_DES_EDE3_ECB_TYPE :
WOLFSSL_MSG("DES3 ECB");
break;
#endif
case WC_ARC4_TYPE :
WOLFSSL_MSG("ARC4");
break;
#if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
case WC_CHACHA20_POLY1305_TYPE:
break;
#endif
#ifdef HAVE_CHACHA
case WC_CHACHA20_TYPE:
break;
#endif
#ifdef WOLFSSL_SM4_ECB
case WC_SM4_ECB_TYPE:
break;
#endif
#ifdef WOLFSSL_SM4_CBC
case WC_SM4_CBC_TYPE:
WOLFSSL_MSG("SM4 CBC");
XMEMCPY(&ctx->cipher.sm4.iv, ctx->iv, SM4_BLOCK_SIZE);
break;
#endif
#ifdef WOLFSSL_SM4_CTR
case WC_SM4_CTR_TYPE:
WOLFSSL_MSG("SM4 CTR");
XMEMCPY(&ctx->cipher.sm4.iv, ctx->iv, SM4_BLOCK_SIZE);
break;
#endif
#ifdef WOLFSSL_SM4_GCM
case WC_SM4_GCM_TYPE:
WOLFSSL_MSG("SM4 GCM");
XMEMCPY(&ctx->cipher.sm4.iv, ctx->iv, SM4_BLOCK_SIZE);
break;
#endif
#ifdef WOLFSSL_SM4_CCM
case WC_SM4_CCM_TYPE:
WOLFSSL_MSG("SM4 CCM");
XMEMCPY(&ctx->cipher.sm4.iv, ctx->iv, SM4_BLOCK_SIZE);
break;
#endif
case WC_NULL_CIPHER_TYPE :
WOLFSSL_MSG("NULL");
break;
default: {
WOLFSSL_MSG("bad type");
return WOLFSSL_FATAL_ERROR;
}
}
return WOLFSSL_SUCCESS;
}
/* set internal IV from external, WOLFSSL_SUCCESS on success */
int wolfSSL_SetInternalIV(WOLFSSL_EVP_CIPHER_CTX* ctx)
{
WOLFSSL_ENTER("wolfSSL_SetInternalIV");
if (ctx == NULL) {
WOLFSSL_MSG("Bad function argument");
return WOLFSSL_FATAL_ERROR;
}
switch (ctx->cipherType) {
#ifndef NO_AES
#if defined(HAVE_AES_CBC) || defined(WOLFSSL_AES_DIRECT)
case WC_AES_128_CBC_TYPE :
case WC_AES_192_CBC_TYPE :
case WC_AES_256_CBC_TYPE :
WOLFSSL_MSG("AES CBC");
XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, WC_AES_BLOCK_SIZE);
break;
#endif
#ifdef HAVE_AESGCM
case WC_AES_128_GCM_TYPE :
case WC_AES_192_GCM_TYPE :
case WC_AES_256_GCM_TYPE :
WOLFSSL_MSG("AES GCM");
XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, WC_AES_BLOCK_SIZE);
break;
#endif
#ifdef HAVE_AES_ECB
case WC_AES_128_ECB_TYPE :
case WC_AES_192_ECB_TYPE :
case WC_AES_256_ECB_TYPE :
WOLFSSL_MSG("AES ECB");
break;
#endif
#ifdef WOLFSSL_AES_COUNTER
case WC_AES_128_CTR_TYPE :
case WC_AES_192_CTR_TYPE :
case WC_AES_256_CTR_TYPE :
WOLFSSL_MSG("AES CTR");
XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, WC_AES_BLOCK_SIZE);
break;
#endif
#endif /* NO_AES */
#ifdef HAVE_ARIA
case WC_ARIA_128_GCM_TYPE :
case WC_ARIA_192_GCM_TYPE :
case WC_ARIA_256_GCM_TYPE :
WOLFSSL_MSG("ARIA GCM");
XMEMCPY(&ctx->cipher.aria.nonce, ctx->iv, ARIA_BLOCK_SIZE);
break;
#endif /* HAVE_ARIA */
#ifndef NO_DES3
case WC_DES_CBC_TYPE :
WOLFSSL_MSG("DES CBC");
XMEMCPY(&ctx->cipher.des.reg, ctx->iv, DES_BLOCK_SIZE);
break;
case WC_DES_EDE3_CBC_TYPE :
WOLFSSL_MSG("DES EDE3 CBC");
XMEMCPY(&ctx->cipher.des3.reg, ctx->iv, DES_BLOCK_SIZE);
break;
#endif
#ifdef WOLFSSL_DES_ECB
case WC_DES_ECB_TYPE :
WOLFSSL_MSG("DES ECB");
break;
case WC_DES_EDE3_ECB_TYPE :
WOLFSSL_MSG("DES3 ECB");
break;
#endif
case WC_ARC4_TYPE :
WOLFSSL_MSG("ARC4");
break;
#if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
case WC_CHACHA20_POLY1305_TYPE:
break;
#endif
#ifdef HAVE_CHACHA
case WC_CHACHA20_TYPE:
break;
#endif
#ifdef WOLFSSL_SM4_ECB
case WC_SM4_ECB_TYPE:
break;
#endif
#ifdef WOLFSSL_SM4_CBC
case WC_SM4_CBC_TYPE:
WOLFSSL_MSG("SM4 CBC");
XMEMCPY(ctx->iv, &ctx->cipher.sm4.iv, ctx->ivSz);
break;
#endif
#ifdef WOLFSSL_SM4_CTR
case WC_SM4_CTR_TYPE:
WOLFSSL_MSG("SM4 CTR");
XMEMCPY(ctx->iv, &ctx->cipher.sm4.iv, ctx->ivSz);
break;
#endif
#ifdef WOLFSSL_SM4_GCM
case WC_SM4_GCM_TYPE:
WOLFSSL_MSG("SM4 GCM");
XMEMCPY(ctx->iv, &ctx->cipher.sm4.iv, ctx->ivSz);
break;
#endif
#ifdef WOLFSSL_SM4_CCM
case WC_SM4_CCM_TYPE:
WOLFSSL_MSG("SM4 CCM");
XMEMCPY(ctx->iv, &ctx->cipher.sm4.iv, ctx->ivSz);
break;
#endif
case WC_NULL_CIPHER_TYPE :
WOLFSSL_MSG("NULL");
break;
default: {
WOLFSSL_MSG("bad type");
return WOLFSSL_FATAL_ERROR;
}
}
return WOLFSSL_SUCCESS;
}
#ifndef NO_DES3
void wolfSSL_3des_iv(WOLFSSL_EVP_CIPHER_CTX* ctx, int doset,
unsigned char* iv, int len)
{
(void)len;
WOLFSSL_MSG("wolfSSL_3des_iv");
if (ctx == NULL || iv == NULL) {
WOLFSSL_MSG("Bad function argument");
return;
}
if (doset)
wc_Des3_SetIV(&ctx->cipher.des3, iv); /* OpenSSL compat, no ret */
else
XMEMCPY(iv, &ctx->cipher.des3.reg, DES_BLOCK_SIZE);
}
#endif /* NO_DES3 */
#ifndef NO_AES
void wolfSSL_aes_ctr_iv(WOLFSSL_EVP_CIPHER_CTX* ctx, int doset,
unsigned char* iv, int len)
{
(void)len;
WOLFSSL_MSG("wolfSSL_aes_ctr_iv");
if (ctx == NULL || iv == NULL) {
WOLFSSL_MSG("Bad function argument");
return;
}
if (doset)
(void)wc_AesSetIV(&ctx->cipher.aes, iv); /* OpenSSL compat, no ret */
else
XMEMCPY(iv, &ctx->cipher.aes.reg, WC_AES_BLOCK_SIZE);
}
#endif /* NO_AES */
#endif /* OPENSSL_EXTRA */
/*******************************************************************************
* END OF EVP_CIPHER API
******************************************************************************/
#ifndef NO_CERTS
#define WOLFSSL_X509_STORE_INCLUDED
#include <src/x509_str.c>
#define WOLFSSL_SSL_P7P12_INCLUDED
#include <src/ssl_p7p12.c>
#endif /* !NO_CERTS */
/*******************************************************************************
* BEGIN OPENSSL FIPS DRBG APIs
******************************************************************************/
#if defined(OPENSSL_EXTRA) && !defined(WC_NO_RNG) && defined(HAVE_HASHDRBG)
int wolfSSL_FIPS_drbg_init(WOLFSSL_DRBG_CTX *ctx, int type, unsigned int flags)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
if (ctx != NULL) {
XMEMSET(ctx, 0, sizeof(WOLFSSL_DRBG_CTX));
ctx->type = type;
ctx->xflags = (int)flags;
ctx->status = DRBG_STATUS_UNINITIALISED;
ret = WOLFSSL_SUCCESS;
}
return ret;
}
WOLFSSL_DRBG_CTX* wolfSSL_FIPS_drbg_new(int type, unsigned int flags)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
WOLFSSL_DRBG_CTX* ctx = (WOLFSSL_DRBG_CTX*)XMALLOC(sizeof(WOLFSSL_DRBG_CTX),
NULL, DYNAMIC_TYPE_OPENSSL);
ret = wolfSSL_FIPS_drbg_init(ctx, type, flags);
if (ret == WOLFSSL_SUCCESS && type != 0) {
ret = wolfSSL_FIPS_drbg_instantiate(ctx, NULL, 0);
}
if (ret != WOLFSSL_SUCCESS) {
WOLFSSL_ERROR(ret);
wolfSSL_FIPS_drbg_free(ctx);
ctx = NULL;
}
return ctx;
}
int wolfSSL_FIPS_drbg_instantiate(WOLFSSL_DRBG_CTX* ctx,
const unsigned char* pers, size_t perslen)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
if (ctx != NULL && ctx->rng == NULL) {
#if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
(defined(HAVE_FIPS) && FIPS_VERSION_GE(5,0)))
ctx->rng = wc_rng_new((byte*)pers, (word32)perslen, NULL);
#else
ctx->rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
if (ctx->rng != NULL) {
#if defined(HAVE_FIPS) && FIPS_VERSION_GE(2,0)
ret = wc_InitRngNonce(ctx->rng, (byte*)pers, (word32)perslen);
#else
ret = wc_InitRng(ctx->rng);
(void)pers;
(void)perslen;
#endif
if (ret != 0) {
WOLFSSL_ERROR(ret);
XFREE(ctx->rng, NULL, DYNAMIC_TYPE_RNG);
ctx->rng = NULL;
}
}
#endif
}
if (ctx != NULL && ctx->rng != NULL) {
ctx->status = DRBG_STATUS_READY;
ret = WOLFSSL_SUCCESS;
}
return ret;
}
int wolfSSL_FIPS_drbg_set_callbacks(WOLFSSL_DRBG_CTX* ctx,
drbg_entropy_get entropy_get, drbg_entropy_clean entropy_clean,
size_t entropy_blocklen,
drbg_nonce_get none_get, drbg_nonce_clean nonce_clean)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
if (ctx != NULL) {
ctx->entropy_get = entropy_get;
ctx->entropy_clean = entropy_clean;
ctx->entropy_blocklen = entropy_blocklen;
ctx->none_get = none_get;
ctx->nonce_clean = nonce_clean;
ret = WOLFSSL_SUCCESS;
}
return ret;
}
void wolfSSL_FIPS_rand_add(const void* buf, int num, double entropy)
{
/* not implemented */
(void)buf;
(void)num;
(void)entropy;
}
int wolfSSL_FIPS_drbg_reseed(WOLFSSL_DRBG_CTX* ctx, const unsigned char* adin,
size_t adinlen)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
if (ctx != NULL && ctx->rng != NULL) {
#if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
(defined(HAVE_FIPS) && FIPS_VERSION_GE(2,0)))
if (wc_RNG_DRBG_Reseed(ctx->rng, adin, (word32)adinlen) == 0) {
ret = WOLFSSL_SUCCESS;
}
#else
ret = WOLFSSL_SUCCESS;
(void)adin;
(void)adinlen;
#endif
}
return ret;
}
int wolfSSL_FIPS_drbg_generate(WOLFSSL_DRBG_CTX* ctx, unsigned char* out,
size_t outlen, int prediction_resistance, const unsigned char* adin,
size_t adinlen)
{
int ret = WC_NO_ERR_TRACE(WOLFSSL_FAILURE);
if (ctx != NULL && ctx->rng != NULL) {
ret = wc_RNG_GenerateBlock(ctx->rng, out, (word32)outlen);
if (ret == 0) {
ret = WOLFSSL_SUCCESS;
}
}
(void)prediction_resistance;
(void)adin;
(void)adinlen;
return ret;
}
int wolfSSL_FIPS_drbg_uninstantiate(WOLFSSL_DRBG_CTX *ctx)
{
if (ctx != NULL && ctx->rng != NULL) {
#if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
(defined(HAVE_FIPS) && FIPS_VERSION_GE(5,0)))
wc_rng_free(ctx->rng);
#else
wc_FreeRng(ctx->rng);
XFREE(ctx->rng, NULL, DYNAMIC_TYPE_RNG);
#endif
ctx->rng = NULL;
ctx->status = DRBG_STATUS_UNINITIALISED;
}
return WOLFSSL_SUCCESS;
}
void wolfSSL_FIPS_drbg_free(WOLFSSL_DRBG_CTX *ctx)
{
if (ctx != NULL) {
/* As safety check if free'ing the default drbg, then mark global NULL.
* Technically the user should not call free on the default drbg. */
if (ctx == gDrbgDefCtx) {
gDrbgDefCtx = NULL;
}
wolfSSL_FIPS_drbg_uninstantiate(ctx);
XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
}
}
WOLFSSL_DRBG_CTX* wolfSSL_FIPS_get_default_drbg(void)
{
if (gDrbgDefCtx == NULL) {
gDrbgDefCtx = wolfSSL_FIPS_drbg_new(0, 0);
}
return gDrbgDefCtx;
}
void wolfSSL_FIPS_get_timevec(unsigned char* buf, unsigned long* pctr)
{
/* not implemented */
(void)buf;
(void)pctr;
}
void* wolfSSL_FIPS_drbg_get_app_data(WOLFSSL_DRBG_CTX *ctx)
{
if (ctx != NULL) {
return ctx->app_data;
}
return NULL;
}
void wolfSSL_FIPS_drbg_set_app_data(WOLFSSL_DRBG_CTX *ctx, void *app_data)
{
if (ctx != NULL) {
ctx->app_data = app_data;
}
}
#endif
/*******************************************************************************
* END OF OPENSSL FIPS DRBG APIs
******************************************************************************/
#endif /* !WOLFCRYPT_ONLY */