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// Copyright (c) 2011 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
// This file includes code SSLClientSocketNSS::DoVerifyCertComplete() derived
// from AuthCertificateCallback() in
// mozilla/security/manager/ssl/src/nsNSSCallbacks.cpp.
/* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1/GPL 2.0/LGPL 2.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is the Netscape security libraries.
*
* The Initial Developer of the Original Code is
* Netscape Communications Corporation.
* Portions created by the Initial Developer are Copyright (C) 2000
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
* Ian McGreer <mcgreer@netscape.com>
* Javier Delgadillo <javi@netscape.com>
* Kai Engert <kengert@redhat.com>
*
* Alternatively, the contents of this file may be used under the terms of
* either the GNU General Public License Version 2 or later (the "GPL"), or
* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
* in which case the provisions of the GPL or the LGPL are applicable instead
* of those above. If you wish to allow use of your version of this file only
* under the terms of either the GPL or the LGPL, and not to allow others to
* use your version of this file under the terms of the MPL, indicate your
* decision by deleting the provisions above and replace them with the notice
* and other provisions required by the GPL or the LGPL. If you do not delete
* the provisions above, a recipient may use your version of this file under
* the terms of any one of the MPL, the GPL or the LGPL.
*
* ***** END LICENSE BLOCK ***** */
#include "net/socket/ssl_client_socket_nss.h"
#include <certdb.h>
#include <hasht.h>
#include <keyhi.h>
#include <nspr.h>
#include <nss.h>
#include <ocsp.h>
#include <pk11pub.h>
#include <secerr.h>
#include <sechash.h>
#include <ssl.h>
#include <sslerr.h>
#include <sslproto.h>
#include <algorithm>
#include <limits>
#include <map>
#include "base/compiler_specific.h"
#include "base/logging.h"
#include "base/memory/singleton.h"
#include "base/metrics/histogram.h"
#include "base/string_number_conversions.h"
#include "base/string_util.h"
#include "base/stringprintf.h"
#include "base/threading/thread_restrictions.h"
#include "base/values.h"
#include "crypto/rsa_private_key.h"
#include "crypto/scoped_nss_types.h"
#include "net/base/address_list.h"
#include "net/base/asn1_util.h"
#include "net/base/cert_status_flags.h"
#include "net/base/cert_verifier.h"
#include "net/base/connection_type_histograms.h"
#include "net/base/dns_util.h"
#include "net/base/dnsrr_resolver.h"
#include "net/base/dnssec_chain_verifier.h"
#include "net/base/transport_security_state.h"
#include "net/base/io_buffer.h"
#include "net/base/net_errors.h"
#include "net/base/net_log.h"
#include "net/base/ssl_cert_request_info.h"
#include "net/base/ssl_connection_status_flags.h"
#include "net/base/ssl_info.h"
#include "net/base/sys_addrinfo.h"
#include "net/ocsp/nss_ocsp.h"
#include "net/socket/client_socket_handle.h"
#include "net/socket/dns_cert_provenance_checker.h"
#include "net/socket/nss_ssl_util.h"
#include "net/socket/ssl_error_params.h"
#include "net/socket/ssl_host_info.h"
#if defined(OS_WIN)
#include <windows.h>
#include <wincrypt.h>
#elif defined(OS_MACOSX)
#include <Security/SecBase.h>
#include <Security/SecCertificate.h>
#include <Security/SecIdentity.h>
#elif defined(USE_NSS)
#include <dlfcn.h>
#endif
static const int kRecvBufferSize = 4096;
// kCorkTimeoutMs is the number of milliseconds for which we'll wait for a
// Write to an SSL socket which we're False Starting. Since corking stops the
// Finished message from being sent, the server sees an incomplete handshake
// and some will time out such sockets quite aggressively.
static const int kCorkTimeoutMs = 200;
#if defined(OS_WIN)
// CERT_OCSP_RESPONSE_PROP_ID is only implemented on Vista+, but it can be
// set on Windows XP without error. There is some overhead from the server
// sending the OCSP response if it supports the extension, for the subset of
// XP clients who will request it but be unable to use it, but this is an
// acceptable trade-off for simplicity of implementation.
static bool IsOCSPStaplingSupported() {
return true;
}
#elif defined(USE_NSS)
typedef SECStatus
(*CacheOCSPResponseFromSideChannelFunction)(
CERTCertDBHandle *handle, CERTCertificate *cert, PRTime time,
SECItem *encodedResponse, void *pwArg);
// On Linux, we dynamically link against the system version of libnss3.so. In
// order to continue working on systems without up-to-date versions of NSS we
// lookup CERT_CacheOCSPResponseFromSideChannel with dlsym.
// RuntimeLibNSSFunctionPointers is a singleton which caches the results of any
// runtime symbol resolution that we need.
class RuntimeLibNSSFunctionPointers {
public:
CacheOCSPResponseFromSideChannelFunction
GetCacheOCSPResponseFromSideChannelFunction() {
return cache_ocsp_response_from_side_channel_;
}
static RuntimeLibNSSFunctionPointers* GetInstance() {
return Singleton<RuntimeLibNSSFunctionPointers>::get();
}
private:
friend struct DefaultSingletonTraits<RuntimeLibNSSFunctionPointers>;
RuntimeLibNSSFunctionPointers() {
cache_ocsp_response_from_side_channel_ =
(CacheOCSPResponseFromSideChannelFunction)
dlsym(RTLD_DEFAULT, "CERT_CacheOCSPResponseFromSideChannel");
}
CacheOCSPResponseFromSideChannelFunction
cache_ocsp_response_from_side_channel_;
};
static CacheOCSPResponseFromSideChannelFunction
GetCacheOCSPResponseFromSideChannelFunction() {
return RuntimeLibNSSFunctionPointers::GetInstance()
->GetCacheOCSPResponseFromSideChannelFunction();
}
static bool IsOCSPStaplingSupported() {
return GetCacheOCSPResponseFromSideChannelFunction() != NULL;
}
#else
// TODO(agl): Figure out if we can plumb the OCSP response into Mac's system
// certificate validation functions.
static bool IsOCSPStaplingSupported() {
return false;
}
#endif
namespace net {
// State machines are easier to debug if you log state transitions.
// Enable these if you want to see what's going on.
#if 1
#define EnterFunction(x)
#define LeaveFunction(x)
#define GotoState(s) next_handshake_state_ = s
#else
#define EnterFunction(x)\
VLOG(1) << (void *)this << " " << __FUNCTION__ << " enter " << x\
<< "; next_handshake_state " << next_handshake_state_
#define LeaveFunction(x)\
VLOG(1) << (void *)this << " " << __FUNCTION__ << " leave " << x\
<< "; next_handshake_state " << next_handshake_state_
#define GotoState(s)\
do {\
VLOG(1) << (void *)this << " " << __FUNCTION__ << " jump to state " << s;\
next_handshake_state_ = s;\
} while (0)
#endif
namespace {
#if defined(OS_WIN)
// This callback is intended to be used with CertFindChainInStore. In addition
// to filtering by extended/enhanced key usage, we do not show expired
// certificates and require digital signature usage in the key usage
// extension.
//
// This matches our behavior on Mac OS X and that of NSS. It also matches the
// default behavior of IE8. See http://support.microsoft.com/kb/890326 and
// http://blogs.msdn.com/b/askie/archive/2009/06/09/my-expired-client-certificates-no-longer-display-when-connecting-to-my-web-server-using-ie8.aspx
BOOL WINAPI ClientCertFindCallback(PCCERT_CONTEXT cert_context,
void* find_arg) {
VLOG(1) << "Calling ClientCertFindCallback from _nss";
// Verify the certificate's KU is good.
BYTE key_usage;
if (CertGetIntendedKeyUsage(X509_ASN_ENCODING, cert_context->pCertInfo,
&key_usage, 1)) {
if (!(key_usage & CERT_DIGITAL_SIGNATURE_KEY_USAGE))
return FALSE;
} else {
DWORD err = GetLastError();
// If |err| is non-zero, it's an actual error. Otherwise the extension
// just isn't present, and we treat it as if everything was allowed.
if (err) {
DLOG(ERROR) << "CertGetIntendedKeyUsage failed: " << err;
return FALSE;
}
}
// Verify the current time is within the certificate's validity period.
if (CertVerifyTimeValidity(NULL, cert_context->pCertInfo) != 0)
return FALSE;
// Verify private key metadata is associated with this certificate.
DWORD size = 0;
if (!CertGetCertificateContextProperty(
cert_context, CERT_KEY_PROV_INFO_PROP_ID, NULL, &size)) {
return FALSE;
}
return TRUE;
}
#endif
// PeerCertificateChain is a helper object which extracts the certificate
// chain, as given by the server, from an NSS socket and performs the needed
// resource management. The first element of the chain is the leaf certificate
// and the other elements are in the order given by the server.
class PeerCertificateChain {
public:
explicit PeerCertificateChain(PRFileDesc* nss_fd)
: num_certs_(0),
certs_(NULL) {
SECStatus rv = SSL_PeerCertificateChain(nss_fd, NULL, &num_certs_);
DCHECK_EQ(rv, SECSuccess);
certs_ = new CERTCertificate*[num_certs_];
const unsigned expected_num_certs = num_certs_;
rv = SSL_PeerCertificateChain(nss_fd, certs_, &num_certs_);
DCHECK_EQ(rv, SECSuccess);
DCHECK_EQ(num_certs_, expected_num_certs);
}
~PeerCertificateChain() {
for (unsigned i = 0; i < num_certs_; i++)
CERT_DestroyCertificate(certs_[i]);
delete[] certs_;
}
unsigned size() const { return num_certs_; }
CERTCertificate* operator[](unsigned i) {
DCHECK_LT(i, num_certs_);
return certs_[i];
}
std::vector<base::StringPiece> AsStringPieceVector() const {
std::vector<base::StringPiece> v(size());
for (unsigned i = 0; i < size(); i++) {
v[i] = base::StringPiece(
reinterpret_cast<const char*>(certs_[i]->derCert.data),
certs_[i]->derCert.len);
}
return v;
}
private:
unsigned num_certs_;
CERTCertificate** certs_;
};
void DestroyCertificates(CERTCertificate** certs, unsigned len) {
for (unsigned i = 0; i < len; i++)
CERT_DestroyCertificate(certs[i]);
}
// DNSValidationResult enumerates the possible outcomes from processing a
// set of DNS records.
enum DNSValidationResult {
DNSVR_SUCCESS, // the cert is immediately acceptable.
DNSVR_FAILURE, // the cert is unconditionally rejected.
DNSVR_CONTINUE, // perform CA validation as usual.
};
// VerifyCAARecords processes DNSSEC validated RRDATA for a number of DNS CAA
// records and checks them against the given chain.
// server_cert_nss: the server's leaf certificate.
// rrdatas: the CAA records for the current domain.
// port: the TCP port number that we connected to.
DNSValidationResult VerifyCAARecords(
CERTCertificate* server_cert_nss,
const std::vector<base::StringPiece>& rrdatas,
uint16 port) {
DnsCAARecord::Policy policy;
const DnsCAARecord::ParseResult r = DnsCAARecord::Parse(rrdatas, &policy);
if (r == DnsCAARecord::SYNTAX_ERROR || r == DnsCAARecord::UNKNOWN_CRITICAL)
return DNSVR_FAILURE;
if (r == DnsCAARecord::DISCARD)
return DNSVR_CONTINUE;
DCHECK(r == DnsCAARecord::SUCCESS);
for (std::vector<DnsCAARecord::Policy::Hash>::const_iterator
hash = policy.authorized_hashes.begin();
hash != policy.authorized_hashes.end();
++hash) {
if (hash->target == DnsCAARecord::Policy::SUBJECT_PUBLIC_KEY_INFO &&
(hash->port == 0 || hash->port == port)) {
CHECK_LE(hash->data.size(), static_cast<unsigned>(SHA512_LENGTH));
uint8 calculated_hash[SHA512_LENGTH]; // SHA512 is the largest.
SECStatus rv = HASH_HashBuf(
static_cast<HASH_HashType>(hash->algorithm),
calculated_hash,
server_cert_nss->derPublicKey.data,
server_cert_nss->derPublicKey.len);
DCHECK(rv == SECSuccess);
const std::string actual_digest(reinterpret_cast<char*>(calculated_hash),
hash->data.size());
// Note that the parser ensures that hash->data.size() is correct for the
// given algorithm. An attacker cannot give a zero length hash that
// always matches.
if (actual_digest == hash->data) {
// A DNSSEC secure hash over the public key of the leaf-certificate
// is sufficient.
return DNSVR_SUCCESS;
}
}
}
// If a CAA record was found, but nothing matched, then we reject the
// certificate.
return DNSVR_FAILURE;
}
// CheckDNSSECChain tries to validate a DNSSEC chain embedded in
// |server_cert_nss_|. It returns true iff a chain is found that proves the
// value of a CAA record that contains a valid public key fingerprint.
// |port| contains the TCP port number that we connected to as CAA records can
// be specific to a given port.
DNSValidationResult CheckDNSSECChain(
const std::string& hostname,
CERTCertificate* server_cert_nss,
uint16 port) {
if (!server_cert_nss)
return DNSVR_CONTINUE;
// CERT_FindCertExtensionByOID isn't exported so we have to install an OID,
// get a tag for it and find the extension by using that tag.
static SECOidTag dnssec_chain_tag;
static bool dnssec_chain_tag_valid;
if (!dnssec_chain_tag_valid) {
// It's harmless if multiple threads enter this block concurrently.
static const uint8 kDNSSECChainOID[] =
// 1.3.6.1.4.1.11129.2.1.4
// (iso.org.dod.internet.private.enterprises.google.googleSecurity.
// certificateExtensions.dnssecEmbeddedChain)
{0x2b, 0x06, 0x01, 0x04, 0x01, 0xd6, 0x79, 0x02, 0x01, 0x04};
SECOidData oid_data;
memset(&oid_data, 0, sizeof(oid_data));
oid_data.oid.data = const_cast<uint8*>(kDNSSECChainOID);
oid_data.oid.len = sizeof(kDNSSECChainOID);
oid_data.desc = "DNSSEC chain";
oid_data.supportedExtension = SUPPORTED_CERT_EXTENSION;
dnssec_chain_tag = SECOID_AddEntry(&oid_data);
DCHECK_NE(SEC_OID_UNKNOWN, dnssec_chain_tag);
dnssec_chain_tag_valid = true;
}
SECItem dnssec_embedded_chain;
SECStatus rv = CERT_FindCertExtension(server_cert_nss,
dnssec_chain_tag, &dnssec_embedded_chain);
if (rv != SECSuccess)
return DNSVR_CONTINUE;
base::StringPiece chain(
reinterpret_cast<char*>(dnssec_embedded_chain.data),
dnssec_embedded_chain.len);
std::string dns_hostname;
if (!DNSDomainFromDot(hostname, &dns_hostname))
return DNSVR_CONTINUE;
DNSSECChainVerifier verifier(dns_hostname, chain);
DNSSECChainVerifier::Error err = verifier.Verify();
if (err != DNSSECChainVerifier::OK) {
LOG(ERROR) << "DNSSEC chain verification failed: " << err;
return DNSVR_CONTINUE;
}
if (verifier.rrtype() != kDNS_CAA)
return DNSVR_CONTINUE;
DNSValidationResult r = VerifyCAARecords(
server_cert_nss, verifier.rrdatas(), port);
SECITEM_FreeItem(&dnssec_embedded_chain, PR_FALSE);
return r;
}
} // namespace
SSLClientSocketNSS::SSLClientSocketNSS(ClientSocketHandle* transport_socket,
const HostPortPair& host_and_port,
const SSLConfig& ssl_config,
SSLHostInfo* ssl_host_info,
const SSLClientSocketContext& context)
: ALLOW_THIS_IN_INITIALIZER_LIST(buffer_send_callback_(
this, &SSLClientSocketNSS::BufferSendComplete)),
ALLOW_THIS_IN_INITIALIZER_LIST(buffer_recv_callback_(
this, &SSLClientSocketNSS::BufferRecvComplete)),
transport_send_busy_(false),
transport_recv_busy_(false),
corked_(false),
ALLOW_THIS_IN_INITIALIZER_LIST(handshake_io_callback_(
this, &SSLClientSocketNSS::OnHandshakeIOComplete)),
transport_(transport_socket),
host_and_port_(host_and_port),
ssl_config_(ssl_config),
user_connect_callback_(NULL),
user_read_callback_(NULL),
user_write_callback_(NULL),
user_read_buf_len_(0),
user_write_buf_len_(0),
server_cert_nss_(NULL),
server_cert_verify_result_(NULL),
ssl_connection_status_(0),
client_auth_cert_needed_(false),
cert_verifier_(context.cert_verifier),
ob_cert_xtn_negotiated_(false),
origin_bound_cert_service_(context.origin_bound_cert_service),
ob_cert_request_handle_(NULL),
handshake_callback_called_(false),
completed_handshake_(false),
eset_mitm_detected_(false),
kaspersky_mitm_detected_(false),
predicted_cert_chain_correct_(false),
next_handshake_state_(STATE_NONE),
nss_fd_(NULL),
nss_bufs_(NULL),
net_log_(transport_socket->socket()->NetLog()),
ssl_host_info_(ssl_host_info),
dns_cert_checker_(context.dns_cert_checker),
valid_thread_id_(base::kInvalidThreadId) {
EnterFunction("");
}
SSLClientSocketNSS::~SSLClientSocketNSS() {
EnterFunction("");
Disconnect();
LeaveFunction("");
}
// static
void SSLClientSocketNSS::ClearSessionCache() {
SSL_ClearSessionCache();
}
void SSLClientSocketNSS::GetSSLInfo(SSLInfo* ssl_info) {
EnterFunction("");
ssl_info->Reset();
if (!server_cert_nss_)
return;
ssl_info->cert_status = server_cert_verify_result_->cert_status;
ssl_info->cert = server_cert_;
ssl_info->connection_status = ssl_connection_status_;
ssl_info->public_key_hashes = server_cert_verify_result_->public_key_hashes;
for (std::vector<SHA1Fingerprint>::const_iterator
i = side_pinned_public_keys_.begin();
i != side_pinned_public_keys_.end(); i++) {
ssl_info->public_key_hashes.push_back(*i);
}
ssl_info->is_issued_by_known_root =
server_cert_verify_result_->is_issued_by_known_root;
PRUint16 cipher_suite =
SSLConnectionStatusToCipherSuite(ssl_connection_status_);
SSLCipherSuiteInfo cipher_info;
SECStatus ok = SSL_GetCipherSuiteInfo(cipher_suite,
&cipher_info, sizeof(cipher_info));
if (ok == SECSuccess) {
ssl_info->security_bits = cipher_info.effectiveKeyBits;
} else {
ssl_info->security_bits = -1;
LOG(DFATAL) << "SSL_GetCipherSuiteInfo returned " << PR_GetError()
<< " for cipherSuite " << cipher_suite;
}
PRBool last_handshake_resumed;
ok = SSL_HandshakeResumedSession(nss_fd_, &last_handshake_resumed);
if (ok == SECSuccess) {
if (last_handshake_resumed) {
ssl_info->handshake_type = SSLInfo::HANDSHAKE_RESUME;
} else {
ssl_info->handshake_type = SSLInfo::HANDSHAKE_FULL;
}
}
LeaveFunction("");
}
void SSLClientSocketNSS::GetSSLCertRequestInfo(
SSLCertRequestInfo* cert_request_info) {
EnterFunction("");
// TODO(rch): switch SSLCertRequestInfo.host_and_port to a HostPortPair
cert_request_info->host_and_port = host_and_port_.ToString();
cert_request_info->client_certs = client_certs_;
LeaveFunction(cert_request_info->client_certs.size());
}
int SSLClientSocketNSS::ExportKeyingMaterial(const base::StringPiece& label,
const base::StringPiece& context,
unsigned char *out,
unsigned int outlen) {
if (!IsConnected())
return ERR_SOCKET_NOT_CONNECTED;
SECStatus result = SSL_ExportKeyingMaterial(
nss_fd_, label.data(), label.size(),
reinterpret_cast<const unsigned char*>(context.data()),
context.length(), out, outlen);
if (result != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_ExportKeyingMaterial", "");
return MapNSSError(PORT_GetError());
}
return OK;
}
SSLClientSocket::NextProtoStatus
SSLClientSocketNSS::GetNextProto(std::string* proto) {
#if defined(SSL_NEXT_PROTO_NEGOTIATED)
unsigned char buf[255];
int state;
unsigned len;
SECStatus rv = SSL_GetNextProto(nss_fd_, &state, buf, &len, sizeof(buf));
if (rv != SECSuccess) {
NOTREACHED() << "Error return from SSL_GetNextProto: " << rv;
proto->clear();
return kNextProtoUnsupported;
}
// We don't check for truncation because sizeof(buf) is large enough to hold
// the maximum protocol size.
switch (state) {
case SSL_NEXT_PROTO_NO_SUPPORT:
proto->clear();
return kNextProtoUnsupported;
case SSL_NEXT_PROTO_NEGOTIATED:
*proto = std::string(reinterpret_cast<char*>(buf), len);
return kNextProtoNegotiated;
case SSL_NEXT_PROTO_NO_OVERLAP:
*proto = std::string(reinterpret_cast<char*>(buf), len);
return kNextProtoNoOverlap;
default:
NOTREACHED() << "Unknown status from SSL_GetNextProto: " << state;
proto->clear();
return kNextProtoUnsupported;
}
#else
// No NPN support in the libssl that we are building with.
proto->clear();
return kNextProtoUnsupported;
#endif
}
int SSLClientSocketNSS::Connect(CompletionCallback* callback) {
EnterFunction("");
DCHECK(transport_.get());
DCHECK(next_handshake_state_ == STATE_NONE);
DCHECK(!user_read_callback_);
DCHECK(!user_write_callback_);
DCHECK(!user_connect_callback_);
DCHECK(!user_read_buf_);
DCHECK(!user_write_buf_);
EnsureThreadIdAssigned();
net_log_.BeginEvent(NetLog::TYPE_SSL_CONNECT, NULL);
int rv = Init();
if (rv != OK) {
net_log_.EndEventWithNetErrorCode(NetLog::TYPE_SSL_CONNECT, rv);
return rv;
}
rv = InitializeSSLOptions();
if (rv != OK) {
net_log_.EndEventWithNetErrorCode(NetLog::TYPE_SSL_CONNECT, rv);
return rv;
}
rv = InitializeSSLPeerName();
if (rv != OK) {
net_log_.EndEventWithNetErrorCode(NetLog::TYPE_SSL_CONNECT, rv);
return rv;
}
if (ssl_config_.cached_info_enabled && ssl_host_info_.get()) {
GotoState(STATE_LOAD_SSL_HOST_INFO);
} else {
GotoState(STATE_HANDSHAKE);
}
rv = DoHandshakeLoop(OK);
if (rv == ERR_IO_PENDING) {
user_connect_callback_ = callback;
} else {
net_log_.EndEventWithNetErrorCode(NetLog::TYPE_SSL_CONNECT, rv);
}
LeaveFunction("");
return rv > OK ? OK : rv;
}
void SSLClientSocketNSS::Disconnect() {
EnterFunction("");
CHECK(CalledOnValidThread());
// Shut down anything that may call us back (through buffer_send_callback_,
// buffer_recv_callback, or handshake_io_callback_).
verifier_.reset();
transport_->socket()->Disconnect();
if (ob_cert_request_handle_ != NULL) {
origin_bound_cert_service_->CancelRequest(ob_cert_request_handle_);
ob_cert_request_handle_ = NULL;
}
// TODO(wtc): Send SSL close_notify alert.
if (nss_fd_ != NULL) {
PR_Close(nss_fd_);
nss_fd_ = NULL;
}
// Reset object state
transport_send_busy_ = false;
transport_recv_busy_ = false;
user_connect_callback_ = NULL;
user_read_callback_ = NULL;
user_write_callback_ = NULL;
user_read_buf_ = NULL;
user_read_buf_len_ = 0;
user_write_buf_ = NULL;
user_write_buf_len_ = 0;
server_cert_ = NULL;
if (server_cert_nss_) {
CERT_DestroyCertificate(server_cert_nss_);
server_cert_nss_ = NULL;
}
local_server_cert_verify_result_.Reset();
server_cert_verify_result_ = NULL;
ssl_connection_status_ = 0;
completed_handshake_ = false;
eset_mitm_detected_ = false;
kaspersky_mitm_detected_ = false;
start_cert_verification_time_ = base::TimeTicks();
predicted_cert_chain_correct_ = false;
nss_bufs_ = NULL;
client_certs_.clear();
client_auth_cert_needed_ = false;
ob_cert_xtn_negotiated_ = false;
LeaveFunction("");
}
bool SSLClientSocketNSS::IsConnected() const {
// Ideally, we should also check if we have received the close_notify alert
// message from the server, and return false in that case. We're not doing
// that, so this function may return a false positive. Since the upper
// layer (HttpNetworkTransaction) needs to handle a persistent connection
// closed by the server when we send a request anyway, a false positive in
// exchange for simpler code is a good trade-off.
EnterFunction("");
bool ret = completed_handshake_ && transport_->socket()->IsConnected();
LeaveFunction("");
return ret;
}
bool SSLClientSocketNSS::IsConnectedAndIdle() const {
// Unlike IsConnected, this method doesn't return a false positive.
//
// Strictly speaking, we should check if we have received the close_notify
// alert message from the server, and return false in that case. Although
// the close_notify alert message means EOF in the SSL layer, it is just
// bytes to the transport layer below, so
// transport_->socket()->IsConnectedAndIdle() returns the desired false
// when we receive close_notify.
EnterFunction("");
bool ret = completed_handshake_ && transport_->socket()->IsConnectedAndIdle();
LeaveFunction("");
return ret;
}
int SSLClientSocketNSS::GetPeerAddress(AddressList* address) const {
return transport_->socket()->GetPeerAddress(address);
}
int SSLClientSocketNSS::GetLocalAddress(IPEndPoint* address) const {
return transport_->socket()->GetLocalAddress(address);
}
const BoundNetLog& SSLClientSocketNSS::NetLog() const {
return net_log_;
}
void SSLClientSocketNSS::SetSubresourceSpeculation() {
if (transport_.get() && transport_->socket()) {
transport_->socket()->SetSubresourceSpeculation();
} else {
NOTREACHED();
}
}
void SSLClientSocketNSS::SetOmniboxSpeculation() {
if (transport_.get() && transport_->socket()) {
transport_->socket()->SetOmniboxSpeculation();
} else {
NOTREACHED();
}
}
bool SSLClientSocketNSS::WasEverUsed() const {
if (transport_.get() && transport_->socket()) {
return transport_->socket()->WasEverUsed();
}
NOTREACHED();
return false;
}
bool SSLClientSocketNSS::UsingTCPFastOpen() const {
if (transport_.get() && transport_->socket()) {
return transport_->socket()->UsingTCPFastOpen();
}
NOTREACHED();
return false;
}
int64 SSLClientSocketNSS::NumBytesRead() const {
if (transport_.get() && transport_->socket()) {
return transport_->socket()->NumBytesRead();
}
NOTREACHED();
return -1;
}
base::TimeDelta SSLClientSocketNSS::GetConnectTimeMicros() const {
if (transport_.get() && transport_->socket()) {
return transport_->socket()->GetConnectTimeMicros();
}
NOTREACHED();
return base::TimeDelta::FromMicroseconds(-1);
}
int SSLClientSocketNSS::Read(IOBuffer* buf, int buf_len,
CompletionCallback* callback) {
EnterFunction(buf_len);
DCHECK(completed_handshake_);
DCHECK(next_handshake_state_ == STATE_NONE);
DCHECK(!user_read_callback_);
DCHECK(!user_connect_callback_);
DCHECK(!user_read_buf_);
DCHECK(nss_bufs_);
user_read_buf_ = buf;
user_read_buf_len_ = buf_len;
int rv = DoReadLoop(OK);
if (rv == ERR_IO_PENDING) {
user_read_callback_ = callback;
} else {
user_read_buf_ = NULL;
user_read_buf_len_ = 0;
}
LeaveFunction(rv);
return rv;
}
int SSLClientSocketNSS::Write(IOBuffer* buf, int buf_len,
CompletionCallback* callback) {
EnterFunction(buf_len);
DCHECK(completed_handshake_);
DCHECK(next_handshake_state_ == STATE_NONE);
DCHECK(!user_write_callback_);
DCHECK(!user_connect_callback_);
DCHECK(!user_write_buf_);
DCHECK(nss_bufs_);
user_write_buf_ = buf;
user_write_buf_len_ = buf_len;
if (corked_) {
corked_ = false;
uncork_timer_.Reset();
}
int rv = DoWriteLoop(OK);
if (rv == ERR_IO_PENDING) {
user_write_callback_ = callback;
} else {
user_write_buf_ = NULL;
user_write_buf_len_ = 0;
}
LeaveFunction(rv);
return rv;
}
bool SSLClientSocketNSS::SetReceiveBufferSize(int32 size) {
return transport_->socket()->SetReceiveBufferSize(size);
}
bool SSLClientSocketNSS::SetSendBufferSize(int32 size) {
return transport_->socket()->SetSendBufferSize(size);
}
int SSLClientSocketNSS::Init() {
EnterFunction("");
// Initialize the NSS SSL library in a threadsafe way. This also
// initializes the NSS base library.
EnsureNSSSSLInit();
if (!NSS_IsInitialized())
return ERR_UNEXPECTED;
#if !defined(OS_MACOSX) && !defined(OS_WIN)
if (ssl_config_.rev_checking_enabled) {
// We must call EnsureOCSPInit() here, on the IO thread, to get the IO loop
// by MessageLoopForIO::current().
// X509Certificate::Verify() runs on a worker thread of CertVerifier.
EnsureOCSPInit();
}
#endif
LeaveFunction("");
return OK;
}
int SSLClientSocketNSS::InitializeSSLOptions() {
// Transport connected, now hook it up to nss
// TODO(port): specify rx and tx buffer sizes separately
nss_fd_ = memio_CreateIOLayer(kRecvBufferSize);
if (nss_fd_ == NULL) {
return ERR_OUT_OF_MEMORY; // TODO(port): map NSPR error code.
}
// Grab pointer to buffers
nss_bufs_ = memio_GetSecret(nss_fd_);
/* Create SSL state machine */
/* Push SSL onto our fake I/O socket */
nss_fd_ = SSL_ImportFD(NULL, nss_fd_);
if (nss_fd_ == NULL) {
LogFailedNSSFunction(net_log_, "SSL_ImportFD", "");
return ERR_OUT_OF_MEMORY; // TODO(port): map NSPR/NSS error code.
}
// TODO(port): set more ssl options! Check errors!
int rv;
rv = SSL_OptionSet(nss_fd_, SSL_SECURITY, PR_TRUE);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_SECURITY");
return ERR_UNEXPECTED;
}
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_SSL2, PR_FALSE);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_SSL2");
return ERR_UNEXPECTED;
}
// Don't do V2 compatible hellos because they don't support TLS extensions.
rv = SSL_OptionSet(nss_fd_, SSL_V2_COMPATIBLE_HELLO, PR_FALSE);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_V2_COMPATIBLE_HELLO");
return ERR_UNEXPECTED;
}
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_SSL3, ssl_config_.ssl3_enabled);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_SSL3");
return ERR_UNEXPECTED;
}
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_TLS, ssl_config_.tls1_enabled);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_TLS");
return ERR_UNEXPECTED;
}
for (std::vector<uint16>::const_iterator it =
ssl_config_.disabled_cipher_suites.begin();
it != ssl_config_.disabled_cipher_suites.end(); ++it) {
// This will fail if the specified cipher is not implemented by NSS, but
// the failure is harmless.
SSL_CipherPrefSet(nss_fd_, *it, PR_FALSE);
}
#ifdef SSL_ENABLE_SESSION_TICKETS
// Support RFC 5077
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_SESSION_TICKETS, PR_TRUE);
if (rv != SECSuccess) {
LogFailedNSSFunction(
net_log_, "SSL_OptionSet", "SSL_ENABLE_SESSION_TICKETS");
}
#else
#error "You need to install NSS-3.12 or later to build chromium"
#endif
#ifdef SSL_ENABLE_DEFLATE
// Some web servers have been found to break if TLS is used *or* if DEFLATE
// is advertised. Thus, if TLS is disabled (probably because we are doing
// SSLv3 fallback), we disable DEFLATE also.
// See http://crbug.com/31628
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_DEFLATE, ssl_config_.tls1_enabled);
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_DEFLATE");
#endif
#ifdef SSL_ENABLE_FALSE_START
rv = SSL_OptionSet(
nss_fd_, SSL_ENABLE_FALSE_START,
ssl_config_.false_start_enabled &&
!SSLConfigService::IsKnownFalseStartIncompatibleServer(
host_and_port_.host()));
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_FALSE_START");
#endif
#ifdef SSL_ENABLE_RENEGOTIATION
// We allow servers to request renegotiation. Since we're a client,
// prohibiting this is rather a waste of time. Only servers are in a
// position to prevent renegotiation attacks.
// http://extendedsubset.com/?p=8
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_RENEGOTIATION,
SSL_RENEGOTIATE_TRANSITIONAL);
if (rv != SECSuccess) {
LogFailedNSSFunction(
net_log_, "SSL_OptionSet", "SSL_ENABLE_RENEGOTIATION");
}
#endif // SSL_ENABLE_RENEGOTIATION
#ifdef SSL_NEXT_PROTO_NEGOTIATED
if (!ssl_config_.next_protos.empty()) {
rv = SSL_SetNextProtoNego(
nss_fd_,
reinterpret_cast<const unsigned char *>(ssl_config_.next_protos.data()),
ssl_config_.next_protos.size());
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_SetNextProtoNego", "");
}
#endif
#ifdef SSL_ENABLE_OCSP_STAPLING
if (IsOCSPStaplingSupported()) {
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_OCSP_STAPLING, PR_TRUE);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet",
"SSL_ENABLE_OCSP_STAPLING");
}
}
#endif
#ifdef SSL_ENABLE_CACHED_INFO
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_CACHED_INFO,
ssl_config_.cached_info_enabled);
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_CACHED_INFO");
#endif
#ifdef SSL_ENABLE_OB_CERTS
rv = SSL_OptionSet(nss_fd_, SSL_ENABLE_OB_CERTS,
ssl_config_.origin_bound_certs_enabled);
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_ENABLE_OB_CERTS");
#endif
rv = SSL_OptionSet(nss_fd_, SSL_HANDSHAKE_AS_CLIENT, PR_TRUE);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_OptionSet", "SSL_HANDSHAKE_AS_CLIENT");
return ERR_UNEXPECTED;
}
rv = SSL_AuthCertificateHook(nss_fd_, OwnAuthCertHandler, this);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_AuthCertificateHook", "");
return ERR_UNEXPECTED;
}
#if defined(NSS_PLATFORM_CLIENT_AUTH)
rv = SSL_GetPlatformClientAuthDataHook(nss_fd_, PlatformClientAuthHandler,
this);
#else
rv = SSL_GetClientAuthDataHook(nss_fd_, ClientAuthHandler, this);
#endif
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_GetClientAuthDataHook", "");
return ERR_UNEXPECTED;
}
rv = SSL_HandshakeCallback(nss_fd_, HandshakeCallback, this);
if (rv != SECSuccess) {
LogFailedNSSFunction(net_log_, "SSL_HandshakeCallback", "");
return ERR_UNEXPECTED;
}
// Tell SSL the hostname we're trying to connect to.
SSL_SetURL(nss_fd_, host_and_port_.host().c_str());
// Tell SSL we're a client; needed if not letting NSPR do socket I/O
SSL_ResetHandshake(nss_fd_, PR_FALSE);
return OK;
}
int SSLClientSocketNSS::InitializeSSLPeerName() {
// Tell NSS who we're connected to
AddressList peer_address;
int err = transport_->socket()->GetPeerAddress(&peer_address);
if (err != OK)
return err;
const struct addrinfo* ai = peer_address.head();
PRNetAddr peername;
memset(&peername, 0, sizeof(peername));
DCHECK_LE(ai->ai_addrlen, sizeof(peername));
size_t len = std::min(static_cast<size_t>(ai->ai_addrlen),
sizeof(peername));
memcpy(&peername, ai->ai_addr, len);
// Adjust the address family field for BSD, whose sockaddr
// structure has a one-byte length and one-byte address family
// field at the beginning. PRNetAddr has a two-byte address
// family field at the beginning.
peername.raw.family = ai->ai_addr->sa_family;
memio_SetPeerName(nss_fd_, &peername);
// Set the peer ID for session reuse. This is necessary when we create an
// SSL tunnel through a proxy -- GetPeerName returns the proxy's address
// rather than the destination server's address in that case.
std::string peer_id = host_and_port_.ToString();
SECStatus rv = SSL_SetSockPeerID(nss_fd_, const_cast<char*>(peer_id.c_str()));
if (rv != SECSuccess)
LogFailedNSSFunction(net_log_, "SSL_SetSockPeerID", peer_id.c_str());
return OK;
}
// Sets server_cert_ and server_cert_nss_ if not yet set.
void SSLClientSocketNSS::UpdateServerCert() {
// We set the server_cert_ from HandshakeCallback().
if (server_cert_ == NULL) {
server_cert_nss_ = SSL_PeerCertificate(nss_fd_);
if (server_cert_nss_) {
PeerCertificateChain certs(nss_fd_);
// This call may fail when SSL is used inside sandbox. In that
// case CreateFromDERCertChain() returns NULL.
server_cert_ = X509Certificate::CreateFromDERCertChain(
certs.AsStringPieceVector());
}
}
}
// Sets ssl_connection_status_.
void SSLClientSocketNSS::UpdateConnectionStatus() {
SSLChannelInfo channel_info;
SECStatus ok = SSL_GetChannelInfo(nss_fd_,
&channel_info, sizeof(channel_info));
if (ok == SECSuccess &&
channel_info.length == sizeof(channel_info) &&
channel_info.cipherSuite) {
ssl_connection_status_ |=
(static_cast<int>(channel_info.cipherSuite) &
SSL_CONNECTION_CIPHERSUITE_MASK) <<
SSL_CONNECTION_CIPHERSUITE_SHIFT;
ssl_connection_status_ |=
(static_cast<int>(channel_info.compressionMethod) &
SSL_CONNECTION_COMPRESSION_MASK) <<
SSL_CONNECTION_COMPRESSION_SHIFT;
// NSS 3.12.x doesn't have version macros for TLS 1.1 and 1.2 (because NSS
// doesn't support them yet), so we use 0x0302 and 0x0303 directly.
int version = SSL_CONNECTION_VERSION_UNKNOWN;
if (channel_info.protocolVersion < SSL_LIBRARY_VERSION_3_0) {
// All versions less than SSL_LIBRARY_VERSION_3_0 are treated as SSL
// version 2.
version = SSL_CONNECTION_VERSION_SSL2;
} else if (channel_info.protocolVersion == SSL_LIBRARY_VERSION_3_0) {
version = SSL_CONNECTION_VERSION_SSL3;
} else if (channel_info.protocolVersion == SSL_LIBRARY_VERSION_3_1_TLS) {
version = SSL_CONNECTION_VERSION_TLS1;
} else if (channel_info.protocolVersion == 0x0302) {
version = SSL_CONNECTION_VERSION_TLS1_1;
} else if (channel_info.protocolVersion == 0x0303) {
version = SSL_CONNECTION_VERSION_TLS1_2;
}
ssl_connection_status_ |=
(version & SSL_CONNECTION_VERSION_MASK) <<
SSL_CONNECTION_VERSION_SHIFT;
}
// SSL_HandshakeNegotiatedExtension was added in NSS 3.12.6.
// Since SSL_MAX_EXTENSIONS was added at the same time, we can test
// SSL_MAX_EXTENSIONS for the presence of SSL_HandshakeNegotiatedExtension.
#if defined(SSL_MAX_EXTENSIONS)
PRBool peer_supports_renego_ext;
ok = SSL_HandshakeNegotiatedExtension(nss_fd_, ssl_renegotiation_info_xtn,
&peer_supports_renego_ext);
if (ok == SECSuccess) {
if (!peer_supports_renego_ext) {
ssl_connection_status_ |= SSL_CONNECTION_NO_RENEGOTIATION_EXTENSION;
// Log an informational message if the server does not support secure
// renegotiation (RFC 5746).
VLOG(1) << "The server " << host_and_port_.ToString()
<< " does not support the TLS renegotiation_info extension.";
}
UMA_HISTOGRAM_ENUMERATION("Net.RenegotiationExtensionSupported",
peer_supports_renego_ext, 2);
}
#endif
if (ssl_config_.ssl3_fallback)
ssl_connection_status_ |= SSL_CONNECTION_SSL3_FALLBACK;
}
void SSLClientSocketNSS::DoReadCallback(int rv) {
EnterFunction(rv);
DCHECK(rv != ERR_IO_PENDING);
DCHECK(user_read_callback_);
// Since Run may result in Read being called, clear |user_read_callback_|
// up front.
CompletionCallback* c = user_read_callback_;
user_read_callback_ = NULL;
user_read_buf_ = NULL;
user_read_buf_len_ = 0;
c->Run(rv);
LeaveFunction("");
}
void SSLClientSocketNSS::DoWriteCallback(int rv) {
EnterFunction(rv);
DCHECK(rv != ERR_IO_PENDING);
DCHECK(user_write_callback_);
// Since Run may result in Write being called, clear |user_write_callback_|
// up front.
CompletionCallback* c = user_write_callback_;
user_write_callback_ = NULL;
user_write_buf_ = NULL;
user_write_buf_len_ = 0;
c->Run(rv);
LeaveFunction("");
}
// As part of Connect(), the SSLClientSocketNSS object performs an SSL
// handshake. This requires network IO, which in turn calls
// BufferRecvComplete() with a non-zero byte count. This byte count eventually
// winds its way through the state machine and ends up being passed to the
// callback. For Read() and Write(), that's what we want. But for Connect(),
// the caller expects OK (i.e. 0) for success.
//
void SSLClientSocketNSS::DoConnectCallback(int rv) {
EnterFunction(rv);
DCHECK_NE(rv, ERR_IO_PENDING);
DCHECK(user_connect_callback_);
CompletionCallback* c = user_connect_callback_;
user_connect_callback_ = NULL;
c->Run(rv > OK ? OK : rv);
LeaveFunction("");
}
void SSLClientSocketNSS::OnHandshakeIOComplete(int result) {
EnterFunction(result);
int rv = DoHandshakeLoop(result);
if (rv != ERR_IO_PENDING) {
net_log_.EndEventWithNetErrorCode(net::NetLog::TYPE_SSL_CONNECT, rv);
DoConnectCallback(rv);
}
LeaveFunction("");
}
void SSLClientSocketNSS::OnSendComplete(int result) {
EnterFunction(result);
if (next_handshake_state_ == STATE_HANDSHAKE) {
// In handshake phase.
OnHandshakeIOComplete(result);
LeaveFunction("");
return;
}
// OnSendComplete may need to call DoPayloadRead while the renegotiation
// handshake is in progress.
int rv_read = ERR_IO_PENDING;
int rv_write = ERR_IO_PENDING;
bool network_moved;
do {
if (user_read_buf_)
rv_read = DoPayloadRead();
if (user_write_buf_)
rv_write = DoPayloadWrite();
network_moved = DoTransportIO();
} while (rv_read == ERR_IO_PENDING &&
rv_write == ERR_IO_PENDING &&
network_moved);
if (user_read_buf_ && rv_read != ERR_IO_PENDING)
DoReadCallback(rv_read);
if (user_write_buf_ && rv_write != ERR_IO_PENDING)
DoWriteCallback(rv_write);
LeaveFunction("");
}
void SSLClientSocketNSS::OnRecvComplete(int result) {
EnterFunction(result);
if (next_handshake_state_ == STATE_HANDSHAKE) {
// In handshake phase.
OnHandshakeIOComplete(result);
LeaveFunction("");
return;
}
// Network layer received some data, check if client requested to read
// decrypted data.
if (!user_read_buf_) {
LeaveFunction("");
return;
}
int rv = DoReadLoop(result);
if (rv != ERR_IO_PENDING)
DoReadCallback(rv);
LeaveFunction("");
}
int SSLClientSocketNSS::DoHandshakeLoop(int last_io_result) {
EnterFunction(last_io_result);
bool network_moved;
int rv = last_io_result;
do {
// Default to STATE_NONE for next state.
// (This is a quirk carried over from the windows
// implementation. It makes reading the logs a bit harder.)
// State handlers can and often do call GotoState just
// to stay in the current state.
State state = next_handshake_state_;
GotoState(STATE_NONE);
switch (state) {
case STATE_NONE:
// we're just pumping data between the buffer and the network
break;
case STATE_LOAD_SSL_HOST_INFO:
rv = DoLoadSSLHostInfo();
break;
case STATE_HANDSHAKE:
rv = DoHandshake();
break;
case STATE_GET_OB_CERT_COMPLETE:
rv = DoGetOBCertComplete(rv);
break;
case STATE_VERIFY_DNSSEC:
rv = DoVerifyDNSSEC(rv);
break;
case STATE_VERIFY_CERT:
DCHECK(rv == OK);
rv = DoVerifyCert(rv);
break;
case STATE_VERIFY_CERT_COMPLETE:
rv = DoVerifyCertComplete(rv);
break;
default:
rv = ERR_UNEXPECTED;
LOG(DFATAL) << "unexpected state " << state;
break;
}
// Do the actual network I/O
network_moved = DoTransportIO();
} while ((rv != ERR_IO_PENDING || network_moved) &&
next_handshake_state_ != STATE_NONE);
LeaveFunction("");
return rv;
}
int SSLClientSocketNSS::DoReadLoop(int result) {
EnterFunction("");
DCHECK(completed_handshake_);
DCHECK(next_handshake_state_ == STATE_NONE);
if (result < 0)
return result;
if (!nss_bufs_) {
LOG(DFATAL) << "!nss_bufs_";
int rv = ERR_UNEXPECTED;
net_log_.AddEvent(NetLog::TYPE_SSL_READ_ERROR,
make_scoped_refptr(new SSLErrorParams(rv, 0)));
return rv;
}
bool network_moved;
int rv;
do {
rv = DoPayloadRead();
network_moved = DoTransportIO();
} while (rv == ERR_IO_PENDING && network_moved);
LeaveFunction("");
return rv;
}
int SSLClientSocketNSS::DoWriteLoop(int result) {
EnterFunction("");
DCHECK(completed_handshake_);
DCHECK(next_handshake_state_ == STATE_NONE);
if (result < 0)
return result;
if (!nss_bufs_) {
LOG(DFATAL) << "!nss_bufs_";
int rv = ERR_UNEXPECTED;
net_log_.AddEvent(NetLog::TYPE_SSL_WRITE_ERROR,
make_scoped_refptr(new SSLErrorParams(rv, 0)));
return rv;
}
bool network_moved;
int rv;
do {
rv = DoPayloadWrite();
network_moved = DoTransportIO();
} while (rv == ERR_IO_PENDING && network_moved);
LeaveFunction("");
return rv;
}
bool SSLClientSocketNSS::LoadSSLHostInfo() {
const SSLHostInfo::State& state(ssl_host_info_->state());
if (state.certs.empty())
return true;
SECStatus rv;
const std::vector<std::string>& certs_in = state.certs;
scoped_array<CERTCertificate*> certs(new CERTCertificate*[certs_in.size()]);
for (size_t i = 0; i < certs_in.size(); i++) {
SECItem derCert;
derCert.data =
const_cast<uint8*>(reinterpret_cast<const uint8*>(certs_in[i].data()));
derCert.len = certs_in[i].size();
certs[i] = CERT_NewTempCertificate(
CERT_GetDefaultCertDB(), &derCert, NULL /* no nickname given */,
PR_FALSE /* not permanent */, PR_TRUE /* copy DER data */);
if (!certs[i]) {
DestroyCertificates(&certs[0], i);
NOTREACHED();
return false;
}
}
rv = SSL_SetPredictedPeerCertificates(nss_fd_, certs.get(), certs_in.size());
DestroyCertificates(&certs[0], certs_in.size());
DCHECK_EQ(SECSuccess, rv);
return true;
}
int SSLClientSocketNSS::DoLoadSSLHostInfo() {
EnterFunction("");
int rv = ssl_host_info_->WaitForDataReady(&handshake_io_callback_);
GotoState(STATE_HANDSHAKE);
if (rv == OK) {
if (!LoadSSLHostInfo())
LOG(WARNING) << "LoadSSLHostInfo failed: " << host_and_port_.ToString();
} else {
DCHECK_EQ(ERR_IO_PENDING, rv);
GotoState(STATE_LOAD_SSL_HOST_INFO);
}
LeaveFunction("");
return rv;
}
int SSLClientSocketNSS::DoHandshake() {
EnterFunction("");
int net_error = net::OK;
SECStatus rv = SSL_ForceHandshake(nss_fd_);
// TODO(rkn): Handle the case in which origin-bound cert generation takes
// too long and the server has closed the connection. Report some new error
// code so that the higher level code will attempt to delete the socket and
// redo the handshake.
if (client_auth_cert_needed_) {
if (ob_cert_xtn_negotiated_) {
GotoState(STATE_GET_OB_CERT_COMPLETE);
net_error = ERR_IO_PENDING;
} else {
net_error = ERR_SSL_CLIENT_AUTH_CERT_NEEDED;
net_log_.AddEvent(NetLog::TYPE_SSL_HANDSHAKE_ERROR,
make_scoped_refptr(new SSLErrorParams(net_error, 0)));
// If the handshake already succeeded (because the server requests but
// doesn't require a client cert), we need to invalidate the SSL session
// so that we won't try to resume the non-client-authenticated session in
// the next handshake. This will cause the server to ask for a client
// cert again.
if (rv == SECSuccess && SSL_InvalidateSession(nss_fd_) != SECSuccess) {
LOG(WARNING) << "Couldn't invalidate SSL session: " << PR_GetError();
}
}
} else if (rv == SECSuccess) {
if (handshake_callback_called_) {
if (eset_mitm_detected_) {
net_error = ERR_ESET_ANTI_VIRUS_SSL_INTERCEPTION;
} else if (kaspersky_mitm_detected_) {
net_error = ERR_KASPERSKY_ANTI_VIRUS_SSL_INTERCEPTION;
} else {
// We need to see if the predicted certificate chain (in
// |ssl_host_info_->state().certs) matches the actual certificate chain
// before we call SaveSSLHostInfo, as that will update
// |ssl_host_info_|.
if (ssl_host_info_.get() && !ssl_host_info_->state().certs.empty()) {
PeerCertificateChain certs(nss_fd_);
const SSLHostInfo::State& state = ssl_host_info_->state();
predicted_cert_chain_correct_ = certs.size() == state.certs.size();
if (predicted_cert_chain_correct_) {
for (unsigned i = 0; i < certs.size(); i++) {
if (certs[i]->derCert.len != state.certs[i].size() ||
memcmp(certs[i]->derCert.data, state.certs[i].data(),
certs[i]->derCert.len) != 0) {
predicted_cert_chain_correct_ = false;
break;
}
}
}
}
#if defined(SSL_ENABLE_OCSP_STAPLING)
// TODO(agl): figure out how to plumb an OCSP response into the Mac
// system library and update IsOCSPStaplingSupported for Mac.
if (!predicted_cert_chain_correct_ && IsOCSPStaplingSupported()) {
unsigned int len = 0;
SSL_GetStapledOCSPResponse(nss_fd_, NULL, &len);
if (len) {
const unsigned int orig_len = len;
scoped_array<uint8> ocsp_response(new uint8[orig_len]);
SSL_GetStapledOCSPResponse(nss_fd_, ocsp_response.get(), &len);
DCHECK_EQ(orig_len, len);
#if defined(OS_WIN)
CRYPT_DATA_BLOB ocsp_response_blob;
ocsp_response_blob.cbData = len;
ocsp_response_blob.pbData = ocsp_response.get();
BOOL ok = CertSetCertificateContextProperty(
server_cert_->os_cert_handle(),
CERT_OCSP_RESPONSE_PROP_ID,
CERT_SET_PROPERTY_IGNORE_PERSIST_ERROR_FLAG,
&ocsp_response_blob);
if (!ok) {
VLOG(1) << "Failed to set OCSP response property: "
<< GetLastError();
}
#elif defined(USE_NSS)
CacheOCSPResponseFromSideChannelFunction cache_ocsp_response =
GetCacheOCSPResponseFromSideChannelFunction();
SECItem ocsp_response_item;
ocsp_response_item.type = siBuffer;
ocsp_response_item.data = ocsp_response.get();
ocsp_response_item.len = len;
cache_ocsp_response(
CERT_GetDefaultCertDB(), server_cert_nss_, PR_Now(),
&ocsp_response_item, NULL);
#endif
}
}
#endif
SaveSSLHostInfo();
// SSL handshake is completed. Let's verify the certificate.
GotoState(STATE_VERIFY_DNSSEC);
}
// Done!
} else {
// Workaround for https://bugzilla.mozilla.org/show_bug.cgi?id=562434 -
// SSL_ForceHandshake returned SECSuccess prematurely.
rv = SECFailure;
net_error = ERR_SSL_PROTOCOL_ERROR;
net_log_.AddEvent(NetLog::TYPE_SSL_HANDSHAKE_ERROR,
make_scoped_refptr(new SSLErrorParams(net_error, 0)));
}
} else {
PRErrorCode prerr = PR_GetError();
net_error = HandleNSSError(prerr, true);
// If not done, stay in this state
if (net_error == ERR_IO_PENDING) {
GotoState(STATE_HANDSHAKE);
} else {
LOG(ERROR) << "handshake with server " << host_and_port_.ToString()
<< " failed; NSS error code " << prerr
<< ", net_error " << net_error;
net_log_.AddEvent(
NetLog::TYPE_SSL_HANDSHAKE_ERROR,
make_scoped_refptr(new SSLErrorParams(net_error, prerr)));
}
}
LeaveFunction("");
return net_error;
}
#if defined(NSS_PLATFORM_CLIENT_AUTH)
int SSLClientSocketNSS::ImportOBCertAndKey(CERTCertificate** cert,
SECKEYPrivateKey** key) {
NOTREACHED();
return ERR_NOT_IMPLEMENTED;
}
#else
int SSLClientSocketNSS::ImportOBCertAndKey(CERTCertificate** cert,
SECKEYPrivateKey** key) {
// Set the certificate.
SECItem cert_item;
cert_item.data = (unsigned char*) ob_cert_.data();
cert_item.len = ob_cert_.size();
*cert = CERT_NewTempCertificate(CERT_GetDefaultCertDB(),
&cert_item,
NULL,
PR_FALSE,
PR_TRUE);
if (*cert == NULL)
return MapNSSError(PORT_GetError());
// Set the private key.
SECItem der_private_key_info;
der_private_key_info.data = (unsigned char*)ob_private_key_.data();
der_private_key_info.len = ob_private_key_.size();
const unsigned int key_usage = KU_DIGITAL_SIGNATURE;
crypto::ScopedPK11Slot slot(PK11_GetInternalSlot());
SECStatus rv = PK11_ImportDERPrivateKeyInfoAndReturnKey(
slot.get(), &der_private_key_info, NULL, NULL, PR_FALSE, PR_FALSE,
key_usage, key, NULL);
if (rv != SECSuccess) {
int error = MapNSSError(PORT_GetError());
CERT_DestroyCertificate(*cert);
*cert = NULL;
return error;
}
return OK;
}
#endif
#if defined(NSS_PLATFORM_CLIENT_AUTH)
int SSLClientSocketNSS::DoGetOBCertComplete(int result) {
NOTREACHED();
return ERR_NOT_IMPLEMENTED;
}
#else
int SSLClientSocketNSS::DoGetOBCertComplete(int result) {
ob_cert_request_handle_ = NULL;
if (result != OK)
return result;
CERTCertificate* cert;
SECKEYPrivateKey* key;
int error = ImportOBCertAndKey(&cert, &key);
if (error != OK)
return error;
CERTCertificateList* cert_chain = CERT_CertChainFromCert(cert,
certUsageSSLClient,
PR_FALSE);
SECStatus rv;
rv = SSL_RestartHandshakeAfterCertReq(nss_fd_, cert, key, cert_chain);
if (rv != SECSuccess)
return MapNSSError(PORT_GetError());
GotoState(STATE_HANDSHAKE);
return OK;
}
#endif
int SSLClientSocketNSS::DoVerifyDNSSEC(int result) {
if (ssl_config_.dns_cert_provenance_checking_enabled &&
dns_cert_checker_) {
PeerCertificateChain certs(nss_fd_);
dns_cert_checker_->DoAsyncVerification(
host_and_port_.host(), certs.AsStringPieceVector());
}
DNSValidationResult r = CheckDNSSECChain(host_and_port_.host(),
server_cert_nss_,
host_and_port_.port());
if (r == DNSVR_SUCCESS) {
local_server_cert_verify_result_.cert_status |= CERT_STATUS_IS_DNSSEC;
local_server_cert_verify_result_.verified_cert = server_cert_;
server_cert_verify_result_ = &local_server_cert_verify_result_;
GotoState(STATE_VERIFY_CERT_COMPLETE);
return OK;
}
GotoState(STATE_VERIFY_CERT);
return OK;
}
int SSLClientSocketNSS::DoVerifyCert(int result) {
DCHECK(server_cert_nss_);
GotoState(STATE_VERIFY_CERT_COMPLETE);
// If the certificate is expected to be bad we can use the
// expectation as the cert status. Don't use |server_cert_| here
// because it can be set to NULL in case we failed to create
// X509Certificate in UpdateServerCert(). This may happen when this
// code is used inside sandbox.
base::StringPiece der_cert(
reinterpret_cast<char*>(server_cert_nss_->derCert.data),
server_cert_nss_->derCert.len);
int cert_status;
if (ssl_config_.IsAllowedBadCert(der_cert, &cert_status)) {
DCHECK(start_cert_verification_time_.is_null());
VLOG(1) << "Received an expected bad cert with status: " << cert_status;
server_cert_verify_result_ = &local_server_cert_verify_result_;
local_server_cert_verify_result_.Reset();
local_server_cert_verify_result_.cert_status = cert_status;
local_server_cert_verify_result_.verified_cert = server_cert_;
return OK;
}
// We may have failed to create X509Certificate object if we are
// running inside sandbox.
if (!server_cert_) {
server_cert_verify_result_ = &local_server_cert_verify_result_;
local_server_cert_verify_result_.Reset();
local_server_cert_verify_result_.cert_status = CERT_STATUS_INVALID;
return ERR_CERT_INVALID;
}
start_cert_verification_time_ = base::TimeTicks::Now();
if (ssl_host_info_.get() && !ssl_host_info_->state().certs.empty() &&
predicted_cert_chain_correct_) {
// If the SSLHostInfo had a prediction for the certificate chain of this
// server then it will have optimistically started a verification of that
// chain. So, if the prediction was correct, we should wait for that
// verification to finish rather than start our own.
net_log_.AddEvent(NetLog::TYPE_SSL_VERIFICATION_MERGED, NULL);
UMA_HISTOGRAM_ENUMERATION("Net.SSLVerificationMerged", 1 /* true */, 2);
base::TimeTicks end_time = ssl_host_info_->verification_end_time();
if (end_time.is_null())
end_time = base::TimeTicks::Now();
UMA_HISTOGRAM_TIMES("Net.SSLVerificationMergedMsSaved",
end_time - ssl_host_info_->verification_start_time());
server_cert_verify_result_ = &ssl_host_info_->cert_verify_result();
return ssl_host_info_->WaitForCertVerification(&handshake_io_callback_);
} else {
UMA_HISTOGRAM_ENUMERATION("Net.SSLVerificationMerged", 0 /* false */, 2);
}
int flags = 0;
if (ssl_config_.rev_checking_enabled)
flags |= X509Certificate::VERIFY_REV_CHECKING_ENABLED;
if (ssl_config_.verify_ev_cert)
flags |= X509Certificate::VERIFY_EV_CERT;
verifier_.reset(new SingleRequestCertVerifier(cert_verifier_));
server_cert_verify_result_ = &local_server_cert_verify_result_;
return verifier_->Verify(server_cert_, host_and_port_.host(), flags,
&local_server_cert_verify_result_,
&handshake_io_callback_);
}
// Derived from AuthCertificateCallback() in
// mozilla/source/security/manager/ssl/src/nsNSSCallbacks.cpp.
int SSLClientSocketNSS::DoVerifyCertComplete(int result) {
verifier_.reset();
if (!start_cert_verification_time_.is_null()) {
base::TimeDelta verify_time =
base::TimeTicks::Now() - start_cert_verification_time_;
if (result == OK)
UMA_HISTOGRAM_TIMES("Net.SSLCertVerificationTime", verify_time);
else
UMA_HISTOGRAM_TIMES("Net.SSLCertVerificationTimeError", verify_time);
}
PeerCertificateChain chain(nss_fd_);
for (unsigned i = 1; i < chain.size(); i++) {
if (strcmp(chain[i]->subjectName, "CN=meta") != 0)
continue;
base::StringPiece leaf_der(
reinterpret_cast<char*>(server_cert_nss_->derCert.data),
server_cert_nss_->derCert.len);
base::StringPiece leaf_spki;
if (!asn1::ExtractSPKIFromDERCert(leaf_der, &leaf_spki))
break;
static SECOidTag side_data_tag;
static bool side_data_tag_valid;
if (!side_data_tag_valid) {
// It's harmless if multiple threads enter this block concurrently.
static const uint8 kSideDataOID[] =
// 1.3.6.1.4.1.11129.2.1.4
// (iso.org.dod.internet.private.enterprises.google.googleSecurity.
// certificateExtensions.sideData)
{0x2b, 0x06, 0x01, 0x04, 0x01, 0xd6, 0x79, 0x02, 0x01, 0x05};
SECOidData oid_data;
memset(&oid_data, 0, sizeof(oid_data));
oid_data.oid.data = const_cast<uint8*>(kSideDataOID);
oid_data.oid.len = sizeof(kSideDataOID);
oid_data.desc = "Certificate side data";
oid_data.supportedExtension = SUPPORTED_CERT_EXTENSION;
side_data_tag = SECOID_AddEntry(&oid_data);
DCHECK_NE(SEC_OID_UNKNOWN, side_data_tag);
side_data_tag_valid = true;
}
SECItem side_data_item;
SECStatus rv = CERT_FindCertExtension(chain[i],
side_data_tag, &side_data_item);
if (rv != SECSuccess)
continue;
base::StringPiece side_data(
reinterpret_cast<char*>(side_data_item.data),
side_data_item.len);
if (!TransportSecurityState::ParseSidePin(
leaf_spki, side_data, &side_pinned_public_keys_)) {
LOG(WARNING) << "Side pinning data failed to parse: "
<< host_and_port_.host();
}
break;
}
// We used to remember the intermediate CA certs in the NSS database
// persistently. However, NSS opens a connection to the SQLite database
// during NSS initialization and doesn't close the connection until NSS
// shuts down. If the file system where the database resides is gone,
// the database connection goes bad. What's worse, the connection won't
// recover when the file system comes back. Until this NSS or SQLite bug
// is fixed, we need to avoid using the NSS database for non-essential
// purposes. See https://bugzilla.mozilla.org/show_bug.cgi?id=508081 and
// http://crbug.com/15630 for more info.
// TODO(hclam): Skip logging if server cert was expected to be bad because
// |server_cert_verify_results_| doesn't contain all the information about
// the cert.
if (result == OK)
LogConnectionTypeMetrics();
completed_handshake_ = true;
if (user_read_callback_) {
int rv = DoReadLoop(OK);
if (rv != ERR_IO_PENDING)
DoReadCallback(rv);
}
// Exit DoHandshakeLoop and return the result to the caller to Connect.
DCHECK(next_handshake_state_ == STATE_NONE);
return result;
}
int SSLClientSocketNSS::DoPayloadRead() {
EnterFunction(user_read_buf_len_);
DCHECK(user_read_buf_);
DCHECK_GT(user_read_buf_len_, 0);
int rv = PR_Read(nss_fd_, user_read_buf_->data(), user_read_buf_len_);
if (client_auth_cert_needed_) {
// We don't need to invalidate the non-client-authenticated SSL session
// because the server will renegotiate anyway.
LeaveFunction("");
rv = ERR_SSL_CLIENT_AUTH_CERT_NEEDED;
net_log_.AddEvent(NetLog::TYPE_SSL_READ_ERROR,
make_scoped_refptr(new SSLErrorParams(rv, 0)));
return rv;
}
if (rv >= 0) {
net_log_.AddByteTransferEvent(NetLog::TYPE_SSL_SOCKET_BYTES_RECEIVED, rv,
user_read_buf_->data());
LeaveFunction("");
return rv;
}
PRErrorCode prerr = PR_GetError();
if (prerr == PR_WOULD_BLOCK_ERROR) {
LeaveFunction("");
return ERR_IO_PENDING;
}
LeaveFunction("");
rv = HandleNSSError(prerr, false);
net_log_.AddEvent(NetLog::TYPE_SSL_READ_ERROR,
make_scoped_refptr(new SSLErrorParams(rv, prerr)));
return rv;
}
int SSLClientSocketNSS::DoPayloadWrite() {
EnterFunction(user_write_buf_len_);
DCHECK(user_write_buf_);
int rv = PR_Write(nss_fd_, user_write_buf_->data(), user_write_buf_len_);
if (rv >= 0) {
net_log_.AddByteTransferEvent(NetLog::TYPE_SSL_SOCKET_BYTES_SENT, rv,
user_write_buf_->data());
LeaveFunction("");
return rv;
}
PRErrorCode prerr = PR_GetError();
if (prerr == PR_WOULD_BLOCK_ERROR) {
LeaveFunction("");
return ERR_IO_PENDING;
}
LeaveFunction("");
rv = HandleNSSError(prerr, false);
net_log_.AddEvent(NetLog::TYPE_SSL_WRITE_ERROR,
make_scoped_refptr(new SSLErrorParams(rv, prerr)));
return rv;
}
void SSLClientSocketNSS::LogConnectionTypeMetrics() const {
UpdateConnectionTypeHistograms(CONNECTION_SSL);
if (server_cert_verify_result_->has_md5)
UpdateConnectionTypeHistograms(CONNECTION_SSL_MD5);
if (server_cert_verify_result_->has_md2)
UpdateConnectionTypeHistograms(CONNECTION_SSL_MD2);
if (server_cert_verify_result_->has_md4)
UpdateConnectionTypeHistograms(CONNECTION_SSL_MD4);
if (server_cert_verify_result_->has_md5_ca)
UpdateConnectionTypeHistograms(CONNECTION_SSL_MD5_CA);
if (server_cert_verify_result_->has_md2_ca)
UpdateConnectionTypeHistograms(CONNECTION_SSL_MD2_CA);
int ssl_version = SSLConnectionStatusToVersion(ssl_connection_status_);
switch (ssl_version) {
case SSL_CONNECTION_VERSION_SSL2:
UpdateConnectionTypeHistograms(CONNECTION_SSL_SSL2);
break;
case SSL_CONNECTION_VERSION_SSL3:
UpdateConnectionTypeHistograms(CONNECTION_SSL_SSL3);
break;
case SSL_CONNECTION_VERSION_TLS1:
UpdateConnectionTypeHistograms(CONNECTION_SSL_TLS1);
break;
case SSL_CONNECTION_VERSION_TLS1_1:
UpdateConnectionTypeHistograms(CONNECTION_SSL_TLS1_1);
break;
case SSL_CONNECTION_VERSION_TLS1_2:
UpdateConnectionTypeHistograms(CONNECTION_SSL_TLS1_2);
break;
};
}
// SaveSSLHostInfo saves the certificate chain of the connection so that we can
// start verification faster in the future.
void SSLClientSocketNSS::SaveSSLHostInfo() {
if (!ssl_host_info_.get())
return;
// If the SSLHostInfo hasn't managed to load from disk yet then we can't save
// anything.
if (ssl_host_info_->WaitForDataReady(NULL) != OK)
return;
SSLHostInfo::State* state = ssl_host_info_->mutable_state();
state->certs.clear();
PeerCertificateChain certs(nss_fd_);
for (unsigned i = 0; i < certs.size(); i++) {
if (certs[i]->derCert.len > std::numeric_limits<uint16>::max())
return;
state->certs.push_back(std::string(
reinterpret_cast<char*>(certs[i]->derCert.data),
certs[i]->derCert.len));
}
ssl_host_info_->Persist();
}
void SSLClientSocketNSS::UncorkAfterTimeout() {
corked_ = false;
int nsent;
do {
nsent = BufferSend();
} while (nsent > 0);
}
// Do as much network I/O as possible between the buffer and the
// transport socket. Return true if some I/O performed, false
// otherwise (error or ERR_IO_PENDING).
bool SSLClientSocketNSS::DoTransportIO() {
EnterFunction("");
bool network_moved = false;
if (nss_bufs_ != NULL) {
int rv;
// Read and write as much data as we can. The loop is neccessary
// because Write() may return synchronously.
do {
rv = BufferSend();
if (rv > 0)
network_moved = true;
} while (rv > 0);
if (BufferRecv() >= 0)
network_moved = true;
}
LeaveFunction(network_moved);
return network_moved;
}
// Return 0 for EOF,
// > 0 for bytes transferred immediately,
// < 0 for error (or the non-error ERR_IO_PENDING).
int SSLClientSocketNSS::BufferSend(void) {
if (transport_send_busy_)
return ERR_IO_PENDING;
EnterFunction("");
const char* buf1;
const char* buf2;
unsigned int len1, len2;
memio_GetWriteParams(nss_bufs_, &buf1, &len1, &buf2, &len2);
const unsigned int len = len1 + len2;
if (corked_ && len < kRecvBufferSize / 2)
return 0;
int rv = 0;
if (len) {
scoped_refptr<IOBuffer> send_buffer(new IOBuffer(len));
memcpy(send_buffer->data(), buf1, len1);
memcpy(send_buffer->data() + len1, buf2, len2);
rv = transport_->socket()->Write(send_buffer, len,
&buffer_send_callback_);
if (rv == ERR_IO_PENDING) {
transport_send_busy_ = true;
} else {
memio_PutWriteResult(nss_bufs_, MapErrorToNSS(rv));
}
}
LeaveFunction(rv);
return rv;
}
void SSLClientSocketNSS::BufferSendComplete(int result) {
EnterFunction(result);
memio_PutWriteResult(nss_bufs_, MapErrorToNSS(result));
transport_send_busy_ = false;
OnSendComplete(result);
LeaveFunction("");
}
int SSLClientSocketNSS::BufferRecv(void) {
if (transport_recv_busy_) return ERR_IO_PENDING;
char *buf;
int nb = memio_GetReadParams(nss_bufs_, &buf);
EnterFunction(nb);
int rv;
if (!nb) {
// buffer too full to read into, so no I/O possible at moment
rv = ERR_IO_PENDING;
} else {
recv_buffer_ = new IOBuffer(nb);
rv = transport_->socket()->Read(recv_buffer_, nb, &buffer_recv_callback_);
if (rv == ERR_IO_PENDING) {
transport_recv_busy_ = true;
} else {
if (rv > 0)
memcpy(buf, recv_buffer_->data(), rv);
memio_PutReadResult(nss_bufs_, MapErrorToNSS(rv));
recv_buffer_ = NULL;
}
}
LeaveFunction(rv);
return rv;
}
void SSLClientSocketNSS::BufferRecvComplete(int result) {
EnterFunction(result);
if (result > 0) {
char *buf;
memio_GetReadParams(nss_bufs_, &buf);
memcpy(buf, recv_buffer_->data(), result);
}
recv_buffer_ = NULL;
memio_PutReadResult(nss_bufs_, MapErrorToNSS(result));
transport_recv_busy_ = false;
OnRecvComplete(result);
LeaveFunction("");
}
int SSLClientSocketNSS::HandleNSSError(PRErrorCode nss_error,
bool handshake_error) {
int net_error = handshake_error ? MapNSSHandshakeError(nss_error) :
MapNSSError(nss_error);
#if defined(OS_WIN)
// On Windows, a handle to the HCRYPTPROV is cached in the X509Certificate
// os_cert_handle() as an optimization. However, if the certificate
// private key is stored on a smart card, and the smart card is removed,
// the cached HCRYPTPROV will not be able to obtain the HCRYPTKEY again,
// preventing client certificate authentication. Because the
// X509Certificate may outlive the individual SSLClientSocketNSS, due to
// caching in X509Certificate, this failure ends up preventing client
// certificate authentication with the same certificate for all future
// attempts, even after the smart card has been re-inserted. By setting
// the CERT_KEY_PROV_HANDLE_PROP_ID to NULL, the cached HCRYPTPROV will
// typically be freed. This allows a new HCRYPTPROV to be obtained from
// the certificate on the next attempt, which should succeed if the smart
// card has been re-inserted, or will typically prompt the user to
// re-insert the smart card if not.
if ((net_error == ERR_SSL_CLIENT_AUTH_CERT_NO_PRIVATE_KEY ||
net_error == ERR_SSL_CLIENT_AUTH_SIGNATURE_FAILED) &&
ssl_config_.send_client_cert && ssl_config_.client_cert) {
CertSetCertificateContextProperty(
ssl_config_.client_cert->os_cert_handle(),
CERT_KEY_PROV_HANDLE_PROP_ID, 0, NULL);
}
#endif
return net_error;
}
// static
// NSS calls this if an incoming certificate needs to be verified.
// Do nothing but return SECSuccess.
// This is called only in full handshake mode.
// Peer certificate is retrieved in HandshakeCallback() later, which is called
// in full handshake mode or in resumption handshake mode.
SECStatus SSLClientSocketNSS::OwnAuthCertHandler(void* arg,
PRFileDesc* socket,
PRBool checksig,
PRBool is_server) {
#ifdef SSL_ENABLE_FALSE_START
// In the event that we are False Starting this connection, we wish to send
// out the Finished message and first application data record in the same
// packet. This prevents non-determinism when talking to False Start
// intolerant servers which, otherwise, might see the two messages in
// different reads or not, depending on network conditions.
PRBool false_start = 0;
SECStatus rv = SSL_OptionGet(socket, SSL_ENABLE_FALSE_START, &false_start);
DCHECK_EQ(SECSuccess, rv);
SSLClientSocketNSS* that = reinterpret_cast<SSLClientSocketNSS*>(arg);
CERTCertificate* cert = SSL_PeerCertificate(that->nss_fd_);
if (cert) {
char* common_name = CERT_GetCommonName(&cert->issuer);
if (common_name) {
if (false_start && strcmp(common_name, "ESET_RootSslCert") == 0)
// ESET anti-virus is capable of intercepting HTTPS connections on
// Windows. However, it is False Start intolerant and causes the
// connections to hang forever. We detect ESET by the issuer of the
// leaf certificate and set a flag to return a specific error, giving
// the user instructions for reconfiguring ESET.
that->eset_mitm_detected_ = true;
if (strcmp(common_name,
"Kaspersky Anti-Virus personal root certificate") == 0) {
// Kaspersky has an unknown intolerance to our HTTPS handshakes and so
// we detect and give a more helpful error message.
that->kaspersky_mitm_detected_ = true;
}
if (false_start &&
strcmp(common_name, "ContentWatch Root Certificate Authority") == 0) {
// This is NetNanny. NetNanny are updating their product so we
// silently disable False Start for now.
rv = SSL_OptionSet(socket, SSL_ENABLE_FALSE_START, PR_FALSE);
DCHECK_EQ(SECSuccess, rv);
false_start = 0;
}
PORT_Free(common_name);
}
CERT_DestroyCertificate(cert);
}
if (false_start && !that->handshake_callback_called_) {
that->corked_ = true;
that->uncork_timer_.Start(FROM_HERE,
base::TimeDelta::FromMilliseconds(kCorkTimeoutMs),
that, &SSLClientSocketNSS::UncorkAfterTimeout);
}
#endif
// Tell NSS to not verify the certificate.
return SECSuccess;
}
#if defined(NSS_PLATFORM_CLIENT_AUTH)
// static
// NSS calls this if a client certificate is needed.
SECStatus SSLClientSocketNSS::PlatformClientAuthHandler(
void* arg,
PRFileDesc* socket,
CERTDistNames* ca_names,
CERTCertList** result_certs,
void** result_private_key) {
SSLClientSocketNSS* that = reinterpret_cast<SSLClientSocketNSS*>(arg);
that->client_auth_cert_needed_ = !that->ssl_config_.send_client_cert;
#if defined(OS_WIN)
if (that->ssl_config_.send_client_cert) {
if (that->ssl_config_.client_cert) {
PCCERT_CONTEXT cert_context =
that->ssl_config_.client_cert->os_cert_handle();
PCERT_KEY_CONTEXT key_context = reinterpret_cast<PCERT_KEY_CONTEXT>(
PORT_ZAlloc(sizeof(CERT_KEY_CONTEXT)));
if (!key_context)
return SECFailure;
key_context->cbSize = sizeof(*key_context);
BOOL must_free = FALSE;
BOOL acquired_key = CryptAcquireCertificatePrivateKey(
cert_context, CRYPT_ACQUIRE_CACHE_FLAG, NULL,
&key_context->hCryptProv, &key_context->dwKeySpec, &must_free);
if (acquired_key && key_context->hCryptProv) {
DCHECK_NE(key_context->dwKeySpec, CERT_NCRYPT_KEY_SPEC);
// The certificate cache may have been updated/used, in which case,
// duplicate the existing handle, since NSS will free it when no
// longer in use.
if (!must_free)
CryptContextAddRef(key_context->hCryptProv, NULL, 0);
SECItem der_cert;
der_cert.type = siDERCertBuffer;
der_cert.data = cert_context->pbCertEncoded;
der_cert.len = cert_context->cbCertEncoded;
// TODO(rsleevi): Error checking for NSS allocation errors.
*result_certs = CERT_NewCertList();
CERTCertDBHandle* db_handle = CERT_GetDefaultCertDB();
CERTCertificate* user_cert = CERT_NewTempCertificate(
db_handle, &der_cert, NULL, PR_FALSE, PR_TRUE);
CERT_AddCertToListTail(*result_certs, user_cert);
// Add the intermediates.
X509Certificate::OSCertHandles intermediates =
that->ssl_config_.client_cert->GetIntermediateCertificates();
for (X509Certificate::OSCertHandles::const_iterator it =
intermediates.begin(); it != intermediates.end(); ++it) {
der_cert.data = (*it)->pbCertEncoded;
der_cert.len = (*it)->cbCertEncoded;
CERTCertificate* intermediate = CERT_NewTempCertificate(
db_handle, &der_cert, NULL, PR_FALSE, PR_TRUE);
CERT_AddCertToListTail(*result_certs, intermediate);
}
*result_private_key = key_context;
return SECSuccess;
}
PORT_Free(key_context);
LOG(WARNING) << "Client cert found without private key";
}
// Send no client certificate.
return SECFailure;
}
that->client_certs_.clear();
std::vector<CERT_NAME_BLOB> issuer_list(ca_names->nnames);
for (int i = 0; i < ca_names->nnames; ++i) {
issuer_list[i].cbData = ca_names->names[i].len;
issuer_list[i].pbData = ca_names->names[i].data;
}
// Client certificates of the user are in the "MY" system certificate store.
HCERTSTORE my_cert_store = CertOpenSystemStore(NULL, L"MY");
if (!my_cert_store) {
LOG(ERROR) << "Could not open the \"MY\" system certificate store: "
<< GetLastError();
return SECFailure;
}
// Enumerate the client certificates.
CERT_CHAIN_FIND_BY_ISSUER_PARA find_by_issuer_para;
memset(&find_by_issuer_para, 0, sizeof(find_by_issuer_para));
find_by_issuer_para.cbSize = sizeof(find_by_issuer_para);
find_by_issuer_para.pszUsageIdentifier = szOID_PKIX_KP_CLIENT_AUTH;
find_by_issuer_para.cIssuer = ca_names->nnames;
find_by_issuer_para.rgIssuer = ca_names->nnames ? &issuer_list[0] : NULL;
find_by_issuer_para.pfnFindCallback = ClientCertFindCallback;
PCCERT_CHAIN_CONTEXT chain_context = NULL;
for (;;) {
// Find a certificate chain.
chain_context = CertFindChainInStore(my_cert_store,
X509_ASN_ENCODING,
0,
CERT_CHAIN_FIND_BY_ISSUER,
&find_by_issuer_para,
chain_context);
if (!chain_context) {
DWORD err = GetLastError();
if (err != CRYPT_E_NOT_FOUND)
DLOG(ERROR) << "CertFindChainInStore failed: " << err;
break;
}
// Get the leaf certificate.
PCCERT_CONTEXT cert_context =
chain_context->rgpChain[0]->rgpElement[0]->pCertContext;
// Copy it to our own certificate store, so that we can close the "MY"
// certificate store before returning from this function.
PCCERT_CONTEXT cert_context2;
BOOL ok = CertAddCertificateContextToStore(X509Certificate::cert_store(),
cert_context,
CERT_STORE_ADD_USE_EXISTING,
&cert_context2);
if (!ok) {
NOTREACHED();
continue;
}
// Copy the rest of the chain to our own store as well. Copying the chain
// stops gracefully if an error is encountered, with the partial chain
// being used as the intermediates, rather than failing to consider the
// client certificate.
net::X509Certificate::OSCertHandles intermediates;
for (DWORD i = 1; i < chain_context->rgpChain[0]->cElement; i++) {
PCCERT_CONTEXT intermediate_copy;
ok = CertAddCertificateContextToStore(X509Certificate::cert_store(),
chain_context->rgpChain[0]->rgpElement[i]->pCertContext,
CERT_STORE_ADD_USE_EXISTING, &intermediate_copy);
if (!ok) {
NOTREACHED();
break;
}
intermediates.push_back(intermediate_copy);
}
scoped_refptr<X509Certificate> cert = X509Certificate::CreateFromHandle(
cert_context2, intermediates);
that->client_certs_.push_back(cert);
X509Certificate::FreeOSCertHandle(cert_context2);
for (net::X509Certificate::OSCertHandles::iterator it =
intermediates.begin(); it != intermediates.end(); ++it) {
net::X509Certificate::FreeOSCertHandle(*it);
}
}
BOOL ok = CertCloseStore(my_cert_store, CERT_CLOSE_STORE_CHECK_FLAG);
DCHECK(ok);
// Tell NSS to suspend the client authentication. We will then abort the
// handshake by returning ERR_SSL_CLIENT_AUTH_CERT_NEEDED.
return SECWouldBlock;
#elif defined(OS_MACOSX)
if (that->ssl_config_.send_client_cert) {
if (that->ssl_config_.client_cert) {
OSStatus os_error = noErr;
SecIdentityRef identity = NULL;
SecKeyRef private_key = NULL;
CFArrayRef chain =
that->ssl_config_.client_cert->CreateClientCertificateChain();
if (chain) {
identity = reinterpret_cast<SecIdentityRef>(
const_cast<void*>(CFArrayGetValueAtIndex(chain, 0)));
}
if (identity)
os_error = SecIdentityCopyPrivateKey(identity, &private_key);
if (chain && identity && os_error == noErr) {
// TODO(rsleevi): Error checking for NSS allocation errors.
*result_certs = CERT_NewCertList();
*result_private_key = private_key;
for (CFIndex i = 0; i < CFArrayGetCount(chain); ++i) {
CSSM_DATA cert_data;
SecCertificateRef cert_ref;
if (i == 0) {
cert_ref = that->ssl_config_.client_cert->os_cert_handle();
} else {
cert_ref = reinterpret_cast<SecCertificateRef>(
const_cast<void*>(CFArrayGetValueAtIndex(chain, i)));
}
os_error = SecCertificateGetData(cert_ref, &cert_data);
if (os_error != noErr)
break;
SECItem der_cert;
der_cert.type = siDERCertBuffer;
der_cert.data = cert_data.Data;
der_cert.len = cert_data.Length;
CERTCertificate* nss_cert = CERT_NewTempCertificate(
CERT_GetDefaultCertDB(), &der_cert, NULL, PR_FALSE, PR_TRUE);
CERT_AddCertToListTail(*result_certs, nss_cert);
}
}
if (os_error == noErr) {
CFRelease(chain);
return SECSuccess;
}
LOG(WARNING) << "Client cert found, but could not be used: "
<< os_error;
if (*result_certs) {
CERT_DestroyCertList(*result_certs);
*result_certs = NULL;
}
if (*result_private_key)
*result_private_key = NULL;
if (private_key)
CFRelease(private_key);
if (chain)
CFRelease(chain);
}
// Send no client certificate.
return SECFailure;
}
that->client_certs_.clear();
// First, get the cert issuer names allowed by the server.
std::vector<CertPrincipal> valid_issuers;
int n = ca_names->nnames;
for (int i = 0; i < n; i++) {
// Parse each name into a CertPrincipal object.
CertPrincipal p;
if (p.ParseDistinguishedName(ca_names->names[i].data,
ca_names->names[i].len)) {
valid_issuers.push_back(p);
}
}
// Now get the available client certs whose issuers are allowed by the server.
X509Certificate::GetSSLClientCertificates(that->host_and_port_.host(),
valid_issuers,
&that->client_certs_);
// Tell NSS to suspend the client authentication. We will then abort the
// handshake by returning ERR_SSL_CLIENT_AUTH_CERT_NEEDED.
return SECWouldBlock;
#else
return SECFailure;
#endif
}
#else // NSS_PLATFORM_CLIENT_AUTH
// static
// NSS calls this if a client certificate is needed.
// Based on Mozilla's NSS_GetClientAuthData.
SECStatus SSLClientSocketNSS::ClientAuthHandler(
void* arg,
PRFileDesc* socket,
CERTDistNames* ca_names,
CERTCertificate** result_certificate,
SECKEYPrivateKey** result_private_key) {
SSLClientSocketNSS* that = reinterpret_cast<SSLClientSocketNSS*>(arg);
// Check if an origin-bound certificate is requested.
PRBool xtn_negotiated = PR_FALSE;
SECStatus rv = SSL_HandshakeNegotiatedExtension(
socket, ssl_ob_cert_xtn, &xtn_negotiated);
DCHECK_EQ(SECSuccess, rv);
that->ob_cert_xtn_negotiated_ = xtn_negotiated ? true : false;
if (that->ob_cert_xtn_negotiated_) {
// We have negotiated the origin-bound certificate extension.
std::string origin = "https://" + that->host_and_port_.ToString();
int error = that->origin_bound_cert_service_->GetOriginBoundCert(
origin,
&that->ob_private_key_,
&that->ob_cert_,
&that->handshake_io_callback_,
&that->ob_cert_request_handle_);
if (error == OK) {
// Synchronous success.
int result = that->ImportOBCertAndKey(result_certificate,
result_private_key);
if (result != OK)
return SECFailure;
return SECSuccess;
}
if (error == ERR_IO_PENDING) {
// Asynchronous case
that->client_auth_cert_needed_ = true;
return SECWouldBlock;
}
return SECFailure; // Synchronous failure.
}
// Regular client certificate requested.
that->client_auth_cert_needed_ = !that->ssl_config_.send_client_cert;
void* wincx = SSL_RevealPinArg(socket);
// Second pass: a client certificate should have been selected.
if (that->ssl_config_.send_client_cert) {
if (that->ssl_config_.client_cert) {
CERTCertificate* cert = CERT_DupCertificate(
that->ssl_config_.client_cert->os_cert_handle());
SECKEYPrivateKey* privkey = PK11_FindKeyByAnyCert(cert, wincx);
if (privkey) {
// TODO(jsorianopastor): We should wait for server certificate
// verification before sending our credentials. See
// http://crbug.com/13934.
*result_certificate = cert;
*result_private_key = privkey;
return SECSuccess;
}
LOG(WARNING) << "Client cert found without private key";
}
// Send no client certificate.
return SECFailure;
}
// Iterate over all client certificates.
CERTCertList* client_certs = CERT_FindUserCertsByUsage(
CERT_GetDefaultCertDB(), certUsageSSLClient,
PR_FALSE, PR_FALSE, wincx);
if (client_certs) {
for (CERTCertListNode* node = CERT_LIST_HEAD(client_certs);
!CERT_LIST_END(node, client_certs);
node = CERT_LIST_NEXT(node)) {
// Only offer unexpired certificates.
if (CERT_CheckCertValidTimes(node->cert, PR_Now(), PR_TRUE) !=
secCertTimeValid)
continue;
// Filter by issuer.
//
// TODO(davidben): This does a binary comparison of the DER-encoded
// issuers. We should match according to RFC 5280 sec. 7.1. We should find
// an appropriate NSS function or add one if needbe.
if (ca_names->nnames &&
NSS_CmpCertChainWCANames(node->cert, ca_names) != SECSuccess)
continue;
X509Certificate* x509_cert = X509Certificate::CreateFromHandle(
node->cert, net::X509Certificate::OSCertHandles());
that->client_certs_.push_back(x509_cert);
}
CERT_DestroyCertList(client_certs);
}
// Tell NSS to suspend the client authentication. We will then abort the
// handshake by returning ERR_SSL_CLIENT_AUTH_CERT_NEEDED.
return SECWouldBlock;
}
#endif // NSS_PLATFORM_CLIENT_AUTH
// static
// NSS calls this when handshake is completed.
// After the SSL handshake is finished, use CertVerifier to verify
// the saved server certificate.
void SSLClientSocketNSS::HandshakeCallback(PRFileDesc* socket,
void* arg) {
SSLClientSocketNSS* that = reinterpret_cast<SSLClientSocketNSS*>(arg);
that->handshake_callback_called_ = true;
that->UpdateServerCert();
that->UpdateConnectionStatus();
}
void SSLClientSocketNSS::EnsureThreadIdAssigned() const {
base::AutoLock auto_lock(lock_);
if (valid_thread_id_ != base::kInvalidThreadId)
return;
valid_thread_id_ = base::PlatformThread::CurrentId();
}
bool SSLClientSocketNSS::CalledOnValidThread() const {
EnsureThreadIdAssigned();
base::AutoLock auto_lock(lock_);
return valid_thread_id_ == base::PlatformThread::CurrentId();
}
} // namespace net