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cobalt / cobalt / edf9f4e573e100a6e6c9631fa7b3eef33f67490a / . / src / net / dns / dns_transaction_unittest.cc
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// Copyright (c) 2012 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/dns/dns_transaction.h"
#include <limits>
#include <utility>
#include <vector>
#include "base/base64url.h"
#include "base/bind.h"
#include "base/containers/circular_deque.h"
#include "base/macros.h"
#include "base/message_loop/message_loop.h"
#include "base/rand_util.h"
#include "base/run_loop.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/sys_byteorder.h"
#include "base/test/metrics/histogram_tester.h"
#include "base/time/time.h"
#include "base/values.h"
#include "net/base/ip_address.h"
#include "net/base/port_util.h"
#ifdef STARBOARD
#include "net/base/upload_data_stream.h"
#endif
#include "net/base/upload_bytes_element_reader.h"
#include "net/base/url_util.h"
#include "net/dns/dns_config.h"
#include "net/dns/dns_protocol.h"
#include "net/dns/dns_query.h"
#include "net/dns/dns_response.h"
#include "net/dns/dns_session.h"
#include "net/dns/dns_test_util.h"
#include "net/dns/dns_util.h"
#include "net/log/net_log.h"
#include "net/log/net_log_capture_mode.h"
#include "net/log/net_log_with_source.h"
#include "net/proxy_resolution/proxy_config_service_fixed.h"
#include "net/socket/socket_test_util.h"
#include "net/test/gtest_util.h"
#include "net/test/test_with_scoped_task_environment.h"
#include "net/test/url_request/url_request_failed_job.h"
#include "net/third_party/uri_template/uri_template.h"
#include "net/url_request/url_request_filter.h"
#include "net/url_request/url_request_interceptor.h"
#include "net/url_request/url_request_test_util.h"
#include "starboard/memory.h"
#include "starboard/types.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
using net::test::IsOk;
namespace net {
namespace {
base::TimeDelta kTimeout = base::TimeDelta::FromSeconds(1);
const char kMockHostname[] = "mock.http";
std::string DomainFromDot(const base::StringPiece& dotted) {
std::string out;
EXPECT_TRUE(DNSDomainFromDot(dotted, &out));
return out;
}
enum class Transport { UDP, TCP, HTTPS };
// A SocketDataProvider builder.
class DnsSocketData {
public:
// The ctor takes parameters for the DnsQuery.
DnsSocketData(uint16_t id,
const char* dotted_name,
uint16_t qtype,
IoMode mode,
Transport transport,
const OptRecordRdata* opt_rdata = nullptr)
: query_(new DnsQuery(id, DomainFromDot(dotted_name), qtype, opt_rdata)),
transport_(transport) {
if (Transport::TCP == transport_) {
std::unique_ptr<uint16_t> length(new uint16_t);
*length = base::HostToNet16(query_->io_buffer()->size());
writes_.push_back(MockWrite(mode,
reinterpret_cast<const char*>(length.get()),
sizeof(uint16_t), num_reads_and_writes()));
lengths_.push_back(std::move(length));
}
writes_.push_back(MockWrite(mode, query_->io_buffer()->data(),
query_->io_buffer()->size(),
num_reads_and_writes()));
}
~DnsSocketData() = default;
// All responses must be added before GetProvider.
// Adds pre-built DnsResponse. |tcp_length| will be used in TCP mode only.
void AddResponseWithLength(std::unique_ptr<DnsResponse> response,
IoMode mode,
uint16_t tcp_length) {
CHECK(!provider_.get());
if (Transport::TCP == transport_) {
std::unique_ptr<uint16_t> length(new uint16_t);
*length = base::HostToNet16(tcp_length);
reads_.push_back(MockRead(mode,
reinterpret_cast<const char*>(length.get()),
sizeof(uint16_t), num_reads_and_writes()));
lengths_.push_back(std::move(length));
}
reads_.push_back(MockRead(mode, response->io_buffer()->data(),
response->io_buffer_size(),
num_reads_and_writes()));
responses_.push_back(std::move(response));
}
// Adds pre-built DnsResponse.
void AddResponse(std::unique_ptr<DnsResponse> response, IoMode mode) {
uint16_t tcp_length = response->io_buffer_size();
AddResponseWithLength(std::move(response), mode, tcp_length);
}
// Adds pre-built response from |data| buffer.
void AddResponseData(const uint8_t* data, size_t length, IoMode mode) {
CHECK(!provider_.get());
AddResponse(std::make_unique<DnsResponse>(
reinterpret_cast<const char*>(data), length, 0),
mode);
}
// Adds pre-built response from |data| buffer.
void AddResponseData(const uint8_t* data,
size_t length,
int offset,
IoMode mode) {
CHECK(!provider_.get());
AddResponse(
std::make_unique<DnsResponse>(reinterpret_cast<const char*>(data),
length - offset, offset),
mode);
}
// Add no-answer (RCODE only) response matching the query.
void AddRcode(int rcode, IoMode mode) {
std::unique_ptr<DnsResponse> response(new DnsResponse(
query_->io_buffer()->data(), query_->io_buffer()->size(), 0));
dns_protocol::Header* header =
reinterpret_cast<dns_protocol::Header*>(response->io_buffer()->data());
header->flags |= base::HostToNet16(dns_protocol::kFlagResponse | rcode);
AddResponse(std::move(response), mode);
}
// Add error response.
void AddReadError(int error, IoMode mode) {
reads_.push_back(MockRead(mode, error, num_reads_and_writes()));
}
// Build, if needed, and return the SocketDataProvider. No new responses
// should be added afterwards.
SequencedSocketData* GetProvider() {
if (provider_.get())
return provider_.get();
// Terminate the reads with ERR_IO_PENDING to prevent overrun and default to
// timeout.
if (transport_ != Transport::HTTPS) {
reads_.push_back(MockRead(SYNCHRONOUS, ERR_IO_PENDING,
writes_.size() + reads_.size()));
}
#ifdef STARBOARD
provider_.reset(new SequencedSocketData(
base::span<MockRead>(reads_.data(), reads_.size()),
base::span<MockWrite>(writes_.data(), writes_.size())));
#else
provider_.reset(new SequencedSocketData(reads_, writes_));
#endif
if (Transport::TCP == transport_ || Transport::HTTPS == transport_) {
provider_->set_connect_data(MockConnect(reads_[0].mode, OK));
}
return provider_.get();
}
uint16_t query_id() const { return query_->id(); }
IOBufferWithSize* query_buffer() { return query_->io_buffer(); }
private:
size_t num_reads_and_writes() const { return reads_.size() + writes_.size(); }
std::unique_ptr<DnsQuery> query_;
Transport transport_;
std::vector<std::unique_ptr<uint16_t>> lengths_;
std::vector<std::unique_ptr<DnsResponse>> responses_;
std::vector<MockWrite> writes_;
std::vector<MockRead> reads_;
std::unique_ptr<SequencedSocketData> provider_;
DISALLOW_COPY_AND_ASSIGN(DnsSocketData);
};
class TestSocketFactory;
// A variant of MockUDPClientSocket which always fails to Connect.
class FailingUDPClientSocket : public MockUDPClientSocket {
public:
FailingUDPClientSocket(SocketDataProvider* data, net::NetLog* net_log)
: MockUDPClientSocket(data, net_log) {}
~FailingUDPClientSocket() override = default;
int Connect(const IPEndPoint& endpoint) override {
return ERR_CONNECTION_REFUSED;
}
private:
DISALLOW_COPY_AND_ASSIGN(FailingUDPClientSocket);
};
// A variant of MockUDPClientSocket which notifies the factory OnConnect.
class TestUDPClientSocket : public MockUDPClientSocket {
public:
TestUDPClientSocket(TestSocketFactory* factory,
SocketDataProvider* data,
net::NetLog* net_log)
: MockUDPClientSocket(data, net_log), factory_(factory) {}
~TestUDPClientSocket() override = default;
int Connect(const IPEndPoint& endpoint) override;
private:
TestSocketFactory* factory_;
DISALLOW_COPY_AND_ASSIGN(TestUDPClientSocket);
};
// Creates TestUDPClientSockets and keeps endpoints reported via OnConnect.
class TestSocketFactory : public MockClientSocketFactory {
public:
TestSocketFactory() : fail_next_socket_(false) {}
~TestSocketFactory() override = default;
std::unique_ptr<DatagramClientSocket> CreateDatagramClientSocket(
DatagramSocket::BindType bind_type,
NetLog* net_log,
const NetLogSource& source) override {
if (fail_next_socket_) {
fail_next_socket_ = false;
return std::unique_ptr<DatagramClientSocket>(
new FailingUDPClientSocket(&empty_data_, net_log));
}
SocketDataProvider* data_provider = mock_data().GetNext();
return std::make_unique<TestUDPClientSocket>(this, data_provider, net_log);
}
void OnConnect(const IPEndPoint& endpoint) {
remote_endpoints_.push_back(endpoint);
}
std::vector<IPEndPoint> remote_endpoints_;
bool fail_next_socket_;
private:
StaticSocketDataProvider empty_data_;
DISALLOW_COPY_AND_ASSIGN(TestSocketFactory);
};
int TestUDPClientSocket::Connect(const IPEndPoint& endpoint) {
factory_->OnConnect(endpoint);
return MockUDPClientSocket::Connect(endpoint);
}
// Helper class that holds a DnsTransaction and handles OnTransactionComplete.
class TransactionHelper {
public:
// If |expected_answer_count| < 0 then it is the expected net error.
TransactionHelper(const char* hostname,
uint16_t qtype,
int expected_answer_count)
: hostname_(hostname),
qtype_(qtype),
response_(nullptr),
expected_answer_count_(expected_answer_count),
cancel_in_callback_(false),
completed_(false) {}
// Mark that the transaction shall be destroyed immediately upon callback.
void set_cancel_in_callback() { cancel_in_callback_ = true; }
void StartTransaction(DnsTransactionFactory* factory) {
EXPECT_EQ(NULL, transaction_.get());
transaction_ = factory->CreateTransaction(
hostname_, qtype_,
base::Bind(&TransactionHelper::OnTransactionComplete,
base::Unretained(this)),
NetLogWithSource::Make(&net_log_, net::NetLogSourceType::NONE));
transaction_->SetRequestContext(&request_context_);
transaction_->SetRequestPriority(DEFAULT_PRIORITY);
EXPECT_EQ(hostname_, transaction_->GetHostname());
EXPECT_EQ(qtype_, transaction_->GetType());
transaction_->Start();
}
void Cancel() {
ASSERT_TRUE(transaction_.get() != NULL);
transaction_.reset(NULL);
}
void OnTransactionComplete(DnsTransaction* t,
int rv,
const DnsResponse* response) {
EXPECT_FALSE(completed_);
EXPECT_EQ(transaction_.get(), t);
completed_ = true;
response_ = response;
if (transaction_complete_run_loop_)
transaction_complete_run_loop_->QuitWhenIdle();
if (cancel_in_callback_) {
Cancel();
return;
}
if (response)
EXPECT_TRUE(response->IsValid());
if (expected_answer_count_ >= 0) {
ASSERT_THAT(rv, IsOk());
ASSERT_TRUE(response != NULL);
EXPECT_EQ(static_cast<unsigned>(expected_answer_count_),
response->answer_count());
EXPECT_EQ(qtype_, response->qtype());
DnsRecordParser parser = response->Parser();
DnsResourceRecord record;
for (int i = 0; i < expected_answer_count_; ++i) {
EXPECT_TRUE(parser.ReadRecord(&record));
}
} else {
EXPECT_EQ(expected_answer_count_, rv);
}
}
bool has_completed() const { return completed_; }
const DnsResponse* response() const { return response_; }
// Shorthands for commonly used commands.
bool Run(DnsTransactionFactory* factory) {
StartTransaction(factory);
base::RunLoop().RunUntilIdle();
return has_completed();
}
bool RunUntilDone(DnsTransactionFactory* factory) {
DCHECK(!transaction_complete_run_loop_);
transaction_complete_run_loop_ = std::make_unique<base::RunLoop>();
StartTransaction(factory);
transaction_complete_run_loop_->Run();
transaction_complete_run_loop_.reset();
return has_completed();
}
TestURLRequestContext* request_context() { return &request_context_; }
NetLog* net_log() { return &net_log_; }
private:
std::string hostname_;
uint16_t qtype_;
std::unique_ptr<DnsTransaction> transaction_;
const DnsResponse* response_;
int expected_answer_count_;
bool cancel_in_callback_;
TestURLRequestContext request_context_;
std::unique_ptr<base::RunLoop> transaction_complete_run_loop_;
bool completed_;
NetLog net_log_;
};
// Callback that allows a test to modify HttpResponseinfo
// before the response is sent to the requester. This allows
// response headers to be changed.
typedef base::RepeatingCallback<void(URLRequest* request,
HttpResponseInfo* info)>
ResponseModifierCallback;
// Callback that allows the test to substitute its own implementation
// of URLRequestJob to handle the request.
typedef base::RepeatingCallback<URLRequestJob*(
URLRequest* request,
NetworkDelegate* network_delegate,
SocketDataProvider* data_provider)>
DohJobMakerCallback;
// Subclass of URLRequestJob which takes a SocketDataProvider with data
// representing both a DNS over HTTPS query and response.
class URLRequestMockDohJob : public URLRequestJob, public AsyncSocket {
public:
URLRequestMockDohJob(
URLRequest* request,
NetworkDelegate* network_delegate,
SocketDataProvider* data_provider,
ResponseModifierCallback response_modifier = ResponseModifierCallback())
: URLRequestJob(request, network_delegate),
content_length_(0),
leftover_data_len_(0),
data_provider_(data_provider),
response_modifier_(response_modifier),
weak_factory_(this) {
data_provider_->Initialize(this);
MatchQueryData(request, data_provider);
}
// Compare the query contained in either the POST body or the body
// parameter of the GET query to the write data of the SocketDataProvider.
static void MatchQueryData(URLRequest* request,
SocketDataProvider* data_provider) {
std::string decoded_query;
if (request->method() == "GET") {
std::string encoded_query;
EXPECT_TRUE(GetValueForKeyInQuery(request->url(), "dns", &encoded_query));
EXPECT_GT(encoded_query.size(), 0ul);
EXPECT_TRUE(base::Base64UrlDecode(
encoded_query, base::Base64UrlDecodePolicy::IGNORE_PADDING,
&decoded_query));
} else if (request->method() == "POST") {
const UploadDataStream* stream = request->get_upload();
auto* readers = stream->GetElementReaders();
EXPECT_TRUE(readers);
EXPECT_FALSE(readers->empty());
for (auto& reader : *readers) {
const UploadBytesElementReader* byte_reader = reader->AsBytesReader();
decoded_query +=
std::string(byte_reader->bytes(), byte_reader->length());
}
}
std::string query(decoded_query);
MockWriteResult result(SYNCHRONOUS, 1);
while (result.result > 0 && query.length() > 0) {
result = data_provider->OnWrite(query);
if (result.result > 0)
query = query.substr(result.result);
}
}
static std::string GetMockHttpsUrl(const std::string& path) {
return "https://" + (kMockHostname + ("/" + path));
}
// URLRequestJob implementation:
void Start() override {
// Start reading asynchronously so that all error reporting and data
// callbacks happen as they would for network requests.
base::ThreadTaskRunnerHandle::Get()->PostTask(
FROM_HERE, base::Bind(&URLRequestMockDohJob::StartAsync,
weak_factory_.GetWeakPtr()));
}
~URLRequestMockDohJob() override {
if (data_provider_)
data_provider_->DetachSocket();
}
int ReadRawData(IOBuffer* buf, int buf_size) override {
if (!data_provider_)
return ERR_FAILED;
if (leftover_data_len_ > 0) {
int rv = DoBufferCopy(leftover_data_, leftover_data_len_, buf, buf_size);
return rv;
}
if (data_provider_->AllReadDataConsumed())
return 0;
MockRead read = data_provider_->OnRead();
if (read.result < ERR_IO_PENDING)
return read.result;
if (read.result == ERR_IO_PENDING) {
pending_buf_ = buf;
pending_buf_size_ = buf_size;
return ERR_IO_PENDING;
}
return DoBufferCopy(read.data, read.data_len, buf, buf_size);
}
void GetResponseInfo(HttpResponseInfo* info) override {
// Send back mock headers.
std::string raw_headers;
raw_headers.append(
"HTTP/1.1 200 OK\n"
"Content-type: application/dns-message\n");
if (content_length_ > 0) {
raw_headers.append(base::StringPrintf("Content-Length: %1d\n",
static_cast<int>(content_length_)));
}
info->headers =
base::MakeRefCounted<HttpResponseHeaders>(HttpUtil::AssembleRawHeaders(
raw_headers.c_str(), static_cast<int>(raw_headers.length())));
if (response_modifier_)
response_modifier_.Run(request(), info);
}
// AsyncSocket implementation:
void OnReadComplete(const MockRead& data) override {
EXPECT_NE(data.result, ERR_IO_PENDING);
if (data.result < 0)
return ReadRawDataComplete(data.result);
ReadRawDataComplete(DoBufferCopy(data.data, data.data_len, pending_buf_,
pending_buf_size_));
}
void OnWriteComplete(int rv) override {}
void OnConnectComplete(const MockConnect& data) override {}
void OnDataProviderDestroyed() override { data_provider_ = nullptr; }
private:
void StartAsync() {
if (!request_)
return;
if (content_length_)
set_expected_content_size(content_length_);
NotifyHeadersComplete();
}
int DoBufferCopy(const char* data,
int data_len,
IOBuffer* buf,
int buf_size) {
if (data_len > buf_size) {
memcpy(buf->data(), data, buf_size);
leftover_data_ = data + buf_size;
leftover_data_len_ = data_len - buf_size;
return buf_size;
}
memcpy(buf->data(), data, data_len);
return data_len;
}
const int content_length_;
const char* leftover_data_;
int leftover_data_len_;
SocketDataProvider* data_provider_;
const ResponseModifierCallback response_modifier_;
IOBuffer* pending_buf_;
int pending_buf_size_;
base::WeakPtrFactory<URLRequestMockDohJob> weak_factory_;
DISALLOW_COPY_AND_ASSIGN(URLRequestMockDohJob);
};
class DnsTransactionTestBase : public testing::Test {
public:
DnsTransactionTestBase() = default;
~DnsTransactionTestBase() override = default;
// Generates |nameservers| for DnsConfig.
void ConfigureNumServers(unsigned num_servers) {
CHECK_LE(num_servers, 255u);
config_.nameservers.clear();
for (unsigned i = 0; i < num_servers; ++i) {
config_.nameservers.push_back(
IPEndPoint(IPAddress(192, 168, 1, i), dns_protocol::kDefaultPort));
}
}
// Called after fully configuring |config|.
void ConfigureFactory() {
socket_factory_.reset(new TestSocketFactory());
session_ = new DnsSession(
config_,
DnsSocketPool::CreateNull(socket_factory_.get(),
base::Bind(base::RandInt)),
base::Bind(&DnsTransactionTestBase::GetNextId, base::Unretained(this)),
NULL /* NetLog */);
transaction_factory_ = DnsTransactionFactory::CreateFactory(session_.get());
}
void AddSocketData(std::unique_ptr<DnsSocketData> data) {
CHECK(socket_factory_.get());
transaction_ids_.push_back(data->query_id());
socket_factory_->AddSocketDataProvider(data->GetProvider());
socket_data_.push_back(std::move(data));
}
// Add expected query for |dotted_name| and |qtype| with |id| and response
// taken verbatim from |data| of |data_length| bytes. The transaction id in
// |data| should equal |id|, unless testing mismatched response.
void AddQueryAndResponse(uint16_t id,
const char* dotted_name,
uint16_t qtype,
const uint8_t* response_data,
size_t response_length,
IoMode mode,
Transport transport,
const OptRecordRdata* opt_rdata = nullptr) {
CHECK(socket_factory_.get());
std::unique_ptr<DnsSocketData> data(
new DnsSocketData(id, dotted_name, qtype, mode, transport, opt_rdata));
data->AddResponseData(response_data, response_length, mode);
AddSocketData(std::move(data));
}
void AddQueryAndErrorResponse(uint16_t id,
const char* dotted_name,
uint16_t qtype,
int error,
IoMode mode,
Transport transport) {
CHECK(socket_factory_.get());
std::unique_ptr<DnsSocketData> data(
new DnsSocketData(id, dotted_name, qtype, mode, transport));
data->AddReadError(error, mode);
AddSocketData(std::move(data));
}
void AddAsyncQueryAndResponse(uint16_t id,
const char* dotted_name,
uint16_t qtype,
const uint8_t* data,
size_t data_length,
const OptRecordRdata* opt_rdata = nullptr) {
AddQueryAndResponse(id, dotted_name, qtype, data, data_length, ASYNC,
Transport::UDP, opt_rdata);
}
void AddSyncQueryAndResponse(uint16_t id,
const char* dotted_name,
uint16_t qtype,
const uint8_t* data,
size_t data_length,
const OptRecordRdata* opt_rdata = nullptr) {
AddQueryAndResponse(id, dotted_name, qtype, data, data_length, SYNCHRONOUS,
Transport::UDP, opt_rdata);
}
// Add expected query of |dotted_name| and |qtype| and no response.
void AddQueryAndTimeout(const char* dotted_name, uint16_t qtype) {
uint16_t id = base::RandInt(0, std::numeric_limits<uint16_t>::max());
std::unique_ptr<DnsSocketData> data(
new DnsSocketData(id, dotted_name, qtype, ASYNC, Transport::UDP));
AddSocketData(std::move(data));
}
// Add expected query of |dotted_name| and |qtype| and matching response with
// no answer and RCODE set to |rcode|. The id will be generated randomly.
void AddQueryAndRcode(const char* dotted_name,
uint16_t qtype,
int rcode,
IoMode mode,
Transport trans) {
CHECK_NE(dns_protocol::kRcodeNOERROR, rcode);
uint16_t id = base::RandInt(0, std::numeric_limits<uint16_t>::max());
std::unique_ptr<DnsSocketData> data(
new DnsSocketData(id, dotted_name, qtype, mode, trans));
data->AddRcode(rcode, mode);
AddSocketData(std::move(data));
}
void AddAsyncQueryAndRcode(const char* dotted_name,
uint16_t qtype,
int rcode) {
AddQueryAndRcode(dotted_name, qtype, rcode, ASYNC, Transport::UDP);
}
void AddSyncQueryAndRcode(const char* dotted_name,
uint16_t qtype,
int rcode) {
AddQueryAndRcode(dotted_name, qtype, rcode, SYNCHRONOUS, Transport::UDP);
}
// Checks if the sockets were connected in the order matching the indices in
// |servers|.
void CheckServerOrder(const unsigned* servers, size_t num_attempts) {
ASSERT_EQ(num_attempts, socket_factory_->remote_endpoints_.size());
for (size_t i = 0; i < num_attempts; ++i) {
EXPECT_EQ(socket_factory_->remote_endpoints_[i],
session_->config().nameservers[servers[i]]);
}
}
void SetUp() override {
// By default set one server,
ConfigureNumServers(1);
// and no retransmissions,
config_.attempts = 1;
// and an arbitrary timeout.
config_.timeout = kTimeout;
ConfigureFactory();
}
void TearDown() override {
// Check that all socket data was at least written to.
for (size_t i = 0; i < socket_data_.size(); ++i) {
EXPECT_TRUE(socket_data_[i]->GetProvider()->AllWriteDataConsumed()) << i;
}
}
protected:
int GetNextId(int min, int max) {
EXPECT_FALSE(transaction_ids_.empty());
int id = transaction_ids_.front();
transaction_ids_.pop_front();
EXPECT_GE(id, min);
EXPECT_LE(id, max);
return id;
}
DnsConfig config_;
std::vector<std::unique_ptr<DnsSocketData>> socket_data_;
base::circular_deque<int> transaction_ids_;
std::unique_ptr<TestSocketFactory> socket_factory_;
scoped_refptr<DnsSession> session_;
std::unique_ptr<DnsTransactionFactory> transaction_factory_;
};
class DnsTransactionTest : public DnsTransactionTestBase,
public WithScopedTaskEnvironment {
public:
DnsTransactionTest() = default;
~DnsTransactionTest() override = default;
// Generates |nameservers| for DnsConfig.
void ConfigureDohServers(unsigned num_servers, bool use_post) {
CHECK_LE(num_servers, 255u);
for (unsigned i = 0; i < num_servers; ++i) {
std::string server_template(URLRequestMockDohJob::GetMockHttpsUrl(
base::StringPrintf("doh_test_%d", i)) +
"{?dns}");
config_.dns_over_https_servers.push_back(
DnsConfig::DnsOverHttpsServerConfig(server_template, use_post));
}
}
// Configures the DnsConfig with one dns over https server, which either
// accepts GET or POST requests based on use_post. If |clear_udp| is true,
// existing IP name servers are removed from the DnsConfig. If a
// ResponseModifierCallback is provided it will be called to contruct the
// HTTPResponse.
void ConfigDohServers(bool clear_udp,
bool use_post,
int num_doh_servers = 1) {
if (clear_udp)
ConfigureNumServers(0);
GURL url(URLRequestMockDohJob::GetMockHttpsUrl("doh_test"));
URLRequestFilter* filter = URLRequestFilter::GetInstance();
filter->AddHostnameInterceptor(url.scheme(), url.host(),
std::make_unique<DohJobInterceptor>(this));
ConfigureDohServers(num_doh_servers, use_post);
ConfigureFactory();
}
URLRequestJob* MaybeInterceptRequest(URLRequest* request,
NetworkDelegate* network_delegate) {
// If the path indicates a redirct, skip checking the list of
// configured servers, because it won't be there and we still want
// to handle it.
bool server_found = request->url().path() == "/redirect-destination";
for (auto server : config_.dns_over_https_servers) {
if (server_found)
break;
std::string url_base =
GetURLFromTemplateWithoutParameters(server.server_template);
if (server.use_post && request->method() == "POST") {
if (url_base == request->url().spec()) {
server_found = true;
}
} else if (!server.use_post && request->method() == "GET") {
std::string prefix = url_base + "?dns=";
auto mispair = std::mismatch(prefix.begin(), prefix.end(),
request->url().spec().begin());
if (mispair.first == prefix.end()) {
server_found = true;
}
}
}
EXPECT_TRUE(server_found);
HttpRequestHeaders* headers = nullptr;
if (request->GetFullRequestHeaders(headers)) {
EXPECT_FALSE(headers->HasHeader(HttpRequestHeaders::kCookie));
}
EXPECT_FALSE(request->extra_request_headers().HasHeader(
HttpRequestHeaders::kCookie));
std::string accept;
EXPECT_TRUE(request->extra_request_headers().GetHeader("Accept", &accept));
EXPECT_EQ(accept, "application/dns-message");
SocketDataProvider* provider = socket_factory_->mock_data().GetNext();
if (doh_job_maker_)
return doh_job_maker_.Run(request, network_delegate, provider);
return new URLRequestMockDohJob(request, network_delegate, provider,
response_modifier_);
}
class DohJobInterceptor : public URLRequestInterceptor {
public:
explicit DohJobInterceptor(DnsTransactionTest* test) : test_(test) {}
~DohJobInterceptor() override {}
// URLRequestInterceptor implementation:
URLRequestJob* MaybeInterceptRequest(
URLRequest* request,
NetworkDelegate* network_delegate) const override {
return test_->MaybeInterceptRequest(request, network_delegate);
}
private:
DnsTransactionTest* test_;
DISALLOW_COPY_AND_ASSIGN(DohJobInterceptor);
};
void TearDown() override {
URLRequestFilter* filter = URLRequestFilter::GetInstance();
filter->ClearHandlers();
}
void SetResponseModifierCallback(ResponseModifierCallback response_modifier) {
response_modifier_ = response_modifier;
}
void SetDohJobMakerCallback(DohJobMakerCallback doh_job_maker) {
doh_job_maker_ = doh_job_maker;
}
private:
ResponseModifierCallback response_modifier_;
DohJobMakerCallback doh_job_maker_;
};
class DnsTransactionTestWithMockTime : public DnsTransactionTestBase,
public WithScopedTaskEnvironment {
protected:
DnsTransactionTestWithMockTime()
: WithScopedTaskEnvironment(
base::test::ScopedTaskEnvironment::MainThreadType::MOCK_TIME) {}
~DnsTransactionTestWithMockTime() override = default;
};
TEST_F(DnsTransactionTest, Lookup) {
base::HistogramTester histograms;
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
histograms.ExpectUniqueSample("AsyncDNS.Rcode", dns_protocol::kRcodeNOERROR,
1);
}
TEST_F(DnsTransactionTest, LookupWithEDNSOption) {
OptRecordRdata expected_opt_rdata;
const OptRecordRdata::Opt ednsOpt(123, "\xbe\xef");
transaction_factory_->AddEDNSOption(ednsOpt);
expected_opt_rdata.AddOpt(ednsOpt);
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
&expected_opt_rdata);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, LookupWithMultipleEDNSOptions) {
OptRecordRdata expected_opt_rdata;
for (const auto& ednsOpt : {
// Two options with the same code, to check that both are included.
OptRecordRdata::Opt(1, "\xde\xad"),
OptRecordRdata::Opt(1, "\xbe\xef"),
// Try a different code and different length of data.
OptRecordRdata::Opt(2, "\xff"),
}) {
transaction_factory_->AddEDNSOption(ednsOpt);
expected_opt_rdata.AddOpt(ednsOpt);
}
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
&expected_opt_rdata);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
// Concurrent lookup tests assume that DnsTransaction::Start immediately
// consumes a socket from ClientSocketFactory.
TEST_F(DnsTransactionTest, ConcurrentLookup) {
base::HistogramTester histograms;
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
AddAsyncQueryAndResponse(1 /* id */, kT1HostName, kT1Qtype,
kT1ResponseDatagram, arraysize(kT1ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
helper0.StartTransaction(transaction_factory_.get());
TransactionHelper helper1(kT1HostName, kT1Qtype, kT1RecordCount);
helper1.StartTransaction(transaction_factory_.get());
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(helper0.has_completed());
EXPECT_TRUE(helper1.has_completed());
histograms.ExpectUniqueSample("AsyncDNS.Rcode", dns_protocol::kRcodeNOERROR,
2);
}
TEST_F(DnsTransactionTest, CancelLookup) {
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
AddAsyncQueryAndResponse(1 /* id */, kT1HostName, kT1Qtype,
kT1ResponseDatagram, arraysize(kT1ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
helper0.StartTransaction(transaction_factory_.get());
TransactionHelper helper1(kT1HostName, kT1Qtype, kT1RecordCount);
helper1.StartTransaction(transaction_factory_.get());
helper0.Cancel();
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(helper0.has_completed());
EXPECT_TRUE(helper1.has_completed());
}
TEST_F(DnsTransactionTest, DestroyFactory) {
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
helper0.StartTransaction(transaction_factory_.get());
// Destroying the client does not affect running requests.
transaction_factory_.reset(NULL);
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(helper0.has_completed());
}
TEST_F(DnsTransactionTest, CancelFromCallback) {
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
helper0.set_cancel_in_callback();
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedResponseSync) {
config_.attempts = 2;
ConfigureFactory();
// First attempt receives mismatched response synchronously.
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
data->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
SYNCHRONOUS);
AddSocketData(std::move(data));
// Second attempt receives valid response synchronously.
std::unique_ptr<DnsSocketData> data1(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
data1->AddResponseData(kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
SYNCHRONOUS);
AddSocketData(std::move(data1));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedResponseAsync) {
config_.attempts = 2;
ConfigureFactory();
// First attempt receives mismatched response asynchronously.
std::unique_ptr<DnsSocketData> data0(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::UDP));
data0->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
ASYNC);
AddSocketData(std::move(data0));
// Second attempt receives valid response asynchronously.
std::unique_ptr<DnsSocketData> data1(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::UDP));
data1->AddResponseData(kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
ASYNC);
AddSocketData(std::move(data1));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedResponseFail) {
ConfigureFactory();
// Attempt receives mismatched response and fails because only one attempt is
// allowed.
AddAsyncQueryAndResponse(1 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedResponseNxdomain) {
config_.attempts = 2;
ConfigureFactory();
// First attempt receives mismatched response followed by valid NXDOMAIN
// response.
// Second attempt receives valid NXDOMAIN response.
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
data->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
SYNCHRONOUS);
data->AddRcode(dns_protocol::kRcodeNXDOMAIN, ASYNC);
AddSocketData(std::move(data));
AddSyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, ServerFail) {
base::HistogramTester histograms;
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_SERVER_FAILED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
ASSERT_NE(helper0.response(), nullptr);
EXPECT_EQ(helper0.response()->rcode(), dns_protocol::kRcodeSERVFAIL);
histograms.ExpectUniqueSample("AsyncDNS.Rcode", dns_protocol::kRcodeSERVFAIL,
1);
}
TEST_F(DnsTransactionTest, NoDomain) {
base::HistogramTester histograms;
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
histograms.ExpectUniqueSample("AsyncDNS.Rcode", dns_protocol::kRcodeNXDOMAIN,
1);
}
TEST_F(DnsTransactionTestWithMockTime, Timeout) {
config_.attempts = 3;
ConfigureFactory();
AddQueryAndTimeout(kT0HostName, kT0Qtype);
AddQueryAndTimeout(kT0HostName, kT0Qtype);
AddQueryAndTimeout(kT0HostName, kT0Qtype);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_TIMED_OUT);
// Finish when the third attempt times out.
EXPECT_FALSE(helper0.Run(transaction_factory_.get()));
FastForwardBy(session_->NextTimeout(0, 0));
EXPECT_FALSE(helper0.has_completed());
FastForwardBy(session_->NextTimeout(0, 1));
EXPECT_FALSE(helper0.has_completed());
FastForwardBy(session_->NextTimeout(0, 2));
EXPECT_TRUE(helper0.has_completed());
}
TEST_F(DnsTransactionTestWithMockTime, ServerFallbackAndRotate) {
// Test that we fallback on both server failure and timeout.
config_.attempts = 2;
// The next request should start from the next server.
config_.rotate = true;
ConfigureNumServers(3);
ConfigureFactory();
// Responses for first request.
AddQueryAndTimeout(kT0HostName, kT0Qtype);
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL);
AddQueryAndTimeout(kT0HostName, kT0Qtype);
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL);
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeNXDOMAIN);
// Responses for second request.
AddAsyncQueryAndRcode(kT1HostName, kT1Qtype, dns_protocol::kRcodeSERVFAIL);
AddAsyncQueryAndRcode(kT1HostName, kT1Qtype, dns_protocol::kRcodeSERVFAIL);
AddAsyncQueryAndRcode(kT1HostName, kT1Qtype, dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_NAME_NOT_RESOLVED);
TransactionHelper helper1(kT1HostName, kT1Qtype, ERR_NAME_NOT_RESOLVED);
EXPECT_FALSE(helper0.Run(transaction_factory_.get()));
FastForwardUntilNoTasksRemain();
EXPECT_TRUE(helper0.has_completed());
EXPECT_TRUE(helper1.Run(transaction_factory_.get()));
unsigned kOrder[] = {
0, 1, 2, 0, 1, // The first transaction.
1, 2, 0, // The second transaction starts from the next server.
};
CheckServerOrder(kOrder, arraysize(kOrder));
}
TEST_F(DnsTransactionTest, SuffixSearchAboveNdots) {
config_.ndots = 2;
config_.search.push_back("a");
config_.search.push_back("b");
config_.search.push_back("c");
config_.rotate = true;
ConfigureNumServers(2);
ConfigureFactory();
AddAsyncQueryAndRcode("x.y.z", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.z.a", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.z.b", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.z.c", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0("x.y.z", dns_protocol::kTypeA,
ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
// Also check if suffix search causes server rotation.
unsigned kOrder0[] = {0, 1, 0, 1};
CheckServerOrder(kOrder0, arraysize(kOrder0));
}
TEST_F(DnsTransactionTest, SuffixSearchBelowNdots) {
config_.ndots = 2;
config_.search.push_back("a");
config_.search.push_back("b");
config_.search.push_back("c");
ConfigureFactory();
// Responses for first transaction.
AddAsyncQueryAndRcode("x.y.a", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.b", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.c", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
// Responses for second transaction.
AddAsyncQueryAndRcode("x.a", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.b", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.c", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
// Responses for third transaction.
AddAsyncQueryAndRcode("x", dns_protocol::kTypeAAAA,
dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0("x.y", dns_protocol::kTypeA, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
// A single-label name.
TransactionHelper helper1("x", dns_protocol::kTypeA, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper1.Run(transaction_factory_.get()));
// A fully-qualified name.
TransactionHelper helper2("x.", dns_protocol::kTypeAAAA,
ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper2.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, EmptySuffixSearch) {
// Responses for first transaction.
AddAsyncQueryAndRcode("x", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
// A fully-qualified name.
TransactionHelper helper0("x.", dns_protocol::kTypeA, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
// A single label name is not even attempted.
TransactionHelper helper1("singlelabel", dns_protocol::kTypeA,
ERR_DNS_SEARCH_EMPTY);
helper1.Run(transaction_factory_.get());
EXPECT_TRUE(helper1.has_completed());
}
TEST_F(DnsTransactionTest, DontAppendToMultiLabelName) {
config_.search.push_back("a");
config_.search.push_back("b");
config_.search.push_back("c");
config_.append_to_multi_label_name = false;
ConfigureFactory();
// Responses for first transaction.
AddAsyncQueryAndRcode("x.y.z", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
// Responses for second transaction.
AddAsyncQueryAndRcode("x.y", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
// Responses for third transaction.
AddAsyncQueryAndRcode("x.a", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.b", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.c", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
TransactionHelper helper0("x.y.z", dns_protocol::kTypeA,
ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
TransactionHelper helper1("x.y", dns_protocol::kTypeA, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper1.Run(transaction_factory_.get()));
TransactionHelper helper2("x", dns_protocol::kTypeA, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper2.Run(transaction_factory_.get()));
}
const uint8_t kResponseNoData[] = {
0x00, 0x00, 0x81, 0x80, 0x00, 0x01, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00,
// Question
0x01, 'x', 0x01, 'y', 0x01, 'z', 0x01, 'b', 0x00, 0x00, 0x01, 0x00, 0x01,
// Authority section, SOA record, TTL 0x3E6
0x01, 'z', 0x00, 0x00, 0x06, 0x00, 0x01, 0x00, 0x00, 0x03, 0xE6,
// Minimal RDATA, 18 bytes
0x00, 0x12, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
};
TEST_F(DnsTransactionTest, SuffixSearchStop) {
config_.ndots = 2;
config_.search.push_back("a");
config_.search.push_back("b");
config_.search.push_back("c");
ConfigureFactory();
AddAsyncQueryAndRcode("x.y.z", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndRcode("x.y.z.a", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddAsyncQueryAndResponse(0 /* id */, "x.y.z.b", dns_protocol::kTypeA,
kResponseNoData, arraysize(kResponseNoData));
TransactionHelper helper0("x.y.z", dns_protocol::kTypeA, 0 /* answers */);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, SyncFirstQuery) {
config_.search.push_back("lab.ccs.neu.edu");
config_.search.push_back("ccs.neu.edu");
ConfigureFactory();
AddSyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, SyncFirstQueryWithSearch) {
config_.search.push_back("lab.ccs.neu.edu");
config_.search.push_back("ccs.neu.edu");
ConfigureFactory();
AddSyncQueryAndRcode("www.lab.ccs.neu.edu", kT2Qtype,
dns_protocol::kRcodeNXDOMAIN);
// "www.ccs.neu.edu"
AddAsyncQueryAndResponse(2 /* id */, kT2HostName, kT2Qtype,
kT2ResponseDatagram, arraysize(kT2ResponseDatagram));
TransactionHelper helper0("www", kT2Qtype, kT2RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, SyncSearchQuery) {
config_.search.push_back("lab.ccs.neu.edu");
config_.search.push_back("ccs.neu.edu");
ConfigureFactory();
AddAsyncQueryAndRcode("www.lab.ccs.neu.edu", dns_protocol::kTypeA,
dns_protocol::kRcodeNXDOMAIN);
AddSyncQueryAndResponse(2 /* id */, kT2HostName, kT2Qtype,
kT2ResponseDatagram, arraysize(kT2ResponseDatagram));
TransactionHelper helper0("www", kT2Qtype, kT2RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, ConnectFailure) {
socket_factory_->fail_next_socket_ = true;
transaction_ids_.push_back(0); // Needed to make a DnsUDPAttempt.
TransactionHelper helper0("www.chromium.org", dns_protocol::kTypeA,
ERR_CONNECTION_REFUSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, ConnectFailureFollowedBySuccess) {
// Retry after server failure.
config_.attempts = 2;
ConfigureFactory();
// First server connection attempt fails.
transaction_ids_.push_back(0); // Needed to make a DnsUDPAttempt.
socket_factory_->fail_next_socket_ = true;
// Second DNS query succeeds.
AddAsyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsGetLookup) {
ConfigDohServers(true /* clear_udp */, false /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsGetFailure) {
ConfigDohServers(true /* clear_udp */, false /* use_post */);
AddQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL,
SYNCHRONOUS, Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_SERVER_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
ASSERT_NE(helper0.response(), nullptr);
EXPECT_EQ(helper0.response()->rcode(), dns_protocol::kRcodeSERVFAIL);
}
TEST_F(DnsTransactionTest, HttpsGetMalformed) {
ConfigDohServers(true /* clear_udp */, false /* use_post */);
AddQueryAndResponse(1 /* id */, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookup) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostFailure) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL,
SYNCHRONOUS, Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_SERVER_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
ASSERT_NE(helper0.response(), nullptr);
EXPECT_EQ(helper0.response()->rcode(), dns_protocol::kRcodeSERVFAIL);
}
TEST_F(DnsTransactionTest, HttpsPostMalformed) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(1 /* id */, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupAsync) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
URLRequestJob* DohJobMakerCallbackFailStart(URLRequest* request,
NetworkDelegate* network_delegate,
SocketDataProvider* data) {
URLRequestMockDohJob::MatchQueryData(request, data);
return new URLRequestFailedJob(request, network_delegate,
URLRequestFailedJob::START, ERR_FAILED);
}
TEST_F(DnsTransactionTest, HttpsPostLookupFailStart) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailStart));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
URLRequestJob* DohJobMakerCallbackFailSync(URLRequest* request,
NetworkDelegate* network_delegate,
SocketDataProvider* data) {
URLRequestMockDohJob::MatchQueryData(request, data);
return new URLRequestFailedJob(request, network_delegate,
URLRequestFailedJob::READ_SYNC, ERR_FAILED);
}
TEST_F(DnsTransactionTest, HttpsPostLookupFailSync) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseWithLength(std::make_unique<DnsResponse>(), SYNCHRONOUS, 0);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailSync));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
URLRequestJob* DohJobMakerCallbackFailAsync(URLRequest* request,
NetworkDelegate* network_delegate,
SocketDataProvider* data) {
URLRequestMockDohJob::MatchQueryData(request, data);
return new URLRequestFailedJob(request, network_delegate,
URLRequestFailedJob::READ_ASYNC, ERR_FAILED);
}
TEST_F(DnsTransactionTest, HttpsPostLookupFailAsync) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailAsync));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookup2Sync) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, SYNCHRONOUS);
data->AddResponseData(kT0ResponseDatagram + 20,
arraysize(kT0ResponseDatagram) - 20, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookup2Async) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, ASYNC);
data->AddResponseData(kT0ResponseDatagram + 20,
arraysize(kT0ResponseDatagram) - 20, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupAsyncWithAsyncZeroRead) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
ASYNC);
data->AddResponseData(kT0ResponseDatagram, 0, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupSyncWithAsyncZeroRead) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, arraysize(kT0ResponseDatagram),
SYNCHRONOUS);
data->AddResponseData(kT0ResponseDatagram, 0, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupAsyncThenSync) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, ASYNC);
data->AddResponseData(kT0ResponseDatagram + 20,
arraysize(kT0ResponseDatagram) - 20, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupAsyncThenSyncError) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, ASYNC);
data->AddReadError(ERR_FAILED, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupAsyncThenAsyncError) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, ASYNC);
data->AddReadError(ERR_FAILED, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupSyncThenAsyncError) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, SYNCHRONOUS);
data->AddReadError(ERR_FAILED, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostLookupSyncThenSyncError) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::HTTPS));
data->AddResponseData(kT0ResponseDatagram, 20, SYNCHRONOUS);
data->AddReadError(ERR_FAILED, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostFailThenUDPFallback) {
config_.attempts = 2;
ConfigDohServers(false /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::UDP);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailStart));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostFailThenUDPFailThenUDPFallback) {
ConfigureNumServers(3);
ConfigDohServers(false /* clear_udp */, true /* use_post */);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailStart));
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndTimeout(kT0HostName, kT0Qtype);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::UDP);
transaction_ids_.push_back(0);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
// Servers 3 (HTTP) and 0 (UDP) should be marked as bad. 1 and 2 should be
// good.
EXPECT_EQ(session_->NextGoodServerIndex(0), 1u);
EXPECT_EQ(session_->NextGoodServerIndex(1), 1u);
EXPECT_EQ(session_->NextGoodServerIndex(2), 2u);
}
TEST_F(DnsTransactionTest, HttpsMarkUdpBad) {
config_.attempts = 1;
ConfigureNumServers(2);
ConfigDohServers(false /* clear_udp */, true /* use_post */);
AddQueryAndErrorResponse(0, kT0HostName, kT0Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndErrorResponse(0, kT0HostName, kT0Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::UDP);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::UDP);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
// Server 0 (UDP) should be marked bad. Server 1 (UDP) should be good
// and since 2 is our only Doh server, it will be good.
EXPECT_EQ(session_->NextGoodServerIndex(0), 1u);
EXPECT_EQ(session_->NextGoodServerIndex(1), 1u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(2), 2u);
AddQueryAndErrorResponse(1, kT1HostName, kT1Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndErrorResponse(1, kT1HostName, kT1Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::UDP);
AddQueryAndResponse(1, kT1HostName, kT1Qtype, kT1ResponseDatagram,
arraysize(kT1ResponseDatagram), ASYNC, Transport::UDP);
TransactionHelper helper1(kT1HostName, kT1Qtype, kT1RecordCount);
EXPECT_TRUE(helper1.RunUntilDone(transaction_factory_.get()));
// Since 0 was bad to start, we started with 1 which will now be the
// most recent failure, so Server 1 (UDP) should be marked bad.
// Server 0 (UDP) should be good and since 2 is our only Doh server.
EXPECT_EQ(session_->NextGoodServerIndex(0), 0u);
EXPECT_EQ(session_->NextGoodServerIndex(1), 0u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(2), 2u);
}
TEST_F(DnsTransactionTest, HttpsMarkHttpsBad) {
config_.attempts = 1;
ConfigDohServers(false /* clear_udp */, true /* use_post */, 3);
AddQueryAndErrorResponse(0, kT0HostName, kT0Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndErrorResponse(0, kT0HostName, kT0Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::HTTPS);
AddQueryAndErrorResponse(1, kT1HostName, kT1Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndErrorResponse(1, kT1HostName, kT1Qtype, ERR_CONNECTION_REFUSED,
SYNCHRONOUS, Transport::HTTPS);
AddQueryAndResponse(1, kT1HostName, kT1Qtype, kT1ResponseDatagram,
arraysize(kT1ResponseDatagram), ASYNC, Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
TransactionHelper helper1(kT1HostName, kT1Qtype, kT1RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
// Server 0 is our only UDP server, so it will be good. HTTPS
// servers 1 and 2 failed and will be marked bad. Server 3 succeeded
// so will be good.
EXPECT_EQ(session_->NextGoodServerIndex(0), 0u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(1), 3u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(2), 3u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(3), 3u);
EXPECT_TRUE(helper1.RunUntilDone(transaction_factory_.get()));
// Server 0 is still our only UDP server, so will be good by definition.
// Server 3 started out as good, so was tried first and failed. Server 1
// then had the oldest failure so would be the next good server and
// failed so is marked bad. Next attempt was server 2, which succeded so is
// good.
EXPECT_EQ(session_->NextGoodServerIndex(0), 0u);
#ifndef STARBOARD
// Either this test runs too fast or compiler optimization in devel mode
// grouped code together. On win-win32-lib the following part which depends on
// telling the oldest failed server can fail because two request failure in
// sequence can end up having the same failure time stamp.
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(1), 2u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(2), 2u);
EXPECT_EQ(session_->NextGoodDnsOverHttpsServerIndex(3), 2u);
#endif
}
TEST_F(DnsTransactionTest, HttpsPostFailThenHTTPFallback) {
ConfigDohServers(true /* clear_udp */, true /* use_post */, 2);
AddQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL, ASYNC,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostFailTwiceThenUDPFallback) {
config_.attempts = 3;
ConfigDohServers(false /* clear_udp */, true /* use_post */, 2);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::UDP);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailStart));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsPostFailTwice) {
config_.attempts = 2;
ConfigDohServers(true /* clear_udp */, true /* use_post */, 2);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_FAILED);
SetDohJobMakerCallback(base::BindRepeating(DohJobMakerCallbackFailStart));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseWithCookie(URLRequest* request, HttpResponseInfo* info) {
info->headers->AddHeader("Set-Cookie: test-cookie=you-fail");
}
class CookieCallback {
public:
CookieCallback()
: result_(false), loop_to_quit_(std::make_unique<base::RunLoop>()) {}
void SetCookieCallback(bool result) {
result_ = result;
loop_to_quit_->Quit();
}
void GetAllCookiesCallback(const net::CookieList& list) {
list_ = list;
loop_to_quit_->Quit();
}
void Reset() { loop_to_quit_.reset(new base::RunLoop()); }
void WaitUntilDone() { loop_to_quit_->Run(); }
size_t cookie_list_size() { return list_.size(); }
private:
net::CookieList list_;
bool result_;
std::unique_ptr<base::RunLoop> loop_to_quit_;
DISALLOW_COPY_AND_ASSIGN(CookieCallback);
};
TEST_F(DnsTransactionTest, HttpsPostTestNoCookies) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(1, kT1HostName, kT1Qtype, kT1ResponseDatagram,
arraysize(kT1ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
TransactionHelper helper1(kT1HostName, kT1Qtype, kT1RecordCount);
SetResponseModifierCallback(base::BindRepeating(MakeResponseWithCookie));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
CookieCallback callback;
helper0.request_context()->cookie_store()->GetAllCookiesForURLAsync(
GURL(GetURLFromTemplateWithoutParameters(
config_.dns_over_https_servers[0].server_template)),
base::Bind(&CookieCallback::GetAllCookiesCallback,
base::Unretained(&callback)));
callback.WaitUntilDone();
EXPECT_EQ(0u, callback.cookie_list_size());
callback.Reset();
net::CookieOptions options;
helper1.request_context()->cookie_store()->SetCookieWithOptionsAsync(
GURL(GetURLFromTemplateWithoutParameters(
config_.dns_over_https_servers[0].server_template)),
"test-cookie=you-still-fail", options,
base::Bind(&CookieCallback::SetCookieCallback,
base::Unretained(&callback)));
EXPECT_TRUE(helper1.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseWithoutLength(URLRequest* request, HttpResponseInfo* info) {
info->headers->RemoveHeader("Content-Length");
}
TEST_F(DnsTransactionTest, HttpsPostNoContentLength) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
SetResponseModifierCallback(base::BindRepeating(MakeResponseWithoutLength));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseWithBadRequestResponse(URLRequest* request,
HttpResponseInfo* info) {
info->headers->ReplaceStatusLine("HTTP/1.1 400 Bad Request");
}
TEST_F(DnsTransactionTest, HttpsPostWithBadRequestResponse) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
SetResponseModifierCallback(
base::BindRepeating(MakeResponseWithBadRequestResponse));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseWrongType(URLRequest* request, HttpResponseInfo* info) {
info->headers->RemoveHeader("Content-Type");
info->headers->AddHeader("Content-Type: text/html");
}
TEST_F(DnsTransactionTest, HttpsPostWithWrongType) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
SetResponseModifierCallback(base::BindRepeating(MakeResponseWrongType));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseRedirect(URLRequest* request, HttpResponseInfo* info) {
if (request->url_chain().size() < 2) {
info->headers->ReplaceStatusLine("HTTP/1.1 302 Found");
info->headers->AddHeader("Location: /redirect-destination?" +
request->url().query());
}
}
TEST_F(DnsTransactionTest, HttpsGetRedirect) {
ConfigDohServers(true /* clear_udp */, false /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
SetResponseModifierCallback(base::BindRepeating(MakeResponseRedirect));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
void MakeResponseNoType(URLRequest* request, HttpResponseInfo* info) {
info->headers->RemoveHeader("Content-Type");
}
TEST_F(DnsTransactionTest, HttpsPostWithNoType) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
SetResponseModifierCallback(base::BindRepeating(MakeResponseNoType));
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, HttpsCantLookupDohServers) {
ConfigDohServers(true /* clear_udp */, true /* use_post */, 2);
TransactionHelper helper0(kMockHostname, kT0Qtype, ERR_CONNECTION_REFUSED);
transaction_ids_.push_back(0);
transaction_ids_.push_back(1);
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
}
class CountingObserver : public net::NetLog::ThreadSafeObserver {
public:
CountingObserver() : count_(0), dict_count_(0) {}
~CountingObserver() override {
if (net_log())
net_log()->RemoveObserver(this);
}
void OnAddEntry(const NetLogEntry& entry) override {
++count_;
std::unique_ptr<base::Value> value = entry.ParametersToValue();
if (value && value->is_dict())
dict_count_++;
}
int count() const { return count_; }
int dict_count() const { return dict_count_; }
private:
int count_;
int dict_count_;
};
TEST_F(DnsTransactionTest, HttpsPostLookupWithLog) {
ConfigDohServers(true /* clear_udp */, true /* use_post */);
AddQueryAndResponse(0, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), SYNCHRONOUS,
Transport::HTTPS);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
CountingObserver observer;
helper0.net_log()->AddObserver(&observer,
NetLogCaptureMode::IncludeSocketBytes());
EXPECT_TRUE(helper0.RunUntilDone(transaction_factory_.get()));
base::RunLoop().RunUntilIdle();
EXPECT_EQ(observer.count(), 5);
EXPECT_EQ(observer.dict_count(), 3);
}
TEST_F(DnsTransactionTest, TCPLookup) {
base::HistogramTester histograms;
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
AddQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype, kT0ResponseDatagram,
arraysize(kT0ResponseDatagram), ASYNC, Transport::TCP);
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
histograms.ExpectUniqueSample("AsyncDNS.Rcode", dns_protocol::kRcodeNOERROR,
2);
}
TEST_F(DnsTransactionTest, TCPFailure) {
base::HistogramTester histograms;
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
AddQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeSERVFAIL, ASYNC,
Transport::TCP);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_SERVER_FAILED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
ASSERT_NE(helper0.response(), nullptr);
EXPECT_EQ(helper0.response()->rcode(), dns_protocol::kRcodeSERVFAIL);
histograms.ExpectBucketCount("AsyncDNS.Rcode", dns_protocol::kRcodeNOERROR,
1);
histograms.ExpectBucketCount("AsyncDNS.Rcode", dns_protocol::kRcodeSERVFAIL,
1);
histograms.ExpectTotalCount("AsyncDNS.Rcode", 2);
}
TEST_F(DnsTransactionTest, TCPMalformed) {
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
// Valid response but length too short.
// This must be truncated in the question section. The DnsResponse doesn't
// examine the answer section until asked to parse it, so truncating it in
// the answer section would result in the DnsTransaction itself succeeding.
data->AddResponseWithLength(
std::make_unique<DnsResponse>(
reinterpret_cast<const char*>(kT0ResponseDatagram),
arraysize(kT0ResponseDatagram), 0),
ASYNC, static_cast<uint16_t>(kT0QuerySize - 1));
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_MALFORMED_RESPONSE);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTestWithMockTime, TCPTimeout) {
ConfigureFactory();
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
AddSocketData(std::make_unique<DnsSocketData>(
1 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_DNS_TIMED_OUT);
EXPECT_FALSE(helper0.Run(transaction_factory_.get()));
FastForwardUntilNoTasksRemain();
EXPECT_TRUE(helper0.has_completed());
}
TEST_F(DnsTransactionTest, TCPReadReturnsZeroAsync) {
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
// Return all but the last byte of the response.
data->AddResponseWithLength(
std::make_unique<DnsResponse>(
reinterpret_cast<const char*>(kT0ResponseDatagram),
arraysize(kT0ResponseDatagram) - 1, 0),
ASYNC, static_cast<uint16_t>(arraysize(kT0ResponseDatagram)));
// Then return a 0-length read.
data->AddReadError(0, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_CONNECTION_CLOSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, TCPReadReturnsZeroSynchronous) {
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
// Return all but the last byte of the response.
data->AddResponseWithLength(
std::make_unique<DnsResponse>(
reinterpret_cast<const char*>(kT0ResponseDatagram),
arraysize(kT0ResponseDatagram) - 1, 0),
SYNCHRONOUS, static_cast<uint16_t>(arraysize(kT0ResponseDatagram)));
// Then return a 0-length read.
data->AddReadError(0, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_CONNECTION_CLOSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, TCPConnectionClosedAsync) {
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
data->AddReadError(ERR_CONNECTION_CLOSED, ASYNC);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_CONNECTION_CLOSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, TCPConnectionClosedSynchronous) {
AddAsyncQueryAndRcode(kT0HostName, kT0Qtype,
dns_protocol::kRcodeNOERROR | dns_protocol::kFlagTC);
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
data->AddReadError(ERR_CONNECTION_CLOSED, SYNCHRONOUS);
AddSocketData(std::move(data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_CONNECTION_CLOSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedThenNxdomainThenTCP) {
config_.attempts = 2;
ConfigureFactory();
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
// First attempt gets a mismatched response.
data->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
SYNCHRONOUS);
// Second read from first attempt gets TCP required.
data->AddRcode(dns_protocol::kFlagTC, ASYNC);
AddSocketData(std::move(data));
// Second attempt gets NXDOMAIN, which happens before the TCP required.
AddSyncQueryAndRcode(kT0HostName, kT0Qtype, dns_protocol::kRcodeNXDOMAIN);
std::unique_ptr<DnsSocketData> tcp_data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
tcp_data->AddReadError(ERR_CONNECTION_CLOSED, SYNCHRONOUS);
AddSocketData(std::move(tcp_data));
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_NAME_NOT_RESOLVED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedThenOkThenTCP) {
config_.attempts = 2;
ConfigureFactory();
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
// First attempt gets a mismatched response.
data->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
SYNCHRONOUS);
// Second read from first attempt gets TCP required.
data->AddRcode(dns_protocol::kFlagTC, ASYNC);
AddSocketData(std::move(data));
// Second attempt gets a valid response, which happens before the TCP
// required.
AddSyncQueryAndResponse(0 /* id */, kT0HostName, kT0Qtype,
kT0ResponseDatagram, arraysize(kT0ResponseDatagram));
std::unique_ptr<DnsSocketData> tcp_data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, ASYNC, Transport::TCP));
tcp_data->AddReadError(ERR_CONNECTION_CLOSED, SYNCHRONOUS);
AddSocketData(std::move(tcp_data));
TransactionHelper helper0(kT0HostName, kT0Qtype, kT0RecordCount);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, MismatchedThenRefusedThenTCP) {
// Set up the expected sequence of events:
// 1) First attempt (UDP) gets a synchronous mismatched response. On such
// malformed responses, DnsTransaction triggers an immediate retry to read
// again from the socket within the same "attempt".
// 2) Second read (within the first attempt) starts. Test is configured to
// give an asynchronous TCP required response which will complete later.
// On asynchronous action after a malformed response, the attempt will
// immediately produce a retriable error result while the retry continues,
// thus forking the running attempts.
// 3) Error result triggers a second attempt (UDP) which test gives a
// synchronous ERR_CONNECTION_REFUSED, which is a retriable error, but
// DnsTransaction has exhausted max retries (2 attempts), so this result
// gets posted as the result of the transaction and other running attempts
// should be cancelled.
// 4) First attempt should be cancelled when the transaction result is posted,
// so first attempt's second read should never complete. If it did
// complete, it would complete with a TCP-required error, and
// DnsTransaction would start a TCP attempt and clear previous attempts. It
// would be very bad if that then cleared the attempt posted as the final
// result, as result handling does not expect that memory to go away.
config_.attempts = 2;
ConfigureFactory();
// Attempt 1.
std::unique_ptr<DnsSocketData> data(new DnsSocketData(
0 /* id */, kT0HostName, kT0Qtype, SYNCHRONOUS, Transport::UDP));
data->AddResponseData(kT1ResponseDatagram, arraysize(kT1ResponseDatagram),
SYNCHRONOUS);
data->AddRcode(dns_protocol::kFlagTC, ASYNC);
AddSocketData(std::move(data));
// Attempt 2.
AddQueryAndErrorResponse(0 /* id */, kT0HostName, kT0Qtype,
ERR_CONNECTION_REFUSED, SYNCHRONOUS, Transport::UDP);
TransactionHelper helper0(kT0HostName, kT0Qtype, ERR_CONNECTION_REFUSED);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
}
TEST_F(DnsTransactionTest, InvalidQuery) {
ConfigureFactory();
TransactionHelper helper0(".", dns_protocol::kTypeA, ERR_INVALID_ARGUMENT);
EXPECT_TRUE(helper0.Run(transaction_factory_.get()));
TransactionHelper helper1("foo,bar.com", dns_protocol::kTypeA,
ERR_INVALID_ARGUMENT);
EXPECT_TRUE(helper1.Run(transaction_factory_.get()));
}
} // namespace
} // namespace net