blob: 5784d83f6ca60e0b190a9c3cc14f52ce56ddd1be [file] [log] [blame]
// Copyright 2016 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/nqe/network_quality_estimator_params.h"
#include <stdint.h>
#include "base/strings/string_number_conversions.h"
#include "base/time/time.h"
namespace net {
const char kForceEffectiveConnectionType[] = "force_effective_connection_type";
const char kEffectiveConnectionTypeSlow2GOnCellular[] = "Slow-2G-On-Cellular";
const base::TimeDelta
kHttpRttEffectiveConnectionTypeThresholds[EFFECTIVE_CONNECTION_TYPE_LAST] =
{base::Milliseconds(0), base::Milliseconds(0),
base::Milliseconds(2010), base::Milliseconds(1420),
base::Milliseconds(272), base::Milliseconds(0)};
namespace {
// Minimum valid value of the variation parameter that holds RTT (in
// milliseconds) values.
static const int kMinimumRTTVariationParameterMsec = 1;
// Minimum valid value of the variation parameter that holds throughput (in
// kilobits per second) values.
static const int kMinimumThroughputVariationParameterKbps = 1;
// Returns the value of |parameter_name| read from |params|. If the
// value is unavailable from |params|, then |default_value| is returned.
int64_t GetValueForVariationParam(
const std::map<std::string, std::string>& params,
const std::string& parameter_name,
int64_t default_value) {
const auto it = params.find(parameter_name);
int64_t variations_value = default_value;
if (it != params.end() &&
base::StringToInt64(it->second, &variations_value)) {
return variations_value;
}
return default_value;
}
// Returns the variation value for |parameter_name|. If the value is
// unavailable, |default_value| is returned.
double GetDoubleValueForVariationParamWithDefaultValue(
const std::map<std::string, std::string>& params,
const std::string& parameter_name,
double default_value) {
const auto it = params.find(parameter_name);
if (it == params.end())
return default_value;
double variations_value = default_value;
if (!base::StringToDouble(it->second, &variations_value))
return default_value;
return variations_value;
}
// Returns the variation value for |parameter_name|. If the value is
// unavailable, |default_value| is returned.
std::string GetStringValueForVariationParamWithDefaultValue(
const std::map<std::string, std::string>& params,
const std::string& parameter_name,
const std::string& default_value) {
const auto it = params.find(parameter_name);
if (it == params.end())
return default_value;
return it->second;
}
double GetWeightMultiplierPerSecond(
const std::map<std::string, std::string>& params) {
// Default value of the half life (in seconds) for computing time weighted
// percentiles. Every half life, the weight of all observations reduces by
// half. Lowering the half life would reduce the weight of older values
// faster.
int half_life_seconds = 60;
int32_t variations_value = 0;
auto it = params.find("HalfLifeSeconds");
if (it != params.end() && base::StringToInt(it->second, &variations_value) &&
variations_value >= 1) {
half_life_seconds = variations_value;
}
DCHECK_GT(half_life_seconds, 0);
return pow(0.5, 1.0 / half_life_seconds);
}
bool GetPersistentCacheReadingEnabled(
const std::map<std::string, std::string>& params) {
if (GetStringValueForVariationParamWithDefaultValue(
params, "persistent_cache_reading_enabled", "true") != "true") {
return false;
}
return true;
}
base::TimeDelta GetMinSocketWatcherNotificationInterval(
const std::map<std::string, std::string>& params) {
// Use 1000 milliseconds as the default value.
return base::Milliseconds(GetValueForVariationParam(
params, "min_socket_watcher_notification_interval_msec", 1000));
}
// static
const char* GetNameForConnectionTypeInternal(
NetworkChangeNotifier::ConnectionType connection_type) {
switch (connection_type) {
case NetworkChangeNotifier::CONNECTION_UNKNOWN:
return "Unknown";
case NetworkChangeNotifier::CONNECTION_ETHERNET:
return "Ethernet";
case NetworkChangeNotifier::CONNECTION_WIFI:
return "WiFi";
case NetworkChangeNotifier::CONNECTION_2G:
return "2G";
case NetworkChangeNotifier::CONNECTION_3G:
return "3G";
case NetworkChangeNotifier::CONNECTION_4G:
return "4G";
case NetworkChangeNotifier::CONNECTION_5G:
return "5G";
case NetworkChangeNotifier::CONNECTION_NONE:
return "None";
case NetworkChangeNotifier::CONNECTION_BLUETOOTH:
return "Bluetooth";
}
return "";
}
// Sets the default observation for different connection types in
// |default_observations|. The default observations are different for
// different connection types (e.g., 2G, 3G, 4G, WiFi). The default
// observations may be used to determine the network quality in absence of any
// other information.
void ObtainDefaultObservations(
const std::map<std::string, std::string>& params,
nqe::internal::NetworkQuality default_observations[]) {
for (size_t i = 0; i < NetworkChangeNotifier::CONNECTION_LAST; ++i) {
DCHECK_EQ(nqe::internal::InvalidRTT(), default_observations[i].http_rtt());
DCHECK_EQ(nqe::internal::InvalidRTT(),
default_observations[i].transport_rtt());
DCHECK_EQ(nqe::internal::INVALID_RTT_THROUGHPUT,
default_observations[i].downstream_throughput_kbps());
}
// Default observations for HTTP RTT, transport RTT, and downstream throughput
// Kbps for the various connection types. These may be overridden by
// variations params. The default observation for a connection type
// corresponds to typical network quality for that connection type.
default_observations[NetworkChangeNotifier::CONNECTION_UNKNOWN] =
nqe::internal::NetworkQuality(base::Milliseconds(115),
base::Milliseconds(55), 1961);
default_observations[NetworkChangeNotifier::CONNECTION_ETHERNET] =
nqe::internal::NetworkQuality(base::Milliseconds(90),
base::Milliseconds(33), 1456);
default_observations[NetworkChangeNotifier::CONNECTION_WIFI] =
nqe::internal::NetworkQuality(base::Milliseconds(116),
base::Milliseconds(66), 2658);
default_observations[NetworkChangeNotifier::CONNECTION_2G] =
nqe::internal::NetworkQuality(base::Milliseconds(1726),
base::Milliseconds(1531), 74);
default_observations[NetworkChangeNotifier::CONNECTION_3G] =
nqe::internal::NetworkQuality(base::Milliseconds(273),
base::Milliseconds(209), 749);
default_observations[NetworkChangeNotifier::CONNECTION_4G] =
nqe::internal::NetworkQuality(base::Milliseconds(137),
base::Milliseconds(80), 1708);
default_observations[NetworkChangeNotifier::CONNECTION_NONE] =
nqe::internal::NetworkQuality(base::Milliseconds(163),
base::Milliseconds(83), 575);
default_observations[NetworkChangeNotifier::CONNECTION_BLUETOOTH] =
nqe::internal::NetworkQuality(base::Milliseconds(385),
base::Milliseconds(318), 476);
// Override using the values provided via variation params.
for (size_t i = 0; i <= NetworkChangeNotifier::CONNECTION_LAST; ++i) {
NetworkChangeNotifier::ConnectionType type =
static_cast<NetworkChangeNotifier::ConnectionType>(i);
int32_t variations_value = kMinimumRTTVariationParameterMsec - 1;
std::string parameter_name =
std::string(GetNameForConnectionTypeInternal(type))
.append(".DefaultMedianRTTMsec");
auto it = params.find(parameter_name);
if (it != params.end() &&
base::StringToInt(it->second, &variations_value) &&
variations_value >= kMinimumRTTVariationParameterMsec) {
default_observations[i] = nqe::internal::NetworkQuality(
base::Milliseconds(variations_value),
default_observations[i].transport_rtt(),
default_observations[i].downstream_throughput_kbps());
}
variations_value = kMinimumRTTVariationParameterMsec - 1;
parameter_name = std::string(GetNameForConnectionTypeInternal(type))
.append(".DefaultMedianTransportRTTMsec");
it = params.find(parameter_name);
if (it != params.end() &&
base::StringToInt(it->second, &variations_value) &&
variations_value >= kMinimumRTTVariationParameterMsec) {
default_observations[i] = nqe::internal::NetworkQuality(
default_observations[i].http_rtt(),
base::Milliseconds(variations_value),
default_observations[i].downstream_throughput_kbps());
}
variations_value = kMinimumThroughputVariationParameterKbps - 1;
parameter_name = std::string(GetNameForConnectionTypeInternal(type))
.append(".DefaultMedianKbps");
it = params.find(parameter_name);
if (it != params.end() &&
base::StringToInt(it->second, &variations_value) &&
variations_value >= kMinimumThroughputVariationParameterKbps) {
default_observations[i] = nqe::internal::NetworkQuality(
default_observations[i].http_rtt(),
default_observations[i].transport_rtt(), variations_value);
}
}
}
// Typical HTTP RTT value corresponding to a given WebEffectiveConnectionType
// value. Taken from
// https://cs.chromium.org/chromium/src/net/nqe/network_quality_estimator_params.cc.
const base::TimeDelta kTypicalHttpRttEffectiveConnectionType
[net::EFFECTIVE_CONNECTION_TYPE_LAST] = {
base::Milliseconds(0), base::Milliseconds(0),
base::Milliseconds(3600), base::Milliseconds(1800),
base::Milliseconds(450), base::Milliseconds(175)};
// Typical downlink throughput (in Mbps) value corresponding to a given
// WebEffectiveConnectionType value. Taken from
// https://cs.chromium.org/chromium/src/net/nqe/network_quality_estimator_params.cc.
const int32_t kTypicalDownlinkKbpsEffectiveConnectionType
[net::EFFECTIVE_CONNECTION_TYPE_LAST] = {0, 0, 40, 75, 400, 1600};
// Sets |typical_network_quality| to typical network quality for different
// effective connection types.
void ObtainTypicalNetworkQualities(
const std::map<std::string, std::string>& params,
nqe::internal::NetworkQuality typical_network_quality[]) {
for (size_t i = 0; i < EFFECTIVE_CONNECTION_TYPE_LAST; ++i) {
DCHECK_EQ(nqe::internal::InvalidRTT(),
typical_network_quality[i].http_rtt());
DCHECK_EQ(nqe::internal::InvalidRTT(),
typical_network_quality[i].transport_rtt());
DCHECK_EQ(nqe::internal::INVALID_RTT_THROUGHPUT,
typical_network_quality[i].downstream_throughput_kbps());
}
typical_network_quality[EFFECTIVE_CONNECTION_TYPE_SLOW_2G] =
nqe::internal::NetworkQuality(
// Set to the 77.5th percentile of 2G RTT observations on Android.
// This corresponds to the median RTT observation when effective
// connection type is Slow 2G.
kTypicalHttpRttEffectiveConnectionType
[EFFECTIVE_CONNECTION_TYPE_SLOW_2G],
base::Milliseconds(3000),
kTypicalDownlinkKbpsEffectiveConnectionType
[EFFECTIVE_CONNECTION_TYPE_SLOW_2G]);
typical_network_quality[EFFECTIVE_CONNECTION_TYPE_2G] =
nqe::internal::NetworkQuality(
// Set to the 58th percentile of 2G RTT observations on Android. This
// corresponds to the median RTT observation when effective connection
// type is 2G.
kTypicalHttpRttEffectiveConnectionType[EFFECTIVE_CONNECTION_TYPE_2G],
base::Milliseconds(1500),
kTypicalDownlinkKbpsEffectiveConnectionType
[EFFECTIVE_CONNECTION_TYPE_2G]);
typical_network_quality[EFFECTIVE_CONNECTION_TYPE_3G] =
nqe::internal::NetworkQuality(
// Set to the 75th percentile of 3G RTT observations on Android. This
// corresponds to the median RTT observation when effective connection
// type is 3G.
kTypicalHttpRttEffectiveConnectionType[EFFECTIVE_CONNECTION_TYPE_3G],
base::Milliseconds(400),
kTypicalDownlinkKbpsEffectiveConnectionType
[EFFECTIVE_CONNECTION_TYPE_3G]);
// Set to the 25th percentile of 3G RTT observations on Android.
typical_network_quality[EFFECTIVE_CONNECTION_TYPE_4G] =
nqe::internal::NetworkQuality(
kTypicalHttpRttEffectiveConnectionType[EFFECTIVE_CONNECTION_TYPE_4G],
base::Milliseconds(125),
kTypicalDownlinkKbpsEffectiveConnectionType
[EFFECTIVE_CONNECTION_TYPE_4G]);
static_assert(
EFFECTIVE_CONNECTION_TYPE_4G + 1 == EFFECTIVE_CONNECTION_TYPE_LAST,
"Missing effective connection type");
}
// Sets the thresholds for different effective connection types in
// |connection_thresholds|.
void ObtainConnectionThresholds(
const std::map<std::string, std::string>& params,
nqe::internal::NetworkQuality connection_thresholds[]) {
// First set the default thresholds.
nqe::internal::NetworkQuality default_effective_connection_type_thresholds
[EffectiveConnectionType::EFFECTIVE_CONNECTION_TYPE_LAST];
DCHECK_LT(base::TimeDelta(), kHttpRttEffectiveConnectionTypeThresholds
[EFFECTIVE_CONNECTION_TYPE_SLOW_2G]);
default_effective_connection_type_thresholds
[EFFECTIVE_CONNECTION_TYPE_SLOW_2G] = nqe::internal::NetworkQuality(
// Set to the 66th percentile of 2G RTT observations on Android.
kHttpRttEffectiveConnectionTypeThresholds
[EFFECTIVE_CONNECTION_TYPE_SLOW_2G],
nqe::internal::InvalidRTT(), nqe::internal::INVALID_RTT_THROUGHPUT);
DCHECK_LT(
base::TimeDelta(),
kHttpRttEffectiveConnectionTypeThresholds[EFFECTIVE_CONNECTION_TYPE_2G]);
default_effective_connection_type_thresholds[EFFECTIVE_CONNECTION_TYPE_2G] =
nqe::internal::NetworkQuality(
// Set to the 50th percentile of RTT observations on Android.
kHttpRttEffectiveConnectionTypeThresholds
[EFFECTIVE_CONNECTION_TYPE_2G],
nqe::internal::InvalidRTT(), nqe::internal::INVALID_RTT_THROUGHPUT);
DCHECK_LT(
base::TimeDelta(),
kHttpRttEffectiveConnectionTypeThresholds[EFFECTIVE_CONNECTION_TYPE_3G]);
default_effective_connection_type_thresholds[EFFECTIVE_CONNECTION_TYPE_3G] =
nqe::internal::NetworkQuality(
// Set to the 50th percentile of 3G RTT observations on Android.
kHttpRttEffectiveConnectionTypeThresholds
[EFFECTIVE_CONNECTION_TYPE_3G],
nqe::internal::InvalidRTT(), nqe::internal::INVALID_RTT_THROUGHPUT);
// Connection threshold should not be set for 4G effective connection type
// since it is the fastest.
static_assert(
EFFECTIVE_CONNECTION_TYPE_3G + 1 == EFFECTIVE_CONNECTION_TYPE_4G,
"Missing effective connection type");
static_assert(
EFFECTIVE_CONNECTION_TYPE_4G + 1 == EFFECTIVE_CONNECTION_TYPE_LAST,
"Missing effective connection type");
for (size_t i = 0; i <= EFFECTIVE_CONNECTION_TYPE_3G; ++i) {
EffectiveConnectionType effective_connection_type =
static_cast<EffectiveConnectionType>(i);
DCHECK_EQ(nqe::internal::InvalidRTT(), connection_thresholds[i].http_rtt());
DCHECK_EQ(nqe::internal::InvalidRTT(),
connection_thresholds[i].transport_rtt());
DCHECK_EQ(nqe::internal::INVALID_RTT_THROUGHPUT,
connection_thresholds[i].downstream_throughput_kbps());
if (effective_connection_type == EFFECTIVE_CONNECTION_TYPE_UNKNOWN)
continue;
std::string connection_type_name = std::string(
DeprecatedGetNameForEffectiveConnectionType(effective_connection_type));
connection_thresholds[i].set_http_rtt(
base::Milliseconds(GetValueForVariationParam(
params, connection_type_name + ".ThresholdMedianHttpRTTMsec",
default_effective_connection_type_thresholds[i]
.http_rtt()
.InMilliseconds())));
DCHECK_EQ(nqe::internal::InvalidRTT(),
default_effective_connection_type_thresholds[i].transport_rtt());
DCHECK_EQ(nqe::internal::INVALID_RTT_THROUGHPUT,
default_effective_connection_type_thresholds[i]
.downstream_throughput_kbps());
DCHECK(i == 0 ||
connection_thresholds[i].IsFaster(connection_thresholds[i - 1]));
}
}
std::string GetForcedEffectiveConnectionTypeString(
const std::map<std::string, std::string>& params) {
return GetStringValueForVariationParamWithDefaultValue(
params, kForceEffectiveConnectionType, "");
}
bool GetForcedEffectiveConnectionTypeOnCellularOnly(
const std::map<std::string, std::string>& params) {
return GetForcedEffectiveConnectionTypeString(params) ==
kEffectiveConnectionTypeSlow2GOnCellular;
}
std::optional<EffectiveConnectionType> GetInitForcedEffectiveConnectionType(
const std::map<std::string, std::string>& params) {
if (GetForcedEffectiveConnectionTypeOnCellularOnly(params)) {
return std::nullopt;
}
std::string forced_value = GetForcedEffectiveConnectionTypeString(params);
std::optional<EffectiveConnectionType> ect =
GetEffectiveConnectionTypeForName(forced_value);
DCHECK(forced_value.empty() || ect);
return ect;
}
} // namespace
NetworkQualityEstimatorParams::NetworkQualityEstimatorParams(
const std::map<std::string, std::string>& params)
: params_(params),
throughput_min_requests_in_flight_(
GetValueForVariationParam(params_,
"throughput_min_requests_in_flight",
5)),
throughput_min_transfer_size_kilobytes_(
GetValueForVariationParam(params_,
"throughput_min_transfer_size_kilobytes",
32)),
throughput_hanging_requests_cwnd_size_multiplier_(
GetDoubleValueForVariationParamWithDefaultValue(
params_,
"throughput_hanging_requests_cwnd_size_multiplier",
1)),
weight_multiplier_per_second_(GetWeightMultiplierPerSecond(params_)),
forced_effective_connection_type_(
GetInitForcedEffectiveConnectionType(params_)),
forced_effective_connection_type_on_cellular_only_(
GetForcedEffectiveConnectionTypeOnCellularOnly(params_)),
persistent_cache_reading_enabled_(
GetPersistentCacheReadingEnabled(params_)),
min_socket_watcher_notification_interval_(
GetMinSocketWatcherNotificationInterval(params_)),
upper_bound_http_rtt_endtoend_rtt_multiplier_(
GetDoubleValueForVariationParamWithDefaultValue(
params_,
"upper_bound_http_rtt_endtoend_rtt_multiplier",
3.0)),
hanging_request_http_rtt_upper_bound_transport_rtt_multiplier_(
GetValueForVariationParam(
params_,
"hanging_request_http_rtt_upper_bound_transport_rtt_multiplier",
8)),
hanging_request_http_rtt_upper_bound_http_rtt_multiplier_(
GetValueForVariationParam(
params_,
"hanging_request_http_rtt_upper_bound_http_rtt_multiplier",
6)),
http_rtt_transport_rtt_min_count_(
GetValueForVariationParam(params_,
"http_rtt_transport_rtt_min_count",
5)),
increase_in_transport_rtt_logging_interval_(
base::Milliseconds(GetDoubleValueForVariationParamWithDefaultValue(
params_,
"increase_in_transport_rtt_logging_interval",
10000))),
recent_time_threshold_(
base::Milliseconds(GetDoubleValueForVariationParamWithDefaultValue(
params_,
"recent_time_threshold",
5000))),
historical_time_threshold_(
base::Milliseconds(GetDoubleValueForVariationParamWithDefaultValue(
params_,
"historical_time_threshold",
60000))),
hanging_request_duration_http_rtt_multiplier_(GetValueForVariationParam(
params_,
"hanging_request_duration_http_rtt_multiplier",
5)),
add_default_platform_observations_(
GetStringValueForVariationParamWithDefaultValue(
params_,
"add_default_platform_observations",
"true") == "true"),
socket_watchers_min_notification_interval_(
base::Milliseconds(GetValueForVariationParam(
params_,
"socket_watchers_min_notification_interval_msec",
200))),
upper_bound_typical_kbps_multiplier_(
GetDoubleValueForVariationParamWithDefaultValue(
params_,
"upper_bound_typical_kbps_multiplier",
3.5)),
adjust_rtt_based_on_rtt_counts_(
GetStringValueForVariationParamWithDefaultValue(
params_,
"adjust_rtt_based_on_rtt_counts",
"false") == "true") {
DCHECK(hanging_request_http_rtt_upper_bound_transport_rtt_multiplier_ == -1 ||
hanging_request_http_rtt_upper_bound_transport_rtt_multiplier_ > 0);
DCHECK(hanging_request_http_rtt_upper_bound_http_rtt_multiplier_ == -1 ||
hanging_request_http_rtt_upper_bound_http_rtt_multiplier_ > 0);
DCHECK(hanging_request_http_rtt_upper_bound_transport_rtt_multiplier_ == -1 ||
hanging_request_http_rtt_upper_bound_http_rtt_multiplier_ == -1 ||
hanging_request_http_rtt_upper_bound_transport_rtt_multiplier_ >=
hanging_request_http_rtt_upper_bound_http_rtt_multiplier_);
DCHECK_LT(0, hanging_request_duration_http_rtt_multiplier());
DCHECK_LT(0, hanging_request_http_rtt_upper_bound_http_rtt_multiplier());
DCHECK_LT(0, hanging_request_http_rtt_upper_bound_transport_rtt_multiplier());
ObtainDefaultObservations(params_, default_observations_);
ObtainTypicalNetworkQualities(params_, typical_network_quality_);
ObtainConnectionThresholds(params_, connection_thresholds_);
}
NetworkQualityEstimatorParams::~NetworkQualityEstimatorParams() = default;
void NetworkQualityEstimatorParams::SetUseSmallResponsesForTesting(
bool use_small_responses) {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
use_small_responses_ = use_small_responses;
}
bool NetworkQualityEstimatorParams::use_small_responses() const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
return use_small_responses_;
}
// static
base::TimeDelta NetworkQualityEstimatorParams::GetDefaultTypicalHttpRtt(
EffectiveConnectionType effective_connection_type) {
return kTypicalHttpRttEffectiveConnectionType[effective_connection_type];
}
// static
int32_t NetworkQualityEstimatorParams::GetDefaultTypicalDownlinkKbps(
EffectiveConnectionType effective_connection_type) {
return kTypicalDownlinkKbpsEffectiveConnectionType[effective_connection_type];
}
void NetworkQualityEstimatorParams::SetForcedEffectiveConnectionTypeForTesting(
EffectiveConnectionType type) {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
DCHECK(!forced_effective_connection_type_on_cellular_only_);
forced_effective_connection_type_ = type;
}
std::optional<EffectiveConnectionType>
NetworkQualityEstimatorParams::GetForcedEffectiveConnectionType(
NetworkChangeNotifier::ConnectionType connection_type) {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
if (forced_effective_connection_type_) {
return forced_effective_connection_type_;
}
if (forced_effective_connection_type_on_cellular_only_ &&
net::NetworkChangeNotifier::IsConnectionCellular(connection_type)) {
return EFFECTIVE_CONNECTION_TYPE_SLOW_2G;
}
return std::nullopt;
}
size_t NetworkQualityEstimatorParams::throughput_min_requests_in_flight()
const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
// If |use_small_responses_| is set to true for testing, then consider one
// request as sufficient for taking throughput sample.
return use_small_responses_ ? 1 : throughput_min_requests_in_flight_;
}
int64_t NetworkQualityEstimatorParams::GetThroughputMinTransferSizeBits()
const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
return static_cast<int64_t>(throughput_min_transfer_size_kilobytes_) * 8 *
1000;
}
const nqe::internal::NetworkQuality&
NetworkQualityEstimatorParams::DefaultObservation(
NetworkChangeNotifier::ConnectionType type) const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
return default_observations_[type];
}
const nqe::internal::NetworkQuality&
NetworkQualityEstimatorParams::TypicalNetworkQuality(
EffectiveConnectionType type) const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
return typical_network_quality_[type];
}
const nqe::internal::NetworkQuality&
NetworkQualityEstimatorParams::ConnectionThreshold(
EffectiveConnectionType type) const {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
return connection_thresholds_[type];
}
} // namespace net