//
// Copyright (C) 2013 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 "shill/wifi/scan_session.h"
#include <errno.h>
#include <limits>
#include <memory>
#include <set>
#include <vector>
#include <base/memory/weak_ptr.h>
#include <gmock/gmock.h>
#include <gtest/gtest.h>
#include "shill/mock_event_dispatcher.h"
#include "shill/net/mock_netlink_manager.h"
#include "shill/net/netlink_manager.h"
#include "shill/net/netlink_message_matchers.h"
#include "shill/net/nl80211_message.h"
using std::set;
using std::vector;
using testing::_;
using testing::ContainerEq;
using testing::Test;
namespace shill {
static const uint16_t kExpectedFreq5640 = 5640;
static const uint16_t kExpectedFreq5600 = 5600;
static const uint16_t kExpectedFreq5580 = 5580;
static const uint16_t kExpectedFreq5560 = 5560;
static const uint16_t kExpectedFreq5620 = 5620;
static WiFiProvider::FrequencyCount kConnectedFrequencies[] = {
WiFiProvider::FrequencyCount(kExpectedFreq5640, 40), // 40th percentile.
WiFiProvider::FrequencyCount(kExpectedFreq5600, 25), // 65th percentile.
WiFiProvider::FrequencyCount(kExpectedFreq5580, 20), // 85th percentile.
WiFiProvider::FrequencyCount(kExpectedFreq5560, 10), // 95th percentile.
WiFiProvider::FrequencyCount(kExpectedFreq5620, 5) // 100th percentile.
};
static const uint16_t kExpectedFreq2432 = 2432;
static const uint16_t kExpectedFreq2427 = 2427;
static const uint16_t kExpectedFreq2422 = 2422;
static const uint16_t kExpectedFreq2417 = 2417;
static const uint16_t kExpectedFreq2412 = 2412;
static uint16_t kUnconnectedFrequencies[] = {
kExpectedFreq2432,
kExpectedFreq2427,
kExpectedFreq2422,
kExpectedFreq2417,
kExpectedFreq2412
};
static const uint16_t kNl80211FamilyId = 0x13;
class ScanSessionTest : public Test {
public:
// Test set of "all the other frequencies this device can support" in
// sorted order.
ScanSessionTest() : weak_ptr_factory_(this) {
WiFiProvider::FrequencyCountList default_connected_frequencies(
kConnectedFrequencies,
kConnectedFrequencies + arraysize(kConnectedFrequencies));
set<uint16_t> default_unconnected_frequencies(
kUnconnectedFrequencies,
kUnconnectedFrequencies + arraysize(kUnconnectedFrequencies));
BuildScanSession(default_connected_frequencies,
default_unconnected_frequencies);
}
void BuildScanSession(const WiFiProvider::FrequencyCountList
&connected_frequencies,
const std::set<uint16_t>& unconnected_frequencies) {
const int kArbitraryMinimum = 1;
const int kArbitraryMaximum = std::numeric_limits<int>::max();
scan_session_.reset(new ScanSession(&netlink_manager_,
&dispatcher_,
connected_frequencies,
unconnected_frequencies,
0,
ScanSession::FractionList(),
kArbitraryMinimum,
kArbitraryMaximum,
Bind(&ScanSessionTest::OnScanError,
weak_ptr_factory_.GetWeakPtr()),
nullptr));
}
virtual std::vector<uint16_t> GetScanFrequencies(float scan_fraction,
size_t min_frequencies,
size_t max_frequencies) {
return scan_session_->GetScanFrequencies(scan_fraction, min_frequencies,
max_frequencies);
}
ScanSession* scan_session() { return scan_session_.get(); }
void SetScanSize(size_t min_frequencies, size_t max_frequencies) {
scan_session_->min_frequencies_ = min_frequencies;
scan_session_->max_frequencies_ = max_frequencies;
}
size_t GetScanFrequencyCount() {
return arraysize(kConnectedFrequencies) +
arraysize(kUnconnectedFrequencies);
}
protected:
MOCK_METHOD0(OnScanError, void());
MockNetlinkManager* netlink_manager() { return &netlink_manager_; }
MockEventDispatcher* dispatcher() { return &dispatcher_; }
MockEventDispatcher dispatcher_;
MockNetlinkManager netlink_manager_;
std::unique_ptr<ScanSession> scan_session_;
base::WeakPtrFactory<ScanSessionTest> weak_ptr_factory_;
};
// Test that we can get a bunch of frequencies up to a specified fraction.
TEST_F(ScanSessionTest, Fraction) {
vector<uint16_t> result;
// Get the first 83% of the connected values.
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580};
result = GetScanFrequencies(.83, 1, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// Get the next 4 values.
{
vector<uint16_t> expected{kExpectedFreq5560, kExpectedFreq5620,
kExpectedFreq2412, kExpectedFreq2417};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 4);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the remaining list.
{
vector<uint16_t> expected{kExpectedFreq2422, kExpectedFreq2427,
kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 20,
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get a bunch of frequencies up to a specified fraction,
// followed by another group up to a specified fraction.
TEST_F(ScanSessionTest, TwoFractions) {
vector<uint16_t> result;
// Get the first 60% of the connected values.
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600};
result = GetScanFrequencies(.60, 0, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// Get the next 32% of the connected values.
{
vector<uint16_t> expected{kExpectedFreq5580, kExpectedFreq5560};
result = GetScanFrequencies(.32, 0, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the remaining list.
{
vector<uint16_t> expected{kExpectedFreq5620, kExpectedFreq2412,
kExpectedFreq2417, kExpectedFreq2422, kExpectedFreq2427,
kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies,
std::numeric_limits<size_t>::max(),
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get a bunch of frequencies up to a minimum count, even
// when the requested fraction has already been reached.
TEST_F(ScanSessionTest, Min) {
vector<uint16_t> result;
// Get the first 3 previously seen values.
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580};
result = GetScanFrequencies(.30, 3, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// Get the next value by requesting a minimum of 1.
{
vector<uint16_t> expected{kExpectedFreq5560};
result = GetScanFrequencies(0.0, 1, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the remaining list.
{
vector<uint16_t> expected{kExpectedFreq5620, kExpectedFreq2412,
kExpectedFreq2417, kExpectedFreq2422, kExpectedFreq2427,
kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies,
std::numeric_limits<size_t>::max(),
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get up to a specified maximum number of frequencies.
TEST_F(ScanSessionTest, Max) {
vector<uint16_t> result;
// Get the first 7 values (crosses seen/unseen boundary).
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580, kExpectedFreq5560, kExpectedFreq5620,
kExpectedFreq2412, kExpectedFreq2417};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 7);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the remaining list.
{
vector<uint16_t> expected{kExpectedFreq2422, kExpectedFreq2427,
kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 20,
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get exactly the seen frequencies and exactly the unseen
// ones.
TEST_F(ScanSessionTest, Exact) {
vector<uint16_t> result;
// Get the first 5 values -- exactly on the seen/unseen border.
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580, kExpectedFreq5560, kExpectedFreq5620};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 5, 5);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the last 5.
{
vector<uint16_t> expected{kExpectedFreq2412, kExpectedFreq2417,
kExpectedFreq2422, kExpectedFreq2427, kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 5, 5);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get everything in one read.
TEST_F(ScanSessionTest, AllOneRead) {
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580, kExpectedFreq5560, kExpectedFreq5620,
kExpectedFreq2412, kExpectedFreq2417, kExpectedFreq2422,
kExpectedFreq2427, kExpectedFreq2432};
vector<uint16_t> result;
result = GetScanFrequencies(ScanSession::kAllFrequencies,
std::numeric_limits<size_t>::max(),
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
// Test that we can get all the previously seen frequencies (and only the
// previously seen frequencies) via the requested fraction.
TEST_F(ScanSessionTest, EverythingConnected) {
vector<uint16_t> result;
// Get the first 100% of the connected values.
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580, kExpectedFreq5560, kExpectedFreq5620};
result = GetScanFrequencies(1.0, 0, std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
// And, get the remaining list.
{
vector<uint16_t> expected{kExpectedFreq2412, kExpectedFreq2417,
kExpectedFreq2422, kExpectedFreq2427, kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies,
std::numeric_limits<size_t>::max(),
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
TEST_F(ScanSessionTest, OnlyPreviouslySeen) {
// Build a scan session with only previously connected frequencies.
WiFiProvider::FrequencyCountList default_connected_frequencies(
kConnectedFrequencies,
kConnectedFrequencies + arraysize(kConnectedFrequencies));
BuildScanSession(default_connected_frequencies, std::set<uint16_t>());
// Get the first 100% of the connected values.
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580, kExpectedFreq5560, kExpectedFreq5620};
vector<uint16_t> result;
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1,
std::numeric_limits<size_t>::max());
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
result = GetScanFrequencies(ScanSession::kAllFrequencies,
std::numeric_limits<size_t>::max(),
std::numeric_limits<size_t>::max());
EXPECT_TRUE(result.empty());
}
// Verify that max works inside the list of connected frequencies.
TEST_F(ScanSessionTest, MaxAppliesToConnected) {
vector<uint16_t> result;
{
vector<uint16_t> expected{kExpectedFreq5640, kExpectedFreq5600,
kExpectedFreq5580};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 3);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq5560, kExpectedFreq5620,
kExpectedFreq2412};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 3);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2417, kExpectedFreq2422,
kExpectedFreq2427};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 3);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2432};
result = GetScanFrequencies(ScanSession::kAllFrequencies, 1, 3);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
// Test that we can get each value individually.
TEST_F(ScanSessionTest, IndividualReads) {
vector<uint16_t> result;
static const float kArbitraryFraction = 0.83;
{
vector<uint16_t> expected{kExpectedFreq5640};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq5600};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq5580};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq5560};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq5620};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2412};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2417};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2422};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2427};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
}
{
vector<uint16_t> expected{kExpectedFreq2432};
result = GetScanFrequencies(kArbitraryFraction, 1, 1);
EXPECT_THAT(result, ContainerEq(expected));
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
}
}
TEST_F(ScanSessionTest, OnTriggerScanResponse) {
Nl80211Message::SetMessageType(kNl80211FamilyId);
EXPECT_CALL(*netlink_manager(), SendNl80211Message(
IsNl80211Command(kNl80211FamilyId, NL80211_CMD_TRIGGER_SCAN), _, _, _));
scan_session()->InitiateScan();
EXPECT_CALL(*this, OnScanError());
NewScanResultsMessage not_supposed_to_get_this_message;
scan_session()->OnTriggerScanResponse(not_supposed_to_get_this_message);
}
TEST_F(ScanSessionTest, ExhaustFrequencies) {
// Set min & max scan frequency count to 1 so each scan will be of a single
// frequency.
SetScanSize(1, 1);
// Perform all the progressive scans until the frequencies are exhausted.
for (size_t i = 0; i < GetScanFrequencyCount(); ++i) {
EXPECT_TRUE(scan_session()->HasMoreFrequencies());
EXPECT_CALL(*netlink_manager(), SendNl80211Message(
IsNl80211Command(kNl80211FamilyId, NL80211_CMD_TRIGGER_SCAN), _, _, _));
scan_session()->InitiateScan();
}
EXPECT_FALSE(scan_session()->HasMoreFrequencies());
EXPECT_CALL(*netlink_manager(), SendNl80211Message(
IsNl80211Command(kNl80211FamilyId, NL80211_CMD_TRIGGER_SCAN), _, _, _))
.Times(0);
scan_session()->InitiateScan();
}
TEST_F(ScanSessionTest, OnError) {
Nl80211Message::SetMessageType(kNl80211FamilyId);
EXPECT_CALL(*netlink_manager(), SendNl80211Message(
IsNl80211Command(kNl80211FamilyId, NL80211_CMD_TRIGGER_SCAN), _, _, _));
scan_session()->InitiateScan();
EXPECT_CALL(*this, OnScanError());
ErrorAckMessage error_message(-EINTR);
scan_session()->OnTriggerScanErrorResponse(NetlinkManager::kErrorFromKernel,
&error_message);
}
TEST_F(ScanSessionTest, EBusy) {
const size_t kSmallRetryNumber = 3;
Nl80211Message::SetMessageType(kNl80211FamilyId);
scan_session()->scan_tries_left_ = kSmallRetryNumber;
EXPECT_CALL(*netlink_manager(), SendNl80211Message(
IsNl80211Command(kNl80211FamilyId, NL80211_CMD_TRIGGER_SCAN), _, _, _));
scan_session()->InitiateScan();
ErrorAckMessage error_message(-EBUSY);
for (size_t i = 0; i < kSmallRetryNumber; ++i) {
EXPECT_CALL(*this, OnScanError()).Times(0);
EXPECT_CALL(*dispatcher(), PostDelayedTask(_, _));
scan_session()->OnTriggerScanErrorResponse(NetlinkManager::kErrorFromKernel,
&error_message);
}
EXPECT_CALL(*this, OnScanError());
scan_session()->OnTriggerScanErrorResponse(NetlinkManager::kErrorFromKernel,
&error_message);
}
TEST_F(ScanSessionTest, ScanHidden) {
scan_session_->AddSsid(ByteString("a", 1));
EXPECT_CALL(netlink_manager_,
SendNl80211Message(HasHiddenSSID(kNl80211FamilyId), _, _, _));
scan_session()->InitiateScan();
}
TEST_F(ScanSessionTest, ScanNoHidden) {
EXPECT_CALL(netlink_manager_,
SendNl80211Message(HasNoHiddenSSID(kNl80211FamilyId), _, _, _));
scan_session()->InitiateScan();
}
} // namespace shill