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mojo / mojo-tools / 2c1caa548c4aa27e5e99209f19c3e7002284adcf / . / net / quic / crypto / quic_crypto_client_config.cc
blob: 268c8ee0f25f0d6d9a28274d3aecf402233bb2cd [file] [log] [blame]
// Copyright 2013 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.
#include "net/quic/crypto/quic_crypto_client_config.h"
#include "base/metrics/histogram.h"
#include "base/metrics/sparse_histogram.h"
#include "base/stl_util.h"
#include "base/strings/string_util.h"
#include "net/quic/crypto/cert_compressor.h"
#include "net/quic/crypto/chacha20_poly1305_encrypter.h"
#include "net/quic/crypto/channel_id.h"
#include "net/quic/crypto/common_cert_set.h"
#include "net/quic/crypto/crypto_framer.h"
#include "net/quic/crypto/crypto_utils.h"
#include "net/quic/crypto/curve25519_key_exchange.h"
#include "net/quic/crypto/key_exchange.h"
#include "net/quic/crypto/p256_key_exchange.h"
#include "net/quic/crypto/proof_verifier.h"
#include "net/quic/crypto/quic_encrypter.h"
#include "net/quic/quic_utils.h"
using base::StringPiece;
using std::find;
using std::make_pair;
using std::map;
using std::string;
using std::vector;
namespace net {
namespace {
// Tracks the reason (the state of the server config) for sending inchoate
// ClientHello to the server.
void RecordInchoateClientHelloReason(
QuicCryptoClientConfig::CachedState::ServerConfigState state) {
UMA_HISTOGRAM_ENUMERATION(
"Net.QuicInchoateClientHelloReason", state,
QuicCryptoClientConfig::CachedState::SERVER_CONFIG_COUNT);
}
// Tracks the state of the QUIC server information loaded from the disk cache.
void RecordDiskCacheServerConfigState(
QuicCryptoClientConfig::CachedState::ServerConfigState state) {
UMA_HISTOGRAM_ENUMERATION(
"Net.QuicServerInfo.DiskCacheState", state,
QuicCryptoClientConfig::CachedState::SERVER_CONFIG_COUNT);
}
} // namespace
QuicCryptoClientConfig::QuicCryptoClientConfig()
: disable_ecdsa_(false) {
SetDefaults();
}
QuicCryptoClientConfig::~QuicCryptoClientConfig() {
STLDeleteValues(&cached_states_);
}
QuicCryptoClientConfig::CachedState::CachedState()
: server_config_valid_(false),
generation_counter_(0) {}
QuicCryptoClientConfig::CachedState::~CachedState() {}
bool QuicCryptoClientConfig::CachedState::IsComplete(QuicWallTime now) const {
if (server_config_.empty()) {
RecordInchoateClientHelloReason(SERVER_CONFIG_EMPTY);
return false;
}
if (!server_config_valid_) {
RecordInchoateClientHelloReason(SERVER_CONFIG_INVALID);
return false;
}
const CryptoHandshakeMessage* scfg = GetServerConfig();
if (!scfg) {
// Should be impossible short of cache corruption.
DCHECK(false);
RecordInchoateClientHelloReason(SERVER_CONFIG_CORRUPTED);
return false;
}
uint64 expiry_seconds;
if (scfg->GetUint64(kEXPY, &expiry_seconds) != QUIC_NO_ERROR) {
RecordInchoateClientHelloReason(SERVER_CONFIG_INVALID_EXPIRY);
return false;
}
if (now.ToUNIXSeconds() >= expiry_seconds) {
UMA_HISTOGRAM_CUSTOM_TIMES(
"Net.QuicClientHelloServerConfig.InvalidDuration",
base::TimeDelta::FromSeconds(now.ToUNIXSeconds() - expiry_seconds),
base::TimeDelta::FromMinutes(1), base::TimeDelta::FromDays(20), 50);
RecordInchoateClientHelloReason(SERVER_CONFIG_EXPIRED);
return false;
}
return true;
}
bool QuicCryptoClientConfig::CachedState::IsEmpty() const {
return server_config_.empty();
}
const CryptoHandshakeMessage*
QuicCryptoClientConfig::CachedState::GetServerConfig() const {
if (server_config_.empty()) {
return nullptr;
}
if (!scfg_.get()) {
scfg_.reset(CryptoFramer::ParseMessage(server_config_));
DCHECK(scfg_.get());
}
return scfg_.get();
}
QuicCryptoClientConfig::CachedState::ServerConfigState
QuicCryptoClientConfig::CachedState::SetServerConfig(
StringPiece server_config, QuicWallTime now, string* error_details) {
const bool matches_existing = server_config == server_config_;
// Even if the new server config matches the existing one, we still wish to
// reject it if it has expired.
scoped_ptr<CryptoHandshakeMessage> new_scfg_storage;
const CryptoHandshakeMessage* new_scfg;
if (!matches_existing) {
new_scfg_storage.reset(CryptoFramer::ParseMessage(server_config));
new_scfg = new_scfg_storage.get();
} else {
new_scfg = GetServerConfig();
}
if (!new_scfg) {
*error_details = "SCFG invalid";
return SERVER_CONFIG_INVALID;
}
uint64 expiry_seconds;
if (new_scfg->GetUint64(kEXPY, &expiry_seconds) != QUIC_NO_ERROR) {
*error_details = "SCFG missing EXPY";
return SERVER_CONFIG_INVALID_EXPIRY;
}
if (now.ToUNIXSeconds() >= expiry_seconds) {
*error_details = "SCFG has expired";
return SERVER_CONFIG_EXPIRED;
}
if (!matches_existing) {
server_config_ = server_config.as_string();
SetProofInvalid();
scfg_.reset(new_scfg_storage.release());
}
return SERVER_CONFIG_VALID;
}
void QuicCryptoClientConfig::CachedState::InvalidateServerConfig() {
server_config_.clear();
scfg_.reset();
SetProofInvalid();
}
void QuicCryptoClientConfig::CachedState::SetProof(const vector<string>& certs,
StringPiece signature) {
bool has_changed =
signature != server_config_sig_ || certs_.size() != certs.size();
if (!has_changed) {
for (size_t i = 0; i < certs_.size(); i++) {
if (certs_[i] != certs[i]) {
has_changed = true;
break;
}
}
}
if (!has_changed) {
return;
}
// If the proof has changed then it needs to be revalidated.
SetProofInvalid();
certs_ = certs;
server_config_sig_ = signature.as_string();
}
void QuicCryptoClientConfig::CachedState::Clear() {
server_config_.clear();
source_address_token_.clear();
certs_.clear();
server_config_sig_.clear();
server_config_valid_ = false;
proof_verify_details_.reset();
scfg_.reset();
++generation_counter_;
}
void QuicCryptoClientConfig::CachedState::ClearProof() {
SetProofInvalid();
certs_.clear();
server_config_sig_.clear();
}
void QuicCryptoClientConfig::CachedState::SetProofValid() {
server_config_valid_ = true;
}
void QuicCryptoClientConfig::CachedState::SetProofInvalid() {
server_config_valid_ = false;
++generation_counter_;
}
bool QuicCryptoClientConfig::CachedState::Initialize(
StringPiece server_config,
StringPiece source_address_token,
const vector<string>& certs,
StringPiece signature,
QuicWallTime now) {
DCHECK(server_config_.empty());
if (server_config.empty()) {
RecordDiskCacheServerConfigState(SERVER_CONFIG_EMPTY);
return false;
}
string error_details;
ServerConfigState state = SetServerConfig(server_config, now,
&error_details);
RecordDiskCacheServerConfigState(state);
if (state != SERVER_CONFIG_VALID) {
DVLOG(1) << "SetServerConfig failed with " << error_details;
return false;
}
signature.CopyToString(&server_config_sig_);
source_address_token.CopyToString(&source_address_token_);
certs_ = certs;
return true;
}
const string& QuicCryptoClientConfig::CachedState::server_config() const {
return server_config_;
}
const string&
QuicCryptoClientConfig::CachedState::source_address_token() const {
return source_address_token_;
}
const vector<string>& QuicCryptoClientConfig::CachedState::certs() const {
return certs_;
}
const string& QuicCryptoClientConfig::CachedState::signature() const {
return server_config_sig_;
}
bool QuicCryptoClientConfig::CachedState::proof_valid() const {
return server_config_valid_;
}
uint64 QuicCryptoClientConfig::CachedState::generation_counter() const {
return generation_counter_;
}
const ProofVerifyDetails*
QuicCryptoClientConfig::CachedState::proof_verify_details() const {
return proof_verify_details_.get();
}
void QuicCryptoClientConfig::CachedState::set_source_address_token(
StringPiece token) {
source_address_token_ = token.as_string();
}
void QuicCryptoClientConfig::CachedState::SetProofVerifyDetails(
ProofVerifyDetails* details) {
proof_verify_details_.reset(details);
}
void QuicCryptoClientConfig::CachedState::InitializeFrom(
const QuicCryptoClientConfig::CachedState& other) {
DCHECK(server_config_.empty());
DCHECK(!server_config_valid_);
server_config_ = other.server_config_;
source_address_token_ = other.source_address_token_;
certs_ = other.certs_;
server_config_sig_ = other.server_config_sig_;
server_config_valid_ = other.server_config_valid_;
if (other.proof_verify_details_.get() != nullptr) {
proof_verify_details_.reset(other.proof_verify_details_->Clone());
}
++generation_counter_;
}
void QuicCryptoClientConfig::SetDefaults() {
// Key exchange methods.
kexs.resize(2);
kexs[0] = kC255;
kexs[1] = kP256;
// Authenticated encryption algorithms. Prefer ChaCha20 by default.
aead.clear();
if (ChaCha20Poly1305Encrypter::IsSupported()) {
aead.push_back(kCC12);
}
aead.push_back(kAESG);
disable_ecdsa_ = false;
}
QuicCryptoClientConfig::CachedState* QuicCryptoClientConfig::LookupOrCreate(
const QuicServerId& server_id) {
CachedStateMap::const_iterator it = cached_states_.find(server_id);
if (it != cached_states_.end()) {
return it->second;
}
CachedState* cached = new CachedState;
cached_states_.insert(make_pair(server_id, cached));
bool cache_populated = PopulateFromCanonicalConfig(server_id, cached);
UMA_HISTOGRAM_BOOLEAN(
"Net.QuicCryptoClientConfig.PopulatedFromCanonicalConfig",
cache_populated);
return cached;
}
void QuicCryptoClientConfig::ClearCachedStates() {
for (CachedStateMap::const_iterator it = cached_states_.begin();
it != cached_states_.end(); ++it) {
it->second->Clear();
}
}
void QuicCryptoClientConfig::FillInchoateClientHello(
const QuicServerId& server_id,
const QuicVersion preferred_version,
const CachedState* cached,
QuicCryptoNegotiatedParameters* out_params,
CryptoHandshakeMessage* out) const {
out->set_tag(kCHLO);
out->set_minimum_size(kClientHelloMinimumSize);
// Server name indication. We only send SNI if it's a valid domain name, as
// per the spec.
if (CryptoUtils::IsValidSNI(server_id.host())) {
out->SetStringPiece(kSNI, server_id.host());
}
out->SetValue(kVER, QuicVersionToQuicTag(preferred_version));
if (!user_agent_id_.empty()) {
out->SetStringPiece(kUAID, user_agent_id_);
}
if (!cached->source_address_token().empty()) {
out->SetStringPiece(kSourceAddressTokenTag, cached->source_address_token());
}
if (server_id.is_https()) {
if (disable_ecdsa_) {
out->SetTaglist(kPDMD, kX59R, 0);
} else {
out->SetTaglist(kPDMD, kX509, 0);
}
}
if (common_cert_sets) {
out->SetStringPiece(kCCS, common_cert_sets->GetCommonHashes());
}
const vector<string>& certs = cached->certs();
// We save |certs| in the QuicCryptoNegotiatedParameters so that, if the
// client config is being used for multiple connections, another connection
// doesn't update the cached certificates and cause us to be unable to
// process the server's compressed certificate chain.
out_params->cached_certs = certs;
if (!certs.empty()) {
vector<uint64> hashes;
hashes.reserve(certs.size());
for (vector<string>::const_iterator i = certs.begin();
i != certs.end(); ++i) {
hashes.push_back(QuicUtils::FNV1a_64_Hash(i->data(), i->size()));
}
out->SetVector(kCCRT, hashes);
}
}
QuicErrorCode QuicCryptoClientConfig::FillClientHello(
const QuicServerId& server_id,
QuicConnectionId connection_id,
const QuicVersion preferred_version,
const CachedState* cached,
QuicWallTime now,
QuicRandom* rand,
const ChannelIDKey* channel_id_key,
QuicCryptoNegotiatedParameters* out_params,
CryptoHandshakeMessage* out,
string* error_details) const {
DCHECK(error_details != nullptr);
FillInchoateClientHello(server_id, preferred_version, cached,
out_params, out);
const CryptoHandshakeMessage* scfg = cached->GetServerConfig();
if (!scfg) {
// This should never happen as our caller should have checked
// cached->IsComplete() before calling this function.
*error_details = "Handshake not ready";
return QUIC_CRYPTO_INTERNAL_ERROR;
}
StringPiece scid;
if (!scfg->GetStringPiece(kSCID, &scid)) {
*error_details = "SCFG missing SCID";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
out->SetStringPiece(kSCID, scid);
const QuicTag* their_aeads;
const QuicTag* their_key_exchanges;
size_t num_their_aeads, num_their_key_exchanges;
if (scfg->GetTaglist(kAEAD, &their_aeads,
&num_their_aeads) != QUIC_NO_ERROR ||
scfg->GetTaglist(kKEXS, &their_key_exchanges,
&num_their_key_exchanges) != QUIC_NO_ERROR) {
*error_details = "Missing AEAD or KEXS";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
// AEAD: the work loads on the client and server are symmetric. Since the
// client is more likely to be CPU-constrained, break the tie by favoring
// the client's preference.
// Key exchange: the client does more work than the server, so favor the
// client's preference.
size_t key_exchange_index;
if (!QuicUtils::FindMutualTag(
aead, their_aeads, num_their_aeads, QuicUtils::LOCAL_PRIORITY,
&out_params->aead, nullptr) ||
!QuicUtils::FindMutualTag(
kexs, their_key_exchanges, num_their_key_exchanges,
QuicUtils::LOCAL_PRIORITY, &out_params->key_exchange,
&key_exchange_index)) {
*error_details = "Unsupported AEAD or KEXS";
return QUIC_CRYPTO_NO_SUPPORT;
}
out->SetTaglist(kAEAD, out_params->aead, 0);
out->SetTaglist(kKEXS, out_params->key_exchange, 0);
StringPiece public_value;
if (scfg->GetNthValue24(kPUBS, key_exchange_index, &public_value) !=
QUIC_NO_ERROR) {
*error_details = "Missing public value";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
StringPiece orbit;
if (!scfg->GetStringPiece(kORBT, &orbit) || orbit.size() != kOrbitSize) {
*error_details = "SCFG missing OBIT";
return QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
}
CryptoUtils::GenerateNonce(now, rand, orbit, &out_params->client_nonce);
out->SetStringPiece(kNONC, out_params->client_nonce);
if (!out_params->server_nonce.empty()) {
out->SetStringPiece(kServerNonceTag, out_params->server_nonce);
}
switch (out_params->key_exchange) {
case kC255:
out_params->client_key_exchange.reset(Curve25519KeyExchange::New(
Curve25519KeyExchange::NewPrivateKey(rand)));
break;
case kP256:
out_params->client_key_exchange.reset(P256KeyExchange::New(
P256KeyExchange::NewPrivateKey()));
break;
default:
DCHECK(false);
*error_details = "Configured to support an unknown key exchange";
return QUIC_CRYPTO_INTERNAL_ERROR;
}
if (!out_params->client_key_exchange->CalculateSharedKey(
public_value, &out_params->initial_premaster_secret)) {
*error_details = "Key exchange failure";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
out->SetStringPiece(kPUBS, out_params->client_key_exchange->public_value());
if (channel_id_key) {
// In order to calculate the encryption key for the CETV block we need to
// serialise the client hello as it currently is (i.e. without the CETV
// block). For this, the client hello is serialized without padding.
const size_t orig_min_size = out->minimum_size();
out->set_minimum_size(0);
CryptoHandshakeMessage cetv;
cetv.set_tag(kCETV);
string hkdf_input;
const QuicData& client_hello_serialized = out->GetSerialized();
hkdf_input.append(QuicCryptoConfig::kCETVLabel,
strlen(QuicCryptoConfig::kCETVLabel) + 1);
hkdf_input.append(reinterpret_cast<char*>(&connection_id),
sizeof(connection_id));
hkdf_input.append(client_hello_serialized.data(),
client_hello_serialized.length());
hkdf_input.append(cached->server_config());
string key = channel_id_key->SerializeKey();
string signature;
if (!channel_id_key->Sign(hkdf_input, &signature)) {
*error_details = "Channel ID signature failed";
return QUIC_INVALID_CHANNEL_ID_SIGNATURE;
}
cetv.SetStringPiece(kCIDK, key);
cetv.SetStringPiece(kCIDS, signature);
CrypterPair crypters;
if (!CryptoUtils::DeriveKeys(out_params->initial_premaster_secret,
out_params->aead, out_params->client_nonce,
out_params->server_nonce, hkdf_input,
CryptoUtils::CLIENT, &crypters,
nullptr /* subkey secret */)) {
*error_details = "Symmetric key setup failed";
return QUIC_CRYPTO_SYMMETRIC_KEY_SETUP_FAILED;
}
const QuicData& cetv_plaintext = cetv.GetSerialized();
scoped_ptr<QuicData> cetv_ciphertext(crypters.encrypter->EncryptPacket(
0 /* sequence number */,
StringPiece() /* associated data */,
cetv_plaintext.AsStringPiece()));
if (!cetv_ciphertext.get()) {
*error_details = "Packet encryption failed";
return QUIC_ENCRYPTION_FAILURE;
}
out->SetStringPiece(kCETV, cetv_ciphertext->AsStringPiece());
out->MarkDirty();
out->set_minimum_size(orig_min_size);
}
// Derive the symmetric keys and set up the encrypters and decrypters.
// Set the following members of out_params:
// out_params->hkdf_input_suffix
// out_params->initial_crypters
out_params->hkdf_input_suffix.clear();
out_params->hkdf_input_suffix.append(reinterpret_cast<char*>(&connection_id),
sizeof(connection_id));
const QuicData& client_hello_serialized = out->GetSerialized();
out_params->hkdf_input_suffix.append(client_hello_serialized.data(),
client_hello_serialized.length());
out_params->hkdf_input_suffix.append(cached->server_config());
string hkdf_input;
const size_t label_len = strlen(QuicCryptoConfig::kInitialLabel) + 1;
hkdf_input.reserve(label_len + out_params->hkdf_input_suffix.size());
hkdf_input.append(QuicCryptoConfig::kInitialLabel, label_len);
hkdf_input.append(out_params->hkdf_input_suffix);
if (!CryptoUtils::DeriveKeys(
out_params->initial_premaster_secret, out_params->aead,
out_params->client_nonce, out_params->server_nonce, hkdf_input,
CryptoUtils::CLIENT, &out_params->initial_crypters,
nullptr /* subkey secret */)) {
*error_details = "Symmetric key setup failed";
return QUIC_CRYPTO_SYMMETRIC_KEY_SETUP_FAILED;
}
return QUIC_NO_ERROR;
}
QuicErrorCode QuicCryptoClientConfig::CacheNewServerConfig(
const CryptoHandshakeMessage& message,
QuicWallTime now,
const vector<string>& cached_certs,
CachedState* cached,
string* error_details) {
DCHECK(error_details != nullptr);
StringPiece scfg;
if (!message.GetStringPiece(kSCFG, &scfg)) {
*error_details = "Missing SCFG";
return QUIC_CRYPTO_MESSAGE_PARAMETER_NOT_FOUND;
}
CachedState::ServerConfigState state = cached->SetServerConfig(
scfg, now, error_details);
if (state == CachedState::SERVER_CONFIG_EXPIRED) {
return QUIC_CRYPTO_SERVER_CONFIG_EXPIRED;
}
// TODO(rtenneti): Return more specific error code than returning
// QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER.
if (state != CachedState::SERVER_CONFIG_VALID) {
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
StringPiece token;
if (message.GetStringPiece(kSourceAddressTokenTag, &token)) {
cached->set_source_address_token(token);
}
StringPiece proof, cert_bytes;
bool has_proof = message.GetStringPiece(kPROF, &proof);
bool has_cert = message.GetStringPiece(kCertificateTag, &cert_bytes);
if (has_proof && has_cert) {
vector<string> certs;
if (!CertCompressor::DecompressChain(cert_bytes, cached_certs,
common_cert_sets, &certs)) {
*error_details = "Certificate data invalid";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
cached->SetProof(certs, proof);
} else {
if (proof_verifier() != nullptr) {
// Secure QUIC: clear existing proof as we have been sent a new SCFG
// without matching proof/certs.
cached->ClearProof();
}
if (has_proof && !has_cert) {
*error_details = "Certificate missing";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
if (!has_proof && has_cert) {
*error_details = "Proof missing";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
}
return QUIC_NO_ERROR;
}
QuicErrorCode QuicCryptoClientConfig::ProcessRejection(
const CryptoHandshakeMessage& rej,
QuicWallTime now,
CachedState* cached,
bool is_https,
QuicCryptoNegotiatedParameters* out_params,
string* error_details) {
DCHECK(error_details != nullptr);
if (rej.tag() != kREJ) {
*error_details = "Message is not REJ";
return QUIC_CRYPTO_INTERNAL_ERROR;
}
QuicErrorCode error = CacheNewServerConfig(rej, now, out_params->cached_certs,
cached, error_details);
if (error != QUIC_NO_ERROR) {
return error;
}
StringPiece nonce;
if (rej.GetStringPiece(kServerNonceTag, &nonce)) {
out_params->server_nonce = nonce.as_string();
}
const uint32* reject_reasons;
size_t num_reject_reasons;
COMPILE_ASSERT(sizeof(QuicTag) == sizeof(uint32), header_out_of_sync);
if (rej.GetTaglist(kRREJ, &reject_reasons,
&num_reject_reasons) == QUIC_NO_ERROR) {
uint32 packed_error = 0;
for (size_t i = 0; i < num_reject_reasons; ++i) {
// HANDSHAKE_OK is 0 and don't report that as error.
if (reject_reasons[i] == HANDSHAKE_OK || reject_reasons[i] >= 32) {
continue;
}
HandshakeFailureReason reason =
static_cast<HandshakeFailureReason>(reject_reasons[i]);
packed_error |= 1 << (reason - 1);
}
DVLOG(1) << "Reasons for rejection: " << packed_error;
if (is_https) {
UMA_HISTOGRAM_SPARSE_SLOWLY("Net.QuicClientHelloRejectReasons.Secure",
packed_error);
} else {
UMA_HISTOGRAM_SPARSE_SLOWLY("Net.QuicClientHelloRejectReasons.Insecure",
packed_error);
}
}
return QUIC_NO_ERROR;
}
QuicErrorCode QuicCryptoClientConfig::ProcessServerHello(
const CryptoHandshakeMessage& server_hello,
QuicConnectionId connection_id,
const QuicVersionVector& negotiated_versions,
CachedState* cached,
QuicCryptoNegotiatedParameters* out_params,
string* error_details) {
DCHECK(error_details != nullptr);
if (server_hello.tag() != kSHLO) {
*error_details = "Bad tag";
return QUIC_INVALID_CRYPTO_MESSAGE_TYPE;
}
const QuicTag* supported_version_tags;
size_t num_supported_versions;
if (server_hello.GetTaglist(kVER, &supported_version_tags,
&num_supported_versions) != QUIC_NO_ERROR) {
*error_details = "server hello missing version list";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
if (!negotiated_versions.empty()) {
bool mismatch = num_supported_versions != negotiated_versions.size();
for (size_t i = 0; i < num_supported_versions && !mismatch; ++i) {
mismatch = QuicTagToQuicVersion(supported_version_tags[i]) !=
negotiated_versions[i];
}
// The server sent a list of supported versions, and the connection
// reports that there was a version negotiation during the handshake.
// Ensure that these two lists are identical.
if (mismatch) {
*error_details = "Downgrade attack detected";
return QUIC_VERSION_NEGOTIATION_MISMATCH;
}
}
// Learn about updated source address tokens.
StringPiece token;
if (server_hello.GetStringPiece(kSourceAddressTokenTag, &token)) {
cached->set_source_address_token(token);
}
// TODO(agl):
// learn about updated SCFGs.
StringPiece public_value;
if (!server_hello.GetStringPiece(kPUBS, &public_value)) {
*error_details = "server hello missing forward secure public value";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
if (!out_params->client_key_exchange->CalculateSharedKey(
public_value, &out_params->forward_secure_premaster_secret)) {
*error_details = "Key exchange failure";
return QUIC_INVALID_CRYPTO_MESSAGE_PARAMETER;
}
string hkdf_input;
const size_t label_len = strlen(QuicCryptoConfig::kForwardSecureLabel) + 1;
hkdf_input.reserve(label_len + out_params->hkdf_input_suffix.size());
hkdf_input.append(QuicCryptoConfig::kForwardSecureLabel, label_len);
hkdf_input.append(out_params->hkdf_input_suffix);
if (!CryptoUtils::DeriveKeys(
out_params->forward_secure_premaster_secret, out_params->aead,
out_params->client_nonce, out_params->server_nonce, hkdf_input,
CryptoUtils::CLIENT, &out_params->forward_secure_crypters,
&out_params->subkey_secret)) {
*error_details = "Symmetric key setup failed";
return QUIC_CRYPTO_SYMMETRIC_KEY_SETUP_FAILED;
}
return QUIC_NO_ERROR;
}
QuicErrorCode QuicCryptoClientConfig::ProcessServerConfigUpdate(
const CryptoHandshakeMessage& server_config_update,
QuicWallTime now,
CachedState* cached,
QuicCryptoNegotiatedParameters* out_params,
string* error_details) {
DCHECK(error_details != nullptr);
if (server_config_update.tag() != kSCUP) {
*error_details = "ServerConfigUpdate must have kSCUP tag.";
return QUIC_INVALID_CRYPTO_MESSAGE_TYPE;
}
return CacheNewServerConfig(server_config_update, now,
out_params->cached_certs, cached, error_details);
}
ProofVerifier* QuicCryptoClientConfig::proof_verifier() const {
return proof_verifier_.get();
}
void QuicCryptoClientConfig::SetProofVerifier(ProofVerifier* verifier) {
proof_verifier_.reset(verifier);
}
ChannelIDSource* QuicCryptoClientConfig::channel_id_source() const {
return channel_id_source_.get();
}
void QuicCryptoClientConfig::SetChannelIDSource(ChannelIDSource* source) {
channel_id_source_.reset(source);
}
void QuicCryptoClientConfig::InitializeFrom(
const QuicServerId& server_id,
const QuicServerId& canonical_server_id,
QuicCryptoClientConfig* canonical_crypto_config) {
CachedState* canonical_cached =
canonical_crypto_config->LookupOrCreate(canonical_server_id);
if (!canonical_cached->proof_valid()) {
return;
}
CachedState* cached = LookupOrCreate(server_id);
cached->InitializeFrom(*canonical_cached);
}
void QuicCryptoClientConfig::AddCanonicalSuffix(const string& suffix) {
canonical_suffixes_.push_back(suffix);
}
void QuicCryptoClientConfig::PreferAesGcm() {
DCHECK(!aead.empty());
if (aead.size() <= 1) {
return;
}
QuicTagVector::iterator pos = find(aead.begin(), aead.end(), kAESG);
if (pos != aead.end()) {
aead.erase(pos);
aead.insert(aead.begin(), kAESG);
}
}
void QuicCryptoClientConfig::DisableEcdsa() {
disable_ecdsa_ = true;
}
bool QuicCryptoClientConfig::PopulateFromCanonicalConfig(
const QuicServerId& server_id,
CachedState* server_state) {
DCHECK(server_state->IsEmpty());
size_t i = 0;
for (; i < canonical_suffixes_.size(); ++i) {
if (EndsWith(server_id.host(), canonical_suffixes_[i], false)) {
break;
}
}
if (i == canonical_suffixes_.size()) {
return false;
}
QuicServerId suffix_server_id(canonical_suffixes_[i], server_id.port(),
server_id.is_https(),
server_id.privacy_mode());
if (!ContainsKey(canonical_server_map_, suffix_server_id)) {
// This is the first host we've seen which matches the suffix, so make it
// canonical.
canonical_server_map_[suffix_server_id] = server_id;
return false;
}
const QuicServerId& canonical_server_id =
canonical_server_map_[suffix_server_id];
CachedState* canonical_state = cached_states_[canonical_server_id];
if (!canonical_state->proof_valid()) {
return false;
}
// Update canonical version to point at the "most recent" entry.
canonical_server_map_[suffix_server_id] = server_id;
server_state->InitializeFrom(*canonical_state);
return true;
}
} // namespace net