//
// Copyright (C) 2012 The Android Open Source Project
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
#include <netinet/in.h>
#include <netinet/ip.h>
#include <sys/socket.h>
#include <unistd.h>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include <base/bind.h>
#include <base/location.h>
#include <base/logging.h>
#include <base/message_loop/message_loop.h>
#include <base/strings/string_number_conversions.h>
#include <base/strings/string_util.h>
#include <base/strings/stringprintf.h>
#include <base/time/time.h>
#include <brillo/bind_lambda.h>
#include <brillo/message_loops/base_message_loop.h>
#include <brillo/message_loops/message_loop.h>
#include <brillo/message_loops/message_loop_utils.h>
#include <brillo/process.h>
#include <brillo/streams/file_stream.h>
#include <brillo/streams/stream.h>
#include <gtest/gtest.h>
#include "update_engine/common/fake_hardware.h"
#include "update_engine/common/file_fetcher.h"
#include "update_engine/common/http_common.h"
#include "update_engine/common/mock_http_fetcher.h"
#include "update_engine/common/multi_range_http_fetcher.h"
#include "update_engine/common/test_utils.h"
#include "update_engine/common/utils.h"
#include "update_engine/libcurl_http_fetcher.h"
#include "update_engine/mock_proxy_resolver.h"
#include "update_engine/proxy_resolver.h"
using brillo::MessageLoop;
using std::make_pair;
using std::pair;
using std::string;
using std::unique_ptr;
using std::vector;
using testing::DoAll;
using testing::Return;
using testing::SaveArg;
using testing::_;
namespace {
const int kBigLength = 100000;
const int kMediumLength = 1000;
const int kFlakyTruncateLength = 29000;
const int kFlakySleepEvery = 3;
const int kFlakySleepSecs = 10;
} // namespace
namespace chromeos_update_engine {
static const char *kUnusedUrl = "unused://unused";
static inline string LocalServerUrlForPath(in_port_t port,
const string& path) {
string port_str = (port ? base::StringPrintf(":%hu", port) : "");
return base::StringPrintf("http://127.0.0.1%s%s", port_str.c_str(),
path.c_str());
}
//
// Class hierarchy for HTTP server implementations.
//
class HttpServer {
public:
// This makes it an abstract class (dirty but works).
virtual ~HttpServer() = 0;
virtual in_port_t GetPort() const {
return 0;
}
bool started_;
};
HttpServer::~HttpServer() {}
class NullHttpServer : public HttpServer {
public:
NullHttpServer() {
started_ = true;
}
};
class PythonHttpServer : public HttpServer {
public:
PythonHttpServer() : port_(0) {
started_ = false;
// Spawn the server process.
unique_ptr<brillo::Process> http_server(new brillo::ProcessImpl());
base::FilePath test_server_path =
test_utils::GetBuildArtifactsPath().Append("test_http_server");
http_server->AddArg(test_server_path.value());
http_server->RedirectUsingPipe(STDOUT_FILENO, false);
if (!http_server->Start()) {
ADD_FAILURE() << "failed to spawn http server process";
return;
}
LOG(INFO) << "started http server with pid " << http_server->pid();
// Wait for server to begin accepting connections, obtain its port.
brillo::StreamPtr stdout = brillo::FileStream::FromFileDescriptor(
http_server->GetPipe(STDOUT_FILENO), false /* own */, nullptr);
if (!stdout)
return;
vector<char> buf(128);
string line;
while (line.find('\n') == string::npos) {
size_t read;
if (!stdout->ReadBlocking(buf.data(), buf.size(), &read, nullptr)) {
ADD_FAILURE() << "error reading http server stdout";
return;
}
line.append(buf.data(), read);
if (read == 0)
break;
}
// Parse the port from the output line.
const size_t listening_msg_prefix_len = strlen(kServerListeningMsgPrefix);
if (line.size() < listening_msg_prefix_len) {
ADD_FAILURE() << "server output too short";
return;
}
EXPECT_EQ(kServerListeningMsgPrefix,
line.substr(0, listening_msg_prefix_len));
string port_str = line.substr(listening_msg_prefix_len);
port_str.resize(port_str.find('\n'));
EXPECT_TRUE(base::StringToUint(port_str, &port_));
started_ = true;
LOG(INFO) << "server running, listening on port " << port_;
// Any failure before this point will SIGKILL the test server if started
// when the |http_server| goes out of scope.
http_server_ = std::move(http_server);
}
~PythonHttpServer() {
// If there's no process, do nothing.
if (!http_server_)
return;
// Wait up to 10 seconds for the process to finish. Destroying the process
// will kill it with a SIGKILL otherwise.
http_server_->Kill(SIGTERM, 10);
}
in_port_t GetPort() const override {
return port_;
}
private:
static const char* kServerListeningMsgPrefix;
unique_ptr<brillo::Process> http_server_;
unsigned int port_;
};
const char* PythonHttpServer::kServerListeningMsgPrefix = "listening on port ";
//
// Class hierarchy for HTTP fetcher test wrappers.
//
class AnyHttpFetcherTest {
public:
AnyHttpFetcherTest() {}
virtual ~AnyHttpFetcherTest() {}
virtual HttpFetcher* NewLargeFetcher(ProxyResolver* proxy_resolver) = 0;
HttpFetcher* NewLargeFetcher(size_t num_proxies) {
proxy_resolver_.set_num_proxies(num_proxies);
return NewLargeFetcher(&proxy_resolver_);
}
HttpFetcher* NewLargeFetcher() {
return NewLargeFetcher(1);
}
virtual HttpFetcher* NewSmallFetcher(ProxyResolver* proxy_resolver) = 0;
HttpFetcher* NewSmallFetcher() {
proxy_resolver_.set_num_proxies(1);
return NewSmallFetcher(&proxy_resolver_);
}
virtual string BigUrl(in_port_t port) const { return kUnusedUrl; }
virtual string SmallUrl(in_port_t port) const { return kUnusedUrl; }
virtual string ErrorUrl(in_port_t port) const { return kUnusedUrl; }
virtual bool IsMock() const = 0;
virtual bool IsMulti() const = 0;
virtual bool IsHttpSupported() const = 0;
virtual void IgnoreServerAborting(HttpServer* server) const {}
virtual HttpServer* CreateServer() = 0;
FakeHardware* fake_hardware() {
return &fake_hardware_;
}
protected:
DirectProxyResolver proxy_resolver_;
FakeHardware fake_hardware_;
};
class MockHttpFetcherTest : public AnyHttpFetcherTest {
public:
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewLargeFetcher;
HttpFetcher* NewLargeFetcher(ProxyResolver* proxy_resolver) override {
brillo::Blob big_data(1000000);
return new MockHttpFetcher(
big_data.data(), big_data.size(), proxy_resolver);
}
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewSmallFetcher;
HttpFetcher* NewSmallFetcher(ProxyResolver* proxy_resolver) override {
return new MockHttpFetcher("x", 1, proxy_resolver);
}
bool IsMock() const override { return true; }
bool IsMulti() const override { return false; }
bool IsHttpSupported() const override { return true; }
HttpServer* CreateServer() override {
return new NullHttpServer;
}
};
class LibcurlHttpFetcherTest : public AnyHttpFetcherTest {
public:
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewLargeFetcher;
HttpFetcher* NewLargeFetcher(ProxyResolver* proxy_resolver) override {
LibcurlHttpFetcher* ret =
new LibcurlHttpFetcher(proxy_resolver, &fake_hardware_);
// Speed up test execution.
ret->set_idle_seconds(1);
ret->set_retry_seconds(1);
fake_hardware_.SetIsOfficialBuild(false);
return ret;
}
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewSmallFetcher;
HttpFetcher* NewSmallFetcher(ProxyResolver* proxy_resolver) override {
return NewLargeFetcher(proxy_resolver);
}
string BigUrl(in_port_t port) const override {
return LocalServerUrlForPath(port,
base::StringPrintf("/download/%d",
kBigLength));
}
string SmallUrl(in_port_t port) const override {
return LocalServerUrlForPath(port, "/foo");
}
string ErrorUrl(in_port_t port) const override {
return LocalServerUrlForPath(port, "/error");
}
bool IsMock() const override { return false; }
bool IsMulti() const override { return false; }
bool IsHttpSupported() const override { return true; }
void IgnoreServerAborting(HttpServer* server) const override {
// Nothing to do.
}
HttpServer* CreateServer() override {
return new PythonHttpServer;
}
};
class MultiRangeHttpFetcherTest : public LibcurlHttpFetcherTest {
public:
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewLargeFetcher;
HttpFetcher* NewLargeFetcher(ProxyResolver* proxy_resolver) override {
MultiRangeHttpFetcher* ret = new MultiRangeHttpFetcher(
new LibcurlHttpFetcher(proxy_resolver, &fake_hardware_));
ret->ClearRanges();
ret->AddRange(0);
// Speed up test execution.
ret->set_idle_seconds(1);
ret->set_retry_seconds(1);
fake_hardware_.SetIsOfficialBuild(false);
return ret;
}
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewSmallFetcher;
HttpFetcher* NewSmallFetcher(ProxyResolver* proxy_resolver) override {
return NewLargeFetcher(proxy_resolver);
}
bool IsMulti() const override { return true; }
};
class FileFetcherTest : public AnyHttpFetcherTest {
public:
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewLargeFetcher;
HttpFetcher* NewLargeFetcher(ProxyResolver* /* proxy_resolver */) override {
return new FileFetcher();
}
// Necessary to unhide the definition in the base class.
using AnyHttpFetcherTest::NewSmallFetcher;
HttpFetcher* NewSmallFetcher(ProxyResolver* proxy_resolver) override {
return NewLargeFetcher(proxy_resolver);
}
string BigUrl(in_port_t port) const override {
return "file://" + temp_file_.path();
}
string SmallUrl(in_port_t port) const override {
test_utils::WriteFileString(temp_file_.path(), "small contents");
return "file://" + temp_file_.path();
}
string ErrorUrl(in_port_t port) const override {
return "file:///path/to/non-existing-file";
}
bool IsMock() const override { return false; }
bool IsMulti() const override { return false; }
bool IsHttpSupported() const override { return false; }
void IgnoreServerAborting(HttpServer* server) const override {}
HttpServer* CreateServer() override { return new NullHttpServer; }
private:
test_utils::ScopedTempFile temp_file_{"ue_file_fetcher.XXXXXX"};
};
//
// Infrastructure for type tests of HTTP fetcher.
// See: http://code.google.com/p/googletest/wiki/AdvancedGuide#Typed_Tests
//
// Fixture class template. We use an explicit constraint to guarantee that it
// can only be instantiated with an AnyHttpFetcherTest type, see:
// http://www2.research.att.com/~bs/bs_faq2.html#constraints
template <typename T>
class HttpFetcherTest : public ::testing::Test {
public:
base::MessageLoopForIO base_loop_;
brillo::BaseMessageLoop loop_{&base_loop_};
T test_;
protected:
HttpFetcherTest() {
loop_.SetAsCurrent();
}
void TearDown() override {
EXPECT_EQ(0, brillo::MessageLoopRunMaxIterations(&loop_, 1));
}
private:
static void TypeConstraint(T* a) {
AnyHttpFetcherTest *b = a;
if (b == 0) // Silence compiler warning of unused variable.
*b = a;
}
};
// Test case types list.
typedef ::testing::Types<LibcurlHttpFetcherTest,
MockHttpFetcherTest,
MultiRangeHttpFetcherTest,
FileFetcherTest>
HttpFetcherTestTypes;
TYPED_TEST_CASE(HttpFetcherTest, HttpFetcherTestTypes);
namespace {
class HttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
HttpFetcherTestDelegate() = default;
void ReceivedBytes(HttpFetcher* /* fetcher */,
const void* bytes,
size_t length) override {
data.append(reinterpret_cast<const char*>(bytes), length);
// Update counters
times_received_bytes_called_++;
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
if (is_expect_error_)
EXPECT_EQ(kHttpResponseNotFound, fetcher->http_response_code());
else
EXPECT_EQ(kHttpResponseOk, fetcher->http_response_code());
MessageLoop::current()->BreakLoop();
// Update counter
times_transfer_complete_called_++;
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
times_transfer_terminated_called_++;
MessageLoop::current()->BreakLoop();
}
// Are we expecting an error response? (default: no)
bool is_expect_error_{false};
// Counters for callback invocations.
int times_transfer_complete_called_{0};
int times_transfer_terminated_called_{0};
int times_received_bytes_called_{0};
// The received data bytes.
string data;
};
void StartTransfer(HttpFetcher* http_fetcher, const string& url) {
http_fetcher->BeginTransfer(url);
}
} // namespace
TYPED_TEST(HttpFetcherTest, SimpleTest) {
HttpFetcherTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
this->loop_.PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
this->test_.SmallUrl(server->GetPort())));
this->loop_.Run();
}
TYPED_TEST(HttpFetcherTest, SimpleBigTest) {
HttpFetcherTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(this->test_.NewLargeFetcher());
fetcher->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
this->loop_.PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
this->test_.BigUrl(server->GetPort())));
this->loop_.Run();
}
// Issue #9648: when server returns an error HTTP response, the fetcher needs to
// terminate transfer prematurely, rather than try to process the error payload.
TYPED_TEST(HttpFetcherTest, ErrorTest) {
if (this->test_.IsMock() || this->test_.IsMulti())
return;
HttpFetcherTestDelegate delegate;
// Delegate should expect an error response.
delegate.is_expect_error_ = true;
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
this->loop_.PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
this->test_.ErrorUrl(server->GetPort())));
this->loop_.Run();
// Make sure that no bytes were received.
CHECK_EQ(delegate.times_received_bytes_called_, 0);
CHECK_EQ(fetcher->GetBytesDownloaded(), static_cast<size_t>(0));
// Make sure that transfer completion was signaled once, and no termination
// was signaled.
CHECK_EQ(delegate.times_transfer_complete_called_, 1);
CHECK_EQ(delegate.times_transfer_terminated_called_, 0);
}
TYPED_TEST(HttpFetcherTest, ExtraHeadersInRequestTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
HttpFetcherTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
fetcher->SetHeader("User-Agent", "MyTest");
fetcher->SetHeader("user-agent", "Override that header");
fetcher->SetHeader("Authorization", "Basic user:passwd");
// Invalid headers.
fetcher->SetHeader("X-Foo", "Invalid\nHeader\nIgnored");
fetcher->SetHeader("X-Bar: ", "I do not know how to parse");
// Hide Accept header normally added by default.
fetcher->SetHeader("Accept", "");
PythonHttpServer server;
int port = server.GetPort();
ASSERT_TRUE(server.started_);
this->loop_.PostTask(
FROM_HERE,
base::Bind(StartTransfer,
fetcher.get(),
LocalServerUrlForPath(port, "/echo-headers")));
this->loop_.Run();
EXPECT_NE(string::npos,
delegate.data.find("user-agent: Override that header\r\n"));
EXPECT_NE(string::npos,
delegate.data.find("Authorization: Basic user:passwd\r\n"));
EXPECT_EQ(string::npos, delegate.data.find("\nAccept:"));
EXPECT_EQ(string::npos, delegate.data.find("X-Foo: Invalid"));
EXPECT_EQ(string::npos, delegate.data.find("X-Bar: I do not"));
}
namespace {
class PausingHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
void ReceivedBytes(HttpFetcher* fetcher,
const void* /* bytes */, size_t /* length */) override {
CHECK(!paused_);
paused_ = true;
fetcher->Pause();
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
void Unpause() {
CHECK(paused_);
paused_ = false;
fetcher_->Unpause();
}
bool paused_;
HttpFetcher* fetcher_;
};
void UnpausingTimeoutCallback(PausingHttpFetcherTestDelegate* delegate,
MessageLoop::TaskId* my_id) {
if (delegate->paused_)
delegate->Unpause();
// Update the task id with the new scheduled callback.
*my_id = MessageLoop::current()->PostDelayedTask(
FROM_HERE,
base::Bind(&UnpausingTimeoutCallback, delegate, my_id),
base::TimeDelta::FromMilliseconds(200));
}
} // namespace
TYPED_TEST(HttpFetcherTest, PauseTest) {
PausingHttpFetcherTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(this->test_.NewLargeFetcher());
delegate.paused_ = false;
delegate.fetcher_ = fetcher.get();
fetcher->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
MessageLoop::TaskId callback_id;
callback_id = this->loop_.PostDelayedTask(
FROM_HERE,
base::Bind(&UnpausingTimeoutCallback, &delegate, &callback_id),
base::TimeDelta::FromMilliseconds(200));
fetcher->BeginTransfer(this->test_.BigUrl(server->GetPort()));
this->loop_.Run();
EXPECT_TRUE(this->loop_.CancelTask(callback_id));
}
// This test will pause the fetcher while the download is not yet started
// because it is waiting for the proxy to be resolved.
TYPED_TEST(HttpFetcherTest, PauseWhileResolvingProxyTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
MockProxyResolver mock_resolver;
unique_ptr<HttpFetcher> fetcher(this->test_.NewLargeFetcher(&mock_resolver));
// Saved arguments from the proxy call.
ProxiesResolvedFn proxy_callback = nullptr;
void* proxy_data = nullptr;
EXPECT_CALL(mock_resolver, GetProxiesForUrl("http://fake_url", _, _))
.WillOnce(DoAll(
SaveArg<1>(&proxy_callback), SaveArg<2>(&proxy_data), Return(true)));
fetcher->BeginTransfer("http://fake_url");
testing::Mock::VerifyAndClearExpectations(&mock_resolver);
// Pausing and unpausing while resolving the proxy should not affect anything.
fetcher->Pause();
fetcher->Unpause();
fetcher->Pause();
// Proxy resolver comes back after we paused the fetcher.
ASSERT_TRUE(proxy_callback);
(*proxy_callback)({1, kNoProxy}, proxy_data);
}
namespace {
class AbortingHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
ADD_FAILURE(); // We should never get here
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
EXPECT_EQ(fetcher, fetcher_.get());
EXPECT_FALSE(once_);
EXPECT_TRUE(callback_once_);
callback_once_ = false;
// The fetcher could have a callback scheduled on the ProxyResolver that
// can fire after this callback. We wait until the end of the test to
// delete the fetcher.
}
void TerminateTransfer() {
CHECK(once_);
once_ = false;
fetcher_->TerminateTransfer();
}
void EndLoop() {
MessageLoop::current()->BreakLoop();
}
bool once_;
bool callback_once_;
unique_ptr<HttpFetcher> fetcher_;
};
void AbortingTimeoutCallback(AbortingHttpFetcherTestDelegate* delegate,
MessageLoop::TaskId* my_id) {
if (delegate->once_) {
delegate->TerminateTransfer();
*my_id = MessageLoop::current()->PostTask(
FROM_HERE,
base::Bind(AbortingTimeoutCallback, delegate, my_id));
} else {
delegate->EndLoop();
*my_id = MessageLoop::kTaskIdNull;
}
}
} // namespace
TYPED_TEST(HttpFetcherTest, AbortTest) {
AbortingHttpFetcherTestDelegate delegate;
delegate.fetcher_.reset(this->test_.NewLargeFetcher());
delegate.once_ = true;
delegate.callback_once_ = true;
delegate.fetcher_->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
this->test_.IgnoreServerAborting(server.get());
ASSERT_TRUE(server->started_);
MessageLoop::TaskId task_id = MessageLoop::kTaskIdNull;
task_id = this->loop_.PostTask(
FROM_HERE,
base::Bind(AbortingTimeoutCallback, &delegate, &task_id));
delegate.fetcher_->BeginTransfer(this->test_.BigUrl(server->GetPort()));
this->loop_.Run();
CHECK(!delegate.once_);
CHECK(!delegate.callback_once_);
this->loop_.CancelTask(task_id);
}
namespace {
class FlakyHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {
data.append(reinterpret_cast<const char*>(bytes), length);
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
EXPECT_TRUE(successful);
EXPECT_EQ(kHttpResponsePartialContent, fetcher->http_response_code());
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
string data;
};
} // namespace
TYPED_TEST(HttpFetcherTest, FlakyTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
{
FlakyHttpFetcherTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
this->loop_.PostTask(FROM_HERE, base::Bind(
&StartTransfer,
fetcher.get(),
LocalServerUrlForPath(server->GetPort(),
base::StringPrintf("/flaky/%d/%d/%d/%d",
kBigLength,
kFlakyTruncateLength,
kFlakySleepEvery,
kFlakySleepSecs))));
this->loop_.Run();
// verify the data we get back
ASSERT_EQ(kBigLength, static_cast<int>(delegate.data.size()));
for (int i = 0; i < kBigLength; i += 10) {
// Assert so that we don't flood the screen w/ EXPECT errors on failure.
ASSERT_EQ(delegate.data.substr(i, 10), "abcdefghij");
}
}
}
namespace {
// This delegate kills the server attached to it after receiving any bytes.
// This can be used for testing what happens when you try to fetch data and
// the server dies.
class FailureHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
explicit FailureHttpFetcherTestDelegate(PythonHttpServer* server)
: server_(server) {}
~FailureHttpFetcherTestDelegate() override {
if (server_) {
LOG(INFO) << "Stopping server in destructor";
delete server_;
LOG(INFO) << "server stopped";
}
}
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {
if (server_) {
LOG(INFO) << "Stopping server in ReceivedBytes";
delete server_;
LOG(INFO) << "server stopped";
server_ = nullptr;
}
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
EXPECT_FALSE(successful);
EXPECT_EQ(0, fetcher->http_response_code());
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
PythonHttpServer* server_;
};
} // namespace
TYPED_TEST(HttpFetcherTest, FailureTest) {
// This test ensures that a fetcher responds correctly when a server isn't
// available at all.
if (this->test_.IsMock())
return;
{
FailureHttpFetcherTestDelegate delegate(nullptr);
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
this->loop_.PostTask(FROM_HERE,
base::Bind(StartTransfer,
fetcher.get(),
"http://host_doesnt_exist99999999"));
this->loop_.Run();
// Exiting and testing happens in the delegate
}
}
TYPED_TEST(HttpFetcherTest, NoResponseTest) {
// This test starts a new http server but the server doesn't respond and just
// closes the connection.
if (this->test_.IsMock())
return;
PythonHttpServer* server = new PythonHttpServer();
int port = server->GetPort();
ASSERT_TRUE(server->started_);
// Handles destruction and claims ownership.
FailureHttpFetcherTestDelegate delegate(server);
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
// The server will not reply at all, so we can limit the execution time of the
// test by reducing the low-speed timeout to something small. The test will
// finish once the TimeoutCallback() triggers (every second) and the timeout
// expired.
fetcher->set_low_speed_limit(kDownloadLowSpeedLimitBps, 1);
this->loop_.PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
LocalServerUrlForPath(port, "/hang")));
this->loop_.Run();
// Check that no other callback runs in the next two seconds. That would
// indicate a leaked callback.
bool timeout = false;
auto callback = base::Bind([&timeout]{ timeout = true;});
this->loop_.PostDelayedTask(FROM_HERE, callback,
base::TimeDelta::FromSeconds(2));
EXPECT_TRUE(this->loop_.RunOnce(true));
EXPECT_TRUE(timeout);
}
TYPED_TEST(HttpFetcherTest, ServerDiesTest) {
// This test starts a new http server and kills it after receiving its first
// set of bytes. It test whether or not our fetcher eventually gives up on
// retries and aborts correctly.
if (this->test_.IsMock())
return;
{
PythonHttpServer* server = new PythonHttpServer();
int port = server->GetPort();
ASSERT_TRUE(server->started_);
// Handles destruction and claims ownership.
FailureHttpFetcherTestDelegate delegate(server);
unique_ptr<HttpFetcher> fetcher(this->test_.NewSmallFetcher());
fetcher->set_delegate(&delegate);
this->loop_.PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
LocalServerUrlForPath(port,
base::StringPrintf("/flaky/%d/%d/%d/%d",
kBigLength,
kFlakyTruncateLength,
kFlakySleepEvery,
kFlakySleepSecs))));
this->loop_.Run();
// Exiting and testing happens in the delegate
}
}
namespace {
const HttpResponseCode kRedirectCodes[] = {
kHttpResponseMovedPermanently, kHttpResponseFound, kHttpResponseSeeOther,
kHttpResponseTempRedirect
};
class RedirectHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
explicit RedirectHttpFetcherTestDelegate(bool expected_successful)
: expected_successful_(expected_successful) {}
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {
data.append(reinterpret_cast<const char*>(bytes), length);
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
EXPECT_EQ(expected_successful_, successful);
if (expected_successful_) {
EXPECT_EQ(kHttpResponseOk, fetcher->http_response_code());
} else {
EXPECT_GE(fetcher->http_response_code(), kHttpResponseMovedPermanently);
EXPECT_LE(fetcher->http_response_code(), kHttpResponseTempRedirect);
}
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
bool expected_successful_;
string data;
};
// RedirectTest takes ownership of |http_fetcher|.
void RedirectTest(const HttpServer* server,
bool expected_successful,
const string& url,
HttpFetcher* http_fetcher) {
RedirectHttpFetcherTestDelegate delegate(expected_successful);
unique_ptr<HttpFetcher> fetcher(http_fetcher);
fetcher->set_delegate(&delegate);
MessageLoop::current()->PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
LocalServerUrlForPath(server->GetPort(), url)));
MessageLoop::current()->Run();
if (expected_successful) {
// verify the data we get back
ASSERT_EQ(static_cast<size_t>(kMediumLength), delegate.data.size());
for (int i = 0; i < kMediumLength; i += 10) {
// Assert so that we don't flood the screen w/ EXPECT errors on failure.
ASSERT_EQ(delegate.data.substr(i, 10), "abcdefghij");
}
}
}
} // namespace
TYPED_TEST(HttpFetcherTest, SimpleRedirectTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
for (size_t c = 0; c < arraysize(kRedirectCodes); ++c) {
const string url = base::StringPrintf("/redirect/%d/download/%d",
kRedirectCodes[c],
kMediumLength);
RedirectTest(server.get(), true, url, this->test_.NewLargeFetcher());
}
}
TYPED_TEST(HttpFetcherTest, MaxRedirectTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
string url;
for (int r = 0; r < kDownloadMaxRedirects; r++) {
url += base::StringPrintf("/redirect/%d",
kRedirectCodes[r % arraysize(kRedirectCodes)]);
}
url += base::StringPrintf("/download/%d", kMediumLength);
RedirectTest(server.get(), true, url, this->test_.NewLargeFetcher());
}
TYPED_TEST(HttpFetcherTest, BeyondMaxRedirectTest) {
if (this->test_.IsMock() || !this->test_.IsHttpSupported())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
string url;
for (int r = 0; r < kDownloadMaxRedirects + 1; r++) {
url += base::StringPrintf("/redirect/%d",
kRedirectCodes[r % arraysize(kRedirectCodes)]);
}
url += base::StringPrintf("/download/%d", kMediumLength);
RedirectTest(server.get(), false, url, this->test_.NewLargeFetcher());
}
namespace {
class MultiHttpFetcherTestDelegate : public HttpFetcherDelegate {
public:
explicit MultiHttpFetcherTestDelegate(int expected_response_code)
: expected_response_code_(expected_response_code) {}
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {
EXPECT_EQ(fetcher, fetcher_.get());
data.append(reinterpret_cast<const char*>(bytes), length);
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
EXPECT_EQ(fetcher, fetcher_.get());
EXPECT_EQ(expected_response_code_ != kHttpResponseUndefined, successful);
if (expected_response_code_ != 0)
EXPECT_EQ(expected_response_code_, fetcher->http_response_code());
// Destroy the fetcher (because we're allowed to).
fetcher_.reset(nullptr);
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
unique_ptr<HttpFetcher> fetcher_;
int expected_response_code_;
string data;
};
void MultiTest(HttpFetcher* fetcher_in,
FakeHardware* fake_hardware,
const string& url,
const vector<pair<off_t, off_t>>& ranges,
const string& expected_prefix,
size_t expected_size,
HttpResponseCode expected_response_code) {
MultiHttpFetcherTestDelegate delegate(expected_response_code);
delegate.fetcher_.reset(fetcher_in);
MultiRangeHttpFetcher* multi_fetcher =
static_cast<MultiRangeHttpFetcher*>(fetcher_in);
ASSERT_TRUE(multi_fetcher);
multi_fetcher->ClearRanges();
for (vector<pair<off_t, off_t>>::const_iterator it = ranges.begin(),
e = ranges.end(); it != e; ++it) {
string tmp_str = base::StringPrintf("%jd+", it->first);
if (it->second > 0) {
base::StringAppendF(&tmp_str, "%jd", it->second);
multi_fetcher->AddRange(it->first, it->second);
} else {
base::StringAppendF(&tmp_str, "?");
multi_fetcher->AddRange(it->first);
}
LOG(INFO) << "added range: " << tmp_str;
}
fake_hardware->SetIsOfficialBuild(false);
multi_fetcher->set_delegate(&delegate);
MessageLoop::current()->PostTask(
FROM_HERE,
base::Bind(StartTransfer, multi_fetcher, url));
MessageLoop::current()->Run();
EXPECT_EQ(expected_size, delegate.data.size());
EXPECT_EQ(expected_prefix,
string(delegate.data.data(), expected_prefix.size()));
}
} // namespace
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherSimpleTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(0, 25));
ranges.push_back(make_pair(99, 0));
MultiTest(this->test_.NewLargeFetcher(),
this->test_.fake_hardware(),
this->test_.BigUrl(server->GetPort()),
ranges,
"abcdefghijabcdefghijabcdejabcdefghijabcdef",
kBigLength - (99 - 25),
kHttpResponsePartialContent);
}
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherLengthLimitTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(0, 24));
MultiTest(this->test_.NewLargeFetcher(),
this->test_.fake_hardware(),
this->test_.BigUrl(server->GetPort()),
ranges,
"abcdefghijabcdefghijabcd",
24,
kHttpResponsePartialContent);
}
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherMultiEndTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(kBigLength - 2, 0));
ranges.push_back(make_pair(kBigLength - 3, 0));
MultiTest(this->test_.NewLargeFetcher(),
this->test_.fake_hardware(),
this->test_.BigUrl(server->GetPort()),
ranges,
"ijhij",
5,
kHttpResponsePartialContent);
}
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherInsufficientTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(kBigLength - 2, 4));
for (int i = 0; i < 2; ++i) {
LOG(INFO) << "i = " << i;
MultiTest(this->test_.NewLargeFetcher(),
this->test_.fake_hardware(),
this->test_.BigUrl(server->GetPort()),
ranges,
"ij",
2,
kHttpResponseUndefined);
ranges.push_back(make_pair(0, 5));
}
}
// Issue #18143: when a fetch of a secondary chunk out of a chain, then it
// should retry with other proxies listed before giving up.
//
// (1) successful recovery: The offset fetch will fail twice but succeed with
// the third proxy.
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherErrorIfOffsetRecoverableTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(0, 25));
ranges.push_back(make_pair(99, 0));
MultiTest(this->test_.NewLargeFetcher(3),
this->test_.fake_hardware(),
LocalServerUrlForPath(server->GetPort(),
base::StringPrintf("/error-if-offset/%d/2",
kBigLength)),
ranges,
"abcdefghijabcdefghijabcdejabcdefghijabcdef",
kBigLength - (99 - 25),
kHttpResponsePartialContent);
}
// (2) unsuccessful recovery: The offset fetch will fail repeatedly. The
// fetcher will signal a (failed) completed transfer to the delegate.
TYPED_TEST(HttpFetcherTest, MultiHttpFetcherErrorIfOffsetUnrecoverableTest) {
if (!this->test_.IsMulti())
return;
unique_ptr<HttpServer> server(this->test_.CreateServer());
ASSERT_TRUE(server->started_);
vector<pair<off_t, off_t>> ranges;
ranges.push_back(make_pair(0, 25));
ranges.push_back(make_pair(99, 0));
MultiTest(this->test_.NewLargeFetcher(2),
this->test_.fake_hardware(),
LocalServerUrlForPath(server->GetPort(),
base::StringPrintf("/error-if-offset/%d/3",
kBigLength)),
ranges,
"abcdefghijabcdefghijabcde", // only received the first chunk
25,
kHttpResponseUndefined);
}
namespace {
class BlockedTransferTestDelegate : public HttpFetcherDelegate {
public:
void ReceivedBytes(HttpFetcher* fetcher,
const void* bytes, size_t length) override {
ADD_FAILURE();
}
void TransferComplete(HttpFetcher* fetcher, bool successful) override {
EXPECT_FALSE(successful);
MessageLoop::current()->BreakLoop();
}
void TransferTerminated(HttpFetcher* fetcher) override {
ADD_FAILURE();
}
};
void BlockedTransferTestHelper(AnyHttpFetcherTest* fetcher_test,
bool is_official_build) {
if (fetcher_test->IsMock() || fetcher_test->IsMulti())
return;
unique_ptr<HttpServer> server(fetcher_test->CreateServer());
ASSERT_TRUE(server->started_);
BlockedTransferTestDelegate delegate;
unique_ptr<HttpFetcher> fetcher(fetcher_test->NewLargeFetcher());
LOG(INFO) << "is_official_build: " << is_official_build;
// NewLargeFetcher creates the HttpFetcher* with a FakeSystemState.
fetcher_test->fake_hardware()->SetIsOfficialBuild(is_official_build);
fetcher->set_delegate(&delegate);
MessageLoop::current()->PostTask(FROM_HERE, base::Bind(
StartTransfer,
fetcher.get(),
LocalServerUrlForPath(server->GetPort(),
fetcher_test->SmallUrl(server->GetPort()))));
MessageLoop::current()->Run();
}
} // namespace
TYPED_TEST(HttpFetcherTest, BlockedTransferTest) {
BlockedTransferTestHelper(&this->test_, false);
}
TYPED_TEST(HttpFetcherTest, BlockedTransferOfficialBuildTest) {
BlockedTransferTestHelper(&this->test_, true);
}
} // namespace chromeos_update_engine