//
// 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 "update_engine/update_attempter.h"
#include <stdint.h>
#include <memory>
#include <base/files/file_util.h>
#include <base/message_loop/message_loop.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 <gtest/gtest.h>
#include <policy/libpolicy.h>
#include <policy/mock_device_policy.h>
#include "update_engine/common/fake_clock.h"
#include "update_engine/common/fake_prefs.h"
#include "update_engine/common/mock_action.h"
#include "update_engine/common/mock_action_processor.h"
#include "update_engine/common/mock_http_fetcher.h"
#include "update_engine/common/mock_prefs.h"
#include "update_engine/common/platform_constants.h"
#include "update_engine/common/prefs.h"
#include "update_engine/common/test_utils.h"
#include "update_engine/common/utils.h"
#include "update_engine/fake_system_state.h"
#include "update_engine/mock_p2p_manager.h"
#include "update_engine/mock_payload_state.h"
#include "update_engine/mock_service_observer.h"
#include "update_engine/payload_consumer/filesystem_verifier_action.h"
#include "update_engine/payload_consumer/install_plan.h"
#include "update_engine/payload_consumer/payload_constants.h"
#include "update_engine/payload_consumer/postinstall_runner_action.h"
using base::Time;
using base::TimeDelta;
using chromeos_update_manager::EvalStatus;
using chromeos_update_manager::UpdateCheckParams;
using std::string;
using std::unique_ptr;
using testing::_;
using testing::DoAll;
using testing::Field;
using testing::InSequence;
using testing::Ne;
using testing::NiceMock;
using testing::Property;
using testing::Return;
using testing::ReturnPointee;
using testing::SaveArg;
using testing::SetArgPointee;
using update_engine::UpdateAttemptFlags;
using update_engine::UpdateEngineStatus;
using update_engine::UpdateStatus;
namespace chromeos_update_engine {
// Test a subclass rather than the main class directly so that we can mock out
// methods within the class. There're explicit unit tests for the mocked out
// methods.
class UpdateAttempterUnderTest : public UpdateAttempter {
public:
explicit UpdateAttempterUnderTest(SystemState* system_state)
: UpdateAttempter(system_state, nullptr) {}
// Wrap the update scheduling method, allowing us to opt out of scheduled
// updates for testing purposes.
void ScheduleUpdates() override {
schedule_updates_called_ = true;
if (do_schedule_updates_) {
UpdateAttempter::ScheduleUpdates();
} else {
LOG(INFO) << "[TEST] Update scheduling disabled.";
}
}
void EnableScheduleUpdates() { do_schedule_updates_ = true; }
void DisableScheduleUpdates() { do_schedule_updates_ = false; }
// Indicates whether ScheduleUpdates() was called.
bool schedule_updates_called() const { return schedule_updates_called_; }
// Need to expose forced_omaha_url_ so we can test it.
const string& forced_omaha_url() const { return forced_omaha_url_; }
private:
bool schedule_updates_called_ = false;
bool do_schedule_updates_ = true;
};
class UpdateAttempterTest : public ::testing::Test {
protected:
UpdateAttempterTest()
: certificate_checker_(fake_system_state_.mock_prefs(),
&openssl_wrapper_) {
// Override system state members.
fake_system_state_.set_connection_manager(&mock_connection_manager);
fake_system_state_.set_update_attempter(&attempter_);
loop_.SetAsCurrent();
certificate_checker_.Init();
// Finish initializing the attempter.
attempter_.Init();
}
void SetUp() override {
EXPECT_NE(nullptr, attempter_.system_state_);
EXPECT_EQ(0, attempter_.http_response_code_);
EXPECT_EQ(UpdateStatus::IDLE, attempter_.status_);
EXPECT_EQ(0.0, attempter_.download_progress_);
EXPECT_EQ(0, attempter_.last_checked_time_);
EXPECT_EQ("0.0.0.0", attempter_.new_version_);
EXPECT_EQ(0ULL, attempter_.new_payload_size_);
processor_ = new NiceMock<MockActionProcessor>();
attempter_.processor_.reset(processor_); // Transfers ownership.
prefs_ = fake_system_state_.mock_prefs();
// Set up store/load semantics of P2P properties via the mock PayloadState.
actual_using_p2p_for_downloading_ = false;
EXPECT_CALL(*fake_system_state_.mock_payload_state(),
SetUsingP2PForDownloading(_))
.WillRepeatedly(SaveArg<0>(&actual_using_p2p_for_downloading_));
EXPECT_CALL(*fake_system_state_.mock_payload_state(),
GetUsingP2PForDownloading())
.WillRepeatedly(ReturnPointee(&actual_using_p2p_for_downloading_));
actual_using_p2p_for_sharing_ = false;
EXPECT_CALL(*fake_system_state_.mock_payload_state(),
SetUsingP2PForSharing(_))
.WillRepeatedly(SaveArg<0>(&actual_using_p2p_for_sharing_));
EXPECT_CALL(*fake_system_state_.mock_payload_state(),
GetUsingP2PForDownloading())
.WillRepeatedly(ReturnPointee(&actual_using_p2p_for_sharing_));
}
public:
void ScheduleQuitMainLoop();
// Callbacks to run the different tests from the main loop.
void UpdateTestStart();
void UpdateTestVerify();
void RollbackTestStart(bool enterprise_rollback, bool valid_slot);
void RollbackTestVerify();
void PingOmahaTestStart();
void ReadScatterFactorFromPolicyTestStart();
void DecrementUpdateCheckCountTestStart();
void NoScatteringDoneDuringManualUpdateTestStart();
void P2PNotEnabledStart();
void P2PEnabledStart();
void P2PEnabledInteractiveStart();
void P2PEnabledStartingFailsStart();
void P2PEnabledHousekeepingFailsStart();
bool actual_using_p2p_for_downloading() {
return actual_using_p2p_for_downloading_;
}
bool actual_using_p2p_for_sharing() {
return actual_using_p2p_for_sharing_;
}
base::MessageLoopForIO base_loop_;
brillo::BaseMessageLoop loop_{&base_loop_};
FakeSystemState fake_system_state_;
UpdateAttempterUnderTest attempter_{&fake_system_state_};
OpenSSLWrapper openssl_wrapper_;
CertificateChecker certificate_checker_;
NiceMock<MockActionProcessor>* processor_;
NiceMock<MockPrefs>* prefs_; // Shortcut to fake_system_state_->mock_prefs().
NiceMock<MockConnectionManager> mock_connection_manager;
bool actual_using_p2p_for_downloading_;
bool actual_using_p2p_for_sharing_;
};
void UpdateAttempterTest::ScheduleQuitMainLoop() {
loop_.PostTask(
FROM_HERE,
base::Bind([](brillo::BaseMessageLoop* loop) { loop->BreakLoop(); },
base::Unretained(&loop_)));
}
TEST_F(UpdateAttempterTest, ActionCompletedDownloadTest) {
unique_ptr<MockHttpFetcher> fetcher(new MockHttpFetcher("", 0, nullptr));
fetcher->FailTransfer(503); // Sets the HTTP response code.
DownloadAction action(prefs_,
nullptr,
nullptr,
nullptr,
fetcher.release(),
false /* is_interactive */);
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _)).Times(0);
attempter_.ActionCompleted(nullptr, &action, ErrorCode::kSuccess);
EXPECT_EQ(UpdateStatus::FINALIZING, attempter_.status());
EXPECT_EQ(0.0, attempter_.download_progress_);
ASSERT_EQ(nullptr, attempter_.error_event_.get());
}
TEST_F(UpdateAttempterTest, ActionCompletedErrorTest) {
MockAction action;
EXPECT_CALL(action, Type()).WillRepeatedly(Return("MockAction"));
attempter_.status_ = UpdateStatus::DOWNLOADING;
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _))
.WillOnce(Return(false));
attempter_.ActionCompleted(nullptr, &action, ErrorCode::kError);
ASSERT_NE(nullptr, attempter_.error_event_.get());
}
TEST_F(UpdateAttempterTest, DownloadProgressAccumulationTest) {
// Simple test case, where all the values match (nothing was skipped)
uint64_t bytes_progressed_1 = 1024 * 1024; // 1MB
uint64_t bytes_progressed_2 = 1024 * 1024; // 1MB
uint64_t bytes_received_1 = bytes_progressed_1;
uint64_t bytes_received_2 = bytes_received_1 + bytes_progressed_2;
uint64_t bytes_total = 20 * 1024 * 1024; // 20MB
double progress_1 =
static_cast<double>(bytes_received_1) / static_cast<double>(bytes_total);
double progress_2 =
static_cast<double>(bytes_received_2) / static_cast<double>(bytes_total);
EXPECT_EQ(0.0, attempter_.download_progress_);
// This is set via inspecting the InstallPlan payloads when the
// OmahaResponseAction is completed
attempter_.new_payload_size_ = bytes_total;
NiceMock<MockServiceObserver> observer;
EXPECT_CALL(observer,
SendStatusUpdate(AllOf(
Field(&UpdateEngineStatus::progress, progress_1),
Field(&UpdateEngineStatus::status, UpdateStatus::DOWNLOADING),
Field(&UpdateEngineStatus::new_size_bytes, bytes_total))));
EXPECT_CALL(observer,
SendStatusUpdate(AllOf(
Field(&UpdateEngineStatus::progress, progress_2),
Field(&UpdateEngineStatus::status, UpdateStatus::DOWNLOADING),
Field(&UpdateEngineStatus::new_size_bytes, bytes_total))));
attempter_.AddObserver(&observer);
attempter_.BytesReceived(bytes_progressed_1, bytes_received_1, bytes_total);
EXPECT_EQ(progress_1, attempter_.download_progress_);
// This iteration validates that a later set of updates to the variables are
// properly handled (so that |getStatus()| will return the same progress info
// as the callback is receiving.
attempter_.BytesReceived(bytes_progressed_2, bytes_received_2, bytes_total);
EXPECT_EQ(progress_2, attempter_.download_progress_);
}
TEST_F(UpdateAttempterTest, ChangeToDownloadingOnReceivedBytesTest) {
// The transition into UpdateStatus::DOWNLOADING happens when the
// first bytes are received.
uint64_t bytes_progressed = 1024 * 1024; // 1MB
uint64_t bytes_received = 2 * 1024 * 1024; // 2MB
uint64_t bytes_total = 20 * 1024 * 1024; // 300MB
attempter_.status_ = UpdateStatus::CHECKING_FOR_UPDATE;
// This is set via inspecting the InstallPlan payloads when the
// OmahaResponseAction is completed
attempter_.new_payload_size_ = bytes_total;
EXPECT_EQ(0.0, attempter_.download_progress_);
NiceMock<MockServiceObserver> observer;
EXPECT_CALL(observer,
SendStatusUpdate(AllOf(
Field(&UpdateEngineStatus::status, UpdateStatus::DOWNLOADING),
Field(&UpdateEngineStatus::new_size_bytes, bytes_total))));
attempter_.AddObserver(&observer);
attempter_.BytesReceived(bytes_progressed, bytes_received, bytes_total);
EXPECT_EQ(UpdateStatus::DOWNLOADING, attempter_.status_);
}
TEST_F(UpdateAttempterTest, BroadcastCompleteDownloadTest) {
// There is a special case to ensure that at 100% downloaded,
// download_progress_ is updated and that value broadcast. This test confirms
// that.
uint64_t bytes_progressed = 0; // ignored
uint64_t bytes_received = 5 * 1024 * 1024; // ignored
uint64_t bytes_total = 5 * 1024 * 1024; // 300MB
attempter_.status_ = UpdateStatus::DOWNLOADING;
attempter_.new_payload_size_ = bytes_total;
EXPECT_EQ(0.0, attempter_.download_progress_);
NiceMock<MockServiceObserver> observer;
EXPECT_CALL(observer,
SendStatusUpdate(AllOf(
Field(&UpdateEngineStatus::progress, 1.0),
Field(&UpdateEngineStatus::status, UpdateStatus::DOWNLOADING),
Field(&UpdateEngineStatus::new_size_bytes, bytes_total))));
attempter_.AddObserver(&observer);
attempter_.BytesReceived(bytes_progressed, bytes_received, bytes_total);
EXPECT_EQ(1.0, attempter_.download_progress_);
}
TEST_F(UpdateAttempterTest, ActionCompletedOmahaRequestTest) {
unique_ptr<MockHttpFetcher> fetcher(new MockHttpFetcher("", 0, nullptr));
fetcher->FailTransfer(500); // Sets the HTTP response code.
OmahaRequestAction action(&fake_system_state_, nullptr,
std::move(fetcher), false);
ObjectCollectorAction<OmahaResponse> collector_action;
BondActions(&action, &collector_action);
OmahaResponse response;
response.poll_interval = 234;
action.SetOutputObject(response);
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _)).Times(0);
attempter_.ActionCompleted(nullptr, &action, ErrorCode::kSuccess);
EXPECT_EQ(500, attempter_.http_response_code());
EXPECT_EQ(UpdateStatus::IDLE, attempter_.status());
EXPECT_EQ(234U, attempter_.server_dictated_poll_interval_);
ASSERT_TRUE(attempter_.error_event_.get() == nullptr);
}
TEST_F(UpdateAttempterTest, ConstructWithUpdatedMarkerTest) {
FakePrefs fake_prefs;
string boot_id;
EXPECT_TRUE(utils::GetBootId(&boot_id));
fake_prefs.SetString(kPrefsUpdateCompletedOnBootId, boot_id);
fake_system_state_.set_prefs(&fake_prefs);
attempter_.Init();
EXPECT_EQ(UpdateStatus::UPDATED_NEED_REBOOT, attempter_.status());
}
TEST_F(UpdateAttempterTest, GetErrorCodeForActionTest) {
extern ErrorCode GetErrorCodeForAction(AbstractAction* action,
ErrorCode code);
EXPECT_EQ(ErrorCode::kSuccess,
GetErrorCodeForAction(nullptr, ErrorCode::kSuccess));
FakeSystemState fake_system_state;
OmahaRequestAction omaha_request_action(&fake_system_state, nullptr,
nullptr, false);
EXPECT_EQ(ErrorCode::kOmahaRequestError,
GetErrorCodeForAction(&omaha_request_action, ErrorCode::kError));
OmahaResponseHandlerAction omaha_response_handler_action(&fake_system_state_);
EXPECT_EQ(ErrorCode::kOmahaResponseHandlerError,
GetErrorCodeForAction(&omaha_response_handler_action,
ErrorCode::kError));
FilesystemVerifierAction filesystem_verifier_action;
EXPECT_EQ(ErrorCode::kFilesystemVerifierError,
GetErrorCodeForAction(&filesystem_verifier_action,
ErrorCode::kError));
PostinstallRunnerAction postinstall_runner_action(
fake_system_state.fake_boot_control(), fake_system_state.fake_hardware());
EXPECT_EQ(ErrorCode::kPostinstallRunnerError,
GetErrorCodeForAction(&postinstall_runner_action,
ErrorCode::kError));
MockAction action_mock;
EXPECT_CALL(action_mock, Type()).WillOnce(Return("MockAction"));
EXPECT_EQ(ErrorCode::kError,
GetErrorCodeForAction(&action_mock, ErrorCode::kError));
}
TEST_F(UpdateAttempterTest, DisableDeltaUpdateIfNeededTest) {
attempter_.omaha_request_params_->set_delta_okay(true);
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _))
.WillOnce(Return(false));
attempter_.DisableDeltaUpdateIfNeeded();
EXPECT_TRUE(attempter_.omaha_request_params_->delta_okay());
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _))
.WillOnce(DoAll(
SetArgPointee<1>(UpdateAttempter::kMaxDeltaUpdateFailures - 1),
Return(true)));
attempter_.DisableDeltaUpdateIfNeeded();
EXPECT_TRUE(attempter_.omaha_request_params_->delta_okay());
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _))
.WillOnce(DoAll(
SetArgPointee<1>(UpdateAttempter::kMaxDeltaUpdateFailures),
Return(true)));
attempter_.DisableDeltaUpdateIfNeeded();
EXPECT_FALSE(attempter_.omaha_request_params_->delta_okay());
EXPECT_CALL(*prefs_, GetInt64(_, _)).Times(0);
attempter_.DisableDeltaUpdateIfNeeded();
EXPECT_FALSE(attempter_.omaha_request_params_->delta_okay());
}
TEST_F(UpdateAttempterTest, MarkDeltaUpdateFailureTest) {
EXPECT_CALL(*prefs_, GetInt64(kPrefsDeltaUpdateFailures, _))
.WillOnce(Return(false))
.WillOnce(DoAll(SetArgPointee<1>(-1), Return(true)))
.WillOnce(DoAll(SetArgPointee<1>(1), Return(true)))
.WillOnce(DoAll(
SetArgPointee<1>(UpdateAttempter::kMaxDeltaUpdateFailures),
Return(true)));
EXPECT_CALL(*prefs_, SetInt64(Ne(kPrefsDeltaUpdateFailures), _))
.WillRepeatedly(Return(true));
EXPECT_CALL(*prefs_, SetInt64(kPrefsDeltaUpdateFailures, 1)).Times(2);
EXPECT_CALL(*prefs_, SetInt64(kPrefsDeltaUpdateFailures, 2));
EXPECT_CALL(*prefs_, SetInt64(kPrefsDeltaUpdateFailures,
UpdateAttempter::kMaxDeltaUpdateFailures + 1));
for (int i = 0; i < 4; i ++)
attempter_.MarkDeltaUpdateFailure();
}
TEST_F(UpdateAttempterTest, ScheduleErrorEventActionNoEventTest) {
EXPECT_CALL(*processor_, EnqueueAction(_)).Times(0);
EXPECT_CALL(*processor_, StartProcessing()).Times(0);
EXPECT_CALL(*fake_system_state_.mock_payload_state(), UpdateFailed(_))
.Times(0);
OmahaResponse response;
string url1 = "http://url1";
response.packages.push_back({.payload_urls = {url1, "https://url"}});
EXPECT_CALL(*(fake_system_state_.mock_payload_state()), GetCurrentUrl())
.WillRepeatedly(Return(url1));
fake_system_state_.mock_payload_state()->SetResponse(response);
attempter_.ScheduleErrorEventAction();
EXPECT_EQ(url1, fake_system_state_.mock_payload_state()->GetCurrentUrl());
}
TEST_F(UpdateAttempterTest, ScheduleErrorEventActionTest) {
EXPECT_CALL(*processor_,
EnqueueAction(Property(&AbstractAction::Type,
OmahaRequestAction::StaticType())));
EXPECT_CALL(*processor_, StartProcessing());
ErrorCode err = ErrorCode::kError;
EXPECT_CALL(*fake_system_state_.mock_payload_state(), UpdateFailed(err));
attempter_.error_event_.reset(new OmahaEvent(OmahaEvent::kTypeUpdateComplete,
OmahaEvent::kResultError,
err));
attempter_.ScheduleErrorEventAction();
EXPECT_EQ(UpdateStatus::REPORTING_ERROR_EVENT, attempter_.status());
}
namespace {
// Actions that will be built as part of an update check.
const string kUpdateActionTypes[] = { // NOLINT(runtime/string)
OmahaRequestAction::StaticType(),
OmahaResponseHandlerAction::StaticType(),
OmahaRequestAction::StaticType(),
DownloadAction::StaticType(),
OmahaRequestAction::StaticType(),
FilesystemVerifierAction::StaticType(),
PostinstallRunnerAction::StaticType(),
OmahaRequestAction::StaticType()
};
// Actions that will be built as part of a user-initiated rollback.
const string kRollbackActionTypes[] = { // NOLINT(runtime/string)
InstallPlanAction::StaticType(),
PostinstallRunnerAction::StaticType(),
};
} // namespace
void UpdateAttempterTest::UpdateTestStart() {
attempter_.set_http_response_code(200);
// Expect that the device policy is loaded by the UpdateAttempter at some
// point by calling RefreshDevicePolicy.
auto device_policy = std::make_unique<policy::MockDevicePolicy>();
EXPECT_CALL(*device_policy, LoadPolicy())
.Times(testing::AtLeast(1)).WillRepeatedly(Return(true));
attempter_.policy_provider_.reset(
new policy::PolicyProvider(std::move(device_policy)));
{
InSequence s;
for (size_t i = 0; i < arraysize(kUpdateActionTypes); ++i) {
EXPECT_CALL(*processor_,
EnqueueAction(Property(&AbstractAction::Type,
kUpdateActionTypes[i])));
}
EXPECT_CALL(*processor_, StartProcessing());
}
attempter_.Update("", "", "", "", false, false);
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::UpdateTestVerify,
base::Unretained(this)));
}
void UpdateAttempterTest::UpdateTestVerify() {
EXPECT_EQ(0, attempter_.http_response_code());
EXPECT_EQ(&attempter_, processor_->delegate());
EXPECT_EQ(arraysize(kUpdateActionTypes), attempter_.actions_.size());
for (size_t i = 0; i < arraysize(kUpdateActionTypes); ++i) {
EXPECT_EQ(kUpdateActionTypes[i], attempter_.actions_[i]->Type());
}
EXPECT_EQ(attempter_.response_handler_action_.get(),
attempter_.actions_[1].get());
AbstractAction* action_3 = attempter_.actions_[3].get();
ASSERT_NE(nullptr, action_3);
ASSERT_EQ(DownloadAction::StaticType(), action_3->Type());
DownloadAction* download_action = static_cast<DownloadAction*>(action_3);
EXPECT_EQ(&attempter_, download_action->delegate());
EXPECT_EQ(UpdateStatus::CHECKING_FOR_UPDATE, attempter_.status());
loop_.BreakLoop();
}
void UpdateAttempterTest::RollbackTestStart(
bool enterprise_rollback, bool valid_slot) {
// Create a device policy so that we can change settings.
auto device_policy = std::make_unique<policy::MockDevicePolicy>();
EXPECT_CALL(*device_policy, LoadPolicy()).WillRepeatedly(Return(true));
fake_system_state_.set_device_policy(device_policy.get());
if (enterprise_rollback) {
// We return an empty owner as this is an enterprise.
EXPECT_CALL(*device_policy, GetOwner(_)).WillRepeatedly(
DoAll(SetArgPointee<0>(string("")),
Return(true)));
} else {
// We return a fake owner as this is an owned consumer device.
EXPECT_CALL(*device_policy, GetOwner(_)).WillRepeatedly(
DoAll(SetArgPointee<0>(string("fake.mail@fake.com")),
Return(true)));
}
attempter_.policy_provider_.reset(
new policy::PolicyProvider(std::move(device_policy)));
if (valid_slot) {
BootControlInterface::Slot rollback_slot = 1;
LOG(INFO) << "Test Mark Bootable: "
<< BootControlInterface::SlotName(rollback_slot);
fake_system_state_.fake_boot_control()->SetSlotBootable(rollback_slot,
true);
}
bool is_rollback_allowed = false;
// We only allow rollback on devices that are not enterprise enrolled and
// which have a valid slot to rollback to.
if (!enterprise_rollback && valid_slot) {
is_rollback_allowed = true;
}
if (is_rollback_allowed) {
InSequence s;
for (size_t i = 0; i < arraysize(kRollbackActionTypes); ++i) {
EXPECT_CALL(*processor_,
EnqueueAction(Property(&AbstractAction::Type,
kRollbackActionTypes[i])));
}
EXPECT_CALL(*processor_, StartProcessing());
EXPECT_TRUE(attempter_.Rollback(true));
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::RollbackTestVerify,
base::Unretained(this)));
} else {
EXPECT_FALSE(attempter_.Rollback(true));
loop_.BreakLoop();
}
}
void UpdateAttempterTest::RollbackTestVerify() {
// Verifies the actions that were enqueued.
EXPECT_EQ(&attempter_, processor_->delegate());
EXPECT_EQ(arraysize(kRollbackActionTypes), attempter_.actions_.size());
for (size_t i = 0; i < arraysize(kRollbackActionTypes); ++i) {
EXPECT_EQ(kRollbackActionTypes[i], attempter_.actions_[i]->Type());
}
EXPECT_EQ(UpdateStatus::ATTEMPTING_ROLLBACK, attempter_.status());
AbstractAction* action_0 = attempter_.actions_[0].get();
ASSERT_NE(nullptr, action_0);
ASSERT_EQ(InstallPlanAction::StaticType(), action_0->Type());
InstallPlanAction* install_plan_action =
static_cast<InstallPlanAction*>(action_0);
InstallPlan* install_plan = install_plan_action->install_plan();
EXPECT_EQ(0U, install_plan->partitions.size());
EXPECT_EQ(install_plan->powerwash_required, true);
loop_.BreakLoop();
}
TEST_F(UpdateAttempterTest, UpdateTest) {
UpdateTestStart();
loop_.Run();
}
TEST_F(UpdateAttempterTest, RollbackTest) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::RollbackTestStart,
base::Unretained(this),
false, true));
loop_.Run();
}
TEST_F(UpdateAttempterTest, InvalidSlotRollbackTest) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::RollbackTestStart,
base::Unretained(this),
false, false));
loop_.Run();
}
TEST_F(UpdateAttempterTest, EnterpriseRollbackTest) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::RollbackTestStart,
base::Unretained(this),
true, true));
loop_.Run();
}
void UpdateAttempterTest::PingOmahaTestStart() {
EXPECT_CALL(*processor_,
EnqueueAction(Property(&AbstractAction::Type,
OmahaRequestAction::StaticType())));
EXPECT_CALL(*processor_, StartProcessing());
attempter_.PingOmaha();
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, PingOmahaTest) {
EXPECT_FALSE(attempter_.waiting_for_scheduled_check_);
EXPECT_FALSE(attempter_.schedule_updates_called());
// Disable scheduling of subsequnet checks; we're using the DefaultPolicy in
// testing, which is more permissive than we want to handle here.
attempter_.DisableScheduleUpdates();
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::PingOmahaTestStart,
base::Unretained(this)));
brillo::MessageLoopRunMaxIterations(&loop_, 100);
EXPECT_EQ(UpdateStatus::UPDATED_NEED_REBOOT, attempter_.status());
EXPECT_TRUE(attempter_.schedule_updates_called());
}
TEST_F(UpdateAttempterTest, CreatePendingErrorEventTest) {
MockAction action;
const ErrorCode kCode = ErrorCode::kDownloadTransferError;
attempter_.CreatePendingErrorEvent(&action, kCode);
ASSERT_NE(nullptr, attempter_.error_event_.get());
EXPECT_EQ(OmahaEvent::kTypeUpdateComplete, attempter_.error_event_->type);
EXPECT_EQ(OmahaEvent::kResultError, attempter_.error_event_->result);
EXPECT_EQ(
static_cast<ErrorCode>(static_cast<int>(kCode) |
static_cast<int>(ErrorCode::kTestOmahaUrlFlag)),
attempter_.error_event_->error_code);
}
TEST_F(UpdateAttempterTest, CreatePendingErrorEventResumedTest) {
OmahaResponseHandlerAction *response_action =
new OmahaResponseHandlerAction(&fake_system_state_);
response_action->install_plan_.is_resume = true;
attempter_.response_handler_action_.reset(response_action);
MockAction action;
const ErrorCode kCode = ErrorCode::kInstallDeviceOpenError;
attempter_.CreatePendingErrorEvent(&action, kCode);
ASSERT_NE(nullptr, attempter_.error_event_.get());
EXPECT_EQ(OmahaEvent::kTypeUpdateComplete, attempter_.error_event_->type);
EXPECT_EQ(OmahaEvent::kResultError, attempter_.error_event_->result);
EXPECT_EQ(
static_cast<ErrorCode>(
static_cast<int>(kCode) |
static_cast<int>(ErrorCode::kResumedFlag) |
static_cast<int>(ErrorCode::kTestOmahaUrlFlag)),
attempter_.error_event_->error_code);
}
TEST_F(UpdateAttempterTest, P2PNotStartedAtStartupWhenNotEnabled) {
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(false);
EXPECT_CALL(mock_p2p_manager, EnsureP2PRunning()).Times(0);
attempter_.UpdateEngineStarted();
}
TEST_F(UpdateAttempterTest, P2PNotStartedAtStartupWhenEnabledButNotSharing) {
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(true);
EXPECT_CALL(mock_p2p_manager, EnsureP2PRunning()).Times(0);
attempter_.UpdateEngineStarted();
}
TEST_F(UpdateAttempterTest, P2PStartedAtStartupWhenEnabledAndSharing) {
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(true);
mock_p2p_manager.fake().SetCountSharedFilesResult(1);
EXPECT_CALL(mock_p2p_manager, EnsureP2PRunning());
attempter_.UpdateEngineStarted();
}
TEST_F(UpdateAttempterTest, P2PNotEnabled) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::P2PNotEnabledStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::P2PNotEnabledStart() {
// If P2P is not enabled, check that we do not attempt housekeeping
// and do not convey that p2p is to be used.
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(false);
EXPECT_CALL(mock_p2p_manager, PerformHousekeeping()).Times(0);
attempter_.Update("", "", "", "", false, false);
EXPECT_FALSE(actual_using_p2p_for_downloading_);
EXPECT_FALSE(actual_using_p2p_for_sharing());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, P2PEnabledStartingFails) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::P2PEnabledStartingFailsStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::P2PEnabledStartingFailsStart() {
// If p2p is enabled, but starting it fails ensure we don't do
// any housekeeping and do not convey that p2p should be used.
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(true);
mock_p2p_manager.fake().SetEnsureP2PRunningResult(false);
mock_p2p_manager.fake().SetPerformHousekeepingResult(false);
EXPECT_CALL(mock_p2p_manager, PerformHousekeeping()).Times(0);
attempter_.Update("", "", "", "", false, false);
EXPECT_FALSE(actual_using_p2p_for_downloading());
EXPECT_FALSE(actual_using_p2p_for_sharing());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, P2PEnabledHousekeepingFails) {
loop_.PostTask(
FROM_HERE,
base::Bind(&UpdateAttempterTest::P2PEnabledHousekeepingFailsStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::P2PEnabledHousekeepingFailsStart() {
// If p2p is enabled, starting it works but housekeeping fails, ensure
// we do not convey p2p is to be used.
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
mock_p2p_manager.fake().SetP2PEnabled(true);
mock_p2p_manager.fake().SetEnsureP2PRunningResult(true);
mock_p2p_manager.fake().SetPerformHousekeepingResult(false);
EXPECT_CALL(mock_p2p_manager, PerformHousekeeping());
attempter_.Update("", "", "", "", false, false);
EXPECT_FALSE(actual_using_p2p_for_downloading());
EXPECT_FALSE(actual_using_p2p_for_sharing());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, P2PEnabled) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::P2PEnabledStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::P2PEnabledStart() {
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
// If P2P is enabled and starting it works, check that we performed
// housekeeping and that we convey p2p should be used.
mock_p2p_manager.fake().SetP2PEnabled(true);
mock_p2p_manager.fake().SetEnsureP2PRunningResult(true);
mock_p2p_manager.fake().SetPerformHousekeepingResult(true);
EXPECT_CALL(mock_p2p_manager, PerformHousekeeping());
attempter_.Update("", "", "", "", false, false);
EXPECT_TRUE(actual_using_p2p_for_downloading());
EXPECT_TRUE(actual_using_p2p_for_sharing());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, P2PEnabledInteractive) {
loop_.PostTask(FROM_HERE,
base::Bind(&UpdateAttempterTest::P2PEnabledInteractiveStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::P2PEnabledInteractiveStart() {
MockP2PManager mock_p2p_manager;
fake_system_state_.set_p2p_manager(&mock_p2p_manager);
// For an interactive check, if P2P is enabled and starting it
// works, check that we performed housekeeping and that we convey
// p2p should be used for sharing but NOT for downloading.
mock_p2p_manager.fake().SetP2PEnabled(true);
mock_p2p_manager.fake().SetEnsureP2PRunningResult(true);
mock_p2p_manager.fake().SetPerformHousekeepingResult(true);
EXPECT_CALL(mock_p2p_manager, PerformHousekeeping());
attempter_.Update("", "", "", "", false, true /* interactive */);
EXPECT_FALSE(actual_using_p2p_for_downloading());
EXPECT_TRUE(actual_using_p2p_for_sharing());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, ReadScatterFactorFromPolicy) {
loop_.PostTask(
FROM_HERE,
base::Bind(&UpdateAttempterTest::ReadScatterFactorFromPolicyTestStart,
base::Unretained(this)));
loop_.Run();
}
// Tests that the scatter_factor_in_seconds value is properly fetched
// from the device policy.
void UpdateAttempterTest::ReadScatterFactorFromPolicyTestStart() {
int64_t scatter_factor_in_seconds = 36000;
auto device_policy = std::make_unique<policy::MockDevicePolicy>();
EXPECT_CALL(*device_policy, LoadPolicy()).WillRepeatedly(Return(true));
fake_system_state_.set_device_policy(device_policy.get());
EXPECT_CALL(*device_policy, GetScatterFactorInSeconds(_))
.WillRepeatedly(DoAll(
SetArgPointee<0>(scatter_factor_in_seconds),
Return(true)));
attempter_.policy_provider_.reset(
new policy::PolicyProvider(std::move(device_policy)));
attempter_.Update("", "", "", "", false, false);
EXPECT_EQ(scatter_factor_in_seconds, attempter_.scatter_factor_.InSeconds());
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, DecrementUpdateCheckCountTest) {
loop_.PostTask(
FROM_HERE,
base::Bind(&UpdateAttempterTest::DecrementUpdateCheckCountTestStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::DecrementUpdateCheckCountTestStart() {
// Tests that the scatter_factor_in_seconds value is properly fetched
// from the device policy and is decremented if value > 0.
int64_t initial_value = 5;
FakePrefs fake_prefs;
attempter_.prefs_ = &fake_prefs;
fake_system_state_.fake_hardware()->SetIsOOBEComplete(Time::UnixEpoch());
EXPECT_TRUE(fake_prefs.SetInt64(kPrefsUpdateCheckCount, initial_value));
int64_t scatter_factor_in_seconds = 10;
auto device_policy = std::make_unique<policy::MockDevicePolicy>();
EXPECT_CALL(*device_policy, LoadPolicy()).WillRepeatedly(Return(true));
fake_system_state_.set_device_policy(device_policy.get());
EXPECT_CALL(*device_policy, GetScatterFactorInSeconds(_))
.WillRepeatedly(DoAll(
SetArgPointee<0>(scatter_factor_in_seconds),
Return(true)));
attempter_.policy_provider_.reset(
new policy::PolicyProvider(std::move(device_policy)));
attempter_.Update("", "", "", "", false, false);
EXPECT_EQ(scatter_factor_in_seconds, attempter_.scatter_factor_.InSeconds());
// Make sure the file still exists.
EXPECT_TRUE(fake_prefs.Exists(kPrefsUpdateCheckCount));
int64_t new_value;
EXPECT_TRUE(fake_prefs.GetInt64(kPrefsUpdateCheckCount, &new_value));
EXPECT_EQ(initial_value - 1, new_value);
EXPECT_TRUE(
attempter_.omaha_request_params_->update_check_count_wait_enabled());
// However, if the count is already 0, it's not decremented. Test that.
initial_value = 0;
EXPECT_TRUE(fake_prefs.SetInt64(kPrefsUpdateCheckCount, initial_value));
attempter_.Update("", "", "", "", false, false);
EXPECT_TRUE(fake_prefs.Exists(kPrefsUpdateCheckCount));
EXPECT_TRUE(fake_prefs.GetInt64(kPrefsUpdateCheckCount, &new_value));
EXPECT_EQ(initial_value, new_value);
ScheduleQuitMainLoop();
}
TEST_F(UpdateAttempterTest, NoScatteringDoneDuringManualUpdateTestStart) {
loop_.PostTask(FROM_HERE, base::Bind(
&UpdateAttempterTest::NoScatteringDoneDuringManualUpdateTestStart,
base::Unretained(this)));
loop_.Run();
}
void UpdateAttempterTest::NoScatteringDoneDuringManualUpdateTestStart() {
// Tests that no scattering logic is enabled if the update check
// is manually done (as opposed to a scheduled update check)
int64_t initial_value = 8;
FakePrefs fake_prefs;
attempter_.prefs_ = &fake_prefs;
fake_system_state_.fake_hardware()->SetIsOOBEComplete(Time::UnixEpoch());
fake_system_state_.set_prefs(&fake_prefs);
EXPECT_TRUE(fake_prefs.SetInt64(kPrefsWallClockWaitPeriod, initial_value));
EXPECT_TRUE(fake_prefs.SetInt64(kPrefsUpdateCheckCount, initial_value));
// make sure scatter_factor is non-zero as scattering is disabled
// otherwise.
int64_t scatter_factor_in_seconds = 50;
auto device_policy = std::make_unique<policy::MockDevicePolicy>();
EXPECT_CALL(*device_policy, LoadPolicy()).WillRepeatedly(Return(true));
fake_system_state_.set_device_policy(device_policy.get());
EXPECT_CALL(*device_policy, GetScatterFactorInSeconds(_))
.WillRepeatedly(DoAll(
SetArgPointee<0>(scatter_factor_in_seconds),
Return(true)));
attempter_.policy_provider_.reset(
new policy::PolicyProvider(std::move(device_policy)));
// Trigger an interactive check so we can test that scattering is disabled.
attempter_.Update("", "", "", "", false, true);
EXPECT_EQ(scatter_factor_in_seconds, attempter_.scatter_factor_.InSeconds());
// Make sure scattering is disabled for manual (i.e. user initiated) update
// checks and all artifacts are removed.
EXPECT_FALSE(
attempter_.omaha_request_params_->wall_clock_based_wait_enabled());
EXPECT_FALSE(fake_prefs.Exists(kPrefsWallClockWaitPeriod));
EXPECT_EQ(0, attempter_.omaha_request_params_->waiting_period().InSeconds());
EXPECT_FALSE(
attempter_.omaha_request_params_->update_check_count_wait_enabled());
EXPECT_FALSE(fake_prefs.Exists(kPrefsUpdateCheckCount));
ScheduleQuitMainLoop();
}
// Checks that we only report daily metrics at most every 24 hours.
TEST_F(UpdateAttempterTest, ReportDailyMetrics) {
FakeClock fake_clock;
FakePrefs fake_prefs;
fake_system_state_.set_clock(&fake_clock);
fake_system_state_.set_prefs(&fake_prefs);
Time epoch = Time::FromInternalValue(0);
fake_clock.SetWallclockTime(epoch);
// If there is no kPrefsDailyMetricsLastReportedAt state variable,
// we should report.
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
// We should not report again if no time has passed.
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// We should not report if only 10 hours has passed.
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(10));
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// We should not report if only 24 hours - 1 sec has passed.
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(24) -
TimeDelta::FromSeconds(1));
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// We should report if 24 hours has passed.
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(24));
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
// But then we should not report again..
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// .. until another 24 hours has passed
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(47));
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(48));
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// .. and another 24 hours
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(71));
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(72));
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// If the span between time of reporting and present time is
// negative, we report. This is in order to reset the timestamp and
// avoid an edge condition whereby a distant point in the future is
// in the state variable resulting in us never ever reporting again.
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(71));
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
// In this case we should not update until the clock reads 71 + 24 = 95.
// Check that.
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(94));
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
fake_clock.SetWallclockTime(epoch + TimeDelta::FromHours(95));
EXPECT_TRUE(attempter_.CheckAndReportDailyMetrics());
EXPECT_FALSE(attempter_.CheckAndReportDailyMetrics());
}
TEST_F(UpdateAttempterTest, BootTimeInUpdateMarkerFile) {
FakeClock fake_clock;
fake_clock.SetBootTime(Time::FromTimeT(42));
fake_system_state_.set_clock(&fake_clock);
FakePrefs fake_prefs;
fake_system_state_.set_prefs(&fake_prefs);
attempter_.Init();
Time boot_time;
EXPECT_FALSE(attempter_.GetBootTimeAtUpdate(&boot_time));
attempter_.WriteUpdateCompletedMarker();
EXPECT_TRUE(attempter_.GetBootTimeAtUpdate(&boot_time));
EXPECT_EQ(boot_time.ToTimeT(), 42);
}
TEST_F(UpdateAttempterTest, AnyUpdateSourceAllowedUnofficial) {
fake_system_state_.fake_hardware()->SetIsOfficialBuild(false);
EXPECT_TRUE(attempter_.IsAnyUpdateSourceAllowed());
}
TEST_F(UpdateAttempterTest, AnyUpdateSourceAllowedOfficialDevmode) {
fake_system_state_.fake_hardware()->SetIsOfficialBuild(true);
fake_system_state_.fake_hardware()->SetAreDevFeaturesEnabled(true);
EXPECT_TRUE(attempter_.IsAnyUpdateSourceAllowed());
}
TEST_F(UpdateAttempterTest, AnyUpdateSourceDisallowedOfficialNormal) {
fake_system_state_.fake_hardware()->SetIsOfficialBuild(true);
fake_system_state_.fake_hardware()->SetAreDevFeaturesEnabled(false);
EXPECT_FALSE(attempter_.IsAnyUpdateSourceAllowed());
}
TEST_F(UpdateAttempterTest, CheckForUpdateAUTest) {
fake_system_state_.fake_hardware()->SetIsOfficialBuild(true);
fake_system_state_.fake_hardware()->SetAreDevFeaturesEnabled(false);
attempter_.CheckForUpdate("", "autest", UpdateAttemptFlags::kNone);
EXPECT_EQ(constants::kOmahaDefaultAUTestURL, attempter_.forced_omaha_url());
}
TEST_F(UpdateAttempterTest, CheckForUpdateScheduledAUTest) {
fake_system_state_.fake_hardware()->SetIsOfficialBuild(true);
fake_system_state_.fake_hardware()->SetAreDevFeaturesEnabled(false);
attempter_.CheckForUpdate("", "autest-scheduled", UpdateAttemptFlags::kNone);
EXPECT_EQ(constants::kOmahaDefaultAUTestURL, attempter_.forced_omaha_url());
}
TEST_F(UpdateAttempterTest, TargetVersionPrefixSetAndReset) {
attempter_.CalculateUpdateParams("", "", "", "1234", false, false);
EXPECT_EQ("1234",
fake_system_state_.request_params()->target_version_prefix());
attempter_.CalculateUpdateParams("", "", "", "", false, false);
EXPECT_TRUE(
fake_system_state_.request_params()->target_version_prefix().empty());
}
TEST_F(UpdateAttempterTest, UpdateDeferredByPolicyTest) {
// Construct an OmahaResponseHandlerAction that has processed an InstallPlan,
// but the update is being deferred by the Policy.
OmahaResponseHandlerAction* response_action =
new OmahaResponseHandlerAction(&fake_system_state_);
response_action->install_plan_.version = "a.b.c.d";
response_action->install_plan_.system_version = "b.c.d.e";
response_action->install_plan_.payloads.push_back(
{.size = 1234ULL, .type = InstallPayloadType::kFull});
attempter_.response_handler_action_.reset(response_action);
// Inform the UpdateAttempter that the OmahaResponseHandlerAction has
// completed, with the deferred-update error code.
attempter_.ActionCompleted(
nullptr, response_action, ErrorCode::kOmahaUpdateDeferredPerPolicy);
{
UpdateEngineStatus status;
attempter_.GetStatus(&status);
EXPECT_EQ(UpdateStatus::UPDATE_AVAILABLE, status.status);
EXPECT_EQ(response_action->install_plan_.version, status.new_version);
EXPECT_EQ(response_action->install_plan_.system_version,
status.new_system_version);
EXPECT_EQ(response_action->install_plan_.payloads[0].size,
status.new_size_bytes);
}
// An "error" event should have been created to tell Omaha that the update is
// being deferred.
EXPECT_TRUE(nullptr != attempter_.error_event_);
EXPECT_EQ(OmahaEvent::kTypeUpdateComplete, attempter_.error_event_->type);
EXPECT_EQ(OmahaEvent::kResultUpdateDeferred, attempter_.error_event_->result);
ErrorCode expected_code = static_cast<ErrorCode>(
static_cast<int>(ErrorCode::kOmahaUpdateDeferredPerPolicy) |
static_cast<int>(ErrorCode::kTestOmahaUrlFlag));
EXPECT_EQ(expected_code, attempter_.error_event_->error_code);
// End the processing
attempter_.ProcessingDone(nullptr, ErrorCode::kOmahaUpdateDeferredPerPolicy);
// Validate the state of the attempter.
{
UpdateEngineStatus status;
attempter_.GetStatus(&status);
EXPECT_EQ(UpdateStatus::REPORTING_ERROR_EVENT, status.status);
EXPECT_EQ(response_action->install_plan_.version, status.new_version);
EXPECT_EQ(response_action->install_plan_.system_version,
status.new_system_version);
EXPECT_EQ(response_action->install_plan_.payloads[0].size,
status.new_size_bytes);
}
}
TEST_F(UpdateAttempterTest, UpdateIsNotRunningWhenUpdateAvailable) {
EXPECT_FALSE(attempter_.IsUpdateRunningOrScheduled());
// Verify in-progress update with UPDATE_AVAILABLE is running
attempter_.status_ = UpdateStatus::UPDATE_AVAILABLE;
EXPECT_TRUE(attempter_.IsUpdateRunningOrScheduled());
}
TEST_F(UpdateAttempterTest, UpdateAttemptFlagsCachedAtUpdateStart) {
attempter_.SetUpdateAttemptFlags(UpdateAttemptFlags::kFlagRestrictDownload);
UpdateCheckParams params = {.updates_enabled = true};
attempter_.OnUpdateScheduled(EvalStatus::kSucceeded, params);
EXPECT_EQ(UpdateAttemptFlags::kFlagRestrictDownload,
attempter_.GetCurrentUpdateAttemptFlags());
}
TEST_F(UpdateAttempterTest, InteractiveUpdateUsesPassedRestrictions) {
attempter_.SetUpdateAttemptFlags(UpdateAttemptFlags::kFlagRestrictDownload);
attempter_.CheckForUpdate("", "", UpdateAttemptFlags::kNone);
EXPECT_EQ(UpdateAttemptFlags::kNone,
attempter_.GetCurrentUpdateAttemptFlags());
}
TEST_F(UpdateAttempterTest, NonInteractiveUpdateUsesSetRestrictions) {
attempter_.SetUpdateAttemptFlags(UpdateAttemptFlags::kNone);
// This tests that when CheckForUpdate() is called with the non-interactive
// flag set, that it doesn't change the current UpdateAttemptFlags.
attempter_.CheckForUpdate("",
"",
UpdateAttemptFlags::kFlagNonInteractive |
UpdateAttemptFlags::kFlagRestrictDownload);
EXPECT_EQ(UpdateAttemptFlags::kNone,
attempter_.GetCurrentUpdateAttemptFlags());
}
} // namespace chromeos_update_engine