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platform-external-webrtc/webrtc/base/opensslidentity.cc
Torbjorn Granlund 46c9cc0190 Provide method for returning certificate expiration time stamp. 
We convert ASN1 time via std::tm to int64_t representing milliseconds-since-epoch. We do not use time_t since that cannot store milliseconds, and expires for 32-bit platforms in 2038 also for seconds.

Conversion via std::tm might might seem silly, but actually doesn't add any complexity.

One would expect tm -> seconds-since-epoch to already exist on the standard library. There is mktime, but it uses localtime (and sets an environment variable, and has the 2038 problem).

The ASN1 TIME parsing is limited to what is required by RFC 5280.

BUG=webrtc:5150
R=hbos@webrtc.org, nisse@webrtc.org, tommi@webrtc.org

Review URL: https://codereview.webrtc.org/1468273004 .

Cr-Commit-Position: refs/heads/master@{#10854}
2015-12-01 12:06:46 +00:00

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/*
* Copyright 2004 The WebRTC Project Authors. All rights reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#if HAVE_OPENSSL_SSL_H
#include "webrtc/base/opensslidentity.h"
// Must be included first before openssl headers.
#include "webrtc/base/win32.h" // NOLINT
#include <openssl/bio.h>
#include <openssl/err.h>
#include <openssl/pem.h>
#include <openssl/bn.h>
#include <openssl/rsa.h>
#include <openssl/crypto.h>
#include "webrtc/base/checks.h"
#include "webrtc/base/helpers.h"
#include "webrtc/base/logging.h"
#include "webrtc/base/openssl.h"
#include "webrtc/base/openssldigest.h"
namespace rtc {
// We could have exposed a myriad of parameters for the crypto stuff,
// but keeping it simple seems best.
// Random bits for certificate serial number
static const int SERIAL_RAND_BITS = 64;
// Certificate validity lifetime
static const int CERTIFICATE_LIFETIME = 60*60*24*30; // 30 days, arbitrarily
// Certificate validity window.
// This is to compensate for slightly incorrect system clocks.
static const int CERTIFICATE_WINDOW = -60*60*24;
// Generate a key pair. Caller is responsible for freeing the returned object.
static EVP_PKEY* MakeKey(const KeyParams& key_params) {
LOG(LS_INFO) << "Making key pair";
EVP_PKEY* pkey = EVP_PKEY_new();
if (key_params.type() == KT_RSA) {
int key_length = key_params.rsa_params().mod_size;
BIGNUM* exponent = BN_new();
RSA* rsa = RSA_new();
if (!pkey || !exponent || !rsa ||
!BN_set_word(exponent, key_params.rsa_params().pub_exp) ||
!RSA_generate_key_ex(rsa, key_length, exponent, NULL) ||
!EVP_PKEY_assign_RSA(pkey, rsa)) {
EVP_PKEY_free(pkey);
BN_free(exponent);
RSA_free(rsa);
LOG(LS_ERROR) << "Failed to make RSA key pair";
return NULL;
}
// ownership of rsa struct was assigned, don't free it.
BN_free(exponent);
} else if (key_params.type() == KT_ECDSA) {
if (key_params.ec_curve() == EC_NIST_P256) {
EC_KEY* ec_key = EC_KEY_new_by_curve_name(NID_X9_62_prime256v1);
if (!pkey || !ec_key || !EC_KEY_generate_key(ec_key) ||
!EVP_PKEY_assign_EC_KEY(pkey, ec_key)) {
EVP_PKEY_free(pkey);
EC_KEY_free(ec_key);
LOG(LS_ERROR) << "Failed to make EC key pair";
return NULL;
}
// ownership of ec_key struct was assigned, don't free it.
} else {
// Add generation of any other curves here.
EVP_PKEY_free(pkey);
LOG(LS_ERROR) << "ECDSA key requested for unknown curve";
return NULL;
}
} else {
EVP_PKEY_free(pkey);
LOG(LS_ERROR) << "Key type requested not understood";
return NULL;
}
LOG(LS_INFO) << "Returning key pair";
return pkey;
}
// Generate a self-signed certificate, with the public key from the
// given key pair. Caller is responsible for freeing the returned object.
static X509* MakeCertificate(EVP_PKEY* pkey, const SSLIdentityParams& params) {
LOG(LS_INFO) << "Making certificate for " << params.common_name;
X509* x509 = NULL;
BIGNUM* serial_number = NULL;
X509_NAME* name = NULL;
time_t epoch_off = 0; // Time offset since epoch.
if ((x509=X509_new()) == NULL)
goto error;
if (!X509_set_pubkey(x509, pkey))
goto error;
// serial number
// temporary reference to serial number inside x509 struct
ASN1_INTEGER* asn1_serial_number;
if ((serial_number = BN_new()) == NULL ||
!BN_pseudo_rand(serial_number, SERIAL_RAND_BITS, 0, 0) ||
(asn1_serial_number = X509_get_serialNumber(x509)) == NULL ||
!BN_to_ASN1_INTEGER(serial_number, asn1_serial_number))
goto error;
if (!X509_set_version(x509, 0L)) // version 1
goto error;
// There are a lot of possible components for the name entries. In
// our P2P SSL mode however, the certificates are pre-exchanged
// (through the secure XMPP channel), and so the certificate
// identification is arbitrary. It can't be empty, so we set some
// arbitrary common_name. Note that this certificate goes out in
// clear during SSL negotiation, so there may be a privacy issue in
// putting anything recognizable here.
if ((name = X509_NAME_new()) == NULL ||
!X509_NAME_add_entry_by_NID(
name, NID_commonName, MBSTRING_UTF8,
(unsigned char*)params.common_name.c_str(), -1, -1, 0) ||
!X509_set_subject_name(x509, name) ||
!X509_set_issuer_name(x509, name))
goto error;
if (!X509_time_adj(X509_get_notBefore(x509), params.not_before, &epoch_off) ||
!X509_time_adj(X509_get_notAfter(x509), params.not_after, &epoch_off))
goto error;
if (!X509_sign(x509, pkey, EVP_sha256()))
goto error;
BN_free(serial_number);
X509_NAME_free(name);
LOG(LS_INFO) << "Returning certificate";
return x509;
error:
BN_free(serial_number);
X509_NAME_free(name);
X509_free(x509);
return NULL;
}
// This dumps the SSL error stack to the log.
static void LogSSLErrors(const std::string& prefix) {
char error_buf[200];
unsigned long err;
while ((err = ERR_get_error()) != 0) {
ERR_error_string_n(err, error_buf, sizeof(error_buf));
LOG(LS_ERROR) << prefix << ": " << error_buf << "\n";
}
}
OpenSSLKeyPair* OpenSSLKeyPair::Generate(const KeyParams& key_params) {
EVP_PKEY* pkey = MakeKey(key_params);
if (!pkey) {
LogSSLErrors("Generating key pair");
return NULL;
}
return new OpenSSLKeyPair(pkey);
}
OpenSSLKeyPair::~OpenSSLKeyPair() {
EVP_PKEY_free(pkey_);
}
OpenSSLKeyPair* OpenSSLKeyPair::GetReference() {
AddReference();
return new OpenSSLKeyPair(pkey_);
}
void OpenSSLKeyPair::AddReference() {
#if defined(OPENSSL_IS_BORINGSSL)
EVP_PKEY_up_ref(pkey_);
#else
CRYPTO_add(&pkey_->references, 1, CRYPTO_LOCK_EVP_PKEY);
#endif
}
#if !defined(NDEBUG)
// Print a certificate to the log, for debugging.
static void PrintCert(X509* x509) {
BIO* temp_memory_bio = BIO_new(BIO_s_mem());
if (!temp_memory_bio) {
LOG_F(LS_ERROR) << "Failed to allocate temporary memory bio";
return;
}
X509_print_ex(temp_memory_bio, x509, XN_FLAG_SEP_CPLUS_SPC, 0);
BIO_write(temp_memory_bio, "\0", 1);
char* buffer;
BIO_get_mem_data(temp_memory_bio, &buffer);
LOG(LS_VERBOSE) << buffer;
BIO_free(temp_memory_bio);
}
#endif
OpenSSLCertificate* OpenSSLCertificate::Generate(
OpenSSLKeyPair* key_pair, const SSLIdentityParams& params) {
SSLIdentityParams actual_params(params);
if (actual_params.common_name.empty()) {
// Use a random string, arbitrarily 8chars long.
actual_params.common_name = CreateRandomString(8);
}
X509* x509 = MakeCertificate(key_pair->pkey(), actual_params);
if (!x509) {
LogSSLErrors("Generating certificate");
return NULL;
}
#if !defined(NDEBUG)
PrintCert(x509);
#endif
OpenSSLCertificate* ret = new OpenSSLCertificate(x509);
X509_free(x509);
return ret;
}
OpenSSLCertificate* OpenSSLCertificate::FromPEMString(
const std::string& pem_string) {
BIO* bio = BIO_new_mem_buf(const_cast<char*>(pem_string.c_str()), -1);
if (!bio)
return NULL;
BIO_set_mem_eof_return(bio, 0);
X509* x509 = PEM_read_bio_X509(bio, NULL, NULL, const_cast<char*>("\0"));
BIO_free(bio); // Frees the BIO, but not the pointed-to string.
if (!x509)
return NULL;
OpenSSLCertificate* ret = new OpenSSLCertificate(x509);
X509_free(x509);
return ret;
}
// NOTE: This implementation only functions correctly after InitializeSSL
// and before CleanupSSL.
bool OpenSSLCertificate::GetSignatureDigestAlgorithm(
std::string* algorithm) const {
int nid = OBJ_obj2nid(x509_->sig_alg->algorithm);
switch (nid) {
case NID_md5WithRSA:
case NID_md5WithRSAEncryption:
*algorithm = DIGEST_MD5;
break;
case NID_ecdsa_with_SHA1:
case NID_dsaWithSHA1:
case NID_dsaWithSHA1_2:
case NID_sha1WithRSA:
case NID_sha1WithRSAEncryption:
*algorithm = DIGEST_SHA_1;
break;
case NID_ecdsa_with_SHA224:
case NID_sha224WithRSAEncryption:
case NID_dsa_with_SHA224:
*algorithm = DIGEST_SHA_224;
break;
case NID_ecdsa_with_SHA256:
case NID_sha256WithRSAEncryption:
case NID_dsa_with_SHA256:
*algorithm = DIGEST_SHA_256;
break;
case NID_ecdsa_with_SHA384:
case NID_sha384WithRSAEncryption:
*algorithm = DIGEST_SHA_384;
break;
case NID_ecdsa_with_SHA512:
case NID_sha512WithRSAEncryption:
*algorithm = DIGEST_SHA_512;
break;
default:
// Unknown algorithm. There are several unhandled options that are less
// common and more complex.
LOG(LS_ERROR) << "Unknown signature algorithm NID: " << nid;
algorithm->clear();
return false;
}
return true;
}
bool OpenSSLCertificate::GetChain(SSLCertChain** chain) const {
// Chains are not yet supported when using OpenSSL.
// OpenSSLStreamAdapter::SSLVerifyCallback currently requires the remote
// certificate to be self-signed.
return false;
}
bool OpenSSLCertificate::ComputeDigest(const std::string& algorithm,
unsigned char* digest,
size_t size,
size_t* length) const {
return ComputeDigest(x509_, algorithm, digest, size, length);
}
bool OpenSSLCertificate::ComputeDigest(const X509* x509,
const std::string& algorithm,
unsigned char* digest,
size_t size,
size_t* length) {
const EVP_MD* md;
unsigned int n;
if (!OpenSSLDigest::GetDigestEVP(algorithm, &md))
return false;
if (size < static_cast<size_t>(EVP_MD_size(md)))
return false;
X509_digest(x509, md, digest, &n);
*length = n;
return true;
}
OpenSSLCertificate::~OpenSSLCertificate() {
X509_free(x509_);
}
OpenSSLCertificate* OpenSSLCertificate::GetReference() const {
return new OpenSSLCertificate(x509_);
}
std::string OpenSSLCertificate::ToPEMString() const {
BIO* bio = BIO_new(BIO_s_mem());
if (!bio) {
FATAL() << "unreachable code";
}
if (!PEM_write_bio_X509(bio, x509_)) {
BIO_free(bio);
FATAL() << "unreachable code";
}
BIO_write(bio, "\0", 1);
char* buffer;
BIO_get_mem_data(bio, &buffer);
std::string ret(buffer);
BIO_free(bio);
return ret;
}
void OpenSSLCertificate::ToDER(Buffer* der_buffer) const {
// In case of failure, make sure to leave the buffer empty.
der_buffer->SetSize(0);
// Calculates the DER representation of the certificate, from scratch.
BIO* bio = BIO_new(BIO_s_mem());
if (!bio) {
FATAL() << "unreachable code";
}
if (!i2d_X509_bio(bio, x509_)) {
BIO_free(bio);
FATAL() << "unreachable code";
}
char* data;
size_t length = BIO_get_mem_data(bio, &data);
der_buffer->SetData(data, length);
BIO_free(bio);
}
void OpenSSLCertificate::AddReference() const {
ASSERT(x509_ != NULL);
#if defined(OPENSSL_IS_BORINGSSL)
X509_up_ref(x509_);
#else
CRYPTO_add(&x509_->references, 1, CRYPTO_LOCK_X509);
#endif
}
// Documented in sslidentity.h.
int64_t OpenSSLCertificate::CertificateExpirationTime() const {
ASN1_TIME* expire_time = X509_get_notAfter(x509_);
bool long_format;
if (expire_time->type == V_ASN1_UTCTIME) {
long_format = false;
} else if (expire_time->type == V_ASN1_GENERALIZEDTIME) {
long_format = true;
} else {
return -1;
}
return ASN1TimeToSec(expire_time->data, expire_time->length, long_format);
}
OpenSSLIdentity::OpenSSLIdentity(OpenSSLKeyPair* key_pair,
OpenSSLCertificate* certificate)
: key_pair_(key_pair), certificate_(certificate) {
ASSERT(key_pair != NULL);
ASSERT(certificate != NULL);
}
OpenSSLIdentity::~OpenSSLIdentity() = default;
OpenSSLIdentity* OpenSSLIdentity::GenerateInternal(
const SSLIdentityParams& params) {
OpenSSLKeyPair* key_pair = OpenSSLKeyPair::Generate(params.key_params);
if (key_pair) {
OpenSSLCertificate* certificate =
OpenSSLCertificate::Generate(key_pair, params);
if (certificate)
return new OpenSSLIdentity(key_pair, certificate);
delete key_pair;
}
LOG(LS_INFO) << "Identity generation failed";
return NULL;
}
OpenSSLIdentity* OpenSSLIdentity::Generate(const std::string& common_name,
const KeyParams& key_params) {
SSLIdentityParams params;
params.key_params = key_params;
params.common_name = common_name;
time_t now = time(NULL);
params.not_before = now + CERTIFICATE_WINDOW;
params.not_after = now + CERTIFICATE_LIFETIME;
return GenerateInternal(params);
}
OpenSSLIdentity* OpenSSLIdentity::GenerateForTest(
const SSLIdentityParams& params) {
return GenerateInternal(params);
}
SSLIdentity* OpenSSLIdentity::FromPEMStrings(
const std::string& private_key,
const std::string& certificate) {
scoped_ptr<OpenSSLCertificate> cert(
OpenSSLCertificate::FromPEMString(certificate));
if (!cert) {
LOG(LS_ERROR) << "Failed to create OpenSSLCertificate from PEM string.";
return NULL;
}
BIO* bio = BIO_new_mem_buf(const_cast<char*>(private_key.c_str()), -1);
if (!bio) {
LOG(LS_ERROR) << "Failed to create a new BIO buffer.";
return NULL;
}
BIO_set_mem_eof_return(bio, 0);
EVP_PKEY* pkey =
PEM_read_bio_PrivateKey(bio, NULL, NULL, const_cast<char*>("\0"));
BIO_free(bio); // Frees the BIO, but not the pointed-to string.
if (!pkey) {
LOG(LS_ERROR) << "Failed to create the private key from PEM string.";
return NULL;
}
return new OpenSSLIdentity(new OpenSSLKeyPair(pkey),
cert.release());
}
const OpenSSLCertificate& OpenSSLIdentity::certificate() const {
return *certificate_;
}
OpenSSLIdentity* OpenSSLIdentity::GetReference() const {
return new OpenSSLIdentity(key_pair_->GetReference(),
certificate_->GetReference());
}
bool OpenSSLIdentity::ConfigureIdentity(SSL_CTX* ctx) {
// 1 is the documented success return code.
if (SSL_CTX_use_certificate(ctx, certificate_->x509()) != 1 ||
SSL_CTX_use_PrivateKey(ctx, key_pair_->pkey()) != 1) {
LogSSLErrors("Configuring key and certificate");
return false;
}
return true;
}
} // namespace rtc
#endif // HAVE_OPENSSL_SSL_H
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