/*
* Copyright (C) 2016, 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 <memory>
#include <string>
#include <vector>
#include <linux/netlink.h>
#include <gtest/gtest.h>
#include "wificond/net/kernel-header-latest/nl80211.h"
#include "wificond/net/netlink_utils.h"
#include "wificond/tests/mock_netlink_manager.h"
using std::string;
using std::unique_ptr;
using std::vector;
using testing::DoAll;
using testing::NiceMock;
using testing::Return;
using testing::_;
namespace android {
namespace wificond {
namespace {
constexpr uint8_t kFakeMaxNumScanSSIDs = 10;
constexpr uint8_t kFakeMaxNumSchedScanSSIDs = 16;
constexpr uint8_t kFakeMaxMatchSets = 18;
constexpr uint8_t kFakeMaxNumScanPlans = 8;
constexpr uint8_t kFakeMaxScanPlanIntervals = 80;
constexpr uint8_t kFakeMaxScanPlanIterations = 10;
constexpr uint16_t kFakeFamilyId = 14;
constexpr uint32_t kFakeFrequency1 = 2412;
constexpr uint32_t kFakeFrequency2 = 2437;
constexpr uint32_t kFakeFrequency3 = 2484;
constexpr uint32_t kFakeFrequency4 = 5200;
constexpr uint32_t kFakeFrequency5 = 5400;
constexpr uint32_t kFakeFrequency6 = 5600;
// 802.11p channel which is not valid for wifi usage.
constexpr uint32_t kFakeInvalidFrequency = 5950;
constexpr uint32_t kFakeSequenceNumber = 162;
constexpr uint32_t kFakeProtocolFeatures = 0x02;
constexpr uint16_t kFakeWiphyIndex = 8;
constexpr uint16_t kFakeWiphyIndex1 = 10;
constexpr int kFakeErrorCode = EIO;
constexpr bool kFakeSupportsRandomMacOneshotScan = true;
constexpr bool kFakeSupportsRandomMacSchedScan = false;
const char kFakeInterfaceName[] = "testif0";
const char kFakeCountryCode[] = "US";
const uint32_t kFakeInterfaceIndex = 34;
const uint32_t kFakeInterfaceIndex1 = 36;
const uint8_t kFakeInterfaceMacAddress[] = {0x45, 0x54, 0xad, 0x67, 0x98, 0xf6};
const uint8_t kFakeInterfaceMacAddress1[] = {0x05, 0x04, 0xef, 0x27, 0x12, 0xff};
const uint8_t kFakeExtFeaturesForLowSpanScan[] = {0x0, 0x0, 0x40};
const uint8_t kFakeExtFeaturesForLowPowerScan[] = {0x0, 0x0, 0x80};
const uint8_t kFakeExtFeaturesForHighAccuracy[] = {0x0, 0x0, 0x0, 0x1};
const uint8_t kFakeExtFeaturesForAllScanType[] = {0x0, 0x0, 0xC0, 0x1};
// Currently, control messages are only created by the kernel and sent to us.
// Therefore NL80211Packet doesn't have corresponding constructor.
// For test we manually create control messages using this helper function.
NL80211Packet CreateControlMessageError(int error_code) {
vector<uint8_t> data;
data.resize(NLMSG_HDRLEN + NLA_ALIGN(sizeof(int)), 0);
// Initialize length field.
nlmsghdr* nl_header = reinterpret_cast<nlmsghdr*>(data.data());
nl_header->nlmsg_len = data.size();
nl_header->nlmsg_type = NLMSG_ERROR;
nl_header->nlmsg_seq = kFakeSequenceNumber;
nl_header->nlmsg_pid = getpid();
int* error_field = reinterpret_cast<int*>(data.data() + NLMSG_HDRLEN);
*error_field = -error_code;
return NL80211Packet(data);
}
NL80211Packet CreateControlMessageAck() {
return CreateControlMessageError(0);
}
void AppendScanCapabilitiesAttributes(NL80211Packet* packet,
bool supports_scan_plan) {
packet->AddAttribute(NL80211Attr<uint8_t>(NL80211_ATTR_MAX_NUM_SCAN_SSIDS,
kFakeMaxNumScanSSIDs));
packet->AddAttribute(NL80211Attr<uint8_t>(
NL80211_ATTR_MAX_NUM_SCHED_SCAN_SSIDS,
kFakeMaxNumSchedScanSSIDs));
packet->AddAttribute(NL80211Attr<uint8_t>(NL80211_ATTR_MAX_MATCH_SETS,
kFakeMaxMatchSets));
if (supports_scan_plan) {
packet->AddAttribute(NL80211Attr<uint32_t>(
NL80211_ATTR_MAX_NUM_SCHED_SCAN_PLANS,
kFakeMaxNumScanPlans));
packet->AddAttribute(NL80211Attr<uint32_t>(
NL80211_ATTR_MAX_SCAN_PLAN_INTERVAL,
kFakeMaxScanPlanIntervals));
packet->AddAttribute(NL80211Attr<uint32_t>(
NL80211_ATTR_MAX_SCAN_PLAN_ITERATIONS,
kFakeMaxScanPlanIterations));
}
}
NL80211NestedAttr GenerateBandsAttributeFor2g() {
NL80211NestedAttr freq_2g_1(1);
NL80211NestedAttr freq_2g_2(2);
NL80211NestedAttr freq_2g_3(3);
freq_2g_1.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency1));
freq_2g_2.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency2));
freq_2g_3.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency3));
NL80211NestedAttr band_2g_freqs(NL80211_BAND_ATTR_FREQS);
band_2g_freqs.AddAttribute(freq_2g_1);
band_2g_freqs.AddAttribute(freq_2g_2);
band_2g_freqs.AddAttribute(freq_2g_3);
NL80211NestedAttr band_2g_attr(1);
band_2g_attr.AddAttribute(band_2g_freqs);
NL80211NestedAttr band_attr(NL80211_ATTR_WIPHY_BANDS);
band_attr.AddAttribute(band_2g_attr);
return band_attr;
}
NL80211NestedAttr GenerateBandsAttributeFor5gAndDfs() {
NL80211NestedAttr freq_5g_1(4);
NL80211NestedAttr freq_5g_2(5);
NL80211NestedAttr freq_5g_3(6);
NL80211NestedAttr freq_dfs_1(7);
freq_5g_1.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency4));
freq_5g_2.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency5));
// This channel is passive only.
freq_5g_2.AddFlagAttribute(NL80211_FREQUENCY_ATTR_NO_IR);
// This channel is not valid for wifi usage.
// We should not include it in the parse result.
freq_5g_3.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeInvalidFrequency));
// DFS frequency.
freq_dfs_1.AddAttribute(NL80211Attr<uint32_t>(NL80211_FREQUENCY_ATTR_FREQ,
kFakeFrequency6));
freq_dfs_1.AddAttribute(NL80211Attr<uint32_t>(
NL80211_FREQUENCY_ATTR_DFS_STATE,
NL80211_DFS_USABLE));
NL80211NestedAttr band_5g_freqs(NL80211_BAND_ATTR_FREQS);
band_5g_freqs.AddAttribute(freq_5g_1);
band_5g_freqs.AddAttribute(freq_5g_2);
band_5g_freqs.AddAttribute(freq_5g_3);
band_5g_freqs.AddAttribute(freq_dfs_1);
NL80211NestedAttr band_5g_attr(1);
band_5g_attr.AddAttribute(band_5g_freqs);
NL80211NestedAttr band_attr(NL80211_ATTR_WIPHY_BANDS);
band_attr.AddAttribute(band_5g_attr);
return band_attr;
}
void AppendBandInfoAttributes(NL80211Packet* packet) {
NL80211NestedAttr attr_2g = GenerateBandsAttributeFor2g();
NL80211NestedAttr attr_5g_and_dfs = GenerateBandsAttributeFor5gAndDfs();
attr_2g.Merge(attr_5g_and_dfs);
packet->AddAttribute(attr_2g);
}
void AppendWiphyFeaturesAttributes(NL80211Packet* packet) {
uint32_t wiphy_features = 0;
if (kFakeSupportsRandomMacOneshotScan) {
wiphy_features |= NL80211_FEATURE_SCAN_RANDOM_MAC_ADDR;
}
if (kFakeSupportsRandomMacSchedScan) {
wiphy_features |= NL80211_FEATURE_SCHED_SCAN_RANDOM_MAC_ADDR;
}
packet->AddAttribute(
NL80211Attr<uint32_t>(NL80211_ATTR_FEATURE_FLAGS, wiphy_features));
}
void AppendWiphyExtFeaturesAttributes(NL80211Packet* packet,
bool support_low_span,
bool support_low_power,
bool support_high_accuracy,
bool support_all) {
ASSERT_LE(support_low_span + support_low_power + support_high_accuracy, 1);
std::vector<uint8_t> ext_feature_flags_bytes;
if (support_low_span) {
ext_feature_flags_bytes =
std::vector<uint8_t>(kFakeExtFeaturesForLowSpanScan,
kFakeExtFeaturesForLowSpanScan +
sizeof(kFakeExtFeaturesForLowSpanScan));
} else if (support_low_power) {
ext_feature_flags_bytes =
std::vector<uint8_t>(kFakeExtFeaturesForLowPowerScan,
kFakeExtFeaturesForLowPowerScan +
sizeof(kFakeExtFeaturesForLowPowerScan));
} else if (support_high_accuracy) {
ext_feature_flags_bytes =
std::vector<uint8_t>(kFakeExtFeaturesForHighAccuracy,
kFakeExtFeaturesForHighAccuracy +
sizeof(kFakeExtFeaturesForHighAccuracy));
} else if (support_all) {
ext_feature_flags_bytes =
std::vector<uint8_t>(kFakeExtFeaturesForAllScanType,
kFakeExtFeaturesForAllScanType +
sizeof(kFakeExtFeaturesForAllScanType));
}
packet->AddAttribute(
NL80211Attr<std::vector<uint8_t>>(NL80211_ATTR_EXT_FEATURES,
ext_feature_flags_bytes));
}
void VerifyScanCapabilities(const ScanCapabilities& scan_capabilities,
bool supports_scan_plan) {
EXPECT_EQ(scan_capabilities.max_num_scan_ssids,
kFakeMaxNumScanSSIDs);
EXPECT_EQ(scan_capabilities.max_num_sched_scan_ssids,
kFakeMaxNumSchedScanSSIDs);
EXPECT_EQ(scan_capabilities.max_match_sets,
kFakeMaxMatchSets);
if (supports_scan_plan) {
EXPECT_EQ(scan_capabilities.max_num_scan_plans,
kFakeMaxNumScanPlans);
EXPECT_EQ(scan_capabilities.max_scan_plan_interval,
kFakeMaxScanPlanIntervals);
EXPECT_EQ(scan_capabilities.max_scan_plan_iterations,
kFakeMaxScanPlanIterations);
} else {
EXPECT_EQ(scan_capabilities.max_num_scan_plans, (unsigned int) 0);
EXPECT_EQ(scan_capabilities.max_scan_plan_interval, (unsigned int) 0);
EXPECT_EQ(scan_capabilities.max_scan_plan_iterations, (unsigned int) 0);
}
}
void VerifyBandInfo(const BandInfo& band_info) {
vector<uint32_t> band_2g_expected = {kFakeFrequency1,
kFakeFrequency2, kFakeFrequency3};
vector<uint32_t> band_5g_expected = {kFakeFrequency4};
// Frequency5 is doesn't belong to a DFS channel. However, our convetion
// requires us to return any passive only channels in DFS band.
vector<uint32_t> band_dfs_expected = {kFakeFrequency5, kFakeFrequency6};
EXPECT_EQ(band_info.band_2g, band_2g_expected);
EXPECT_EQ(band_info.band_5g, band_5g_expected);
EXPECT_EQ(band_info.band_dfs, band_dfs_expected);
}
void VerifyWiphyFeatures(const WiphyFeatures& wiphy_features) {
EXPECT_TRUE(wiphy_features.supports_random_mac_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_random_mac_sched_scan);
}
} // namespace
// This mocks the behavior of SendMessageAndGetResponses(), which returns a
// vector of NL80211Packet using passed in pointer.
ACTION_P(MakeupResponse, response) {
// arg1 is the second parameter: vector<unique_ptr<const NL80211Packet>>* responses.
for (auto& pkt : response) {
arg1->push_back(unique_ptr<NL80211Packet>(new NL80211Packet(pkt)));
}
}
class NetlinkUtilsTest : public ::testing::Test {
protected:
std::unique_ptr<NiceMock<MockNetlinkManager>> netlink_manager_;
std::unique_ptr<NetlinkUtils> netlink_utils_;
virtual void SetUp() {
netlink_manager_.reset(new NiceMock<MockNetlinkManager>());
netlink_utils_.reset(new NetlinkUtils(netlink_manager_.get()));
ON_CALL(*netlink_manager_,
GetSequenceNumber()).WillByDefault(Return(kFakeSequenceNumber));
ON_CALL(*netlink_manager_,
GetFamilyId()).WillByDefault(Return(kFakeFamilyId));
}
void SetSplitWiphyDumpSupported(bool supported) {
netlink_utils_->supports_split_wiphy_dump_ = supported;
}
};
TEST_F(NetlinkUtilsTest, CanGetWiphyIndex) {
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
// Insert wiphy_index attribute.
NL80211Attr<uint32_t> wiphy_index_attr(NL80211_ATTR_WIPHY, kFakeWiphyIndex);
new_wiphy.AddAttribute(wiphy_index_attr);
// Mock a valid response from kernel.
vector<NL80211Packet> response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
uint32_t wiphy_index;
EXPECT_TRUE(netlink_utils_->GetWiphyIndex(&wiphy_index));
EXPECT_EQ(kFakeWiphyIndex, wiphy_index);
}
TEST_F(NetlinkUtilsTest, CanHandleGetWiphyIndexError) {
// Mock an error response from kernel.
vector<NL80211Packet> response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
uint32_t wiphy_index;
EXPECT_FALSE(netlink_utils_->GetWiphyIndex(&wiphy_index));
}
TEST_F(NetlinkUtilsTest, CanSetIntrerfaceMode) {
// Mock a ACK response from kernel.
vector<NL80211Packet> response = {CreateControlMessageAck()};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
EXPECT_TRUE(netlink_utils_->SetInterfaceMode(kFakeInterfaceIndex,
NetlinkUtils::STATION_MODE));
}
TEST_F(NetlinkUtilsTest, CanHandleSetIntrerfaceModeError) {
// Mock an error response from kernel.
vector<NL80211Packet> response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
EXPECT_FALSE(netlink_utils_->SetInterfaceMode(kFakeInterfaceIndex,
NetlinkUtils::STATION_MODE));
}
TEST_F(NetlinkUtilsTest, CanGetInterfaces) {
NL80211Packet new_interface(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_INTERFACE,
netlink_manager_->GetSequenceNumber(),
getpid());
// Insert interface name attribute.
NL80211Attr<string> if_name_attr(NL80211_ATTR_IFNAME, string(kFakeInterfaceName));
new_interface.AddAttribute(if_name_attr);
// Insert interface index attribute.
NL80211Attr<uint32_t> if_index_attr(NL80211_ATTR_IFINDEX, kFakeInterfaceIndex);
new_interface.AddAttribute(if_index_attr);
// Insert mac address attribute.
std::vector<uint8_t> if_mac_addr;
if_mac_addr.assign(
kFakeInterfaceMacAddress,
kFakeInterfaceMacAddress + sizeof(kFakeInterfaceMacAddress));
NL80211Attr<vector<uint8_t>> if_mac_attr(NL80211_ATTR_MAC, if_mac_addr);
new_interface.AddAttribute(if_mac_attr);
// Mock a valid response from kernel.
vector<NL80211Packet> response = {new_interface};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
vector<InterfaceInfo> interfaces;
EXPECT_TRUE(netlink_utils_->GetInterfaces(kFakeWiphyIndex, &interfaces));
EXPECT_TRUE(interfaces.size() == 1);
EXPECT_EQ(kFakeInterfaceIndex, interfaces[0].index);
EXPECT_EQ(string(kFakeInterfaceName), interfaces[0].name);
EXPECT_EQ(if_mac_addr, interfaces[0].mac_address);
}
TEST_F(NetlinkUtilsTest, SkipsPseudoDevicesWhenGetInterfaces) {
// This might be a psuedo p2p interface without any interface index/name
// attributes.
NL80211Packet psuedo_interface(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_INTERFACE,
netlink_manager_->GetSequenceNumber(),
getpid());
psuedo_interface.AddAttribute(NL80211Attr<uint64_t>(
NL80211_ATTR_WDEV, 0));
// This is a regular client interface.
NL80211Packet expected_interface(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_INTERFACE,
netlink_manager_->GetSequenceNumber(),
getpid());
expected_interface.AddAttribute(NL80211Attr<string>(
NL80211_ATTR_IFNAME, string(kFakeInterfaceName)));
expected_interface.AddAttribute(NL80211Attr<uint32_t>(
NL80211_ATTR_IFINDEX, kFakeInterfaceIndex));
std::vector<uint8_t> if_mac_addr;
if_mac_addr.assign(
kFakeInterfaceMacAddress,
kFakeInterfaceMacAddress + sizeof(kFakeInterfaceMacAddress));
expected_interface.AddAttribute(
NL80211Attr<vector<uint8_t>>(NL80211_ATTR_MAC, if_mac_addr));
// Kernel can send us the pseduo interface packet first
vector<NL80211Packet> response = {psuedo_interface, expected_interface};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
vector<InterfaceInfo> interfaces;
EXPECT_TRUE(netlink_utils_->GetInterfaces(kFakeWiphyIndex, &interfaces));
EXPECT_TRUE(interfaces.size() == 1);
EXPECT_EQ(kFakeInterfaceIndex, interfaces[0].index);
EXPECT_EQ(string(kFakeInterfaceName), interfaces[0].name);
EXPECT_EQ(if_mac_addr, interfaces[0].mac_address);
}
TEST_F(NetlinkUtilsTest, HandleP2p0WhenGetInterfaces) {
NL80211Packet new_interface(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_INTERFACE,
netlink_manager_->GetSequenceNumber(),
getpid());
// Insert interface name attribute.
NL80211Attr<string> if_name_attr(NL80211_ATTR_IFNAME, string(kFakeInterfaceName));
new_interface.AddAttribute(if_name_attr);
// Insert interface index attribute.
new_interface.AddAttribute(
NL80211Attr<uint32_t>(NL80211_ATTR_IFINDEX, kFakeInterfaceIndex));
// Insert mac address attribute.
std::vector<uint8_t> if_mac_addr(
kFakeInterfaceMacAddress,
kFakeInterfaceMacAddress + sizeof(kFakeInterfaceMacAddress));
new_interface.AddAttribute(
NL80211Attr<vector<uint8_t>>(NL80211_ATTR_MAC, if_mac_addr));
// Create a new interface packet for p2p0.
NL80211Packet new_interface_p2p0(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_INTERFACE,
netlink_manager_->GetSequenceNumber(),
getpid());
// Insert interface name attribute.
new_interface_p2p0.AddAttribute(
NL80211Attr<string>(NL80211_ATTR_IFNAME, "p2p0"));
// Insert interface index attribute.
new_interface_p2p0.AddAttribute(
NL80211Attr<uint32_t>(NL80211_ATTR_IFINDEX, kFakeInterfaceIndex1));
// Insert mac address attribute.
std::vector<uint8_t> if_mac_addr_p2p(
kFakeInterfaceMacAddress1,
kFakeInterfaceMacAddress1 + sizeof(kFakeInterfaceMacAddress1));
new_interface_p2p0.AddAttribute(
NL80211Attr<vector<uint8_t>>(NL80211_ATTR_MAC, if_mac_addr_p2p));
// Mock response from kernel, including 2 interfaces.
vector<NL80211Packet> response = {new_interface_p2p0, new_interface};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
vector<InterfaceInfo> interfaces;
EXPECT_TRUE(netlink_utils_->GetInterfaces(kFakeWiphyIndex, &interfaces));
EXPECT_TRUE(interfaces.size() == 2);
EXPECT_EQ(kFakeInterfaceIndex1, interfaces[0].index);
EXPECT_EQ(string("p2p0"), interfaces[0].name);
EXPECT_EQ(if_mac_addr_p2p, interfaces[0].mac_address);
EXPECT_EQ(kFakeInterfaceIndex, interfaces[1].index);
EXPECT_EQ(string(kFakeInterfaceName), interfaces[1].name);
EXPECT_EQ(if_mac_addr, interfaces[1].mac_address);
}
TEST_F(NetlinkUtilsTest, CanHandleGetInterfacesError) {
// Mock an error response from kernel.
vector<NL80211Packet> response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
vector<InterfaceInfo> interfaces;
EXPECT_FALSE(netlink_utils_->GetInterfaces(kFakeWiphyIndex, &interfaces));
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfo) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, true);
AppendWiphyFeaturesAttributes(&new_wiphy);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, true);
VerifyWiphyFeatures(wiphy_features);
EXPECT_FALSE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoWithNoDbsParam) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
AppendWiphyExtFeaturesAttributes(&new_wiphy, false, false, false, false);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
EXPECT_FALSE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoWithLowSpanScan) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
AppendWiphyExtFeaturesAttributes(&new_wiphy, true, false, false, false);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
EXPECT_TRUE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoWithLowPowerScan) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
AppendWiphyExtFeaturesAttributes(&new_wiphy, false, true, false, false);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
EXPECT_FALSE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_TRUE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoWithHighAccuracyScan) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
AppendWiphyExtFeaturesAttributes(&new_wiphy, false, false, true, false);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
EXPECT_FALSE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_FALSE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_TRUE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoWithAllDbsParams) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
AppendWiphyExtFeaturesAttributes(&new_wiphy, false, false, false, true);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
EXPECT_TRUE(wiphy_features.supports_low_span_oneshot_scan);
EXPECT_TRUE(wiphy_features.supports_low_power_oneshot_scan);
EXPECT_TRUE(wiphy_features.supports_high_accuracy_oneshot_scan);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoScanPlanNotSupported) {
SetSplitWiphyDumpSupported(false);
NL80211Packet new_wiphy(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
AppendBandInfoAttributes(&new_wiphy);
AppendScanCapabilitiesAttributes(&new_wiphy, false);
AppendWiphyFeaturesAttributes(&new_wiphy);
vector<NL80211Packet> get_wiphy_response = {new_wiphy};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
}
TEST_F(NetlinkUtilsTest, CanGetWiphyInfoSplitDump) {
SetSplitWiphyDumpSupported(true);
NL80211Packet new_wiphy_packet1(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy_packet1.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
new_wiphy_packet1.AddAttribute(GenerateBandsAttributeFor5gAndDfs());
NL80211Packet new_wiphy_packet2(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy_packet2.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex));
new_wiphy_packet2.AddAttribute(GenerateBandsAttributeFor2g());
AppendScanCapabilitiesAttributes(&new_wiphy_packet2, false);
AppendWiphyFeaturesAttributes(&new_wiphy_packet2);
// Insert a packet for wiphy with index kFakeWiphyIndex1.
// This is unrelated and should be ingnored by |GetWiphyInfo|.
NL80211Packet new_wiphy_packet3(
netlink_manager_->GetFamilyId(),
NL80211_CMD_NEW_WIPHY,
netlink_manager_->GetSequenceNumber(),
getpid());
new_wiphy_packet3.AddAttribute(NL80211Attr<uint32_t>(NL80211_ATTR_WIPHY,
kFakeWiphyIndex1));
AppendBandInfoAttributes(&new_wiphy_packet3);
vector<NL80211Packet> get_wiphy_response =
{new_wiphy_packet1, new_wiphy_packet2, new_wiphy_packet3};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_TRUE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
VerifyBandInfo(band_info);
VerifyScanCapabilities(scan_capabilities, false);
VerifyWiphyFeatures(wiphy_features);
}
TEST_F(NetlinkUtilsTest, CanHandleGetWiphyInfoError) {
SetSplitWiphyDumpSupported(false);
// Mock an error response from kernel.
vector<NL80211Packet> get_wiphy_response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(get_wiphy_response), Return(true)));
BandInfo band_info;
ScanCapabilities scan_capabilities;
WiphyFeatures wiphy_features;
EXPECT_FALSE(netlink_utils_->GetWiphyInfo(kFakeWiphyIndex,
&band_info,
&scan_capabilities,
&wiphy_features));
}
TEST_F(NetlinkUtilsTest, CanGetProtocolFeatures) {
// There is no specification for the response packet id for
// NL80211_CMD_GET_PROTOCOL_FEATURES.
// Still use NL80211_CMD_GET_PROTOCOL_FEATURES here.
NL80211Packet get_features_response(
netlink_manager_->GetFamilyId(),
NL80211_CMD_GET_PROTOCOL_FEATURES,
netlink_manager_->GetSequenceNumber(),
getpid());
get_features_response.AddAttribute(
NL80211Attr<uint32_t>(NL80211_ATTR_PROTOCOL_FEATURES,
kFakeProtocolFeatures));
vector<NL80211Packet> response = {get_features_response};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
uint32_t features;
EXPECT_TRUE(netlink_utils_->GetProtocolFeatures(&features));
EXPECT_EQ(kFakeProtocolFeatures, features);
}
TEST_F(NetlinkUtilsTest, CanHandleGetProtocolFeaturesError) {
// Mock an error response from kernel.
vector<NL80211Packet> response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
uint32_t features_ignored;
EXPECT_FALSE(netlink_utils_->GetProtocolFeatures(&features_ignored));
}
TEST_F(NetlinkUtilsTest, CanGetCountryCode) {
// There is no specification for the response packet id for
// NL80211_CMD_GET_REG.
// Still use NL80211_CMD_GET_REG here.
NL80211Packet get_country_code_response(
netlink_manager_->GetFamilyId(),
NL80211_CMD_GET_PROTOCOL_FEATURES,
netlink_manager_->GetSequenceNumber(),
getpid());
get_country_code_response.AddAttribute(
NL80211Attr<string>(NL80211_ATTR_REG_ALPHA2,
kFakeCountryCode));
vector<NL80211Packet> response = {get_country_code_response};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
string country_code;
EXPECT_TRUE(netlink_utils_->GetCountryCode(&country_code));
EXPECT_EQ(kFakeCountryCode, country_code);
}
TEST_F(NetlinkUtilsTest, CanHandleGetCountryCodeError) {
// Mock an error response from kernel.
vector<NL80211Packet> response = {CreateControlMessageError(kFakeErrorCode)};
EXPECT_CALL(*netlink_manager_, SendMessageAndGetResponses(_, _)).
WillOnce(DoAll(MakeupResponse(response), Return(true)));
string country_code_ignored;
EXPECT_FALSE(netlink_utils_->GetCountryCode(&country_code_ignored));
}
} // namespace wificond
} // namespace android